Download Antiparasitic Chemotherapy for Human and Veterinary Use 3rd

3rd COST ACTION CM1307 CONFERENCE ● SOCEPA ● SEFIG Antiparasitic Chemotherapy for Human and Veterinary Use 3rd COST Action CM1307 Conference / SOCEPA / SEFIG Joint Meeting & WG2 and WG3 Meeting October 24‐26, 2016 Madrid, Spain 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
COST Action CM1307
Chemotherapy towards diseases caused by
endoparasites: Antiparasitic Chemotherapy for
Human and Veterinary Use
3rd COST Action CM1307 Conference
/ SOCEPA / SEFIG Joint Meeting
& WG2 and WG3 Meeting
October 24-26, 2016
Madrid, Spain
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 1 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
The Joint COST Action CM1307 3rd Conference / Sociedad Española de
Parasitología (SOCEPA) / Sociedad Española de Farmacia Industrial y
Galénica (SEFIG)/ WG2 and WG3 Meeting has been organized by the UCM
Research Group ICPVet, Faculty of Veterinary Medicine, Universidad
Complutense de Madrid, Madrid, Spain. Conference and WG2 and WG3 will be
held in the Hotel Tryp Chamartín, Calle Mauricio Ravel 10, 28046 Madrid
(http://www.melia.com/en/hotels/spain/madrid/tryp-madrid-chamartinhotel/index.html).
This meeting is focused on different topics covering the scope of the COST
Action CM1307. Invited conferences and talks have been organized in several
sessions:

Molecules and targets I

Molecules and targets II

Molecules and targets III

Molecules and targets IV

Natural products

Drug delivery I

Drug delivery II

Drug delivery III

Screening models

Chemotherapy of parasitic diseases in human and veterinary medicine
The meeting also includes posters and a round table discussion at the end of
the 3rd Conference COST CM1307/SEFIG/SOCEPA meeting.
The meeting will be followed by the meetings of working groups WG2
(Medicinal Chemistry) and WG3 (Natural products) and the meeting of
Management Committee of the COST Action.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 2 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Scientific Committee
Philippe M. Loiseau (University of Paris-SUD-CNRS, France)
R. Luise Krauth-Siegel (University of Heidelberg, Germany)
Harry P. de Koning (University of Glasgow, United Kingdom)
M. Paola Costi (University of Modena and Reggio Emilia, Italy)
Tomaž Šolmajer (University of Ljubljana, Slovenia)
Vassilios Roussis (National and Kapodistrian University of Athens, Greece)
Thomas J. Schmidt (University of Münster, Germany)
Francisco J. Otero-Espinar (University of Santiago de Compostela, Spain)
Fred Opperdoes (De Duve Institute, Belgium)
Ana Tomás (University of Porto, Portugal)
Juan M. Irache (University of Navarra, Spain)
Organizing Committee
María Jesús Corral (University Complutense of Madrid, Spain)
Ana Isabel Olías-Molero (University Complutense of Madrid, Spain)
M. Dolores Jiménez-Antón (University Complutense of Madrid, Spain)
Alberto Gutiérrez-Dionisio (University Complutense of Madrid, Spain)
José María Alunda (University Complutense of Madrid, Spain)
Philippe M. Loiseau (University of Paris-SUD-CNRS, France)
Sponsors
The meeting has been sponsored by the Universidad Complutense of
Madrid, SOCEPA and the Colegio de Veterinarios de Madrid (Colvema).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 3 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 4 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Scientific Programme
October 23rd
18:30 Get-together meeting: cocktail –“vino español”
October 24th
OPENING OF THE CONFERENCE
9:00
Otero-Espinar F.J., President SEFIG
Valladares B., President SOCEPA
Loiseau P.M., Chair COST Action CM1307
OPENING LECTURE
9:20 Descoteaux A., INRS- Institut Armand-Frappier, Laval, Canada (COST invited
speaker)
Leishmania targets the host cell membrane fusion machinery to modulate
immune responses
MOLECULES AND TARGETS I
Chairpersons A. Descoteaux, A. Tomas
10:00 Loiseau P.M., University of Paris-Sud, France
Design of antileishmanial agents targeting host cell vesicular trafficking
10:20 Pomel S., University of Paris-Sud, France
GDP-mannose pyrophosphorylase: a therapeutic target for the selection of new
specific antileishmanial agents
10:40 Mangalagiu I.I., Alexandru Ioan Cuza University of Iasi, Romania
New azaheterocycles derivatives of potential interest in leishmaniasis
11:00 Stevanović S., University of Belgrade, Serbia
Design of novel NADH dehydrogenase inhibitors as antileishmanial agents
11:20-11:50 Coffee break and poster viewing
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 5 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS II
Chairpersons E. Davioud-Charvet, R. Leurs
11:50 Kivrak A., Yuzuncu Yil University, Turkey
Synthesis of novel thienocarbazole derivatives via intramolecular cyclization
reactions
12:10 Botta M., University of Siena, Italy
New promising targets vs neglected Tropical Diseases (Leishmaniasis and
Trypanosomiasis)
12:30 García-Sosa A.T., University of Tartu, Estonia
Designing inhibitors with pan-activity and poly-pharmacology for neglected
diseases and parasites
12:50-14:00 Lunch and poster viewing
MOLECULES AND TARGETS III
Chairpersons H. de Koning, F. Opperdoes
14:00 Krauth-Siegel R.L., Biochemie-Zentrum der Universität Heidelberg, Germany
Small redoxins as target molecules in antitrypanosomal drug development
14:20 Leurs R., VU University Amsterdam, The Netherlands
Phosphodiesterase inhibitors as a potential treatment for Neglected Parasitic
Diseases
14:40 Dardonville C., Instituto de Química Médica IQM-CSIC, Spain
Targeting trypanosome alternative oxidase (TAO) inhibitors to mitochondria:
original targeting for a unique target
15:00 Davioud-Charvet E., University of Strasbourg, France
Repurposing and old anti-arthritis golden drug, auranofin, and its anticancer
GoPi-sugar surrogate for the treatment of human parasitic diseases: from
Leishmania to
helminth infections
15:20-15:40 Coffee break and poster viewing
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 6 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS IV
Chairpersons R.L. Krauth-Siegel, P. Loiseau
15:40 de Koning H.P., University of Glasgow, United Kingdom
Trypanocydal action of bisphosphonium salts through a mitochondrial target in
bloodstream form of Trypanosoma brucei
16:00 Mukherjee B., University of Geneva, Switzerland
Structure-function relationships of Toxoplasma gondii aspartyl protease 3
16:20 Doligalska M., University of Warsaw, Poland
On the way to find a cure for infection with Babesia microti
16:40 de Koning H.P., University of Glasgow, United Kingdom
Potential antischistosomal activity of PDE inhibitors using in vitro Schistosoma
mansoni worm killing
17:00 Leontovyč A., The Czech Academy of Sciences, Czech Republic
Secreted serine protease SmSP2 of the blood fluke Schistosoma mansoni:
biochemical characterization, localization and host protein processing
17:20 Cordeiro-da-Silva A., I3S, IBMC, University of Porto, Portugal
Trypanosomatid ribose 5-phosphate isomerase structures and fragment
screening revels novel lead compound series
17:40 Free time*
*18:00: Walking free tour: a visit to monumental Madrid
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 7 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
October 25th
NATURAL PRODUCTS
Chairpersons T.J. Schmidt, V. Roussis
09:00 Schmidt T.J., University of Münster, Germany
European box tree (Buxus sempervirens L.) contains alkaloids with potent and
selective anti-protozoal activity
09:20 Biedermann D., The Czech Academy of Sciences, Czech Republic
The effect of flavonolignans on the Mesocestoides vogae (Cestoda) tetrathyridia
09:40 Gemma S., University of Siena, Italy
From the natural compound dihydroplakortin to synthetic bicyclic and bridged
endoperoxides active against chloroquine-sensitive and chloroquine-resistant
Plasmodium falciparum parasites
10:00 Ebiloma G.U., University of Glasgow, United Kingdom
Antiprotozoal compounds from Nigerian medicinal plants: identification and
mode-of-action studies
DRUG DELIVERY I
Chairpersons P. Couvreur, J.J. Torrado
10:20 Couvreur P., University of Paris-Sud, France (COST Invited speaker)
Nanotechnologies for the treatment of severe diseases
11:00-11:20 Coffee break and poster viewing
DRUG DELIVERY II
Chairpersons P. Couvreur, J.J. Torrado
11:20 Otero-Espinar F.J., University of Santiago de Compostela, Spain (SEFIG
sponsored speaker)
Development and in vivo efficacy of biocompatible drug-loaded microspheres
against Cryptosporidium parvum
11:40 Serrano D.R., University Complutense of Madrid, Spain
Is the oral delivery of Amphotericin B possible to treat parasitic diseases?
12:00 Lopes F., University of Lisbon, Portugal
Nanoencapsulation of tetraoxane-based double drugs with antileishmanial
activity
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 8 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
DRUG DELIVERY III
Chairpersons F.J. Otero-Espinar, L. Maes
12:20 Golenser J., The Hebrew University of Jerusalem, Israel
Inhibition of Schistosoma mansoni development in mice by slow release of
artemisone
12:40 Ucisik M.H., Istanbul Medipol University, Turkey
Emulsomes: A tool for delivery of anti-leishmanial BNIP derivatives to
macrophages
13:00 Torrado J.J., University Complutense of Madrid, Spain (SEFIG sponsored
speaker)
Cyclodextrins in antiparasitic drug formulations
13:30-14:30. Lunch and poster viewing
SCREENING MODELS
Chairpersons C.R. Caffrey, T. Solmajer
14:30 Caffrey C.R., University of California San Diego, USA
An automated screening technology for the schistosome helminth parasite
14:50 Hendrickx S., University of Antwerp, Belgium
In vitro “time-to-kill” assay to assess the cidal activity dynamics of current
reference drugs against Leishmania donovani and L.infantum
15:10 Caljon G., University of Antwerp, Belgium
Is it important to include the insect vector to evaluate the potential of a drug?
EMERGING ISSUES
Chairpersons M.P. Costi, J.Mª Alunda
15:30 Vivancos V., University Miguel Hernández Elche, Spain (SEFIG sponsored
speaker)
Drug absorption modifications in giardiasis
15:50 Costi M.P., University of Modena and Reggio Emilia, Italy
Fragment-based drug discovery fosters the identification of new leads against
Trypanosoma brucei PTR1
16:10-16:30. Coffee break and poster viewing
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 9 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
CHEMOTHERAPY OF PARASITIC DISEASES IN HUMAN AND VETERINARY
MEDICINE
Chairpersons K. Pfister, J.M. Harrington
16:30 Pfister K., LMU Munich, Germany (COST invited speaker)
Anti-parasitic treatment in veterinary medicine: a big challenge..!
17:10 Harrington J.M., Merial Inc., USA
Past, present and future of endoparasiticides at Merial
17:50-19:00. Round table discussion: Resistance, therapeutic failure and beyond
Moderator F. Gamarro, Instituto de Parasitologia y Biomedicina López-Neyra, CSIC
(IPBLN-CSIC), Granada, Spain
Pfister K., LMU Munich, Germany
Maes L., University of Antwerp, Belgium
Hervás P., Veterindustria, Spain
Alunda J.M., University Complutense of Madrid, Spain
Loiseau P.M., University of Paris-Sud, France
Otero Espinar F.J., SEFIG, University of Santiago de Compostela, Spain
López Medrano F., Hospital 12 de Octubre Madrid, Spain
Harrington J.M., Merial Inc, USA
Selzer P., Boehringer Ingelheim Animal Health, Germany
19:00 Concluding remarks and closure of the annual plenary COST CM1307
Conference and Joint meeting with SEFIG and SOCEPA
20:30 Gala dinner
Restaurante “La Chalana”
Paseo de la Castellana, 179
Madrid 28015
October 26th
9:00-12:00
Meetings of the COST Working groups WG2 (Medicinal Chemistry) and
WG3 (Natural products). Separate meetings and common discussion.
12:00-12:45
Quick lunch for WG participants and MC members
12:45-14:30
COST Management Committee meeting (only for MC members and
MC substitutes)
14:30
Farewell
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 10 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Poster Outline (24th & 25th October 2016)
P.1. Palmieri N., University of Tartu, Estonia
Identification of protein kinase inhibitors in Cystoisospora suis by genomic-based virtual
screening
P.2. Vasilache V., Alexandru Ioan Cuza University of Iasi, Romania
New bis-pyridazine derivatives of potential interest in leishmaniasis
P.3. Sarlauskas J., Vilnius University, Lithuania
Preliminary in vitro studies of antiprotozoal activity of some heterocyclic N-oxides and
N,N’-dioxides
P.4. Horn M., The Czech Academy of Sciences, Czech Republic
Structural basis for vinyl sulfone inhibition of the SmCB1 drug target from the human
blood fluke
P.5. Gomes-Alves A.G., I3S, IBMC, University of Porto, University of Minho, Portugal
Anti-Leishmania activity of a series of Quinolin-4(1H)-imines
P.6. Gil C., Centro de Investigaciones Biológicas, CSIC, Spain
Development of new quinone derivatives against Leishmania
P.7. Natto M.J., University of Glasgow, United Kingdom
Molecular characterisation and cloning of Novel Equilibrative Nucleoside Transporter
family members in Trichomonas vaginalis
P.8. Peric M., University of Zagreb, Croatia
Anti-Toxoplasma activity of novel macrolide hybrid derivatives
P.9. Loiseau P.M., University of Paris-Sud, France
Anti-malarial combination therapy: synergistic effect between an antisense strategy and
different antimalarial drugs in resistant strains of Plamodium falciparum
P.10. Gil C., Centro de Investigaciones Biológicas, CSIC, Spain
Drug repurposing of human kinase inhibitors as new hits against Leishmania
P.11. Baltas M., CNRS, University Paul Sabatier, France
Microwave-assisted and conventional 1,3-dipolar cycloaddition reactions to the
synthesis of some benzimidazole/(benzo)indolizine hybrids: a comparative study
P.12. André-Barrès C., CNRS, University Paul Sabatier, France
DFT studies of autoxidation of 2-alkylidene-1,3-cyclohaxadione leading to bicyclichemiketal endoperoxides
P.13. Calogeropoulou T., National Hellenic Research Foundation, Greece
Dinitroaniline-Ether Phospholipid Hybrids
P.14. Castro G., University of Porto, Portugal
In vitro anti-parasitic activity of marine cyanobacterial extracts against Leishmania,
Giardia and Trichomonas
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 11 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.15. Dea-Ayuela M.A., University CEU Cardenal Herrera, Spain
Efficacy of oral and parenteral Amphotericin B systems against experimental
Trypanosoma cruzi infection
P.16. Serrano D.R., University Complutense of Madrid, Spain
Oral Nanomedicines for Chagas Disease
P.17. Fernández R., University Complutense of Madrid, Spain
Effect of the aggregation state of Amphotericin B on red blood cells
P.18. Alunda J.M., University Complutense of Madrid, Spain
Antiparasitic chemotherapy in veterinary medicine: challenges, hurdles and
opportunities
P.19. Espuelas S., University of Navarra, Spain
Early preclinical studies of new selenocyanate and diselenide compounds as
leishmanicidal agents
P.20. Espuelas S., University of Navarra, Spain
Topical treatment of CL with paromomycin and anti-TNF-α antibodies: efficacy study in
L.major infected BALB/c mice
P.21. Bautista L., University Complutense of Madrid, Spain
Novel oral formulations of Active Hexose Correlated Compound (AHCC) and their
antiparasitic activity in an in vivo model
P.22. Roussis V., National and Kapodistrian University of Athens, Greece
In vitro activity evaluation of marine metabolites against bloodstream forms of
Trypanosoma brucei
P.23. Gamarro F., Instituto de Parasitología y Biomedicina López-Neyra, CSIC
(IPBLN-CSIC), Granada, Spain
Influence of glutathione and antimony in the ATPase activity of Leishmania LABCG2
transporter
P.24. Costi M.P., University of Modena and Reggio Emilia, Italy
The NMTRyPI - New Medicines for Trypanosomatidic Infections – drug discovery
platform
P.25. Gandhi H., University College Cork, Ireland
Modelling, synthesis and evaluation of novel quinine analogues-new drugs for Chagas
disease
P.26. Boije af Gennäs G., University of Helsinki, Finland
Membrane-bound pyrophosphatases – A novel approach to target pathogenic
protozoan parasite
P.27. Costi M.P., University of Modena and Reggio Emilia, Italy
Synergy activities on Neglected Tropical Diseases drug discovery within FP7 EU
context
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 12 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
OPENING LECTURE
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 13 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 14 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Leishmania targets the host cell membrane fusion machinery to
modulate immune responses
Albert Descoteaux
INRS- Institut Armand-Frappier, Laval, QC, Canada
Successful vacuolar pathogens have developed sophisticated strategies to hijack
the endomembrane system of host cells and evade antimicrobial responses. The
protozoan parasite Leishmania, the causative agent of leishmaniases in humans, is
particularly adept at transforming the macrophage into a hospitable host cell. As they
establish within phagocytes, Leishmania promastigotes release molecules that
sabotage host cell microbicidal and immune functions. Lipophosphoglycan (LPG) and
GP63 are two virulence factors involved in this process. Hence, we previously
established that insertion of LPG from L. donovani promastigotes into host cell lipid
microdomains causes remodeling of the parasitophorous vacuole, delays its maturation
into a highly microbicidal phagolysosome, and prevents recruitment of the v-ATPase.
We also discovered that the surface metalloprotease GP63 enables Leishmania
promastigotes to target the macrophage membrane fusion machinery, to create an
intracellular compartment favorable to the establishment of infection and to manipulate
host immune responses. To achieve this, LPG and GP63 must traffic from the
parasitophorous vacuole to the cytoplasm. We obtained evidence that the mechanism
associated to this trafficking process involves the host cell endoplasmic reticulum-Golgi
intermediate compartment. Collectively, these studies provide insights into the
mechanisms of Leishmania pathogenesis.
Supported by the Canadian Institutes of Health Research
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 15 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 16 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS I
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 17 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 18 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Anti-malarial combination therapy: synergistic effect between
an antisense strategy and different anti-malarial drugs in
resistant strains of Plasmodium falciparum
Soulaf Suyyagh-Albouz1, Fernanda Bruxel2, Nicolas Tsapis3, Elias Fattal3,
Philippe Loiseau1, Helder Teixeira4, Sandrine Cojean1,5.
1
Université Paris-Sud, UMR 8076 BioCIS CNRS, LabEx LERMIT, Châtenay-Malabry ;
Universidade Federal do Pampa, Brésil; 3 Université Paris-Sud, UMR 8612 institut Galien Paris
Sud, CNRS, Châtenay-Malabry; 4 Universidade Rio Grande do Sul, Porto Alegre, Brésil ; 5 CNR
Paludisme, Hôpital Bichat Claude Bernard, Paris
2
In these days, only the Artemisinin-based Combination Therapy still effective in
fighting malaria. But a threat exists in these associations due to the emergence of
resistance to artemisinin derivatives in Southeast Asia. Which could lead to a restriction
in used anti-malarial drugs as increasing doses is limited to avoid toxicity.
Antisense strategies represent a promising new therapeutic approach targeting
nucleic acids. Antisense oligonucleotides (ODN) may be employed to treat malaria.
Their limitations were mainly their low intracellular penetration to their target and their
rapid degradation. New generations of vectors have helped to enhance the effects of
ODN with reduced toxicity. During our studies, we have developed a cationic
nanoemulsion (NE) in order to adsorb ODN directed against the topoisomerase II of
Plasmodium falciparum. This NE/ODN allowed the inhibition of parasite growth.
To develop a combination therapy, some anti-malarial drugs, whose resistances are
proven, were associated with the NE/ODN. We tested our NE/ODN in combination with
chloroquine, atovaquone and dihydroartemisinin on the 3D7 strain sensitive to all antimalarial drugs, the W2 strain resistant to chloroquine and PAV strain resistant to
atovaquone. A synergistic effect, no matter which anti-malarial drug was associated
with the NE –ODN, was observed. There was also a limited reinfection in presence of
the different combinations even in the resistant strains.
Our perspective is to encapsulate the atovaquone inside the NE/ODN due to its
lipophilic properties in order to prevent or reverse the resistance, and reduce the dose
used by increasing the bioavailability of atovaquone.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 19 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
GDP-mannose Pyrophosphorylase: a therapeutic target for the
selection of new specific antileishmanial agents
W. Mao 1, P.Daligaux 1, N.Lazar 2, C.Cavé 1, H.van Tilbeurgh 2, P.M.Loiseau 1
and S.Pomel 1
1
Université Paris-Sud, Faculté de Phamarcie, UMR CNRS 8076 BioCIS, Châtenay-Malabry
2
Université Paris-Sud, UMR CNRS 9198, Institut de Biologie Intégrative de la Cellule
E-mail: [email protected]
Leishmaniases are neglected tropical diseases caused by the protozoan parasite
belonging to the genus Leishmania, and transmitted by an insect vector, the sandfly.
Currently, about 350 million people are threatened in 88 countries by leishmaniases,
with around 2 million new cases each year. The few existing treatments are very limited
because of their cost, toxicity, besides increasing problems of drug resistance. In this
context, the development of new antileishmanial drugs specifically directed against a
therapeutic target becomes crucial. The GDP-Mannose Pyrophosphorylase (GDP-MP)
has been validated as a promising therapeutic target since it was previously shown to
be essential for parasite survival in macrophages both in vitro and in vivo. In this work,
recombinant GDP-MPs from human and three Leishmania species responsible for
either the visceral (L. donovani) or the cutaneous (L. mexicana) form of leishmaniasis
were produced and purified in order to determine and compare their enzymatic
properties. Previous comparative molecular modelling and docking analyses of human
and leishmanial GDP-MPs allowed to design and synthesize 100 compounds derivated
from the substrate GDP-mannose. The activity of these compounds was evaluated on
the purified enzymes as well as on axenic and intramacrophage amastigotes of L.
donovani and L. mexicana. Two compounds presented promising activities on both the
purified enzymes and the parasites. Further crystallization studies will allow to
determine new pharmacomodulations in order to improve the affinity and specificity of
the compounds for the leishmanial GDP-MPs.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 20 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
New azaheterocycles derivatives of potential interest in
leishmaniasis
Ionel I. Mangalagiu
“Alexandru Ioan Cuza” University of Iasi, Faculty of Chemistry, Bd. Carol 11, 700506 Iasi,
Romania.
E-mail: [email protected]
Nitrogen derivatives are “privileged structures” in drug design, optoelectronics, etc.,
the azaheterocycle scaffold being a core skeleton for multiple purposes.
Imidazoquinolines (IMQ), especially imiquimod, resiquimod and gardiquimod,
represent a class of drugs used in cutaneous leishmaniasis, several mechanisms being
described for their antileishmania activity: directly activate macrophages , TLR7 and/or
TLR8 agonists, etc. On the other hand, pentamide is a second-line drug largely used in
leishmaniasis.
The emphasis of this work consist in design, synthesis and characterization of new
azaheterocycles derivatives of potential interest in leishmaniasis.
Acknowledgements. Authors are thankful to COST Action CM1307 and to CNCS Bucharest,
Romania, project PN-II-DE-PCE-2011-3-0038, no. 268/05.10.2011, for financial support.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 21 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Design of novel NADH dehydrogenase inhibitors as
antileishmanial agents
Strahinja Stevanović1, Andrej Perdih2, Sanja Glišić1, Tomaž Šolmajer2
1
Center of Multidisciplinary Research, Institute of Nuclear Sciences “Vinča”, University
of Belgrade, Mike Petrovića Alasa 12-14, 11001 Belgrade, Serbia; 2National Institute of
Chemistry, Hajdrihova 19 1001 Ljubljana, Slovenia.
E-mail: [email protected]
Alternative NADH dehydrogenase (NDH2) is essential enzyme of the Leishmania
Infantum respiratory systhem. These enzymes catalyze transference of electrons from
NADH to ubiquinone molecule, without coupled proton pumping.
Previous studies of NADH-II: rubiquinone oxydoreductase (NDH2) crystal structure
reported that there are two close ubiqinone UQ binding sites, which are responsible for
mechanism of oxydoreduction in presence of cofactors NADH and FAD. We developed
novel NADH dehydrogenase (Leishmania Infantum) 3D model structure based on
homologus models1 using advanced remote homology detection methods (Phyre2
server2). In order to select commertially available compounds for potential inhibitor
activity against LiNDH2, we trained pharmacophore models based on homologus
NDH2 activity profile of inhibitors of the quinone class, from another study (Plasmodium
Falciparum) 3. Approximately 550,000 commercially available compounds were
screened using LigandScout4 and compounds with desired pharmacophoric features
had been selected. Afterwards, docking screening in GOLD Suite5, using genetic
algorithm, tested selected compounds fittings into selected UQ binding site in LiNDH2
homology model. Resulting compounds list is consensus from docking scores,
pharmacophore fit scores and visual examination of structure-based and ligand-based
designs. We selected 24 hits with variety of scaffolds for further testing.
References:
1. Feng Y, Li W, Li J, Wang J, Ge J, Xu D et al. Structural insight into the type-II
mitochondrial NADH dehydrogenases. Nature 2012 491(7424):478-482.
2. The Phyre2 web portal for protein modeling, prediction and analysisKelley LA et
al. Nature Protocols 2015 10: 845-858
3. Biagini G, Fisher N, Shone A, Mubaraki M, Srivastava A, Hill A et al. Generation of
quinolone antimalarials targeting the Plasmodium falciparum mitochondrial respiratory
chain for the treatment and prophylaxis of malaria. Proceedings of the National
Academy of Sciences 2012 109(21):8298-8303.
4. Wolber GLanger T. LigandScout: 3-D Pharmacophores Derived from Protein-Bound
Ligands and Their Use as Virtual Screening Filters. Journal of Chemical Information and
Modeling 2005 45(1):160-169.
5. Jones G, Willett P, Glen R, Leach A, Taylor R. Development and validation of a genetic
algorithm for flexible docking. Journal of Molecular Biology 1997 267(3):727-748.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 22 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS II
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 23 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 24 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Synthesis of Novel Thienocarbazole derivatives via
intramolecular cyclization reactions
Arif Kivrak
Department of Chemistry, Yuzuncu Yil University, 65080 Van, TURKEY
E-mail: [email protected]
Carbazoles and derivatives have emerged as central candidates for pharmaceutical
applications since they show remarkable analgesic, anti-inflammatory, anti-bacterial
antiparasitic, antitussive, hypoglycemic, antitumor and/or anticancer activities. Many
synthetic methods have been used for the synthesis of new heterocyclic compounds.
They have also been isolated from different kinds of plants and used to treat different
diseases for many years. On the other hand, there are a few studies for
thienocarbazoles which may have critical biological properties. Thieno[c]carbazoles are
bioisosters of pyridocarbazoles which have a broad range of biological activities
including anticancer, antibacterial and antifungal properties. In this study, novel
methodologies for the synthesis of potentially biologically active thieno[c]carbazoles
was developed by using intramolecular cyclization reactions.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 25 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
New Promising Targets vs Neglected Tropical Diseases
(Leishmaniasis and Trypanosomiasis)
Giusy Tassone1, Laura Friggeri1, Mattia Mori1,2, Claudio Zamperini1 Fernanda
A.H. Batista3, Julio Cesar Borges3, Kevin Read4, Manu De Rycker5 and
Maurizio Botta6
1
University of Siena, Department of Biotechnology, Chemistry and Pharmacy, Siena. Italy;
2
Instituto Italiano di Tecnologia, Center for Life Nano Science@Sapienza, Roma. Italy;
3
Universidade de São Paulo (USP), Instituto de Química de São Carlos, Grupo de Biologia
Molecular e Bioquímica, São Carlos. Brazil; 4University of Dundee, School of Life Sciences,
Biological Chemistry and Drug Discovery. United Kingdom; 5University of Dundee, Drug
Discovery Unit, Division of Biological Chemistry and Drug Discovery. United Kingdom;
6
Sbarro Institute for Cancer Research and Molecular Medicine, Center for Biotechnology,
Philadelphia. USA
E-mail: [email protected]
Leishmaniasis and trypanosomiasis are two of the most important neglected tropical
diseases. These diseases affect largely the poorest side of population leaving in
developing countries and more than 20 million people are infected worldwide. [1]
Currently available therapy against these diseases is not satisfactory, as it relies on
non-specific, toxic and not effective drugs. [2] Therefore it is necessary to develop a
new specific drug therapy against these diseases. In a medicinal chemistry-oriented
strategy for identifying new scaffolds potentially active against Leishmania donovani
and Trypanosoma cruzi, we selected 80 compounds with different chemical scaffolds,
belonging to our in house library. These compounds were tested against Leishmania
spp, and the obtained data demonstrated that eight molecules showed interesting
antileishmanial activity. Four potential Hit to Lead: KLDS-20, -67, -2, -61 showing
interesting activity with pEC50 (log(EC50[M])) values approximately of 5 (IC50=10 μM),
were identified. These compounds were subjected to the experimental determination of
ADME proprieties. These studies have shown a good permeability profile and many
compounds have shown a high metabolic stability. Currently, some studies to increase
the activity of compounds with similar structure to KLD20 are running, in order to
increase its solubility, improve the ADME characteristics but without altering the
pharmacological activity. Preliminary results of our 80 compounds vs amastigote stage
of Trypanosoma cruzi show that some compounds emerge as potential
antitrypanosomal compounds. The most promising compounds are the ones with a
Trypanosoma cruzi maximum effect > 90% (100% means that the compound is as
good at clearing parasites as Nifurtimox). In particular, the compound KLD47 shows a
Trypanosoma cruzi maximum effect of 94%, a pEC50 of 5.2 and a cytotoxic effect of
22%.
In addition, we selected Heat shock protein 90 (Hsp90) of Leishmania braziliensis as
a potential specific target for the development of a specific drug therapy against
leishmaniasis. [3] Heat shock protein is an ubiquitous protein functioning as molecular
chaperone that stabilizes client proteins in a folded and functional state. Hsp90 plays a
significant role in the life cycle control of the protozoan parasite Leishmania braziliensis
and is essential for survival and proliferation of the intracellular mammalian stage, the
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 26 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
amastigote. At first we set up a robust structure-based approach boosted by similarity
search and docking-based virtual screening studies for identifying small molecule
inhibitors of N-terminal domain of Leishmania braziliensis Hsp90. These compounds
were investigated in vitro for anti-protozoa activity and some of them emerged as
potential ligands of Hsp90. In particular, for one of them a Kd of about 17 μM has been
determined. To date, the crystallographic structure of Leishmania braziliensis is not
available. For this reason we have initiated the process of determining the threedimensional structure of the protein in order to obtain insight into its structure and
protein-inhibitors complexes. The protein was overexpressed in Escherichia coli strain
BL21 and the purification trial was carried out using a Nickel affinity column at levels
and purities sufficient for performing the crystallization trials that currently are ongoing.
References
[1] Li, Q. et al, Parasitology research. 2009, 105 (6), 1539-48
[2] McGwire, B. S.et al, QJM : monthly journal of the Association of Physicians.
2014, 107 (1), 7-14
[3] Silva KP et al, Biochim Biophys Acta. 2013;1834(1):351-6
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 27 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Designing inhibitors with pan-activity and poly-pharmacology
for neglected diseases and parasites
Alfonso T. García-Sosa 1
1
Institute of Chemistry, University of Tartu, Ravila 14a, Tartu 54011, Estonia
E-mail: [email protected]
A variety of neglected diseases present as comorbidity. In addition, compounds that
could treat several diseases would be highly desirable from an affordability point of
view, as well as for compliance to treatment regimen, and delaying drug-resistance
development. There are reports of compounds that can inhibit several diseases at the
same time, such as leishmaniasis, Chagas disease, and sleeping sickness.[1]
Arginase is a critical component for several Leishmania organisms.[2] Virtual
screening using a database of natural products with EIIP/AQVN and 3D QSAR filters,
as well as docking to Leishmania and human arginase structures in addition to antitargets, has been performed resulting in a list of compounds with desirable properties.
A known inhibitor, flavonoid, natural compound was recovered among this list.
Cystoisospora suis is an intestinal parasite present in pigs and responsible for large
losses. Virtual screening was conducted on the target CDPK1 (Toxoplasma gondii
homolog), with a list of compounds selected for further testing.
1. Khare, S.; Nagle, A. S.; Biggart, A.; et al. “Proteasome inhibition for treatment of
leishmaniasis, Chagas disease, and sleeping sickness”, Nature, 2016,
doi:10.1038/nature19339
2. Glisic S., Sencanski M., Perovic V., Stevanovic S., García-Sosa A. T., "Arginase
flavonoid anti-leishmanial in silico inhibitors flagged against anti-targets", Molecules,
2016, Vol. 21, Iss. 5, 589. doi:10.3390/molecules21050589
Acknowledgments
Dr. Sanja Glisic, Dr. Milan Sencanski, and Dr. Nicola Palmieri for collab.
Estonian Ministry of Science and Education, Grant Number: IUT34-14
EU COST Action CM1307 Targeted chemotherapy towards diseases caused by endoparasites
EU COST Action CA15135 Multi-target paradigm for innovative ligand identification in the drug
discovery process (MuTaLig)
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 28 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS III
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 29 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 30 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Small Redoxins as Target Molecules in Antitrypanosomal Drug
Development
Samantha Ebersoll1, Blessing Musunda1, Marcelo A. Comini2 and
R. Luise Krauth-Siegel1
1
Biochemie-Zentrum der Universität Heidelberg (BZH), Im Neuenheimer Feld 328, D69120
Heidelberg, Germany, E-mail: [email protected];
2
Group Redox Biology of Trypanosomes, Institut Pasteur de Montevideo, Mataojo 2020, CP
11400, Montevideo, Uruguay.
In all organisms, redoxins are involved in the redox regulation of a huge number of
cellular processes. Typical representatives are thioredoxins and glutaredoxins (Grxs),
proteins with a molecular mass of 10-15 kDa and a redox active CXXC motif. Work of
the last few years revealed the small oxidoreductases as targets of different antitumor
drugs.
For maintaining the intracellular thiol redox homeostasis, trypanosomatids employ
trypanothione [T(SH)2] which is kept reduced by trypanothione reductase (TR). T(SH)2
is the direct electron donor for a variety of vital pathways, most of the reactions being
mediated by the parasite specific tryparedoxin (Tpx). The T(SH)2/Tpx couple is the
electron donor for ribonucleotide reductase, methionine sulfoxide reductase and the
enzymes that catalyze the detoxification of peroxides. Tpx is the central cytosolic
redoxin. The oxidoreductase is essential and its inactivation is an attractive approach
for the development of novel antitrypanosomal drugs.
Here I will also discuss the role of two Grxs of African trypanosomes which are
located in the cytosol and mitochondrial intermembrane space. Both proteins are kept
reduced by T(SH)2. They catalyze the thiol/disulfide exchange between glutathione
disulfide and T(SH)2 as well as the deglutathionylation of different model components.
The cytosolic Grx1 accounts for the major part of the total deglutathionylation capacity
of the parasite. Deletion of both grx1 and grx2 alleles, respectively, did not result in any
proliferation defect of bloodstream parasites, even not under various stress conditions.
Apparently, these redoxins are dispensable and thus unlikely to represent putative drug
targets. Intriguingly, when rising the culture temperature from 37 °C to 39 °C,
proliferation of the Grx1- and Grx2-deficient bloodstream parasites is even significantly
less affected compared to that of wildtype cells indicating that the proteins play a
regulatory role in the thermotolerance of the parasites (Musunda et al. 2015, Mol.
Biochem. Parasitol. 204, 93-105).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 31 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Phosphodiesterase Inhibitors as a Potential Treatment for
Neglected Parasitic Diseases
Rob Leurs
Division of Medicinal Chemistry, Faculty of Science, Amsterdam Institute for Molecules,
Medicines and Systems (AIMMS), VU University Amsterdam, the Netherlands.
E-mail: [email protected], [email protected]
Cyclic nucleotide phosphodiesterases (PDEs) have emerged as attractive molecular
targets for a novel treatment for a variety of Neglected Parasitic diseases, including
African trypanosomiasis, Chagas disease, and malaria. For example, both genetic
knock-down and chemical inhibition of PDE activity resulted in halted proliferation and
eventually elimination of Trypanosoma brucei (Tbr), the causative agent of African
sleeping sickness. The vast knowledge and generated expertise within the field of
human PDEs provides a shortcut to high-affinity inhibitors of parasitic PDEs. We have
brought together a public-private consortium with PDE experts, medicinal chemists and
parasitologists to effectively target parasitic PDEs.
The PDE4NPD project is an EU-funded platform to develop new chemical entities
targeting parasitic PDEs. The PDE4NPD project is supported by the European Union
7th Framework Program (FP7/2007-2013) under grant agreement n° 602666 and
involves ten consortium members and research labs in seven countries
(www.PDE4NPD.eu). In this presentation we will show our progress in developing
approaches to combat parasitic diseases by both a phenotypic and target-based
approaches.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 32 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Targeting trypanosome alternative oxidase (TAO) inhibitors to
mitochondria: original targeting for a unique target
Christophe Dardonville1, Francisco José Fueyo González1, Godwin U. Ebiloma2,
Carolina Izquierdo García1, Victor Bruggeman1, José María Sánchez
Villamañán1, Anne Donachie2, Emmanuel Balogun3, Kiyoshi Kita3,
Harry P. de Koning2
1
Instituto de Química Médica, IQM–CSIC, Juan de la Cierva 3, E–28006 Madrid, Spain.
Institute of Infection, Immunity and Inflammation, College of Medical, Veterinary and Life
Sciences, University of Glasgow, Glasgow, United Kingdom.
3
Department of Biomedical Chemistry, Graduate School of Medicine, The University of Tokyo,
Japan.
2
During their life-cycle, trypanosomes adapt their energy metabolism to the
availability of nutrients in their environment. Hence, procyclic forms of T. brucei have a
fully functional respiratory chain and synthesize ATP by oxidative phosphorylation in
the mitochondrion. In contrast, respiration of bloodstream forms (BSF) of T. brucei (i.e.
the human-infective form) relies exclusively on glycolysis for energy production. The
trypanosome alternative oxidase (TAO) is the sole terminal oxidase enzyme to reoxidize NADH accumulated during glycolysis. It is a cyanide-resistant and cytochromeindependent ubiquinol oxidase which is sensitive to the specific inhibitors
salicylhydroxamic acid (SHAM) and ascofuranone. This enzyme which is essential to
the viability of BSF trypanosomes and has no counterpart in the mammalian host is a
potential target for chemotherapy.
To boost the activity of a TAO inhibitor, 4-(decyloxy)-2-hydroxybenzoic acid (1),
which was inactive against T. brucei in a whole cell assay, we investigated a chemical
strategy consisting of the conjugation of the inhibitor with lipophilic cations (LC) that
can cross lipid bilayers by non-carrier mediated transport, and thus accumulate
specifically into mitochondria, driven by the plasma and mitochondrial transmembrane
potentials (negative inside). This design afforded several LC–TAO inhibitor conjugates
active in the submicromolar to low nanomolar range against wild type and resistant
strains of African trypanosomes (T. b. brucei, T. congolense). Selectivity over human
cells was >500 and reached >23,000 for one compound. Studies of the effects on
purified TAO, parasite respiration, mitochondrial membrane potential (Ψm), and cell
cycle showed that the compounds effectively target TAO in vitro. Hence, the LC-carrier
strategy successfully delivers specific antiparasitic drugs to their mitochondrial target.
This chemical approach could be applied to other mitochondrial targets validated for
antiparasitic drug discovery, including against intracellular parasites.
Acknowledgements. This work was funded by the Spanish Ministerio de Economia y
Competitividad (SAF2015-66690-R). G. U. Ebiloma was supported by a TET-fund studentship
from the government of Nigeria and by a Mac Robertson Travel Scholarship from the College of
Medical, Veterinary and Life Sciences of the University of Glasgow.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 33 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Repurposing an old anti-arthritis golden drug, auranofin, and
its anticancer GoPI-sugar surrogate for the treatment of human
parasitic diseases: from Leishmania to helminth infections
L. Feng,1 S. Pomel,2 P. Loiseau, 2 D. L. Williams,3 E. Davioud-Charvet 1
1
UMR 7509 CNRS University of Strasbourg, European School of
Chemistry, Polymers and Materials (ECPM), F-67087 Strasbourg, France; 2 UMR 8076 CNRS
BioCIS, University of Paris-Sud, 92290 Chatenay-Malabry France; 3 Department of
Immunology/Microbiology, Rush University Medical Center, IL 60612 Chicago.
E-mail: [email protected]
Schistosomiasis (also known as bilharzia)—infection with the helminth parasites in
the genus Schistosoma—remains an important infection in many tropical areas,
especially Africa. More than 200 million people have schistosomiasis, with 20 million
exhibiting severe symptoms. The approved drug auranofin (Ridaura®) targets the
seleno-dependent Schistosoma worm thioredoxin-glutathione reductase (TGR) and
rapidly kill juvenile and adult Schistosoma mansoni in culture at concentrations
achievable in patients (5 μM).1 This phosphine-coordinated gold (I) thiosugar complex
was initially developed for the treatment of rheumatoid arthritis, a disorder associated
to TrxR overexpression, and reported to inhibit the purified thioredoxin reductase
(TrxR) from human placenta.2 In our team, several TrxR inhibitors have already been
identified and have shown growth-inhibitory properties on tumor cells and parasites.
Among those, the phosphole-containing gold complex {1-phenyl-2,5-di(2pyridyl)phosphole}AuCl (abbreviated as GoPI) is an irreversible inhibitor of both
purified human GR and TrxR.3 GoPI-sugar is a novel 1-thio-β-D-glucopyranose
2,3,4,6-tetraacetatoS-derivative, which was designed from the structure of GoPI and
auranofin, for an improved stability and bioavailability upon GoPI. These metal-ligand
complexes are of particular interest because of their combined abilities to irreversibly
target the dithiol/selenol catalytic pair essential for TrxR activity in addition to bind to
DNA, and to kill cancers cells from breast and brain tumors.4
Figure 1. Structures of gold (I)-based complexes as human glutathione and thioredoxin
reductases and Schistosoma mansoni thioredoxin-glutathione reductase.
Recently, auranofin has been shown to inhibit the growth of various parasites5: both
the bloodstream and procyclic stages of Trypanosoma brucei, the malarial parasite
Plasmodium falciparum, to kill larval worms of Echinococcus granulosus in vitro, and
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 34 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
also the promastigote stage of Leishmania infantum. Consequently, screening of
parasites to identify the most sensitive organism to GoPI-sugar, compared to
auranofin, has been undertaken in our team. Selected data will be presented.
1
Kuntz et al. Thioredoxin glutathione reductase from Schistosoma mansoni: an essential
parasite enzyme and a key drug target. PLoS Med 2007, 4, e206.
2
Gromer et al. Human placenta thioredoxin reductase. Isolation of the selenoenzyme, steady
state kinetics, and inhibition by therapeutic gold compounds. J Biol Chem. 1998, 273:20096101.
3
a) Deponte et al., Mechanistic studies on a novel, highly potent gold-phosphole inhibitor of
human glutathione reductase. J. Biol. Chem. 2005, 280:20628-37; b) Urig et al., Undressing of
phosphine gold(I) complexes as irreversible inhibitors of human disulfide reductases. Angew
Chem Int Ed Engl. 2006, 45:1881-6.
4
a) Viry et al., A sugar-modified phosphole gold complex with antiproliferative properties acting
as a thioredoxin reductase inhibitor in MCF-7 cells. ChemMedChem 2008, 3:1667-70; b) Jortzik
et al., Antiglioma activity of GoPI-sugar, a novel gold(I)-phosphole inhibitor: chemical synthesis,
mechanistic studies, and effectiveness in vivo. Biochim Biophys Acta 2014, 1844:1415-26.
5
a) Lobanov, A.V., Gromer, S., Salinas, G. & Gladyshev, V.N. Selenium metabolism in
Trypanosoma: characterization of selenoproteomes and identification of a kinetoplastidaspecific selenoprotein. Nucleic Acids Res. 2006, 34, 4012–4024; b) Sannella, A.R. et al. New
uses for old drugs. Auranofin, a clinically established antiarthritic metallodrug, exhibits potent
antimalarial effects in vitro: Mechanistic and pharmacological implications. FEBS Lett. 2008,
582, 844–847; c) Bonilla, M. et al. Platyhelminth mitochondrial and cytosolic redox homeostasis
is controlled by a single thioredoxin glutathione reductase and dependent on selenium and
glutathione. J. Biol. Chem. 2008, 283, 17898–17907; d) Ilari, A. et al. A gold-containing drug
against parasitic polyamine metabolism: the X-ray structure of trypanothione reductase from
Leishmania infantum in complex with auranofin reveals a dual mechanism of enzyme inhibition.
Amino Acids 2012, 42, 803–811.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 35 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 36 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
MOLECULES AND TARGETS IV
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 37 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 38 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Trypanocidal action of bisphosphonium salts through a
mitochondrial target in bloodstream form Trypanosoma brucei
Abdulsalam A. M. Alkhaldi,1 Jan Martinek, 2 Brian Panicucci,2 Christophe
Dardonville,3 Alena Zíková 2 and Harry P de Koning 1
1
Institute of Infection, Immunity and Inflammation, College of Medical, Veterinary and Life
Sciences, University of Glasgow, Glasgow, United Kingdom; 2 Institute of Parasitology, Biology
Centre & Faculty of Science, University of South Bohemia, České Budějovice, Czech Republic;
3
Instituto de Química Médica, IQM–CSIC, Madrid, Spain.
Lipophilic bisphosphonium salts are among the most promising antiprotozoal leads
currently under investigation. As part of their preclinical evaluation we here report on
their mode of action against African trypanosomes, the etiological agents of sleeping
sickness. The bisphosphonium compounds CD38 and AHI-9 exhibited rapid inhibition
of T. brucei growth, apparently the result of cell cycle arrest that blocked the replication
of mitochondrial DNA, contained in the kinetoplast, thereby preventing the initiation of
S-phase. Incubation with either compound led to a rapid reduction in mitochondrial
membrane potential, and ATP levels decreased by approximately 50% within 1 h.
Between 4 and 8 h, cellular calcium levels increased, consistent with release from the
depolarized mitochondria. Within the mitochondria, the Succinate Dehydrogenase
complex (SDH) was investigated as a target for bisphosphonium salts, but while its
subunit 1 (SDH1) was present at low levels in the bloodstream form trypanosomes, the
assembled complex was hardly detectable. RNAi knockdown of the SDH1 subunit
produced no growth phenotype, either in bloodstream or in the procyclic (insect) forms
and we conclude that in trypanosomes SDH is not the target for bisphosphonium salts.
Instead, the compounds inhibited ATP production in intact mitochondria, as well as the
purified F1 ATPase, to a level that was similar to 1 mM azide. Co-incubation with azide
and bisphosphonium compounds did not inhibit ATPase activity more than either
product alone. The results show that, in Trypanosoma brucei, bisphosphonium
compounds do not principally act on succinate dehydrogenase but on the mitochondrial
FoF1 ATPase. This study also provides the first comprehensive investigation of the
Succinate Dehydrogenase Complex in bloodstream and procyclic Trypanosoma brucei.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 39 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Structure-function relationships of Toxoplasma gondii
aspartyl protease 3
Budhaditya Mukherjee1, Sunil Kumar Dogga1, Marq JB1, Paco Pino1, Francesca
Tessaro2, Ruben Hartkoorn3, Gianpaolo Chiriano2, Leonardo Scapozza2 and
Dominique Soldati-Favre1
1
Department of Microbiology and Molecular Medicine. Faculty of Medicine. University of
Geneva, CMU, 1 rue Michel-Servet, 1211 Geneva 4 Switzerland.
2
Pharmaceutical Biochemistry, School of Pharmaceutical Sciences, University of Lausanne,
University of Geneva, Switzerland. Quai Ernest-Ansermet 30, 1211 Genève 4 – Switzerland.
3
Institut Pasteur de Lille, Lille France
Email: [email protected]
Toxoplasma gondii is a member of the phylum Apicomplexa and an important
pathogen for humans and animals. Active entry and egress from infected host cells are
key steps in the lytic cycle of this obligate intracellular parasite. Adhesins, perforins and
proteases are discharged by the regulated secretory organelles called micronemes and
critically contribute to parasite motility invasion and egress. The T. gondii aspartyl
protease 3 (TgASP3) resides in the endosomal-like compartment (ELC) and acts as a
maturase that processes at least one microneme protein, TgMIC6, which traffics
through the ELC as part of its targeting to the organelles. Conditional deletion of
TgASP3 gene severely impairs invasion and egress without impacting on parasite
intracellular growth or gliding motility.
A peptidomimetic inhibitor based on a hydroxy-ethyl-amine scaffold (compound
49c); developed against the Plasmodium aspartyl protease Plasmepsin II exhibits an
IC50 of ~ 0.6 µM against T. gondii. Importantly 49c recapitulates TgASP3 depletion
phenotypes and inhibits TgASP3 activity in vitro. 49c also blocks malaria parasite
egress from infected erythrocytes at subnaomolar concentrations and presumably
targets the orthologues of TgASP3, Plasmepsin IX and X but not the hemoglobin
degrading enzyme Plasmepsin II.
The catalytic dyad of the aspartyl proteases is composed of two aspartic acid
residues, acting as proton donor and acceptor when cleaving the peptide bond. The
flap and flap-like structures of several Plasmepsins have been reported to be highly
flexible in both free and ligand-bound form and to critically modulate the access of the
binding cavity to various inhibitors. Compared modeled structures of various
Plasmepsins and TgASP3 in presence of 49c predicted that key conserved
phenylanine residues in the flap could account for the sensitivity of ASP3 to 49c.
Expression of ASP3 mutated in these residues in parasites lacking ASP3 confirmed
this prediction with an increased IC50 value to ~ 2 µM.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 40 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
On the way to find a cure for infection with B. microti
Joanna SZYMCZAK, Katarzyna Donskow-Łysoniewska, Maria DOLIGALSKA
Department of Parasitology, Institute of Zoology, Faculty of Biology, University of Warsaw
Address: Ilji Miecznikowa 1, 02-096 Warszawa, Poland
Email: [email protected]
Babesiosis is an emerging, tick-borne disease caused by intraerythrocytic parasite
Babesia microti. In immunocompetent individuals B. microti infection is typically
asymptomatic or appears as a mild flu-like disease that quickly resolves.
Immunocompromised patients, particularly those suffered from B-cell lymphoid
malignancies and treated with rituximab, experience severe, persistent and relapsing
babesiosis. In these individuals B. microti infection may persist despite multiple courses
of treatment with standard antiprotozoal drugs. The increasing incidence of human
babesiosis caused by B. microti coupled with a growing number of immunosuppressed
people who live or travel in areas where babesiosis is endemic, emphasize the need
for new therapeutics for this protozoan infection with more effective mechanisms of
action.
The results of our study revealed that in experimental B. microti infection, B cells
interact in a complex duet with CD4+ T cells. The cooperation between B cells and T
CD4+ cells affects the activation, differentiation and effector functions of both cell
populations over the course of babesiosis. The Inhibited interaction between B cells
and CD4+ T cells resulted in impaired immune response and consequently, may lead to
increased susceptibility to babesia infection.
It is known that rituximab induces a profound and long-term depletion of CD20+ B
cells, including the majority of the B-cell lineages, before plasma cell differentiation.
These data suggest that the relapse of acute, symptomatic babesiosis in patients with
B-cell lymphoid malignancies treated with rituximab may be a result of abnormal
interactions between B cells and CD4+ T cells.
Accumulating evidence demonstrates that B cells and CD4+ T cells play a critical
role in determining host propensity to cause acute versus persistent disease.
Understanding the multiple roles of B cells and CD4+ T cells in regulating cellular and
humoral immune responses to parasite may be helpful for the development of an
effective vaccine or novel therapeutics against B. microti that can potentially modulate
CD4+ T-cell-B-cell interactions for better infection outcome. Further, identifying the
possible mechanism involving B cells that is responsible for babesiosis relapse may
provide important clues for contributing to optimal treatment for immunocompromised
patients infected with B. microti.
Project was co-financed by ESF under the Operational Programme Human Capital,
POKL.04.03.00-00-060/12 and Principal Research/2015 of Faculty of Biology, University of
Warsaw.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 41 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Potential antischistosomal activity of PDE inhibitors using in
vitro Schistosoma mansoni worm killing
Sanaa S. Botros1; Samia William1, Abdel-Nasser Sabra1; Geert J. Sterk2; Irene
G. Salado3; Koen Augustyns3; Victor Sebastian4; Nuria E. Campillo4; Carmen
Gil4; Louis Maes3; Jane C. Munday5; Rob Leurs1; Harry P. De Koning5
1
Theodor Bilharz Research Institute1, Warrak El-Hadar, Imbaba, P.O. Box 30, Giza, Egypt
2
Vrije Universiteit Amsterdam, The Netherlands (VUA).
3
Universiteit van Antwerpen, Belgium (UA).
4
Centro de InvestigacionesBiológicas (CSIC), Madrid, Spain.
5
University of Glasgow, UK.
Email: [email protected]
We report the testing of 135 non-toxic phosphodiesterase inhibitors developed at
VUA, UA and CSIC, with molecular weights between 234 and 606, for their potential
antischistosomal activity. The compounds were assessed for killing of adult and early
mature Schistosoma mansoni in vitro; female ovipositing capacity and worm coupling.
Findings of 2-3 repeat experiments revealed potential antischistosomal activities
against adult mature schistosomes, expressed as worm killing/and or sluggish worm
movement for 19 compounds. However, the effect was recorded using high
concentrations of 100 µM and 50 µM, resulting in worm killing of 17%-100% and 8%64%, respectively. For 74% of the compounds we observed at least some worm killing,
with survivors showing sluggish movement. For a further 5% of compounds we
observed sluggish worm movement but no worm killing.
In 18 out of 19 promising compounds, only male worms were affected and 100% of
those were killed. Meanwhile insult to early mature worms was more pronounced: The
percentage worm killing recorded at 25 µM of test compound was 19%-44%, with the
insult directed against male worms only.
A subset of the compounds was tested for worm uncoupling with absence of ova,
and this was recorded for 74% of the compounds at concentrations of 100 µM and 50
µM; 11% and 5% of the compounds showed the same profile at concentrations of 25
µM and 10 µM, respectively.
The most promising compound was the NPD-000223 (VUA): this compound showed
100%, 64%, 25% and 7% worm killing at concentrations of 100 µM, 50 µM, 25 µM and
10 µM.
Expression and cloning analysis of PDEs in S. mansoni adult and early mature
worms revealed higher expression of Sm4A, Sm4C and Sm11 in adult and early
mature male worms than in female worms. Sm9C is highly expressed in juvenile male.
This work is part of the PDE4NPD consortium supported by Framework Program 7of the
European Commission No: 602666
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 42 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Secreted serine protease SmSP2 of the blood fluke
Schistosoma mansoni: biochemical characterization,
localization and host protein processing
Adrian Leontovyč1, Lenka Ulrychová1, Anthony J. O’Donoghue2, Lucie
Marešová1, Jiří Vondrášek1, Conor R. Caffrey2, Michael Mareš1, Martin Horn1,
Jan Dvořák1,3
1
Institute of Organic Chemistry and Biochemistry, the Czech Academy of Sciences,
Prague, Czech Republic
2
Center for Discovery and Innovation in Parasitic Diseases, Skaggs School of Pharmacy and
Pharmaceutical Sciences, University of California San Diego, La Jolla, CA 92093, USA
3
Institute of Molecular Genetics, the Czech Academy of Sciences, Prague, Czech
Republic
Schistosomiasis caused by parasitic blood flukes of the genus Schistosoma is the
second most important parasitic infection after malaria with more than 240 million
people infected. There is an urgent need to identify novel anti-schistosomal targets for
therapeutic interventions. Our work is focused on S. mansoni serine protease 2
(SmSP2). It was localized in the tegument and esophageal glands, ovaries, testes and
vitelaria of adult schistosomes by immunofluorescence microscopy and in situ RNA
hybridization. Enzyme activity measurements and immunoblotting identified SmSP2 in
the excretory/secretory products. Recombinant SmSP2 was produced in the Pichia
pastoris expression system and its cleavage specificity was investigated using
combinatorial substrate libraries and 3D model analysis. SmSP2 was found to activate
plasmin, the key component of the fibrinolytic system, and releases vasoregulatory
kinins from kininogen. Our results suggest that SmSP2 plays a role in host-parasite
interactions and represents a potential target for inhibitory drugs.
This work was supported by the grant LD15101 and the project InterBioMed LO1302 from the
Ministry of Education, Youth and Sports of the Czech Republic, the institutional project RVO
61388963, the Academy of Sciences of the Czech Republic, Center for Discovery and
Innovation in Parasitic Diseases.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 43 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Trypanosomatid Ribose 5-phosphate isomerase structures and
fragment screening reveals novel lead compound series
Nathalie Trouche5, Céline Ronin5, Joana Tavares1,2, Monica Silva1,2, Nuno Santarem1,2,
Joana Faria1,2, Emily A. Dickie4, Louise L. Major4, Fabrice Ciesielski5, Dominique
Roecklin5, Emmanuel Klein5, Christina Muller5, Terry K, Smith4, Anabela Cordeiro-daSilva1,2,3* & Paola Ciapetti5
1
Parasite Disease group, IBMC - Instituto de Biologia Celular e Molecular, Porto, Portugal;
Instituto de Investigação e Inovação em Saúde, Porto, Portugal; 3Faculdade de Farmácia da
Universidade do Porto, Porto, Portugal
4
Biomedical Sciences Research Complex, University of St Andrews, North Haugh, St Andrews,
Fife, KY16 9ST, UK
5
NovAliX, BioParc, 850 Boulevard Sébastien Brant, BP30170 F-67405 Illkirch, France
Email: [email protected]
2
Ribose 5-phosphate isomerase is an enzyme involved in the non-oxidative branch of
the pentose phosphate pathway, that catalyses the inter-conversion of D-ribose 5phosphate and D-ribulose 5-phosphate. This enzyme in the trypanosomatids:
Leishmania infantum and Trypanosome brucei has been genetically validated as
essential and therefore a candidate drug target.
Fragment libraries were screened using the thermal shift technology, which originate
promising hits. Subsequently the most interesting fragments were tested against the
RIP enzyme assays as well as their trypanocidal effect on Leishmania infantum and on
Trypanosoma brucei parasites.
X-ray crystal structures of both the L. infantum and T. brucei ribose 5-phosphate
isomerase were obtained complexed with potential inhibitors. Structural comparisons
with human and parasitic ribose 5-phosphate isomerase complexes reveal interesting
differences in the binding modes of these inhibitors.
Overall, these results are of general interest since they open the way to novel
structure-based drug design for these and other Neglected tropical diseases.
The research leading to these results has received funding from: the European Community’s
Seventh Framework Programme under grant agreement No.602773 (Project KINDRED)
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 44 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
NATURAL PRODUCTS
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 45 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 46 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 47 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
The effect of flavonolignans on the Mesocestoides vogae
(Cestoda) tetrathyridia
Gabriela Hrčková1, David Biedermann2, Terézia Mačák-Kubašková1
1
Parazitologický ústav SAV, Slovak Academy of Sciences, Hlinkova 3, 040 01 Košice,
Slovakia; 2Institute of Microbiology, Czech Academy of Sciences, Vídeňská 1083, Praha 4-Krč,
142 20
Milk thistle (Silybum marianum L. Gaertn (Asteraceae)) is medicinally used at least
from 14th century.[1] Today it is a source of silymarin – standardized extract of its fruits
– which is used as nutraceutical and for treatment of the liver problem. Silymarin
contains several flavonolignans, among them silybin (SB) and silychristin (SCH) are the
most abundant. 2,3-dehydrosilybin (DHSB) can be prepared from silybin, which tend to
posses better activity but it is also more toxic. Recently antiparasitic activity of those
compounds were reported.[2]
SB and SCH were isolated from silymarin using Sephadex LH-20 collumn
chromatography and DHSB was prepared by oxidation with iodine in boiling acetic
acid.
Larval stage, tetrathyridium, of cestode Mesocestoides vogae possess the ability to
proliferate asexually in various hosts including cold-blooded animals and mammals
(mice, dogs, cats). Since the first passage in laboratory mice, M. vogae larvae have
been distributed to several laboratories in the world. Due to many biological and
molecular similarities with other larval cestode infections it was recommended by WHO
(1996) as a suitable model for the slower developing metacestode infections. We
developed the system for long-term in vitro cultivation of the larvae [3].
We examined activity of SB, SCH and DHSB at concentrations of 5 and 50 μM on
larvae incubated up to 7 days in RPMI media under hypoxic conditions. Only DHSB
had the significant larvicidal effect seen already after 72 h of incubation. All compounds
modulated metabolic activity in mitochondria. After 24 h, only DHSB at concentration of
50 μM reduced metabolic activity what correlated with time-dependent inhibition of GST
activity and concentration of enzyme in larvae.
In conclusion our preliminary data showed that selected flavonolignans have
different mechanisms of activity on molecular targets in M. vogae model eukaryotic
parasite and 2,3-dehydrosilybin exerted profound larvicidal effect in vitro.
The study was partially supported by MAD project between AV ČR and SAV no. 1613 and by MŠMT project LD 15081.
1. Biedermann D, Vavrikova E, Cvak L, Kren V. Chemistry of silybin. Natural Product
Reports 2014;31:1138-1157
2. Rabia, I.; Nagy, F.; Ali, E.; Mohamed, A.; El-Assal, F.; El-Amir, A. Effect of treatment
with antifibrotic drugs in combination with PZQ in immunized Schistosoma mansoni
infected murine model. International Journal of Infectious Diseases 14, S16-S17.
3. Vendelova E, Hrckova G, Lutz M.B, Brehm K, J. NONO Komguep J.N. In vitro culture
of Mesocestoides corti metacestodes and isolation of immunomodulatory excretory–
secretory products. Parasite Immunology, 2016; 38: 403–413
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 48 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
From the natural compound dihydroplakortin to synthetic
bicyclic and bridged endoperoxides active against chloroquinesensitive and chloroquine-resistant P. falciparum parasites
Sandra Gemma, Luisa Di Cerbo, Alessandra Vallone, Gloria Alfano, Simone
Brogi, Giuseppe Campiani, Stefania Butini, Sarah D’Alessandro, Silvia Parapini,
Nicoletta Basilico, Donatella Taramelli
Department of Biotechnology, Chemistry and Pharmacy, University of Siena, via Aldo Moro 2,
53100, Siena, Italy.
Email: [email protected]
Cyclic peroxides such as 1,2-dioxolanes, 1,2,4-trioxanes and 1,2- dioxanes are a class
of organic compounds with interesting pharmacological properties and widely
represented in nature. Artemisinin is an endoperoxide-based natural product, which is
highly effective against clinically relevant P. falciparum strains responsible for human
malaria. Currently, the so-called artemisinin-based combination therapies are
employed as first line treatment in most malaria endemic countries, adhering to WHO
recommendations. However, lower susceptibility to artemisinins is being reported from
highly malaria endemic regions. So, novel peroxides characterized by different
structural features could delay the potential selection of P. falciparum resistant strains.
Moreover, the cost associated with the extraction of this drug or with synthetic
precursors from natural sources prompted researchers to develop synthetic peroxides
as low-cost alternatives to artemisinins. Here we describe the development of novel
series of endoperoxides as synthetic analogues of the natural product dihydroplakortin.
Suitable and straightforward synthetic procedures for the preparation of bicyclic,
bridged and spirocyclic endoperoxides have been developed. The peroxides presented
here are more potent antiplasmodials than dihydroplakortin itself and they showed
antimalarial activity in vivo.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 49 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Anti-protozoal compounds from Nigerian medicinal plants:
identification and mode-of-action studies
Godwin U. Ebiloma1, Evangelos Katsoulis1, John Igoli2, Alexander I. Gray2, and
Harry P. de Koning1
1
Institute of Infection, immunity and Inflammation, College of Medical, Veterinary and Life
Sciences, University of Glasgow, UK. 2Strathclyde Institute of Pharmacy and Biomedical
Sciences, University of Strathclyde, Glasgow.
Email: [email protected]
African trypanosomiasis is a disease caused by infection of humans and animals
with parasites called trypanosomes, usually through the bite of infected tsetse flies.
Unfortunately, the current drugs are ineffective due to drug resistance and efforts
towards new drug development are inadequate. Using in vitro models of Trypanosoma
brucei, we used a multiple approach towards the identification of new lead compounds
and evaluate their potency, based on extracts from traditional medicinal plants from
West Africa. The result shows that neither the crude extracts or the active compounds
isolated from them are toxic to Human Embryonic Kidney (HEK) cells, whereas
promising activity was found against Trypanosoma brucei, a drug sensitive wild type
strain Trypanosoma brucei (s427-WT) and a multi-drug resistant strain, B48, which
lacks both the TbAT1/P2 transporter and the high affinity pentamidine transporter
(HAPT). The isolated compounds displayed the same activity against both
trypanosomes strains tested (EC50 ~ 0.3 µg/ml). Fluorescence microscopic assessment
of DNA configuration revealed cell cycle defects after 8 hours of incubation with the
natural compounds: DNA synthesis could not be initiated, leading to a dramatic
reduction of cells in the S phase. DNA fragmentation became evident after 10 hours of
incubation with compound HDK-20, visualised by flow cytometry and Terminal
deoxynucleotidyl transferase dUTP Nick-End Labelling (TUNEL) assay, which reveal
up to 80% of cells with DNA fragmentation after 12 hours. Compounds HDK-20 and
HDK-40 also induced a fast and profound depolarisation of the parasites’ mitochondrial
membrane potential after 1 hour of incubation and this continued until a near complete
depolarization was achieved after 12 hours. Intracellular ATP levels of the T. brucei
were also measured and were found to be depleted. Metabolomic assessments of T.
brucei cells did not reveal the targeting of any specific metabolic pathway. Since the
isolated compounds have almost no toxicity against human cells but are very active in
vitro against multidrug-resistant trypanosomes, these compounds could serve as lead
compounds towards the identification of more efficient anti-trypanosome drugs.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 50 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
DRUG DELIVERY I
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 51 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 52 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Nanotechnologies for the treatment of severe diseases
Patrick COUVREUR
University of Paris-Sud, Institut Galien, UMR CNRS 8612, 5 rue J-B Clément F-92296
Chatenay-Malabry (France)
Even if new molecules are discovered to treat severe diseases, the clinical use and
efficacy of conventional chemotherapeutics is hampered by the following limitations: (i)
drug resistance at the tissue level due to physiological barriers (non cellular based
mechanisms), (ii) drug resistance at the cellular level (cellular mechanisms), and (iii)
non specific distribution, biotransformation and rapid clearance of the drugs in the
body. It is therefore of importance to develop nanodevices able to overcome these
limitations.
This will be illustrated by various nanomedicine platforms developed in the
laboratory: the design of biodegradable nanoparticles loaded with doxorubicin for the
treatment of the resistant hepatocarcinoma (a nanomedicine currently in phase III
clinical trials) (1), the construction of nanoparticles made of metal oxide frameworks
(NanoMOFs) (10) and the “squalenoylation” (2), a technology that takes advantage of
squalene's dynamically folded conformation to link this natural and biocompatible lipid
to anticancer (3), antimicrobial (4) or neuroprotective compounds (5) in order to
achieve the spontaneous formation of nanoassemblies (100–300 nm) in water, without
the aid of surfactants. The design of “multidrug” nanoparticles combining in the same
nanodevice chemotherapy and imaging (ie., “nanotheranostics”) or various drugs with
complementary biological targets will be also discussed (6). Finally, it will be shown
that the construction of nanodevices sensitive to endogenous (ie. pH, ionic strenght,
enzymes etc.) or exogenous (ie., magnetic or electric field, light, ultrasounds etc.)
stimuli may allow the spatio-temporal controlled delivery of drugs and overcome
resistance to current treatments (7). The possibility to use other terpenes (natural or
synthetic) than squalene to design nanoparticles for the treatment of resistant
intracellular infections (8) or cancer will be discussed, too (9).
References
1. L. Barraud et al., J. Hepatology, 42, 736-743 (2005)
2. P. Couvreur et al., Nano Letters, 6, 2544-2548 (2006)
3. A. Maksimenko et al., Proceedings of the National Academy of Science, 111 (2) E217- E226
(2014)
4. N. Semiramoth et al., ACS Nano, 6, 3820-3831 (2012)
5. A. Gaudin et al., Nature Nanotechnology, 9, 1054-1063 (2014)
6. A. Maksimenko et al., ACS Nano, 8, 2018-2032 (2014)
7. S. Mura et al., Nature Materials, 12, 991-1003 (2013)
8. N. Abed et al., Scientific Reports (Nature), doi: 10.1038/srep13500 (2015)
9. S. Harisson et al., Angewandte Chemie Int. Edition, 52, 1678-1682 (2013)
10. Horcajada P et al., Nature Materials. 9, 172-178 (2010)
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 53 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 54 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
DRUG DELIVERY II
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 55 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 56 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Development and in vivo efficacy of biocompatible drug-loaded
microspheres against C. parvum
E. Blanco García1,, J. Blanco Méndez1 , F. J. Otero Espinar1, H. Gómez Couso2,
E. Ares Mazás2, A. Luzardo Álvarez1
1
Departamento de Farmacología, Farmacia y Tecnología Farmacéutica. Universidad de
Santiago de Compostela. Spain; 2 Departamento de Microbiología y Parasitología. Universidad
de Santiago de Compostela. Spain.
E-mail: [email protected]
Human cryptosporidiosis is one of the most commonly diagnosed protozoanassociated intestinal diseases worldwide. It is recognised as one of the main causes of
diarrhoeal in immunocompromised hosts (children, AIDS patients) as an opportunistic
pathogen [1]. Up to now, there is no any completely efficient treatment. Based on
previous work [2], an alternative therapy against Cryptosporidium parvum using
bioadhesive Paromomycin and Diloxanide Furoate (DF)-loaded microspheres have
been developed. Microspheres (MS) were prepared using chitosan (CHI) and poly(vinyl
alcohol) (PVA) and two types of cyclodextrins (β-CD and DM-β-CD) for the potential
use of treating cryptosporidiosis. Microparticle formulations were characterized in terms
of size, surface charge, drug release and morphology. In vivo bioadhesion properties of
CHI/PVA microspheres were also evaluated. In addition, the in vivo efficacy of
CHI/PVA microspheres against C. parvum was tested in neonatal mouse model of
cryptosporidiosis.
Microspheres prepared by spray-drying showed spherical shape, diameters
between 6.67 ± 0.11 and 18.78 ± 0.07 µm and positively surface charged. The
bioadhesion studies demonstrated that MS remained attached at +16h (post-infection)
to the intestinal cells as detected by fluorescence. The study of efficacy of treatment
determined in mice receiving orally administered microspheres with and without drug
showed significantly lower parasite loads compared with the control mice.
Our results suggest that microspheres appear to be a safe and simple system to be
used in an anticryptosporidial treatment. This work demonstrated the high potential of
using bioadhesive chitosan/PVA microspheres for the possible application in the
antiparasitic drug delivery by oral route in the treatment or prevention of C. parvum
infections.
[1] Bouzid, M. et al., 2013. Clin Microbiol Rev. 26, 115–34.
[2] Luzardo-Álvarez, A. et. 2012. Eur. J. Pharm. Sci. 47, 215-227.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 57 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Is the oral delivery of Amphotericin B possible to treat parasitic
diseases?
D. R. Serrano1, A. Lalatsa2, MA. Dea-Ayuela3, P. Bilbao-Ramos1, NL. Garrett4,
J. Moger4, J. Guarro5, J. Capilla5, MP. Ballesteros1, AG. Schätzlein6,║, F. Bolas1,
JJ. Torrado1, IF. Uchegbu6,║
1
School of Pharmacy, Complutense University of Madrid, Plaza Ramon y Cajal s/n, Madrid,
28040, Spain. 2 School of Pharmacy and Biomedical Sciences, University of Portsmouth, PO1
2DT, UK. 3 School of Health Sciences, Universidad Cardenal Herrera-CEU, Moncada, Valencia,
46113, Spain. 4 School of Physics, University of Exeter, Stocker Road, Exeter, EX4 4QL, UK. 5
Facultat de Medicina, IISPV, Universitat Rovira i Virgili, Reus, 43201, Spain. 6 UCL School of
Pharmacy, University of London, 29-39, Brunswick Square, London, WC1N 1AX, UK. ║
Nanomerics Ltd., 14 Approach Road, St. Albans, Hertfordshire, AL1 1SR, UK.
INTRODUCTION. Amphotericin B (AmB) is one of the drugs of choice for visceral
leishmaniasis (VL) which is fatal if left untreated. However, AmB provokes severe
adverse effects such as nephrotoxicity and infusion-related side effects that limit its use
in clinical practice. Marketed formulations are only parenterally available due to its poor
aqueous solubility and permeability which obliges to prolonged hospitalization. The
development of an AmB oral nanomedicine would expand the treatment access.
METHODS. AmB was encapsulated into quaternary ammonium palmitoyl glycol
chitosan (GCPQ) nanoparticles [1]. Biodistribution in plasma and in major target organs
such as spleen, liver, lung and bone marrow following single or multiple oral
nanoparticle administration was evaluated in mice and dogs. Anti-leishmanial activity in
infected mice was assessed in order to correlate with the increase in oral
bioavailability. Multimodal multiphoton microscopy was used to image AmB in major
target organs.
RESULTS. AmB levels reached in liver (Fig. 1), spleen and lungs were higher with
respect to kidney concentration obtaining a favourable risk- benefit ratio (Fig. 2). The
oral bioavalability of AmB was 24.7% in mice. AmB-GCPQ nanoparticles also enabled
oral absorption in dogs. The oral administration resulted in 98.9±1.2% and 92.1±7.5%
suppression of parasites in liver and spleen respectively.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 58 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
CONCLUSIONS. An oral therapy for 10 consecutive days at 5 mg kg-1 of AmBGCPQ exhibited a similar potency to parenterally administered AmBisome® against
Leishmania parasites in liver and spleen. The high activity linked with a low toxicity
results in an effective and safe oral AmB therapy which it can expand the access for
the treatment of VL especially in developing countries.
REFERENCES. Serrano DR et a. Mol Pharm 2015, 12:420-431.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 59 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Nanoencapsulation of tetraoxane-based double drugs with
antileishmanial activity
João P. Quintas, Manuela Carvalheiro, António J. Almeida and Francisca Lopes
Research Institute for Medicines (iMed.ULisboa), Faculty of Pharmacy, Universidade de Lisboa,
Lisbon, Portugal,
Email: [email protected]
Leishmania genera stand out by their complex redox metabolism, depending on the
flavoenzyme trypanothione reductase (TR) as a defence against oxidative stress, by
neutralizing hydrogen peroxide produced by macrophages during infection [1]. Thus,
the development of potent inhibitors of TR could lead to new drugs to treat the various
forms of leishmaniasis.
In this context, we propose novel endoperoxide-based hybrid compounds capable of
selectively release TR inhibitors inside the amastigotes. This approach is applicable to
any infectious agents that acquire high levels of iron at critical steps of their life cycle,
such as Leishmania, which is dependent on an iron pool for amastigote differentiation
and virulence [2]. It provides an unprecedented class of antiparasitic compounds able
of disrupting the redox balance through two different and potentially synergistic
mechanisms, leading to high levels of ROS and ultimately to parasite death. We
selected 1,2,4,5-tetraoxanes, which are reductively activated by iron(II)-heme to form
carbon-centered radicals, ROS and carbonyl species [3].
Solid lipid nanoparticles (SLN) are efficient colloidal drug carriers mainly due to their
stability profile, ease of scalability and cost efficacy. Due to their particulate nature and
inherent structure SLN exhibit good potential in the treatment of parasitic infections [4].
Furthermore, SLN are rapidly cleared by MPS (mononuclear phagocyte system)
leading to passive targeting to liver and spleen, which would be quite useful for the
incorporation and selective delivery of novel TR inhibitors. Here, we report the
synthesis of novel hybrid tetraoxane-based agents, their loading in SLN and the in vitro
activity of the double-acting compounds and loaded SLN particles against leishmania
amastigotes in THP-1 cells. The implications in for future development into useful
antileishmanial agents will be discussed.
1. Tovar J, Cunningham ML, Smith AC, Croft SL, Fairlamb AH (1998). Down-regulation of
Leishmania donovani trypanothione reductase by heterologous expression of a transdominant mutant homologue: effect on parasite intracellular survival. PNAS, 95: 5311-5316.
2. Flannery AR, Renberg RL, Andrews NW (2013). Pathways of iron acquisition and utilization
in leishmania. Curr Opin Microbiol. 16: 716-721.
3. Oliveira R, Guedes RC, Meireles P, Albuquerque IS, Goncalves LM, Pires E, Bronze MR,
Gut J, Rosenthal PJ, Prudencio M, Moreira R, O'Neill PM, Lopes F (2014). Tetraoxanepyrimidine nitrile hybrids as dual stage antimalarials. J. Med. Chem. 57: 4916-4923.
4. Lopes RM, Pereira J, Esteves A, Gaspar MM, Carvalheiro M, Eleutério CV, Gonçalves LMD,
Jiménez-Ruiz A, Almeida AJ, Cruz MEM (2016). Lipid-based nanoformulations of trifluralin
analogs in the management of Leishmania infantum infections. Nanomedicine (Lond), 11:
153-170.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 60 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
DRUG DELIVERY III
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 61 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 62 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Inhibition of Schistosoma mansoni development in mice by
slow release of artemisone
D. Gold1, M. Alian2, A. Domb2, Y. Karawani3, M. Jbarien3, J. Chollet4, R. K.
Haynes5, V. Buchholz6, A. Greiner6, J. Golenser3
1Department
of Clinical Microbiology and Immunology, Sackler Faculty of Medicine,
Tel Aviv University; 2School of Pharmacy, and 3The Kuvin Center for the Study of
Infectious and Tropical Diseases, The Department of Microbiology and Molecular
Genetics; Faculty of Medicine, Hebrew University of Jerusalem, Israel; 4Swiss Tropical
Institute, Basel, Switzerland; 5Centre of Excellence for Pharmaceutical Sciences,
North-West University, South Africa; 6Macromolecular Chemistry II, University of
Bayreuth, Germany
Schistosomes are parasitic helminths, most important in terms of socio-economic
and public health in tropical and subtropical areas. Schistosomiasis causes skin
allergies, intestinal, liver and urinary pathologies. Chronic disease may also lead to
cancer. In addition, there are often systemic symptoms, such as retarded growth,
slowing of cognitive development and the effect of continuous low-level blood loss.
Current treatment is based on the anti-helminthic drug praziquantel (PZQ). PZQ affects
only the adult stages of schistosomes. Also, unfortunately, following its widespread
use, there are reports of PZQ resistance.
It is our purpose to test a drug, which could serve as a potential alternative or
complement to PZQ, and also as a means of treating infections at an earlier, pregranuloma schistosome stage. Derivatives of artemisinin, effective anti-malarials, have
been indicated as potential alternatives, because both plasmodia and schistosomes
are blood-dwelling and blood-feeding parasites. The mechanism of action of
artemisinins is ascribed inter alia to oxidative effects of the peroxide on intracellular
reductants such as reduced flavins that lead to formation of cytotoxic reactive oxygen
species. In this work we used the artemisinin derivative artemisone, which has
improved pharmacokinetics and anti-plasmodial activity, and reduced toxicity compared
to other artemisinin derivatives that are in current use.
We infected adult mice by subcutaneous injection of S. mansoni cercariae and
treated them at various times post infection by the following methods: a. artemisone
suspension administered by gavage; b. subcutaneous injection of a gel containing a
known concentration of artemisone; c. subcutaneous insertion of the drug incorporated
in a solid polymer; d. intraperitoneal injection of the drug solubilized in DMSO. Drug
insertion in gel and solid polymer was performed to enable slow release of the
artemisone that was verified in a bioassay system of sensitive malaria parasites.
Treatment was performed once, twice or thrice, usually starting about three weeks post
infection with schistosomes. The results were estimated by counting the adult worms,
males and females, surgically extracted from the mice. In most cases we found strong
anti-schistosome effects, mainly following repetitive treatments – either by injection of
the drug absorbed in the polymers or by gavage of its suspension. The results indicate
that artemisone has a potential anti-schistosome activity. Its main importance in this
context, however, is its effectiveness in treating hosts harboring juvenile schistosomes,
before egg-deposition and induction of deleterious immune responses.
We thank Cipla for the kind donation of artemisone.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 63 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Emulsomes: A Tool for Delivery of anti-leishmanial BNIP
Derivatives to Macrophages
Zeynep Islek1, Mustafa Güzel2, Fikrettin Sahin1, Mehmet H. Ucisik3,*
1
Department of Genetics and Bioengineering, Faculty of Engineering, Yeditepe University,
Istanbul, Turkey; 2 Department of Medical Pharmacology, International School of Medicine,
Istanbul Medipol University, Istanbul, Turkey; 3 Department of Biomedical Engineering, School
of Engineering and Natural Sciences, Istanbul Medipol University, Istanbul, Turkey
Corresponding Author; Phone: +90 216 681 5154;
E-mail: [email protected]
Similar to other parasitic diseases, chemotherapy is the most efficient strategy for
leishmaniasis. However, the high toxicity of many antiparasitic compounds restricts
their utility, and the emergence of drug resistant strains often impairs the lifespan of a
given drug.
Among alternative drug candidates, bisnapthalimidopropyl (BNIP) derivatives have
been recently shown to have anti-leishmanial activities, which even surpass the
standard and most common Amphotericin B therapy [1]. However BNIP derivatives
have some drawbacks including low aqueous solubility and toxicity. Addressing these
limitations, this study applies two diverse technologies including medical chemistry
approach together with the structure-based drug design, and nanotechnological drug
delivery approach. The former approach will focus on design of new BNIP derivatives
that have higher efficacy and bioavailability, whereas the latter will be used to deliver
the drug specifically to the parasite, thereby decreasing the side effects of the
chemotherapy, in particular on macrophages.
The delivery of BNIP derivatives into the macrophages will be achieved by
encapsulating the active molecule in a lipid- based nanocarrier system, so-called
emulsomes [2]. Emulsome is preferred mainly because of its four major features.
Firstly, owing a solid lipid core like the solid lipid nanoparticles, emulsome may offer
high loading capacities for hydrophobic substances such as BNIP [2,3]. Secondly,
composed of only lipids and in the absence of any surfactants, emulsome is highly
biocompatible [3]. Thirdly, the solid character of the nanocarrier provides a prolonged
drug release profile, which can be controlled, or tuned, by the selection of the lipid
composition as well as by surface modifications [4]. Lastly, but most importantly, the
natural feature of lipids allows emulsome to accumulate in the organs of the
reticuloendothelial system (RES) instead of the kidney, which will not only largely
reduce toxicity, but will also improve the anti-leishmaniasis efficacy of the loaded drug,
as parazites are also located in the organs of RES.
The development of new active BNIP derivatives and the emulsome-BNIP
nanoformulations facilitating the targeted delivery to the macrophages is expected to
substantially contribute to the improvements in treating parasitic disease Leishmaniasis
in European region as well as worldwide.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 64 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
References
[1] Tavares J., Quaissi A., Lin P.K.T., Loureiro I., Kaur S., Roy N., Cordeiro-da-Silva A.,
ChemMedChem (2010), 5, 140-147
[2] Ucisik M.H., Küpcü S., Debreczeny M., Schuster B., Sleytr U.B., Small (2013), 9, 28952904.
[3] Ucisik M.H., Küpcü S., Schuster B., Sleytr U.B., J. Nanobiotechnology (2013), 11, 37.
[4] Ucisik M.H., Küpcü S., Breitwieser A., Gelbmann N., Schuster B., Sleytr U.B., Colloids Surf.
B. (2015),132-139.
Acknowledgement
This study is supported by Tübitak EU-COST project no. 115Z846 and integrated to the COST
action CM1307 entitled “Targeted chemotherapy towards diseases caused Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 65 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Cyclodextrins in antiparasitic drug formulations
Juan José Torrado
Universidad Complutense de Madrid, School of Pharmacy, Plaza Ramón y Cajal, 28040,
Madrid (Spain), Email: [email protected]
Cyclodextrins are cyclic ring oligosaccharides of six, seven or eight glucose
molecules forming α, β and γ-cyclodextrins, respectively. These cyclic oligosaccharides
are characterized by a pore structure an inner lipophilic diameter of 0.5-0.8 nm. The
hydrophilic hydroxyl groups are located on the outside structure of these cyclic
oligosaccharides while a lipophilic core region is formed. Lipophilic low soluble drug
compounds can be inserted in this lipophilic core part of the cyclodextrins.
Furthermore, on the drug-cyclodextrin mixtures the lipophilic drug molecules are stably
distributed in extremely small particles. This type of distribution increases their surface
area enhancing the relative solubility. These drug-cyclodextrin mixtures can form
different complex interactions with different properties. Two of the most important
characteristics of these drug-cyclodextrin complexes are the solubility improvement
and the increase of stability.
For many lipophilic drugs its low water solubility characteristics compromises its oral
absorption. Inclusion of this type of drugs into cyclodextrins enhances its oral
bioavailability. Moreover, the inclusion of the drug molecules inside the oligosaccharide
ring can avoid or delay chemical degradation reactions. So, chemical stability of the
drug molecules can be improved by complexation with cyclodextrins.
Examples of how different types of cyclodextrins can be useful in antiparasitic drug
formulation are obtained from the scientific literature. The pharmacokinetic and
pharmacodynamic characteristics of drug-cyclodextrin complexes for the treatment of
different parasitic diseases are described. Examples include the following diseases:
-
Leishmaniosis
Trypanosomiasis
Malaria
Trypanosomiasis
Cryptosporidiosis
Toxoplasmosis
Trichinellosis
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 66 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
SCREENING MODELS
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 67 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 68 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
An automated screening technology for the schistosome
helminth parasite
Conor R. Caffrey1, Steven Chen2, Brian M. Suzuki1, Rahul Singh3, Michelle R.
Arkin2
1
Center for Discovery and Innovation in Parasitic Diseases, Skaggs School of Pharmacy and
Pharmaceutical Sciences, University of California San Diego, La Jolla, CA, USA;
2
Small Molecule Discovery Center, Department of Pharmaceutical Chemistry, University of
California San Francisco, San Francisco, CA, USA;
3
Department of Computer Science, San Francisco State University, San Francisco, CA, USA
To accelerate drug discovery for schistosomiasis, we have developed an automated
high-throughput and high-content drug screening platform to quantify the chemically
induced responses of Schistosoma mansoni. I will describe the challenges overcome
to standardize the preparation and handling of the parasite. These include interfacing it
with an automated instrumentation environment - image acquisition, object
segmentation and tracking, and feature extraction. We tested the platform with a
number of anthelmintic drugs to measure a range of static and dynamic phenotypes as
a function of time and concentration. We developed a user interface to visualize and
interrogate the data, which are maintained in a customized database. We combined
the high-dimensional data into a single metric output suitable for primary first pass
library screening. The platform increases throughput, improves rigor and will support
the identification of targets and mechanisms of action.
Supported by NIH grants R01AI089896 and R21AI107390.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 69 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
In vitro ‘time-to-kill’ assay to assess the cidal activity dynamics
of current reference drugs against Leishmania donovani and
L. infantum.
Louis Maes, Jolien Beyers, Annelies Mondelaers, Magali Van den Kerkhof,
Eline Eberhardt, Guy Caljon, Sarah Hendrickx
University of Antwerp, Universiteitsplein 1, 2610 Wilrijk (Antwerp),
Email: [email protected]
INTRODUCTION: Despite a continued search for novel antileishmanial drugs,
treatment options remain restricted to a few standard drugs, e.g. antimonials,
miltefosine, amphotericin B and paromomycin. Although already used now for several
decades, their action mechanism still remains partly hypothetical and their dynamics of
cidal action and time-to-kill are still fairly poorly documented.
METHODS: An in vitro time-to-kill assay on intracellular amastigotes of the
laboratory reference strains Leishmania donovani (MHOM/ET/67/L82) and L. infantum
(MHOM/MA(BE)/67/ITMAP263) evaluated the cidal action dynamics of the listed
reference drugs at three different concentrations: at IC50, 2x IC50 and the near
cytotoxic dose level (CC90: determined on MRC-5 cells). This assay focused at
identifying the minimal exposure time needed to completely eliminate viable
intracellular amastigotes, using the standard microscopic Giemsa-assay and the
promastigote back-transformation assay.
RESULTS: While 100% reduction was microscopically apparent for most drugs, the
promastigote back-transformation assay clearly demonstrated a concentration- and
time-dependent cidal mechanism. The time-to-kill at 2x IC50 was >240h for
pentavalent antimony (77 µg eq./ml), 96h for trivalent antimony (44 µg eq./ml), 168192h for miltefosine (10 µM), 192h for paromomycin (100 µM) and 192-216h for
amphotericin B (2 µM). No major differences were noted between both Leishmania
species.
CONCLUSIONS: Evaluation of the concentration- and time-dependent cidal activity
using the promastigote back-transformation assay revealed striking differences in
efficacy of the antileishmania reference drugs. This assay allows in-depth
pharmacodynamic evaluation of novel drug leads in comparison to the existing
antileishmanial drug repertoire.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 70 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Is it important to include the insect vector to evaluate the
potential of a drug?
Louis Maes, Eline Eberhardt, Mabille Dorien, Lieselotte Van Bockstal, Annelies
Mondelaers, Magali Van den Kerkhof, Sarah Hendrickx, Guy Caljon
University of Antwerp, Universiteitsplein 1, 2610 Wilrijk (Antwerp),
Email: [email protected]
African trypanosomes and Leishmania belong to the same family of protozoan
parasites (Trypanosomatidae) and share the feature of being transmitted by the bites of
blood feeding insects, tsetse and sand flies respectively. The role these bugs in the
parasite transmission cycles clearly extends beyond a role as flying syringes.
These insect vectors create a very peculiar host-parasite interphase which involves
the deposition of parasites in the specific microenvironment of the host dermis together
with a range of pharmacologically and immunologically active components from the
anterior part of the insect alimentary tract and/or from the salivary glands. Recent
findings for tsetse fly transmitted trypanosomes and a review of the sand fly
contribution to Leishmania transmission indicate some distinctive features of infections
initiated through the natural route. Parasites benefit from an altered vector behavior
resulting in multiple inoculations and from co-inoculated components and recruited host
innate immune cells for an enhanced host colonization process. Parasites were also
found to interact with somatic cells such as adipocytes and are able to establish a
dermal parasite population proximal to the site of infection initiation.
Despite the compelling evidence of the importance of the vector component, hostparasite interactions such as parasite virulence (infectivity and fitness), diseaseassociated pathology, and treatment efficacy are nearly exclusively studied in
laboratory rodent models that exclude the insect vector. It can be assumed that the
specific cellular interactions with immune and somatic cells and the parasite tissue
tropism resulting from a bite-mediated transmission could impact treatment efficacy
and relapse rate depending on the specific drug characteristics. Collectively, these
observations advocate for including the insect vector in animal models to evaluate drug
efficacy.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 71 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 72 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
EMERGING ISSUES
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 73 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 74 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Drug absorption modifications in Giardiasis
Verónica Vivancos1; Isabel Gonzalez-Alvarez1, Marta Gonzalez-Alvarez1, María
A. Dea2, María del Val Bermejo1
1
Departamento de Ingeniería. Área Farmacia y Tecnología Farmacéutica. Universidad Miguel
Hernández de Elche. 2. Departamento de parasitología. Universidad Cardenal Herrera CEU,
Valencia
[email protected];[email protected];[email protected];[email protected]
Giardia intestinalis is a flagellated protozoon able to colonize the small intestine of
many vertebrates, including humans. It is the causative agent of giardiasis, one of the
most common reason of parasitic gastrointestinal disease. In children is especially
important as diarrhea and malabsorption are responsible for anemia, stunting and
cognitive delay. Several mechanisms could be involved infection, most notably
impaired intercellular junctions and apoptosis of host cells. After that, it is observed
enterocytes damage, loss of brush border of intestines, shortening of microvilli and
impaired epithelial barrier function.
The effect of Giardia on the absorption of nutrients and vitamins has been widely
studied, although there are few studies conducted on how this parasite affects drug
absorption. Craft et al., found that the absorption of some antibiotics decreased in
patients with giardiasis, compromising the effectiveness and safety of drug therapy.
This is dangerous for paediatric patients because small changes in the absorbed dose
can lead to toxicity or undertherapeutic drug concentrations. A reliable experimental
model for determining the effect that this parasite has on the absorption of drugs is
necessary, especially for drugs with narrow therapeutic window.
Drug absorption experiments were performed using in vitro and in situ models of the
intestinal barrier in the presence and absence of G.intestinalis. The parasite was added
to Caco-2 cells. The transport study was performed in apical to basal direction. Closed
loop in situ perfusion method using the duodenum section (Doluisios´technique) was
also performed. The in vitro Permeability coefficients were obtained by linear
regression of the accumulated amounts versus time in the acceptor chamber after
checking sink conditions maintenance. The apparent first order absorption rate
coefficients (ka) from in situ experiments were obtained by non-linear fitting of a
monoexponential equation to the luminal concentrations versus time.
The results suggest that Giardia intestinalis modifies the permeability of the drugs
tested, which is consistent with the in vivo findings observed in other drugs or nutrients.
The growth of Giardia intestinalis involves the formation of a monolayer that adheres to
the intestinal membrane and prevents the correct performance of biological transport
mechanisms. The permeability is reduced in drugs absorbed by passive diffusion due
to steric hindrance exerted by the parasite. Conversely, the absorption is increased in
drugs transported via the paracellular pathway due to the damage of tight junctions
caused by G. intestinalis. Furthermore, active carriers are blocked in the presence of
G. intestinalis causing a decrease in permeability if the drug is carried by influx, or an
increase in permeability if it is carried by efflux.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 75 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
References: Rópolo, A. S. & Touz, M. C. A lesson in survival, by Giardia lamblia. Scientific
World Journal. 10, 2019-31 (2010). Banik, S., Renner Viveros, P., Seeber, F., Klotz, C.,
Ignatius, R. & Aebischer, T. Giardia duodenalis arginine deiminase modulates the phenotype
and cytokine secretion of human dendritic cells by depletion of arginine and formation of
ammonia. Infect. Immun. 81, 2309-17 (2013).
Acknowledgements: EUROPEAN COMISSION: DCI ALA/19.09.01/10/21526/245-297/ALFA
111(2010)29: Red-Biofarma
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 76 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Fragment-Based Drug Discovery fosters the identification of
new leads against Trypanosoma brucei PTR1
Maria Paola Costi1, Cecilia Pozzi2, Joanna Panecka5, Sheraz Gul3, Anabela
Cordeiro da Silva4, Luca Costantino1, Pasquale Linciano1, Rebecca Wadee,
Stefano Mangani2.
1
Università degli Studi di Modena e Reggio Emilia, Via Campi 103, 41125 Modena, Italy.
Università di Siena, Via Aldo Moro 2 – 53100 Siena, Italy, 3Fraunhofer Institute for Molecular
Biology and Applied Ecology ScreeningPort (Fraunhofer-IME SP), Schnackenburgallee 114, D22525 Hamburg, Germany.4IBMC - Instituto de Biologia Molecular e Celular, Universidade do
Porto, Oporto, Portogual.5Heidelberg Institute for Theoretical Studies (HITS), SchlossWolfsbrunnenweg 35, 69118 Heidelberg, Germany.
2
According to the World Health Organization (WHO), parasitic diseases, such as
African (sleeping sickness) and American (Chagas disease) trypanosomiasis and
Leishmaniasis, affect over three billion people in the world. There is a clear necessity to
discover new targets and new drugs to treat these diseases. Trypanosomatids lack the
ability to synthesize folates de novo and are totally dependent on the salvage of
extracellular folates for growth. However, antifolates cannot be used in the therapy of
trypanosomatidic infections because dihydrofolate reductase (DHFR) inhibition is
compensated by pteridine reductase-1 (PTR1). PTR1 is involved in the reduction of
biopterin but can also reduce folates, thereby safeguarding the cell survival. Therefore,
PTR1 is a promising target for the design and the development of new antiparasitic
drugs. [1] To address these issues, we are employing a fragment-based drug design
(FBDD) approach to drug discovery. Crystallographic screening revealed the binding
modes of several pteridine-like fragments with inhibition constants (Ki) values ranging
between 10-3-10-4 M. Subsequent structure-based design, guided by previously
published structural data, resulted in two series of compounds with high affinity and
good ligand efficiency. Structure–activity relationships were established, and more
potent compounds were designed and synthesized using fragment growth and
fragment linking strategies. All the synthesized compounds were evaluated for their
ability to inhibit parasitic PTR1 as well as other parasitic folate-dependent enzymes (TS
and DHFR) in enzymatic assays. The early toxicity profiles were also determined. All
assays were performed using HTS technologies. Seven new crystallographic structures
of ternary complexes of developed compounds with TbPTR1 and NADPH were also
obtained. The determined poses support the design by reproducing the poses and by
retaining the key interactions of the initial binding fragments. Additional binding regions
surrounding the PTR1 active site were also identified. The compounds were tested
against different parasites as single agents and in combination with methotrexate,
revealing good antiparasitic activity, selectivity and synergy against T. brucei. The
progress of the compounds through the pipeline reduced the liabilities of the drug
candidates, allowing us to identify the best candidates for further in vivo studies, such
as the determination of the pharmacokinetic and antiparasitic activity in mouse models.
The resultssuggest that the FBDD approach provides a route to high-quality lead
candidates.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 77 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
This work was carried out by the NMTrypI (New medicine for Trypanosomatidic Infections,
www.nmtrypi.eu) consortium with funding from the European Union’s Seventh Framework
Programme for research, technological development and demonstration under grant agreement
No. 603240.
Reference [1] Cavazzuti, A., et al., Discovery of potent pteridine reductase inhibitors to
guide antiparasite drug development. Proc Natl Acad Sci U S A, 2008. 105(5): p. 144853.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 78 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
CHEMOTHERAPY OF PARASITIC
DISEASES IN HUMAN AND
VETERINARY MEDICINE
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 79 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 80 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Anti-parasitic treatment in veterinary medicine: a big
challenge..!
Kurt Pfister
Prof. Dr. med. vet., Dip EVPC
Parasite Consulting GmbH, CH-3006 Berne – Switzerland
&
Comparative Tropical Medicine and Parasitology, LMU Munich - Germany
www.parasiten-bekaempfung.ch
Parasites are widely spread in domestic and wild animals all over the world, and
quite many are of considerable relevance in veterinary medicine.
It is primordial to notice that the major impact of veterinary parasites is much more
their pathogenic potential and therewith associated clinical and pathologic
consequences for the animals including the economic losses for the owners, rather
than their presence in a host or their overall prevalence. For many parasites, this is
even the case with regard to their zoonotic potential. It is thus obvious that such
aspects have several consequences for the decision whether or not to initiate an
antiparasitic treatment. In many respect, endemic outbreaks of certain parasite
infections in livestock but also in other animals have often caused high lethal rates and
therewith associated tremendous economic losses.
The discovery and introduction of highly efficacious drugs in the 1960-1970’s (BZM,
Pyrimidines, Imidazothiazoles) and subsequently of the AVM (1980’s) has given rise to
the most welcomed idea of the so-called mass treatment strategy. To some extent this
was initially even thought to have the potential to eliminate (or even eradicate) some
parasites of greater pathologic/clinical importance. However, it became relatively
qjuickly evident that one of the most severe (negative) consequence of this „routine
type of treatment over years“ was a selection for specific drug-resistant parasite
populations. The development of resistance became rather quickly relevant for some
pathogenic nematodes in small ruminants (sheep and goats) and equids, but is
meanwhile also widely detectable in various cattle and pig parasites as well as in other
animal species.
Another important issue regarding mass treatment is the so-called „overtreatment“of animals at a too young age (or entire flocks: e.g. against D. viviparus or O.
ostertagi in cattle, etc.) which has led to an insufficient immune reaction and
consequently in many cases to subsequent lethal disease outbreaks (due to a lacking
immune reaction).
A quite important handicap in veterinary parasitology – for several parasite species
– is the lack of authority-registered drugs and, according to the animal species (in
particular for livestock), drug-related withdrawal periods for their products (milk, meat
etc.) have to be respected. Consequently, such hurdles have to be taken into
consideration, too.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 81 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
What can we conclude from all the presented aspects and what kind of
consequences should we consider? In order to better deal with this we have to
consider:
‐
the way of treatment
‐
the status of resistance
‐
the biology (reachability of the parasite in a high metabolic activity stage)
‐
the specific diagnosis and appropriate parasite identification
‐
the seasonal occurrence (epidemiology)
‐
in some cases rather a metaphylactic instead of a prophylactic treatment
‐
the economic (and maybe the zoonotic) importance of the parasite
infection to be treated
‐
the immune competence of the given parasite species
An alternative treatment approach to the above focuses either predominantly on
animals with a high environmental contamination rate (e. g. egg production) or, on
animals which are highly affected, i. e. which carry a high, clinico - pathologically
relevant parasite burden. This approach – typically evidence-based - is called
„selective treatment“, is epidemiologically appropriate and includes often also an
adaptation of management aspects for the given flock/herd/farm/pet family. There are
various types of selective treatment, but most importantly, this procedure allows to
maintain at the same time a refugium of drug-sensitive parasites on a given
entity/surface.
However, there are also a lot of parasites (e. g. many coccidia species, various
gastrointestinal cestodes, trematodes and nematodes) which are of a high prevalence
but which do not need any treatment because of their low-level pathologic potential.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 82 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Past, Present and Future of Endoparasiticides at Merial
John M. Harrington
Merial, Inc., Duluth, GA, USA., [email protected]
While Merial has existed in an independent form since 1997, its origins can be
traced back decades further and include fundamental discoveries in anthelmintic
chemotherapy and introduction of products that revolutionized production and
companion animal health. Paramount to these products are the macrocyclic lactones
exemplified by ivermectin. The discovery of ivermectin and subsequent development
of related compounds such as eprinomectin hold important lessons for the anthelmintic
discovery and development process today.
While these compounds laid the
foundations for Merial’s current leadership in animal health parasiticides, Merial’s
worldwide presence also facilitates our leadership in solutions to animal diseases
caused by protozoan parasites. A historical footprint, industrial collaborations and
regional hubs in African countries allow us to provide the only complete program for
prevention and treatment of animal trypanosomiasis. Looking forward, Merial’s
pharmaceutical discovery group is poised to deliver new solutions to issues such as
resistance by finding molecules with new modes of action. To do so, we utilize diverse
technologies including phenotypic and target based screening and engage in
collaborations with academic research groups, crop-protection and human health
partners. With these efforts we will uphold the high standards of parasiticide discovery
and development that are at the basis of Merial’s origins.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 83 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 84 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
POSTERS
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 85 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 86 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.1. Identification of protein kinase inhibitors in Cystoisospora
suis by genomic-based virtual screening
Alfonso Garcia-Sosa1, Nicola Palmieri2
1
Institute of Chemistry, University of Tartu, Ülikooli 18, 50090 Tartu, Estonia – email:
[email protected] ; 2 Institute of Parasitology, Department of Pathobiology, University of
Veterinary Medicine, Veterinärplatz 1, A-1210, Vienna, Austria – email:
[email protected]
Cystoisospora suis is a protozoan parasite (phylum Apicomplexa) that causes
enteritis and diarrhea in suckling piglets and is responsible for significant economic
losses in swine production across Europe and worldwide. While this disease is
currently treated with toltrazuril, drug costs and drug resistance are of increasing
concern. Protein kinases are attractive drug targets in Apicomplexa, as they have
pleiotropic roles in many essential cellular processes. However, the screening for
kinase inhibitors among thousands of molecules can be a daunting task, thus virtual
screening methods can be a powerful way to scan large libraries of molecules. Here we
sequenced and annotated the 84Mb genome of C. suis and identified a set of 318
protein kinases through functional annotation analyses. Comparative searches with the
Protein Data Bank identified the presence of an ortholog 3D protein structure for one of
these kinases (CDPK1) in the closely related species Toxoplasma gondii. By using this
structure as a template we constructed a homology 3D model for the C. suis CDPK1
and used it for scanning a library of commercially available drug compounds by
molecular docking techniques, in order to find potential inhibitors. We identified 60
natural compounds with low Glide docking scores including two interesting candidates
with low molecular weight: 2-(4-hydroxyphenyl)ethyl and a gallotannine. These
molecules will be tested on an established in vitro model of C. suis through invasioninhibition assays. Our study showed that is possible to pinpoint molecules with
bioactive function in a non-model organism using an in-silico approach based on
genomics and proteomics data.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 87 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.2. New bis-pyridazine derivatives of potential interest in
leishmaniasis
Violeta Vasilache,2,3 Dorina Mantu,1 Vasilichia Antoci,1 Ionel I. Mangalagiu1
1
“Alexandru Ioan Cuza” University of Iasi, Faculty of Chemistry, Bd. Carol 11, 700506 Iasi,
Romania; 2“Alexandru Ioan Cuza” University of Iasi, CERNESIM Research Center, Bd. Carol 11,
700506 Iasi, Romania; 3“Stefan cel Mare” University Suceava, Faculty of Food Engineering, Str.
Universitatii 13, Suceava, Romania.
Cutaneous Leishmaniasis is the most common form of leishmaniasis.
Current treatments for cutaneous leishmaniasis are performed with success using
classical drugs such us pentamide and imidazoquinolines. However, their use is limited
by their toxicity, side effects, relatively high cost, discomfort and the emergence of drug
resistance. This is why new approaches are urgently needed.
Nitrogen derivatives are “privileged structures” in drug design, optoelectronics, etc.,
the azaheterocycle scaffold being a core skeleton for multiple purposes.
Pentamide is a second-line drug largely used in treatment against cutaneous
leishmaniasis caused by Leishmania major infection.
The emphasis of this work consist in design, synthesis and characterization of new
bis-pyridazine derivatives of potential interest in leishmaniasis, analogues of
pentamide.
The in vitro anti-leishmaniasis tests are under going.
Acknowledgements. Authors are thankful to COST Action: CM1307 and to CNCS Bucharest,
Romania, project PN-II-DE-PCE-2011-3-0038, no. 268/05.10.2011, for financial support.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 88 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.3.Preliminary in vitro studies of antiprotozoal activity of some
heterocyclic N-oxides and N,N’-dioxides
Jonas SARLAUSKAS1,Philippe GRELLIER2, Diego BENITEZ3, Marcelo A.
COMINI3, Louis MAES4, Jurgen JOOSSENS5, Sandrine COJEAN6 , Philippe
LOISEAU6, and Narimantas CENAS1
1
Department of Xenobiotics Biochemistry of Institute of Biochemistry, Vilnius University,
Sauletekio av. 7, Vilnius, LT-10257, Lithuania; 2Laboratoire USM 0504 Biologie Fonctionnelle
des Protozoaires, Département RDDM, Museum National d'Histoire Naturelle, FRE 3206
CNRS, 61 rue Buffon, Paris Cedex 05, France; 3Redox Biology of Trypanosomes Laboratory,
Institut Pasteur de Montevideo, Mataojo 2020, Montevideo, Uruguay; 4Laboratory of
Microbiology, Parasitology and Hygiene (LMPH), Departments of Pharmaceutical and
Biomedical Sciences,University of Antwerp (UA), Universiteitsplein 1, B-2610 Antwerp, Belgium;
5
Medicinal Chemistry (UAMC), Department of Pharmaceutical Sciences, University of Antwerp
(UA), Universiteitsplein 1, B-2610 Antwerp, Belgium; 6Groupe Chimiotherapie Antiparasitaire
UMR 8076 CNRS Faculte de Pharmacie Universite de Paris-Sud 11, France
E-mail: [email protected]
In this continuation of our collaborative research [1-3] we have studied in vitro
antiprotozoal activity of some compounds from the three selected chemical classes of
potentially interesting redox active agents: substituted benzofuroxans, pyridine Noxides and quinoxaline N, N’-dioxides. The library of all studied compounds were
synthesized in Vilnius University by one of the authors (J.S.) The aim of the present
research was to investigate the main structure-activity relationships and to detect the
most perspective pharmacophoric functional groups for the further structure
optimization.
Generally, it was found that a number of functional groups located at specific
positions of aromatic ring in evaluated heterocyclic molecules can serve as promising
pharmacophores: nitro, halogens (Cl, Br), CF3 and in some particular cases, CH3 and
alkoxy/ alkylendioxy groups. A potential impact of enzymatic bio-reduction products
(1,2-benzoquinondioxime (o-BODOX) and 2,3-diaminophenazine (PHADA) [5]) and
their derivatives as an active metabolites of benzofuroxans on antiparasitic activity
has been proposed in the present work for the first time.
In this preliminary study, the most effective compounds were found: against
Plasmodium falciparum str. FcB1 (chloroquine resistant strain) - JSQ-33 (pyridine Noxide derivative, IC50 =5.4 µM), against Trypanosoma brucei brucei str. 427 – JOSHA20 (benzofuroxan derivative, IC50=0.3 µM), against Trypanosoma cruzi Tulahuen CL2
strain – LXBD-096 (benzofuroxan nitroderivative, IC50=4.5 µM) and against Leishmania
donovani - JSLT-09 (pyridine N-oxide derivative, IC50=1.6 µM).
1. Grellier, P. et al, Arch Biochem Biophys. 2010; 394(1):32-39.
2. Sarlauskas, J. et al:
http://www.vin.bg.ac.rs/180/cost_cm1307/CM1307_Belgrade_oct_2015_book_of_a
bstracts.pdf, p.57
3. Benitez D. et al. PLOS Neglected Tropical Diseases. 2016, 10: e0004617.
4. Sarlauskas J. et al, Int. J. Mol. Sci., 2014, 15: 23307-23331.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 89 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.4. Structural basis for vinyl sulfone inhibition of the SmCB1
drug target from the human blood fluke
Adela Jilkova1, Martin Horn1, Petra Rubesova1, Pavla Fajtova1, Pavlina
Rezacova1, Jiri Brynda1, James H. McKerrow2, Conor R. Caffrey2 and
Michael Mares1
1
Institute of Organic Chemistry and Biochemistry, The Czech Academy of Sciences, Flemingovo
nam. 2,16610 Prague, Czech Republic; 2Center for Discovery and Innovation in Parasitic
Diseases, Skaggs School of Pharmacy and Pharmaceutical Sciences, University of California,
San Diego, San Diego, CA 92093, USA
Schistosomiasis caused by parasitic blood flukes of the genus Schistosoma afflicts
over 240 million people worldwide. Schistosoma mansoni cathepsin B1 (SmCB1) is a
gut-associated peptidase that digests host blood proteins as a source of nutrients. In
our recent work we demonstrated that SmCB1 is a drug target for vinyl sulfone
peptidomimetic inhibitors. Now we performed a detailed analysis with a unique set of
30 vinyl sulfone derivatives with diverse substituents. The inhibitors were screened in
vitro against recombinant SmCB1 and ex vivo against cultivated S. mansoni. Two most
effective inhibitors in terms of IC50 values and parasite suppression were complexed
with SmCB1, and high resolution crystal structures were determined. Analysis of 3D
structures and inhibition profiling identify key binding interactions and provide insight
into SmCB1 inhibition specificity. Our work provides a footing for the rational design of
anti-schistosomal chemotherapeutics.
This work was supported by the grant LD15101 and the project InterBioMed LO1302 from the
Ministry of Education, Youth and Sports of the Czech Republic, the institutional project RVO
61388963, the Academy of Sciences of the Czech Republic, and the Skaggs School of
Pharmacy and Pharmaceutical Sciences.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 90 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.5. Anti-Leishmania activity of a series of
Quinolin-4(1H)-imines
Ana G. Gomes-Alves1,2,3, Margarida Duarte1,2, Tânia Cruz1,2, Rui Moreira4, Ana
S. Ressurreição4,*, Ana M. Tomás1,5,*
1
i3S - Instituto de Investigação e Inovação em Saúde, Porto, Portugal. 2IBMC - Instituto de
Biologia Molecular e Celular, Porto, Portugal. 3University do Minho, Braga, Portugal.
4
iMed.ULisboa - Research Institute for Medicines, Lisboa, Portugal. 5 ICBAS - Instituto de
Ciências Biomédicas Abel Salazar, Porto, Portugal.
E-mail: *[email protected]; [email protected]
Leishmaniasis comprise a set of neglected tropical diseases, caused by
trypanosomatid protozoan parasites of the genus Leishmania. Depending on the host
immune response and on the Leishmania species, leishmaniasis can range from a
nonlethal cutaneous form (e.g. by L. major and L. amazonensis) to a fatal visceral
condition (e.g. by L. infantum). Current treatments for leishmaniasis rely on inadequate
chemotherapeutics with poor efficacy and high host toxicity forcing people to stop
therapy. This leads to disease relapse and emergence of resistant strains. Besides
this, the high costs associated to most of the available therapeutic options are far from
suitable for developing countries.
This absence of satisfactory treatments prompts the discovery of new compounds
with leishmanicidal activity. Using a high content-based platform previously
implemented in the lab, we screened about 40 different compounds against
intracellular L. infantum (in bone marrow-derived macrophages). From this screening, a
set of quinolin-4(1H)-imines, which were previously shown to display antiplasmodial
activity [1], emerged as the most interesting family of compounds, the most active ones
presenting half maximal inhibitory concentrations (IC50) around 1µM and selectivity
indexes of 7-11 (host cell cytotoxicity evaluated also in bone marrow-derived
macrophages). Quinolin-4(1H)-imines active against L. infantum were also tested
against intracellular L. major and L. amazonensis but we observed a lower activity
against the cutaneous forms of the disease (IC50 two to three times higher when
compared to L. infantum).
Some quinoline derivatives were previously suggested to have their mechanism of
action on the disruption of normal mitochondrial function in Plasmodium falciparum [2].
Quinolin-4(1H)-imines were initially designed to target mitochondrial cytochrome bc1
[1]. The inhibitory effect on the basal oxygen consumption of intact L. infantum
amastigotes, suggests that the mode of action of these compounds could also include
inhibition of cytochrome bc1 and/or other respiratory chain enzymes.
In short, this study suggests that quinolin-4(1H)-imines might be an interesting
chemotype in the search of new anti-Leishmania leads.
Ana G. Alves and Ana S. Ressurreição are financed by the Portuguese Foundation for Science
and Technology with PhD (SFRH/BD/93766/2013) and FCT Investigator Starting
(IF/01034/2014) Grants, respectively.
[1] a) Ressurreição, et al. Med. Chem. 2013, 56, 7679; b) Rodrigues, et al Med. Chem. 2013,
56, 4811.
[2] Teguh, et al. Med. Chem. 2013, 56, 6200.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 91 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.6. Development of new quinone derivatives against
Leishmania
Carmen Gil, Maria Ángeles Abengózar, Sara Sandoval, Víctor Sebastián,
Ana Martínez, Nuria E. Campillo, Luis Rivas
Centro de Investigaciones Biológicas (CSIC), Ramiro de Maeztu 9, 28040 Madrid, Spain
Contact: [email protected]
From a human health perspective, leishmaniasis is the second protozoan disease in
importance, only superseded by malaria. The disease encompasses the wide range of
clinical pathologies produced by the infection with different protozoan species of the
genus Leishmania. Globally, the disease accounts for 10-12 million people infected
worldwide, with an incidence of 1.5 million new cases per year. Despite the
considerable advances carried out in the last years, nowadays none human vaccine is
currently available, and the efforts to curtail dissemination by vector and reservoir
control are far less than satisfactory. This leaves chemotherapy as the sole method to
combat efficiently the disease. The chemotherapeutic arsenal is quite limited and its
efficacy is increasingly eroded by growing resistance, aside from the severe side
effects associated to many of them. Furthermore, the high cost for their implementation
is unaffordable for the bulk of the patients, belonging to low-income countries. Thus,
development of new drugs is urgently required.1
In this work the search of new drugs for leishmaniasis was based on a phenotypicbased approach using as source of new hits our in-house chemical library. A new class
of quinone derivatives has emerged as potential hits for this disease and a medicinal
chemistry optimization program is ongoing. Furthermore, initial results on their
mechanism of action supported the importance of the bioenergetic collapse of the
parasite induced by the quinones, with a rapid drop of intracellular ATP levels in the
parasites and decrease of the respiration rate in Leishmania donovani promastigotes.
Its role in the lethal mechanism of these quinones and SAR studies with a limited set of
compounds will be discussed.
Acknowledgments: This work was supported by the Spanish Ministry of Economy and
Competitiveness (MINECO, project no. SAF2015-65740), Redes de Investigación Cooperativa
Instituto de Salud Carlos III RICET (RD12/0018/0007 & RD16/0027/0010) and FEDER funds.
1
Nagle, A. S.; Khare, S.; Kumar, A. B.; Supek, F.; Buchynskyy, A.; Mathison, C. J.;
Chennamaneni, N. K.; Pendem, N.; Buckner, F. S.; Gelb, M. H.; Molteni, V. Recent
developments in drug discovery for leishmaniasis and human African trypanosomiasis. Chem
Rev 2014, 114, 11305-11347.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 92 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.7. Molecular Characterisation and cloning of Novel
Equilibrative Nucleoside Transporter family members in
Trichomonas vaginalis
Manal J. Natto, Neils B. Quashi and Harry de P. Koning
Institute of Infection, Immunity and Inflammation, University of Glasgow, UK
E-mail: [email protected]
Trichomoniasis is the most common, non-viral sexually transmitted disease (STD),
caused by the amitochondriate protozoan Trichomonas vaginalis. The disease annually
affects over 170 million people in the world. Increased resistance of T. vaginalis to
metronidazole, the drug of choice for the treatment of the disease, necessitates the
development of newer chemical entities with different chemotypes. To date, no highthroughput library screens have been performed against this parasite, but it is possible
to identify essential biochemical pathways in this parasite. The nucleoside/nucleobase
salvage system of the parasite is an attractive target, because the parasite cannot
synthesise either purines or pyrimidines de novo and has to salvage the nutrients from
the host through transporters, whereas their human hosts have both purine salvage
and synthesis pathways for purines and pyrimidines. Therefore, depriving the parasites
of these essential requirements, through controlled blockage of the salvage pathways,
is certain to cause parasite death, but should not affect the human host. Nucleoside
salvage in the parasite was therefore systematically investigated using the rapid oil
stop technique. The results show the existence in T. vaginalis of at least four
transporters: with high and low affinity for purine and pyrimidine nucleosides as well as
adenine similar to that of the Equilibrative Nucleoside Transporter (ENT) family
observed for other protozoans. In order to match the observed transport activities to
genes, all 9 T. vaginalis ENT genes were cloned, sequenced, and expressed in
Trypanosoma brucei, selecting a strain from which one of the main nucleoside
transporters, TbAT1, was already deleted. Each gene was resynthesized in the codon
preference of T. brucei since T. vaginalis DNA is very A/T-rich. This will allow us to
characterise each of the transporters in isolation. Two identical sets of transfectants are
being constructed: one with synthetic but other original open reading frames, and one
with the ORFs coupled C-terminally to Green Fluorescent protein to assess cellular
localisation of the gene products.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 93 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.8. Anti-toxoplasma activity of novel macrolide hybrid
derivatives
Mihaela Peric1, Budhaditya Mukherjee2, Andrea Fajdetic3,4,
Dominique Soldati-Favre2
1
University of Zagreb School of Medicine, Center for Translational and Clinical Research,
Salata 2, 10000 Zagreb, Croatia; 2 University of Geneva, Faculty of Medicine, Department of
Microbiology and Molecular Medicine, Rue Michel Servet 1 - 1211 Genève 4, Switzerland;
3
Fidelta d.o.o., Prilaz baruna Filipovića 29, 10000 Zagreb, Croatia; 4 Present address: Xellia
d.o.o (Xellia Ltd), Slavonska avenija 24/6, 10000 Zagreb, Croatia
Novel therapeutics to treat toxoplasma infections are highly needed since currently
available therapeutic options are limited and often associated with safety and parasite
resistance issues. Azithromycin is a semi-synthetic macrolide antibiotic, the first
member of the azalide class. It is also known for its antimalarial and anti-toxoplasma
activity and its clinical usefulness and safety have been well documented. Recently,
novel classes of azalide derivatives were reported as potent antimalarial agents. Two
of the most promising derivatives, both comprising azithromycin scaffold with
chloroquinoline moiety linked at two different positions, were tested in various
Toxoplasma gondii in vitro assays and their activity compared to azithromycin and
clarithromycin. Both compounds exhibited improved activity over standard macrolide
antibiotics. As two macrolide hybrid compounds have the same building blocks their
mode of action could be linked to the specific linking position on the azalide scaffold. In
conclusion, macrolide hybrid compounds have the potential to be further investigated
as promising anti-toxoplasma agents.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 94 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.9. Anti-malarial combination therapy: synergistic effect
between an antisense strategy and different anti-malarial drugs
in resistant strains of Plasmodium falciparum
Soulaf Suyyagh-Albouz1, Fernanda Bruxel2, Nicolas Tsapis3, Elias Fattal3,
Philippe Loiseau1, Helder Teixeira4, Sandrine Cojean1,5.
1
Université Paris-Sud, UMR 8076 BioCIS CNRS, LabEx LERMIT, Châtenay-Malabry
2
Universidade Federal do Pampa, Brésil
3
Université Paris-Sud, UMR 8612 institut Galien Paris Sud, CNRS, Châtenay-Malabry
4
Universidade Rio Grande do Sul, Porto Alegre, Brésil
5
CNR Paludisme, Hôpital Bichat Claude Bernard, Paris
In these days, only the Artemisinin-based Combination Therapy still effective in
fighting malaria. But a threat exists in these associations due to the emergence of
resistance to artemisinin derivatives in Southeast Asia. Which could lead to a restriction
in used anti-malarial drugs as increasing doses is limited to avoid toxicity.
Antisense strategies represent a promising new therapeutic approach targeting
nucleic acids. Antisense oligonucleotides (ODN) may be employed to treat malaria.
Their limitations were mainly their low intracellular penetration to their target and their
rapid degradation. New generations of vectors have helped to enhance the effects of
ODN with reduced toxicity. During our studies, we have developed a cationic
nanoemulsion (NE) in order to adsorb ODN directed against the topoisomerase II of
Plasmodium falciparum. This NE/ODN allowed the inhibition of parasite growth.
To develop a combination therapy, some anti-malarial drugs, whose resistances are
proven, were associated with the NE/ODN. We tested our NE/ODN in combination with
chloroquine, atovaquone and dihydroartemisinin on the 3D7 strain sensitive to all antimalarial drugs, the W2 strain resistant to chloroquine and PAV strain resistant to
atovaquone. A synergistic effect, no matter which anti-malarial drug was associated
with the NE –ODN, was observed. There was also a limited reinfection in presence of
the different combinations even in the resistant strains.
Our perspective is to encapsulate the atovaquone inside the NE/ODN due to its
lipophilic properties in order to prevent or reverse the resistance, and reduce the dose
used by increasing the bioavailability of atovaquone.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 95 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.10. Drug repurposing of human kinase inhibitors as new hits
against Leishmania
Carmen Gil, Maria Ángeles Abengózar, Paula Martínez de Iturrate, Víctor
Sebastián, Ana Martínez, Nuria E. Campillo, Luis Rivas
Centro de Investigaciones Biológicas (CSIC), Ramiro de Maeztu 9, 28040 Madrid, Spain
Contact: [email protected]
Treatment of leishmaniasis, the second human protozoan disease in importance,
relies almost exclusively on chemotherapy, on its turn reduced to a scarce number of
drugs. Their efficacy is threatened by rising resistance, and pipeline for new leads is
scarcely populated. Due to the low economical level of the bulk of affected population,
investment for development of new drugs received a poor investment. Drug
repurposing resulted as a fast and low cost approach to add new drugs into
leishmaniasis treatment.2
The inhibition of protein kinases of Leishmania constitutes an appealing approach to
tackle infections by this parasite. Globally, protein kinases constitute a substantial
target of the drug discovery efforts, accounting for nearly a third of the “druggable
genome”. In fact, the inhibition of specific protein kinases by small molecules inhibitors
has been pharmacologically validated for the treatment of a wide range of therapeutic
indications. This fact, together with the growing number of parasite kinases validated
as targets for parasitic disease allowed us to surmise that protein kinases are
druggable targets for leishmaniasis.3
Based on our previous experience on human GSK-3 and CK1 inhibitors, we have
focused our attention on these two kinases also present in Leishmania (GSK3 and
CK1.2) as targets for the development of antileishmania drugs. A number of specific
human kinase inhibitors with different chemical structures have been tested in a
phenotypic assay at low micromolar concentrations, some of them with an adequate
specificity index. Their ability to inhibit Leishmania kinases will be further elucidated by
experimental and molecular modelling techniques.
Acknowledgments: This work was supported by the Spanish Ministry of Economy and
Competitiveness (MINECO, project no. SAF2015-65740), Redes de Investigación Cooperativa
Instituto de Salud Carlos III RICET (RD12/0018/0007 & RD16/0027/0010) and FEDER funds. P.
M. acknowledges the contract from the Fondo de Garantía Juvenil (European Social Fund,
Youth Employment Initiative) and FEDER funds.
2 Andrews,
K. T.; Fisher, G.; Skinner-Adams, T. S. Drug repurposing and human parasitic
protozoan diseases. Int J Parasitol Drugs Drug Resist 2014, 4, 95-111.
3
Merritt, C.; Silva, L. E.; Tanner, A. L.; Stuart, K.; Pollastri, M. P. Kinases as druggable targets
in trypanosomatid protozoan parasites. Chem Rev 2014, 114, 11280-11304.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 96 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.11. Microwave-assisted and conventional 1,3-dipolar
cycloaddition reactions to the synthesis of some
benzimidazole/(benzo)indolizine hybrids: a comparative study
Roumaissa Belguedj1,2, Christophe Menendez2, Michel Baltas2,
Abdelmalek Bouraiou1
1
Université des Frères Mentouri, Unité de Recherche de Chimie de l’Environnement et
Moléculaire Structurale, Constantine 25000, Algérie ; 2Université Paul Sabatier, Laboratoire de
Synthèse et Physico-Chimie de Molécules d’Intérêt Biologique, UMR-CNRS 5068, Toulouse,
France
Indolizines constitute the core structure of many naturally occurring alkaloids such
as, (-)-slaframine,1 (-)-dendroprimine, and coniceine. Many indolizine derivatives have
important biological activities, including anti-inflammatory, anti-HIV, hypoglycemic, CNS
depressant1
The synthetic utility of microwave irradiation has increased considerably in recent
years due to its capacity to reduce chemical reaction times, increase yields, and in
some cases to lead to outcomes different from those obtained with conventional
means2.
In continuation of our research interest in heteroatomic N-ylide involving 1,3cycloaddition reactions3 we report here the synthesis, spectroscopic identification and
the crystal structures of some new benzimidazole/(benzo)indolizine hybrids and
benzimidazole/furane compounds Indolizines were obtained via 1,3-dipolar
cycloaddition of alkynes with 1-(2’-benzimidazolyl-methyl)(benzo)pyridinium ylide.
Optimal conditions under microwave has been elucidated and compared to the
conventional ones indicating that reactions for the microwave-assisted 1,3cycloaddition reaction of 1-(2’ benzimidazolylmethyl) (benzo) pyridinium ylide are faster
and higher-yielding. Similarly furanes were obtained via a three component reaction
using 1-(2’-benzimidazolylmethyl)(benzo)pyridinium ylides, benzaldehyde derivatives
and active methylene compounds (ie. 2,4-pentanedione and ethyl acetoacetate).
The biological activities of some synthesized indolizines and furanes against
Leishmania Parasite4 are underway by the team of Pr. P. Loiseau.
R1
1
2
R
N
N
H
(1)
(2)
(3)
(4)
N
R
MW
Cl
N
N
H
R2
N
G. S. Singh, E. E. Mmatli, Eur. J. Med. Chem. 2011, 46, 5237.
M. Pineiro, T. M. V. D. Pinho e Melo, Eur. J. Org. Chem. 2009, 5287.
R. Belguedj, A. Bouraiou*, S. Bouacida, H. Merazig, A Chibani, Z. Naturforsh. 2015,
885.
J.F. Marquis, I. Hardy, M. Olivier, Parasitology. 2005, 131, 197.
We thank (Ministère de l’Enseignement Supérieur et de la Recherche Scientifique) Algerie, for
PNE program (Programme National Exceptionnel, R.B.) and CNRS/France and the University
Toulouse 3 for financial support.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 97 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.12. DFT studies of autoxidation of 2-alkylidene-1,3cyclohaxadione leading to bicyclic-hemiketal endoperoxides
B. Tuccio,1 C. André-Barrès2
1
Institut de Chimie Radicalaire, UMR AMU-CNRS 7273, Laboratoire Chimie Provence, Equipe
SACS, Aix-Marseille Université, Campus de Saint Jérôme, 13397 Marseille cedex 20, France
2
Laboratoire de Synthèse et de Physicochimie de Molécules d'Intérêt Biologique, UMR CNRS
5068, Université Paul-Sabatier, 118 route de Narbonne, F-31062 Toulouse cedex 04, France
We are interested in antimalarial agents acting as artemisinin and we focused on the
syntheses of new endoperoxides, related to the natural phytohormones known as G
factors (G1, G2, G3) issued from the leaves of Eucalyptus grandis. The synthesis is
based on spontaneous oxygen uptake on a dienol system furnishing exclusively
required endoperoxides.
This autoxidation was investigated by a combined spin trapping/EPR/mass
spectrometry approach allowing the characterizing of the diradical species present in
pathway B.
Based on these previous results, a theoretical study was undertaken.
Each step of the mechanism of addition of triplet oxygen on the dienolic precursor
was calculated by DFT using the restricted or unrestricted B3LYP with 6-311+G(d,p) as
set of bases. The geometry and energy of each minima and transition states were
characterized, in singlet and triplet state, allowing the description of the complete
reaction pathway of the formation of endoperoxides. The crossing between triplet and
singlet potential energy surfaces was found. The singlet diradical character changing
was also examined along the intrinsic reaction coordinate (IRC) calculations leading to
the endoperoxide.
Mathilde Triquigneaux, Laurence Charles, Christiane André-Barrès and Béatrice Tuccio, Org.
Biomol. Chem., 2010, 8, 1361-1367.
Jérémy Ruiz, Joëlle Azéma, Corinne Payrastre, Michel Baltas, Béatrice Tuccio, Henri Vial,
Christiane André-Barrès. Current Topics in Medicinal Chemistry, 2014, 14, 1668-16683.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 98 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.13. Dinitroaniline-Ether Phospholipid Hybrids
M. Roussaki1, K. C. Prousis1, P. Afroudakis1, A. Cordeiro-da Silva2, N.
Santarem2, D. Costa2, S. Gul3, J. Clos4, I. M. de Amorim,5 E.S. Barrias,6 W. de
Souza,5 T.M.U. de Carvalho5, T. Calogeropoulou1*
1
National Hellenic Research Foundation, Institute of Biology, Medicinal Chemistry and
Biotechnology, Athens, Greece; 2Instituto de Investigação e Inovação em Saúde, Universidade
do Porto, Portugal and Instituto de Biologia Molecular e Celular (IBMC) da Universidade do
Porto, Portugal; 3Fraunhofer Institute for Molecular Biology and Applied Ecology IME, Hamburg,
Germany; 4Bernhard Nocht Institute for Tropical Medicine, Hamburg, Germany; 5Laboratório de
Ultraestrutura Celular Hertha Meyer, Instituto de Biofísica Carlos Chagas Filho, CCS, UFRJ, Rio
de Janeiro, Brazi; l6Diretoria de Programas, Instituto Nacional de Metrologia, Qualidade e
Tecnologia-Inmetro, Xerém, Rio de Janeiro, Brazil
Email: [email protected]
Protozoa are unicellular eukaryotes and represent one of most important
sources of parasitic diseases. Every year, more than one million people die from
complications from protozoal infections worldwide. Trypanosomatidae protozoa
constitute the causative agents of several human diseases such as Chagas disease
(Trypanosoma cruzi), sleeping sickness (Trypanosoma brucei) and leishmaniasis
(Leishmania sp). These illnesses have been classified by the WHO as neglected
diseases, which affect people living in poverty in developing countries and for which no
efficient therapy is available.2,3 Miltefosine (hexadecylphosphocholine) is an
alkylphosphocholine with demonstrated activity against various parasite species and
cancer cells, as well as some pathogenic bacteria and fungi. Moreover, Miltefosine is
currently the only oral drug available for the treatment of visceral (VL) and cutaneous
leishmaniasis (CL). However, at the therapeutically effective doses, severe
gastrointestinal side effects and serious weight loss were observed while, teratogenicity
remains a problem.
During the last decade our group has been investigating ring-substituted
alkylphosphocholines and we have indicated that introduction of cycloalkane rings in
the lipid portion provides compounds with enhanced activity and reduced toxicity.1-3
In the context of more in depth SAR studies we designed and synthesised hybrid
molecules which combine in one molecular scaffold two pharmacophores, the
dinitroaniline moiety and the ether phospholipid structure.4 This approach would enable
us to address two different mechanisms of action, namely the inhibition of the alphatubulin of the parasite, targeted by dinitroaniline herbicides such as trifluraline, and the
putative molecular targets of alkylphosphocholines.
The new trifluraline-substituted ether phospholipids encompass analogues
active against L. infantum, L. donovani and T. cruzi amastigotes as well as T. b. brucei
(blood stream form). Extensive ADME-Tox studies demonstrated that the toxicity of the
majority of the compounds is very low and much lower than Miltefosine, especially
against THP-1 macrophages.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 99 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Acknowledgement
This project has received funding from the European Union’s Seventh Framework Programme
for research, technological development and demonstration under grant agreement n° 603240
(NMTrypI - New Medicine for Trypanosomatidic Infections). http://www.nmtrypi.eu/
References
1
Calogeropoulou et al. (2012), US8,097,752
Calogeropoulou. et al. Bioorg. Med. Chem. Lett., 2010, 20, 5484-5487.
3
Calogeropoulou et al. J. Med. Chem. 2008, 51, 897-908.
4
Godinho J.L et al. Exp Parasitol. 2013, 135, 153-165.
2
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 100 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P. 14. In vitro Anti-parasitic activity of Marine Cyanobacterial
extracts against Leishmania, Giardia and Trichomonas
Gisela Castro,1,2, Sandra Gomes-Pereira3,4, Rita F. Oliveira3, Agostinho Cruz3,
Vítor Vasconcelos1,2, Rosário Martins1,3
1Interdisciplinary
Centre of Marine and Environmental Research (CIIMAR/CIMAR),
University of Porto, Portugal; 2Faculty of Sciences, University of Porto, Portugal; 3
Centre of Health and Environmental Research (CISA), Superior School of Health,
Polytechnic of Porto, Portugal;4 ISLA-Instituto Politécnico de Gestão e Tecnologia,
Porto-Portugal
Leishmaniosis is a neglected disease that affects the poorest and most vulnerable
populations in developing countries. Currently, high rates of clinical failures have been
reported associated with the classical treatments like miltefosine. Giardiasis is the most
common parasitic diarrheal disease affecting humans. The first-line nitroimidazoles
drugs were found to have relevant side effects and single and multidrug resistance to
compounds has been reported. Trichomoniasis is sexual transmitted parasitosis that
increases the risk of HIV transmission and leads to adverse outcomes of pregnancy.
Treatment options are in this case reduced to nitroimidazole compounds. For all the
described parasitosis the search for new medicines seems mandatory.
Marine organisms are recognized as source of secondary metabolites promising for
drug discovery. Among those, cyanobacteria have come into focus for the production of
bioactive compounds with potential phamacological applications namely as
antiparasitic. In Portugal, the Interdisciplinary Centre of Marine and Environmental
Research (CIIMAR) hosts a cyanobacteria culture collection (LEGE culture collection)
composed manly by strains isolated from the portuguese coast. The aim of this work
was to evaluate the antiparasitic potential of LEGE cyanobacterial strains against
Leishmania infantum, Giardia duodenalis and Trichomonas vaginalis, in vitro.
Cyanobacteria crude extracts obtained by a dichloromethane:methanol (2:1) extraction
of freeze dried biomass were tested at a final concentration of 1mg/mL, 0,1mg/mL and
0,01mg/mL.
L. infantum promastigotes were cultured in RPMI medium. Parasites at a
concentration of 1,5x106 parasites/mL were exposed to the cyanobacteria extracts for
72h. G. duodenalis was cultured in TYI-S-33 medium and T. vaginalis trophozoites
were cultured in Diamond-TYM medium. Parasites at a concentration of 5x104 and
2,8x105 parasites/mL respectively were exposed to the extracts for 24 hours at
37ºC.The MTT assay was applied in order to verify an anti-parasitic effect.
Cyanobacteria extract from Leptolyngbya halophila LEGE 06102 and Synechocystis
salina
LEGE 06099 isolates showed inhibition of Leishmania promastigotes
growth. Concerning Giardia parasite a growth inibithion was registered with the two
Cyanobium sp. strains, LEGE07175 and LEGE06113. Trichomonas trophozoites were
not affected by the presence of cyanobacterial extracts.
These results show that some cyanobacterial strains present activity against
Leishmania and Giardia parasites but not against Trichomonas. Further studies are
needed in order to confirm their potential anti- parasitic effect.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 101 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Acknowledgements: This research was partially supported by FCT – Foundation for Science
and Technology under the project UID/Multi/04423/2013 and by the Structured Program of
R&D&I INNOVMAR - Innovation and Sustainability in the Management and Exploitation of
Marine Resources (reference NORTE-01-0145-FEDER-000035, Research Line NOVELMAR),
funded by the Northern Regional Operational Program (NORTE2020) through the European
Regional Development Fund (ERDF).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 102 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.15. Efficacy of Oral and Parenteral Amphotericin B Systems
against Experimental Trypanosoma cruzi Infection
M. Rolón1, D.R. Serrano2, A. Lalatsa3, E. de Pablo2, JJ. Torrado2, M.P.
Ballesteros2, A.M. Healy4, C. Vega1, C. Coronel1, F. Bolás-Fernández5,
M.A. Dea-Ayuela6
1
Centro para el Desarrollo de la Investigación Científica (CEDIC),Asunción, Paraguay.
Departamento de Farmacia y Tecnología Farmacéutica, Facultad de Farmacia, Universidad
Complutense de Madrid, Spain. 3School of Pharmacy and Biomedical Sciences, University of
Portsmouth, PO1 2DT, UK. 4School of Pharmacy and Pharmaceutical Sciences, Trinity College
Dublin, Ireland. 5Departamento de Parasitología, Facultad de Farmacia, Universidad
Complutense de Madrid, Spain. 6Departamento de Farmacia, Facultad de Ciencias de la Salud,
Universidad CEU Cardenal Herrera, Moncada, Valencia, Spain.
2
INTRODUCTION. Chagas disease is a chronic parasitic infection caused by
Trypanosoma cruzi. Although chemotherapy is available, existing drugs (benznidazol
and nifurtimox) are far from ideal. Activity of amphotericin B (AmB) in T. cruzi infections
has not been well documented. In this work, oral and parenteral drug delivery systems
of AmB with different aggregation states were tested.
METHODS. Dimeric AmB (AmB-NaDC), poly-aggregated AmB and poly-aggregated
AmB encapsulated in albumin microspheres (AmB-AME) were prepared and
characterised by TEM, SEM, DSC, TGA, FTIR, PXRD as previsouly described [1]. In
vitro activity on extracellular and intracellular T.cruzi forms and cytotoxicity on
NCTC929 fibroblasts was evaluated. In vivo efficacy was assessed after intravenous
and oral administration of AmB-AME and AmB- sodium deoxycholate micelles (AmBNaDC) respectively [2].
RESULTS. AmB aggregation state was correlated to the λmax of the absorption
spectra. Dimeric AmB spectra was characterized by a broad intense band at 328-340
nm while poly-aggregated AmB and AmB-AME displayed bands of smaller intensity at
360–363, 383–385 and 406–420 nm. Different molecular structures were observed in
TEM and SEM micrographs (Fig.1). All three formulations displayed promising IC50
values and selectivity index against T.cruzi both epimastigotes and amastigotes. AmBAME showed a better efficacy after the intravenous administration of three doses of 5
mg/kg. On the contrary, oral administration of AmB-NaDC was the most effective
formulation resulting in a >75% reduction of parasitemia when doses higher than 10
mg/kg were administered (Fig. 2).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 103 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
CONCLUSIONS. Oral administration of AmB-NaDC (> 10 mg/kg) is a greater and
inexpensive therapy to trypanosomiasis compared to parenteral AmB-AME allowing
treatment access worldwide.
REFERENCES
[1] Serrano DR et al. Int J Pharm. 2013;447:38-46; [2] Vega C, et al. Parasitol Res.
2005;95:296-8.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 104 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.16. Oral Nanomedicines for Chagas Disease
Eustine M. Hanna1, Dolores R. Serrano2, Aikaterini Lalatsa1
1
School of Pharmacy and Biomedical Sciences, St Michaels Building, University of Portsmouth,
White Swan, Portsmouth, PO1 2DT, UK. 2Departamento de Farmacia y Tecnología
Farmacéutica, Facultad de Farmacia, Universidad Complutense de Madrid, Plaza Ramon y
Cajal, Spain, S/N28040.
INTRODUCTION: Chagas disease (CD) is a parasitic zoonosis endemic in most
mainland countries of central and South America affecting nearly 10 million people
amongst 100 million people that are at high risk. Treatment is only effective if applied at
early stages of the disease. The only two marketed drugs (benznidazole (BNZ) and
nifurtimox (NFX)) are poorly soluble (BCS Class II) and are both widely criticised
because of their low efficacy and oral bioavailbility and serious toxic side effects
leading to discontinuation of 20–30% treatments. However, none of them can still be
replaced with more effective novel drugs. Thus, reformulating them in more effective
oral formulation with reduced frequency of administration and better oral bioavailability
is imperative and Self-Nanoemulsifying Drug Delivery Systems (SNEDDS) made from
generally regarded as safe (GRAS) excipients can be an easily scalable, safe and costeffective formulations with increased patient compliance.
METHODS: Quality by Design (QbD) experiments were carried out to identify the
optimal ration of Labrasol, Labrafil M1944 and Capryol 90 than would produce
nanometric particle size of SNEDDS upon aqueous dispersion and high drug loading.
Solid SNEDDS were prepared by adsorption of drug loaded SNEDDS onto solid silica
carriers (Syloid 244 FP, or Syloid XDP 3050) and mixing the resulting powder with
microcrystalline cellulose and sodium starch glycolate [SNEDDS : solid carriers ratio of
1:3w/w] and compressed into tablets that were overcoated with Eudragit RS PO or
Eudragit RL PO to control the dissolution profile. Dissolution testing using flow throughcell was performed. Powder flow properties and tablet characteristics were also
investigated and compared to commercially available tablets [Lampit (Bayer) and
Rochagan (Roche)]. Accelerated stability studies over a range of temperatures (2580oC) were conducted over five weeks.
RESULTS: NFX and BNZ loaded optimal SNEDDS illustrated a particle size below
400 nm and good drug loading (2mg/g and 10mg/g respectively or combined). NFX
and BNZ loaded SNEDDS enhanced the dissolution rate and increased the solubility in
simulated gastrointestinal media compared to commercially available tablets. For
SNEDDS loaded with both NFX and BNZ, however, a reduction in the level of drug
released was observed possibly due to electrostatic interactions between both drugs.
Solid SNEDDS prepared with Syloid 244 FP illustrated optimal flow properties, while
those prepared with Syloid XDP 3050 possessed better compressibility properties.
However, only overcoated tablets were able to pass the friability test. Model stability
data indicated that NFX loaded SNEDDS will only be stable if refrigerated in an airtight
vial for one month, while NFX Solid SNEDDS were stable in similar conditions for six
months. Combined solid SNEDDS illustrated an increased stability for NFX.
CONCLUSIONS: NFX and BNZ nanomedicines illustrated an improved dissolution
profile compared to commercial formulations. Co-formulating both drugs in a single
solid SNEDDS leads to an increase in chemical stability of NFX while maintaining a
good dissolution profile resulting in a cost-effective, easily scalable and combined
effective treatment for CD worldwide.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 105 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.17. Effect of the aggregation state of Amphotericin B on Red
Blood Cells
Raquel Fernández1, M. Paloma Ballesteros1, Dolores R. Serrano1
1
Departamento de Farmacia y Tecnología Farmacéutica, Facultad de Farmacia, Universidad
Complutense de Madrid. Plaza Ramón y Cajal, s/n, 28040-Madrid, Spain.
Introduction: Amphotericin B (AmB) is a macrolide produced by Streptomyces
nodosuswith antifungal and antileishmanial activity. This drug joins to the sterols in the
cell-membrane forming a pore that destabilises the cell and causes apoptosis. AmB
has a higher affinity for the ergosterol in fungal cells and some parasites, such as
Leishmania. However, it can also binds to the cholesterol of the mammalian cells
leading to toxicity such as haemolysis. This drug is only commercially available in
different intravenous formulations.AmBcan be found in three different aggregation
states: monomer, dimer or polyaggregate. The aggregation state can be easily
identified by UV. The dimer has a characteristic band at 328nm wavelength,the
monomer at 406nm wavelength and a mixture of them for the polyaggregated
form.AmB was prepared in its three aggregation states and the haemolytic activity was
evaluated in vitro.
Methods:
Poly-aggregated AmB(1): AmB (50 mg) was added in 10 ml of an aqueous
solution containing 41 mg of sodium deoxycholate, 10 mg of dibasic sodium phosphate
and 0.9 mg of monobasic sodium phosphate. The dispersion was stirred until a
homogeneous yellow suspension was obtained. Dimeric AmB: Dimeric AmB was
prepared similarly to poly-aggregated AmB. However, before adding the drug into the
aqueous solution, the pH was adjusted to 12.0 in order to solubilise the drug and
subsequently reduced to 7.4.
Monomeric AmB: it was prepared similar to dimeric AmB but using ϒ-cyclodextrin
instead of sodium deoxycholate.
Ex vivo Red Blood Cell (RBC)haemolysis assay (2): Diluted RBCs to 4%
concentration were added into a 96 well plate (180 µl/well). Formulations were diluted
using deionised water. 20 µl of each sample concentration was loaded into the wells in
triplicate. For positive control wells, a 20% solution of Triton X-100 (20 µl) was added.
For negative control wells, PBS at pH 7.4 (20 µl) was incorporated. Plates were
incubated at 37 ⁰C for 1 h. Subsequently, plates were centrifugedand 50 µl of
supernatant from each well were transferred into a clear, flat-bottomed 96-well plate.
The absorbance of the supernatants was measured using a plate reader at 570 nm.
The percentage of haemolysis was calculated using the following equation:
Haemolysis (%) = (ABSsample – ABSPBS)/ABSTriton x 100;
where ABSPBS is the average of the absorbance from the negative control samples and
the ABSTriton is the average of the absorbance from the positive control samples. The
concentration of AmB that produces 50% haemolysis at the tested conditions (HC50)
was calculated using Compusyn software.
Results: The HC50 for the monomer, dimer and poly-aggregated AmB was: 9.8,
229, 753 µg/ml respectively. The poly-aggregated form was 76-fold less haemolytic
than the monomeric form and 3.3-fold less than the dimeric aggregation state.
Conclusions: Monomeric AmB is the most hemolytic aggregation state while the
poly-aggregate is the least. Formulations containing poly-aggregated AmB could have
a therapeutical advantage over the other aggregation states, considering that AmB
formulations are intravenously administered.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 106 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
References:
(1) D.R. Serrano et al. InternationalJournal of Pharmaceutics, 2013; 447(1-2)38-46.
(2) B.C. Evans, et al. Journal of visualized experiments, (2013); JoVE:e50166.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 107 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.18. Antiparasitic Chemotherapy in Veterinary Medicine:
Challeges, Hurdles and Opportunities
María J. Corral, M. Dolores Jiménez-Antón, Ana Isabel Olías-Molero,
José Mª Alunda
Departamento de Sanidad Animal (ICPVet Group), Faculty of Veterinary Medicine, University
Complutense of Madrid, Madrid, Spain
It is considered that integrated control systems should be the choice to reduce the
extension and severity of parasitic diseases affecting animals. Biological complexity of
parasites and their life cycles and fragmented knowledge of immune system in many
animal species make that vaccines against parasitic diseases are very limited. Non
medical preventive measures are sometimes unpractical, unacceptable by
environmental reasons or unaffordable. Thus veterinary medicine of pets and livestock
strongly relies on the use of antiparasitic drugs. However chemotherapy of most
parasitic diseases affecting animals, domestic and wild, has important shortcomings.
Some of the currently used drugs of choice were synthesized over 50 years ago and no
new chemical entities (NCE) are foreseen. For some parasitic diseases there is no
available chemotherapy. Socioeconomic changes have increased the demand of
products of animal origin and there is growing social awareness of the presence of
drug residues in the environment.
Global market and reduced economic margins in farm activities require efficient
control systems including affordable prices of antiparasitic drugs and sustainability in
environmental terms. Resistant strains to chemotherapeutic agents have been reported
in parasitic protozoa, helminths and arthropods and there is spread resistance to all
available drugs in gastrointestinal nematodiases of small ruminants. There is a
shortage of new drug launches despite the massive investment made by
pharmaceutical companies and the public sector. This scarcity is probably rooted on
both managerial (e.g. reduction of pharma companies; strict separation of financial and
technical departments), social (e.g. more strict regulations on animal experimentation)
and scientific reasons (e.g. limited chemical space explored; trenched strategies in
drug discovery (DD) pipeline; inadequate laboratory models).
This scenario favors the fine tuning of DD pipeline and the evaluation of potential
antiparasitic drugs. Of paramount importance will be the widening of chemical space to
get NCE by using different sources (e.g. natural or natural-derived scaffolds); the
reevaluation of selection criteria along the DD pipeline; identification of resistance and
therapeutic failure; and use of truly predictive animal models. The path from molecular
biology to pharmacology and, finally, chemotherapy is longer and more complex than
previously thought; and DD should integrate all these steps. It is expected that
veterinary medicine, with a deep understanding of the pathophysiology of parasitic
diseases, plays a significant role in the development of refined animal models. These
predictive models will increase health, welfare and production.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 108 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.19. Early preclinical studies of new selenocyanate and
diselenide compounds as leishmanicidal agents
Verónica Alcolea1,2, Esther Moreno3, Elena González-Peñas1, Juan Manuel
Irache4, Juan Antonio Palop1,2, Carmen Sanmartín1,2, Socorro Espuelas3,4
1
Department of Organic and Pharmaceutical Chemistry, University of Navarra, Pamplona,
Spain; 2 Instituto de Investigación Sanitaria de Navarra (IdiSNA), Pamplona, Spain; 3 Institute of
Tropical Health, University of Navarra; 4 Pharmacy and Pharmaceutical Technology
Department, University of Navarra, Pamplona, Spain.
[email protected], [email protected], [email protected], [email protected]
Leishmaniasis is a neglected tropical disease caused by the parasite Leishmania
spp. The infection can cause different clinical syndromes which range from a
cutaneous form to the affectation of mucocutaneous tissues or visceral organs.
Visceral leishmaniasis (VL) is the most severe form, causing 20,000-40,000 deaths per
year. Current drugs for the treatment of VL are not completely effective and they show
important drawbacks such as severe toxicity, high cost, long-term treatments or
resistances. Therefore, there is an urgent need to develop new effective, safe and
cheap leishmanicidal agents.
In a previous publication, we synthesized a series of novel heteroaryl
selenocyanates and diselenides and they were screened for their activity and
selectivity against L. infantum amastigotes (1). Two compounds (2d and 1h) emerged
as the lead compounds of these series, showing excellent values of activity and
selectivity. In the present work we have evaluated the appropriate dose and route of
administration of these two compounds for the in vivo efficacy studies in L. infantuminfected mice. Since the novel compounds exhibited poor values of intestinal
permeability, they are not suitable for oral administration. Therefore, the intravenous
(i.v.) route has been explored. A lipid nano-emulsion formulation has been developed
to allow the i.v. administration of compound 2d. This new formulation has been found
to be safe for the i.v. administration of 2d at the dose of 2 mg/kg for five consecutive
days. On the other hand, compound 1h showed higher toxicity in vitro and in vivo and
thus it has to be administered at the dose of 1 mg/kg. The studies of efficacy in L.
infantum infected-BALB/c mice are now in course.
References
(1) Novel heteroaryl selenocyanates and diselenides as potent antileishmanial agents. Y.
Baquedano, V. Alcolea, M.A. Toro, K.J. Gutiérrez, P. Nguewa, M. Font, E. Moreno, S. Espuelas,
A. Jiménez-Ruiz, J.A. Palop, D. Plano, C. Sanmartín. Antimicrob. Agents Chemother.60:6 (20)
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 109 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.20. Topical treatment of CL with paromomycin and anti-TNF-α
antibodies: efficacy study in L. major infected BALB/c mice
Juana Schwartz, Esther Moreno, Alba Calvo, Socorro Espuelas
Institute of Tropical Health and Pharmacy and Pharmaceutical Technology Department,
University of Navarra, Instituto de Investigación Sanitaria de Navarra (IdiSNA), 31008
Pamplona, Spain
[email protected], [email protected], [email protected],
[email protected]
The immune responses induced by Leishmania infection determine the disease
pathogenesis, as lack of immune response is related to chronification and severity and
an effective immune response leads to infection resolution. Thus, an obvious strategy
seems to be to modulate the immune response with the aim to boost antileishmanial
mechanisms using pro-inflammatory drugs. However, in localized cutaneous (CL) and
mucocutaneous leishmaniasis, disease severity has been linked to an excessive
production of pro-inflammatory mediators. In both cases, parasites in the affected
tissue are scanty and ulceration and tissue destruction are a consequence of the
vigorous local inflammatory response. Thus, in order to minimize tissue destruction that
leads to scar formation, treatment of the lesions with anti-inflammatory agents could be
also an interesting strategy to explore. Despite immunochemotherapy is arising as a
promising strategy, clinical studies have shown that the use of immunomodulators
alone does not lead to parasite clearance although it improved the response to
treatment when combined with leishmanicidal drugs. Therefore, in this work, we
proposed combining the antileishmanial drug paromomycin with poly(I:C) (PIC) (proinflammatory) or anti-TNFα (anti-inflammatory) to explore the potential of these
formulations to both lead to parasite clearance and wound healing.
In our work, we first evaluated the antileishmanial activity of the drugs. Then, skin
permeability of the compounds and their anti-inflammatory activity were assessed in a
mouse model of IMQ-induced inflammation. Finally, the different drugs and
combinations were tested in a L. major BALB/c model of infection.
Immunohistochemistry studies were also carried out in skin lesions to observe if there
were changes in the expression of genes that are involved in inflammation and wound
healing. In our study, combinations of paromomycin with anti-TNFα or PIC were similar
in terms of in vitro parasite clearance in infected macrophages. In the BALB/c mouse
model of inflammed skin, paromomycin and anti-TNFα applied separately were able to
reduce inflammation locally. In infected mice, combination of PM plus PIC or anti-TNFα
significantly reduced the parasite burden in skin, lymph nodes, liver, and spleen
similarly to PM alone and PM with methylbenzethonium chloride (the marketed
formulation). However, in L. major-infected BALB/c mice, the combination therapy of
paromomycin with anti-TNFα had a stronger anti-inflammatory activity that was
confirmed by the down-regulation of TNF-α, IL-1β, iNOS, IL-17, and CCL3, whereas
paromomycin alone only decreased the expression of iNOS and IL-17.
Immunohistochemistry studies confirmed a decrease of the neutrophilic infiltrate during
infection. Therefore, topical application of formulations combining leishmanicidal drugs
with small biological anti-inflammatory molecules could be useful to reduce
inflammation and scarring in CL.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 110 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.21. Novel oral formulations of Active Hexose Correlated
Compound (AHCC) and its parasitic activity in an in vivo model
Liliana Bautista1, Hajime Fujji2 and Juan J. Torrado1
1
Complutense University of Madrid, Faculty of Pharmacy; 2Amino Up Chemical, Sapporo,Japan
AHCC is extracted from Shiitake mushroom (Lentinus edades). AHCC is a
functional food; published studies indicate that it has immunostimulatory properties
being beneficial in adjuvant therapy in patients with cancer. A scientific collaboration
between the pharmaceutical company and the depatament of Pharmaceutical
Technology at the Complutense University of Madrid was establisehd in order to
develop more hydrophilic oral formulations as an alternative to the lipidic formulations
already marketed. These hydrophobic formulations contain large amounts of lipidic
excipient with the aim of protecting the lyophilized powder from the humidity which
leads to chemical degradation and compromises the product activity. In Japan,
commonly, the form of consumption of AHCC is directly from the scahets without water.
However, in Western countries the sachets are usually dispersed in water and taken as
oral suspensions or extemporary oral solutions. Therefore, a hydrophilic formulation
would be more convenient than a hydrophobic formulation to improve the dispersability
of the product in water and the patient compliance.
Aims
1. To develop and characterize novel hydrophilic formulations of sachets containing
AHCC and the study the stability of the developed formulations in accordance with ICH
guidelines.
2. To study the in vivo bioavailability of novel oral formulations of AHCC.
Methodology
The excipients used in this research are approved for use in nutraceutical
formulations in most countries. Stability studies were performed according to the ICH
Q1A ( R2 ). The in vitro an in vivo activity of the formulations was evaluated.
Results
1.We have developed and characterized novel AHCC hydrophilic formulations in
sachets, during stability studies was the caking tendency This effect occurs under
extreme conditions of humidity (96%  5%) and after 24 months being easily reversible
because the formulations are dispersed and solubilized in an aqueous medium.
Therefore, we suggest 24 months as expiration date.The improved formulation in
sachets from a stability point of view has to contain a relatively low dose of AHCC (0.6
g) with lots of excipients resulting in a final weight of 3.13 g granulate. As packaging
materials, aluminium- aluminium sachets are used and is recommended to avoid
storage conditions with excessive moisture.
2.The characteristics invivo of AHCC were evaluated by analyzing some of its
components: glucose, G1 and isomaltol after oral administration. No hyperglycemic
effect was detected even after oral administration of doses up to 5 g of AHCC-FD to
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 111 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
healthy volunteers under fasting conditions. G1 and isomalt are not detected in plasma
samples after oral administration of AHCC in humans and mice. We conclude therefore
that these molecules are not useful to indicate the oral bioavailability of the formulation.
3.It was observed that AHCC is useful by itself to reduce the number of parasites in
an experimental mouse model of T. spiralis. The anthelmintic efficacy of AHCC is
proportional to the dose. AHCC administration reduces the duration of the infection
(decreasing faster the number of parasites in the intestinal phase) and inflammation
(Th1 response decreases which was quantified by interleukins: TNF, and IL-2 IFN)
compared to the untreated control group.
4.No significant differences in activity was observed after the administration of the
same dose of raw material (AHCC-FD) and the developed formulation in sachets
concluding that they are pharmacodynamic bioequivalent.
Acknowledgment
Animo Up Chemical.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 112 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P. 22. In vitro activity evaluation of marine metabolites against
bloodstream forms of Trypanosoma brucei
Maria Harizani1, Sara Costa2, Nuno Santarem 2, Anabela Cordeiro-da-Silva2,3,
Vassilios Roussis1 and Efstathia Ioannou1
1
Department of Pharmacognosy and Chemistry of Natural Products, School of Pharmacy,
National and Kapodistrian University of Athens, Athens 15771, Greece.
2
I3S – Instituto de Investigação e Inovação em Saúde, Universidade do Porto, Porto 4200-135,
Portugal.
3
Department of Biological Sciences, Faculty of Pharmacy, University of Porto, Porto 4050-313,
Portugal.
Parasites of the family Trypanosomatidae are causing serious human diseases,
including leishmaniasis, African sleeping sickness and Chagas disease. The currently
used therapeutics are not devoid of problems, such as toxicity, side effects and
development of drug resistance, so there is an urgent need for the discovery of new,
more effective chemotherapeutics.
Nature, the most prolific source of biological and chemical diversity, has provided
mankind with remedies to health problems since the ancient years and continues to be
the most promising reservoir of bioactive chemicals for the development of modern
drugs. In addition to terrestrial organisms that still remain a promising source of new
bioactive metabolites, the marine environment, covering approximately 70% of the
Earth’s surface and hosting a largely unexplored biodiversity, offers an enormous
resource for the discovery of novel bioactive compounds.
As part of our ongoing studies towards the isolation and structure elucidation of new
bioactive metabolites from marine macro- and microorganisms from the East
Mediterranean Sea, the antiparasitic activity against Trypanosoma brucei and the
cytotoxicity against THP-1 macrophages of a panel of structurally diverse natural
products, including halogenated sesquiterpenes, diterpenes, acetogenins and
polyethers, were evaluated.
Among the 27 tested metabolites a polyether of actinobacterial origin showed
promising activity against T. brucei with IC50 = 240 nM and a selectivity index (SI) of 58.
Further testing of structurally related metabolites and pharmacokinetic studies of the
bioactive polyether are currently in progress.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 113 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.23. Influence of glutathione and antimony in the ATPase
activity of Leishmania LABCG2 transporter
Ana Perea1, Yasuhisa Kimura2*, José Ignacio Manzano1*, Santiago Castanys1#,
Kazumitsu Ueda2,3#, Francisco Gamarro1#
* Both authors contributed equally to this work. # Equal senior authors.
1
Instituto de Parasitología y Biomedicina “López-Neyra” (IPBLN-CSIC), Parque Tecnológico de
Ciencias de la Salud, Granada (Spain). Email: [email protected]
2
Division of Applied Life Sciences, Graduate School of Agriculture, Kyoto University, Kyoto
(Japan)
3
Institute for Integrated Cell-Material Sciences (iCeMS), Kyoto University, Kyoto (Japan)
The Leishmania LABCG2 transporter is involved in protecting these protozoan
parasites against the toxic effects of antimony, probably by efflux as conjugated thiol
complexes. However, the effects of glutathione (GSH) and antimony (SbIII) on the
ATPase activity of LABCG2 protein have not been described. We have expressed and
purified a functional LABCG2 protein using the baculovirus-Sf9 insect cell system. By
reconstitution of purified Leishmania LABCG2 in liposomes, we have analyzed the
ATPase activity. LABCG2 reconstituted in brain polar extract showed an ATPase
activity that was stimulated (3.5-fold) at 30 µM GSH, with Vmax and Km values of 678.6 ±
0.14 nmol Pi/min/mg and 9.02 ± 3.00 µM, respectively. Additionally, we examined the
kinetics of ATPase activity of purified LABCG2 after incubation with increasing
concentrations of SbIII. As a result, we found an increase in the LABCG2 ATPase
activity (3.2-fold), reaching the maximum activity at 30 µM SbIII with Vmax and Km values
of 405.3 ± 0.03 nmol Pi/min/mg and 12.84 ± 3.11 µM, respectively. Taken together,
these data corroborate the hypothesis that LABCG2 is an active GSH and SbIII
transporter. In the future, this achievement will allow the screening of potential
substrates and inhibitors of LABCG2, contributing to the understanding of this
transporter and its biological role in Leishmania.
This work was supported by the Spanish Grants SAF2015-68042-R (to S.C. and F.G.),
SAF2012-34267 (to F.G.) and Junta de Andalucía, Ref. CTS-7282 (to F.G.).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 114 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P. 24. The NMTRyPI - New Medicines for Trypanosomatidic
Infections – drug discovery platform
M.P.Costi, J.M.Alunda, J.Clos, A.Cordeiro da-Silva, A.Khalid, S.Gul, S.Mangani,
C.Morales, W.Muller, T.Calogeropoulou, A.Venturelli, R.C.Wade, S.Wrigley.
The NMTrypI Consortium (http://www.nmtrypi.eu/), Email: [email protected]
According to the WHO (1) one billion people are at risk of or are affected by
Neglected Tropical Diseases (NTD). Diseases caused by kinetoplastids, HAT, Chagas
disease and Leishmaniasis continue to cause major problems in humans (2) and
conventional available therapies show several drawbacks. . Furthermore, research
on Trypanosomatid diseases is limited and fragmented. Open economy and human
relocation by regional wars besides consistently increasing business travel,
immigration, worker exchange, and global climate changes alter the geographic
distribution of parasites and vectors and further the spread of vector-born diseases.
Europe is particularly susceptible to these challenges. To meet the medical need an
European project in the drug discovery and development field has been performed. The NMTrypI project takes a multipronged approach to discovering and characterizing new candidate drugs. Some of the achievements are: 1) The development of an alkylphospholipid compound exhibiting improved efficacy
and lower toxicity than Miltefosine. A early protein biomarker set to detect the
candidate efficacy and giving hints of its potential mechanism of action on a cellular
basis has been generated. A SAR around the compound and a backup compound
have been developed.
2) Pathogenic protozoa Trypanosoma brucei spp., T.cruzi and Leishmania spp are
digenetic (complete their life cycle in two host organisms) and closely related. Thus we
have focused on a target that is homologous to in all three of these closely related
organisms and has no human homologue: pteridine reductase 1 (PTR1). We validated
the concept of the pteridine reductase 1 (PTR1) bypass block discovering several
classes of compounds targeted against PTR1, with no activity against the parasite but
able to potentiate the effect of a parasitic DHFR inhibitor. These compounds are now
under evaluation in vivo.
3) We have implemented a kinetoplastid-based screening platform and efficiently
screened over 14000 compounds in phenotypic assays, and 5000 compounds in
biochemical assays against 6 targets and three off-targets,as well as an array of earlytox assays. Furthermore, we have performed phenotypic screening against three
parasites of the Hypha Mycodiverse library of natural compounds.
4) Synergetic collaborations between four large FP7 EU projects on discovery of
drugs for neglected diseases have been established, including sharing an innovative
drug discovery pipeline.
5) All data generated are stored and shared using the SEEK platform ((https://fp7hsynergy.h-its.org) and will be made openly available upon publication.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 115 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Acknowledgment.
This project has received funding from the European Union’s Seventh Framework Programme
for research, technological development and demonstration under grant agreement n° 603240
(NMTrypI - New Medicine for Trypanosomatidic Infections). http://www.nmtrypi.eu/
1. http://www.who.int/neglected_diseases/2010report/en/;
2. Ken Stuart, et al. J Clin Invest. 2008.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 116 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P. 25. Modelling, Synthesis and Evaluation of Novel Quinine
Analogues – New Drugs for Chagas Disease
Hirenkumar Gandhi1, Ligia F. Ceole2, Luz H. Villamizar2, Maurilio J. Soares2,
and Timothy P. O’Sullivan1
1
Department of Chemistry, Analytical and Biological Chemistry Research Facility, University
College Cork, Cork, Ireland
2
Laboratory of Cell Biology, Carlos Chagas Institute/Fiocruz, Curitiba, PR, Brazil
Email: [email protected], [email protected]
Chagas disease is caused by the protozoan Trypanosoma cruzi and is endemic in
regions of Latin America. The drugs used most extensively for the treatment of Chagas
disease are benznidazole and nifurtimox. Neither of these drugs has been shown to
eradicate infection during the chronic phase when most patients are diagnosed.[1] While
the search for the novel drug targets and new lead structures for the treatment of
Chagas disease is of critical importance, a complimentary strategy is to utilise and
further develop lead structures from nature with proven biological activity. Quinine, an
alkaloid derived from the bark of the cinchona tree, is highly effective against parasitic
infections despite almost 400 years of use. Quinine is a potent molecule completely
inhibiting T. cruzi epimastigote replication in vitro.[2] Interaction with DNA would seem to
be a reasonable mechanistic hypothesis. Using the Heck reaction, we have pursued
modification of the vinyl group in quinine.[3] Following molecular-docking studies on
Trypanosoma cruzi trypanothione reductase (TcTR) (PDB Id: 1GXF) and energy
minimisation of the ligands, our quinine analogues have displayed excellent binding
affinity.[4] For biological activity, all quinine analogues were first screened against
cultured epimastigotes with benznidazole as the benchmark. The most active
compounds were subsequently tested against Vero cell cultures infected with
intracellular amastigotes. Dose-response curves were obtained from CompuSyn
software in combination with Operetta Imaging system and Harmony Software.
References:
[1] F.S. Buckner, A.J. Wilson, T.C. White, W.C. Van Voorhis, Antimicrob Agents Chemother 42
(12): 3245-50. PMC 106029, PMID 9835521.
[2] S. Sepulveda-Boza, B.K. Cassels, Planta Medica, 62(1996), 98-105.
[3] T. Dinio, A.P. Gorka, A. McGinniss, P.D. Roepe, J.B. Morgan, Bioorg Med Chem, 2012,
20(10): 3292-3297.
[4] D. Saha, A. Sharma, Med Chem Res, 2014, 21 (12).
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 117 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.26. Emulsomes: A Tool for Delivery of anti-leishmanial BNIP
Derivatives to Macrophages
Zeynep Islek1, Mustafa Güzel2, Fikrettin Sahin1, Mehmet H. Ucisik3,*
1
Department of Genetics and Bioengineering, Faculty of Engineering, Yeditepe University,
Istanbul, Turkey
2
Department of Medical Pharmacology, International School of Medicine, Istanbul Medipol
University, Istanbul, Turkey
3
Department of Biomedical Engineering, School of Engineering and Natural Sciences, Istanbul
Medipol University, Istanbul, Turkey
Corresponding Author; Phone: +90 216 681 5154; E-mail: [email protected]
Similar to other parasitic diseases, chemotherapy is the most efficient strategy for
leishmaniasis. However, the high toxicity of many antiparasitic compounds restricts
their utility, and the emergence of drug resistant strains often impairs the lifespan of a
given drug.
Among alternative drug candidates, bisnapthalimidopropyl (BNIP) derivatives have
been recently shown to have anti-leishmanial activities, which even surpass the
standard and most common Amphotericin B therapy [1]. However BNIP derivatives
have some drawbacks including low aqueous solubility and toxicity. Addressing these
limitations, this study applies two diverse technologies including medical chemistry
approach together with the structure-based drug design, and nanotechnological drug
delivery approach. The former approach will focus on design of new BNIP derivatives
that have higher efficacy and bioavailability, whereas the latter will be used to deliver
the drug specifically to the parasite, thereby decreasing the side effects of the
chemotherapy, in particular on macrophages.
The delivery of BNIP derivatives into the macrophages will be achieved by
encapsulating the active molecule in a lipid- based nanocarrier system, so-called
emulsomes [2]. Emulsome is preferred mainly because of its four major features.
Firstly, owing a solid lipid core like the solid lipid nanoparticles, emulsome may offer
high loading capacities for hydrophobic substances such as BNIP [2,3]. Secondly,
composed of only lipids and in the absence of any surfactants, emulsome is highly
biocompatible [3]. Thirdly, the solid character of the nanocarrier provides a prolonged
drug release profile, which can be controlled, or tuned, by the selection of the lipid
composition as well as by surface modifications [4]. Lastly, but most importantly, the
natural feature of lipids allows emulsome to accumulate in the organs of the
reticuloendothelial system (RES) instead of the kidney, which will not only largely
reduce toxicity, but will also improve the anti-leishmaniasis efficacy of the loaded drug,
as parazites are also located in the organs of RES.
The development of new active BNIP derivatives and the emulsome-BNIP
nanoformulations facilitating the targeted delivery to the macrophages is expected to
substantially contribute to the improvements in treating parasitic disease Leishmaniasis
in European region as well as worldwide.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 118 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
References
[1] Tavares J., Quaissi A., Lin P.K.T., Loureiro I., Kaur S., Roy N., Cordeiro-da-Silva A.,
ChemMedChem (2010), 5, 140-147
[2] Ucisik M.H., Küpcü S., Debreczeny M., Schuster B., Sleytr U.B., Small (2013), 9, 28952904.
[3] Ucisik M.H., Küpcü S., Schuster B., Sleytr U.B., J. Nanobiotechnology (2013), 11, 37.
[4] Ucisik M.H., Küpcü S., Breitwieser A., Gelbmann N., Schuster B., Sleytr U.B., Colloids Surf.
B. (2015),132-139.
Acknowledgement
This study is supported by Tübitak EU-COST project no. 115Z846 and integrated to the
COST action CM1307 entitled “Targeted chemotherapy towards diseases caused by
endoparasites
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 119 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
P.27. Synergy activities on Neglected tropical diseases drug
discovery within FP7 EU context
M.P.Costi1, Rob Leurs2, Jane MacDougall3, Raymond J. Pierce4
NMTrypI, www.nmtrypi.eu1; KINDReD, www.kinderd.eu3, PDE4NPD, www.pde4npd.eu2;
A-ParaDDisE, www.a-paraddise.eu4
The EC has, historically, generously supported research into Neglected Tropical
Diseases (NTDs), starting well before the London Declaration of 2012, which put the
control or elimination of NTDs at the forefront of global efforts to “chart a new course
toward health and sustainability among the world’s poorest communities to a stronger,
healthier future”. The development of new drugs is particularly important in these
efforts in order to circumvent problems with current treatments, including drug
resistance, severe side-effects or exacting dosing schedules. With this aim, four
different consortia (NMTrypI, KINDReD, A-ParaDDisE and PDE4NPD), involving more
than 50 teams in Europe, Africa, South America Australia and the USA, were funded in
the last call related to drug development in neglected infectious diseases;
HEALTH.2013.2.3.4-2: Drug development for neglected parasitic diseases. FP7HEALTH-2013-INNOVATION-1. The projects targeted the major chronic parasitic
diseases Leishmaniasis, Chagas Disease, Sleeping Sickness, Schistosomiasis and
Malaria. Together, these diseases affect more than a billion people worldwide, cause
hundreds of thousands of deaths and are major contributors to the poverty trap in the
countries concerned. The projects were given the following objectives:
To establish a common drug discovery platform that should have the
capacity to undertake screening of compound libraries, lead development and
Testing in relevant animal models as well as toxicology and safety
testing of new drug candidates.
It was also requested that a minimum of three parasitic diseases, should be
studied. With an expected impact to gather a comprehensive portfolio of drug leads,
and develop the most promising of these into drug candidates that can be tested in
early clinical trials.
In this call, the Commission particularly emphasized the need for the consortia to
work together in a synergistic manner in order to maximise effort and reduce
duplications. This aim has been achieved through multiple meetings, teleconferences
and bilateral contacts, culminating in a joint meeting in Modena (mid-June 2016). As a
result of this meeting, and since three of the four consortia reach termination within the
next six months, it is opportune to focus attention on our achievements to date
and set out the reasons why the Commission should seek to build on their
significant investment and cement these considerable advances by future
funding.
The four consortia have used various approaches to develop “hit” and “lead”
candidates for drug development. These include: phenotypic screening of extensive or
focused compound libraries or natural products, target-based screening
(phosphodiesterases, epigenetic enzymes, dihydrofolate reductases etc.) including
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 120 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
HTS and in silico screening, repurposing or modifying existing approved
drugs,extensive ADMET in a novel high throughput format to pre-select candidates for
in vivo studies. In vivo screening in animal disease models including for the most
advanced candidates a NHP primate model. As a result of the synergy discussions
standardization of criteria for the definition of hit and lead compounds has been
achieved, based on published criteria1,2. A number of activities have been carried
out. In the present communication we present the shared activities and most
important disclosable results including perspectives for results exploitation.
We thank the European commission for the support of the following projects: NMTrypI,
KINDReD, A-ParaDDisE and PDE4NPD.
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 121 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 122 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
LIST OF PARTICIPANTS
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 123 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 124 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Name
Institution
E-mail address
Alunda J. M.
Universidad Complutense
de Madrid, Spain
[email protected]
André-Barrès C.
CNRS-Université Paul
Sabatier, France
[email protected]
Baltas M.
CNRS-Université Paul
Sabatier, France
[email protected]
Bautista L.
Universidad Complutense
de Madrid, Spain
Bermejo M.
Vitakoras Pharma S.L.,
Spain
Biedermann D.
The Czech Academy of
Science, Czech Republic
Boije af Gennäs G.
University of Helsinki,
Finland
Bolás F.
Universidad Complutense
de Madrid, Spain
Botta M.
Università di Siena, Italy
Caffrey C. R.
University of California
San Diego, USA
[email protected]
Caljon G.
University of Antwerp,
Belgium
[email protected]
Calogeropoulou T.
National Hellenic
Research Foundation,
Greece
[email protected]
Campillo N. E.
Centro de Investigaciones
Biológicas, CSIC, Spain
Castro G.
Polytechnic Institute of
Porto, Portugal
Cordeiro-Da Silva A.
I3S, Institute for Molecular
and Cella Biology (IBMC),
Portugal
[email protected]
Corral M. J.
Universidad Complutense
de Madrid, Spain
[email protected]
Costi M. P.
Università degli Studi di
Modena e Reggio Emilia,
Italy
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 125 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Couvreur P.
Université Paris-Saclay,
France
Dardonville C.
Medicinal Chemistry
Institute, CSIC, Spain
[email protected]
Davioud-Charvet E.
CNRS - Université de
Strasbourg, France
[email protected]
De Koning H. P.
University of Glasgow,
United Kingdom
[email protected]
Dea Ayuela M.A.
Universidad CEUCardenal Herrera, Spain
Descoteaux A.
INRS-Institut ArmandFrappier, Canada
[email protected]
Doligalska M. J.
University of Warsaw,
Poland
[email protected]
Ebiloma G. U.
University of Glasgow,
United Kingdom
[email protected]
Espuelas M. S.
Universidad de Navarra,
Spain
Fernández García R.
Universidad Complutense
de Madrid, Spain
[email protected]
Gamarro F.
Instituto de Parasitología y
Biomedicina
López-Neyra, CSIC, Spain
[email protected]
Gandhi H.
University College Cork,
Ireland
García-Sosa A.T.
University of Tartu,
Estonia
Gemma S.
Università di Siena, Italy
Gil C.
Centro de Investigaciones
Biológicas, CSIC, Spain
[email protected]
Gold D.
The Hebrew University of
Jerusalem, Israel
[email protected]
Golenser J.
The Hebrew University of
Jerusalem, Israel
[email protected]
Gomes-Alves A. G.
I3S, Institute for Molecular
and Cella Biology (IBMC),
Portugal
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 126 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
González Sánchez M. E.
Universidad Complutense
de Madrid, Spain
González-Álvarez I.
Vitakoras Pharma S.L.,
Spain
[email protected]
González-Álvarez M.
Vitakoras Pharma S.L.,
Spain
[email protected]
Gul S.
Fraunhofer IME-SP,
Germany
Gutiérrez A.
Universidad Complutense
de Madrid, Spain
Harrington J. M.
Merial Inc., USA
Heby O.
Umeå University, Sweden
Hendrickx S.
University of Antwerp,
Belgium
[email protected]
Hervás P.
Veterindustria, Spain
[email protected]
Horn M.
The Czech Academy of
Sciences, Czech Republic
[email protected]
Jaffe C.
The Hebrew University of
Jerusalem-Hadassah,
Israel
[email protected]
Jiménez-Antón M. D.
Universidad Complutense
de Madrid, Spain
[email protected]
Kivrak A.
Yuzuncu Yil University,
Turkey
[email protected]
Krauth-Siegel R. L.
Biochemie-Zentrum der
Universität Heidelberg,
Germany
[email protected]
Leontovyč A.
The Czech Academy of
Sciences, Czech Republic
[email protected]
Leurs R.
Vrije Universiteit
Amsterdam, The
Netherlands
Loiseau P. M.
Université Paris-Sud,
France
Lopes F.
Universidade de Lisboa,
Portugal
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 127 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
López Medrano F.
Hospital 12 de Octubre
Madrid, Spain
[email protected]
Maes L.
University of Antwerp,
Belgium
[email protected]
Mangalagiu I. I.
Alexandru Ioan Cuza
University of Iaşi, Romania
Maran U.
University of Tartu,
Estonia
Martins R.
Polytechnic Institute of
Porto, Portugal
[email protected]
Mukherjee B.
University of Geneva,
Switzerland
[email protected]
Natto M. J.
University of Glasgow,
United Kingdom
[email protected]
Olías-Molero A. I.
Universidad Complutense
de Madrid, Spain
[email protected]
Opperdoes F.
De Duve Institute, Belgium
[email protected]
Otero-Espinar F. J.
Universidad de Santiago
de Compostela, Spain
[email protected]
Palmieri N.
Instiute of ParasitologyVetmeduni Vienna, Austria
[email protected]
Pereira S. I.
Polytechnic Institute of
Porto, Portugal
Peric M.
University of Zagreb,
Croatia
[email protected]
Persson L.
Lund University, Sweden
[email protected]
Peterlin Mašič L.
University of Ljubljana,
Slovenia
Pfister K.
LMU München, Germany
Pomel S.
Université Paris-Sud,
France
Quirynen L. M. M.
Janssen Pharmaceutica,
Belgium
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
[email protected]
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 128 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Roussis V.
National and Kapodistrian
University of Athens,
Greece
Sarlauskas J.
Vilnius University,
Lithuania
[email protected]
Schmidt T. J.
Universität Münster,
Germany
[email protected]
Sebastián V.
Centro de Investigaciones
Biológicas, CSIC, Spain
Selzer P. M.
Boehringer Ingelheim
Animal Health, Germany
[email protected]
Serrano D. R.
Universidad Complutense
de Madrid, Spain
[email protected]
Šolmajer T.
National Institute of
Chemistry, Slovenia
[email protected]
Stevanović S.
Center for Multidisciplinary
Science Vinča, Serbia
[email protected]
Tomás A. M.
I3S, Institute for Molecular
and Cella Biology (IBMC),
Portugal
[email protected]
Torrado J. J.
Universidad Complutense
de Madrid, Spain
[email protected]
Ucisik M. H.
Istanbul Medipol
University, Turkey
[email protected]
Valladares B.
Universidad de las
Palmas, Spain
[email protected]
Vasilache V.
Alexandru Ioan Cuza
University of Iaşi, Romania
[email protected]
Vivancos V.
Universidad Miguel
Hernández de Elche,
Spain
[email protected]
[email protected]
[email protected]
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 129 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 130 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
NOTES Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 131 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 132 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 133 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 134 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 135 3rd COST Action CM1307 Conference ● SOCEPA ● SEFIG, Madrid, 2016
Chemotherapy towards diseases caused by endoparasites: Antiparasitic Chemotherapy for Human and Veterinary use| 136 3rd COST ACTION CM1307 CONFERENCE ● SOCEPA ● SEFIG