Download GGT - Unisi.it

GenOMeC – SIENA 29/03/13
Gamma-glutamyltransferase activity:
a biochemical factor in cell regulation,
pathogenesis and clinical diagnosis
Alfonso Pompella, MD PhD
Dipartim. di Ricerca Traslazionale NTMC
Università di Pisa
COOH
GGT
catalytic site
Ser 406
Asp 423
Thr 524
plasma membrane
NH
2
γ-Glutamyltransferase, γ -Glutamyl transpeptidase
(γ-GT; GGT; EC 2.3.2.2.)
GGT effects the recovery of extracellular GSH
extracellular
GSH
acceptor
gly-cys-SH
γ-glu-acceptor
GGT
GSH
(intracellular)
DIPEPTIDASES
glutamic acid
cell
glycine intracellular
cysteine GSH resynthesis
Glutathione, GSH
GGT
glutamate
glycine
cysteine
H
N
O
II
C
C
N
II
H
O
COO-
H
H3
N+
COO-
HS
metabolite: Cys-Gly
reduced glutathione
GSH : SEVEN FACES / FOUR ROLES
a Nucleofile
a Cofactor of Enzymes
an Antioxidant
a Metal ion reductant
a Prooxidant
formation of GS-NO
protein S-glutathiolation
antioxidant role
“prooxidant” role
transport of NO
‘protein modulation’
GGT effects the recovery of extracellular GSH
extracellular
GSH
acceptor
gly-cys-SH
γ-glu-acceptor
GGT
GSH
(intracellular)
DIPEPTIDASES
glutamic acid
cell
glycine intracellular
cysteine GSH resynthesis
CHEMICALLY-INDUCED EXPERIMENTAL LIVER CARCINOGENESIS
DEN
2-AAF in diet
i.p.
0
1
2
3
4 weeks
SACRIFICE
partial
hepatectomy
Cameron R, Kellen J, Kolin A, Malkin A, Farber E - Cancer Res (1978)
GGT foci correspond to GSH-dependent lipid peroxidation
+ exogenous GSH
GGT histochemistry
LPO histochemistry
Pompella et al., Histochem. Cell Biol. (1996)
!?
GGT / GSH - dependent
lipid peroxidation ?
Thiols, metal cation reduction and redox cycling
Steven D. Aust
Utah State University
GHS metabolites can play as metal cation reductants
gly-cys-SH
Fe 3+
REDOX
CYCLING
.
Fe 2+
gly-cys-S
H+
A.A. Stark, E. Zeiger, D.A. Pagano
Glutathione metabolism by γ-glutamyl transpeptidase leads to
lipid peroxidation. Carcinogenesis (1993) 14(2): 183-189
Avishay-Abraham Stark
University of Tel Aviv , IL
ROS
Active site of GGT faces outwards
U937 cells – Fluorescent detection of 5-nitrosalicylaldehyde precipitation
Vis microscopy
Fluorescence microscopy
Paolicchi et al. (unublished results)
A “pro-oxidant” function for GGT
γγ-glu-gly
γ−glu-gly
22 2
-glu-gly
cell
cell
cell
GSH
GSH
GSH
[pKa
(SH) = 8.56]
[pKa(SH)=8.56]
[pKa (SH) = 8.56]
.
gly-cys-S
gly-cys-S. .
gly-cys-S
GGT
GGT
GGT
thiyl
radical
thiylradical
radical
thiyl
2+
Fe
Fe
Fe2+2+
gly
gly222
gly
.
O
O.
_
_
2
2
gly-cys-S
gly-cys-S-gly-cys-S
gly-cys-SH
gly-cys-SH
gly-cys-SH
HH22O
O22
H++
H
[pKa
(SH)
[pKa(SH)=6.4]
[pKa
(SH)==6.4]
6.4]
H ++
H
3+
3+
Fe
Fe
Fe 3+
O
O22
Pompella et al., 1997–2002
GGT-dependent production of ROS
Human hepatoblastoma HepG2 cells
HepG2 cells
+ GSH
HepG2 cells
+ GSH + gly-gly
NBT reduction
+ GGT inhibitor
Paolicchi et al. (1998)
R-SH
.
R-S
H2O2
.
R-S
H2O2
.
O2 −
R-SH
.
R-S
O2
Fe(III)
S
.
SUPEROXIDE
Fe(II)
thiyl radicals
GSH
SH
H2O2
SH
γ
SS
SS
SH
γ
SS
OUTSIDE
SH
S-S
S-S
GGT
INSIDE
SH
γ
GSH
γ-glutamyl cycle
INTRACELLULAR EFFECTS
Pompella et al. 2002
GGT activity basally down-regulates membrane protein thiols
U937 hystiocytoma / MPB-EaFITC reaction / CLS fluorescence microscopy
Control
GGT inhibition
Dominici et al., Free Rad. Biol. Med. (1999)
O2
PROTEIN S-THIOLATION
Fe(III)
S
.
SUPEROXIDE
Fe(II)
thiyl radicals
GSH
SH
H2O2
SH
γ
SS
SS
SH
γ
SS
OUTSIDE
SH
S-S
S-S
GGT
INSIDE
SH
γ
GSH
γ-glutamyl cycle
INTRACELLULAR EFFECTS
Pompella et al. 2002
S-Thiolation >>> Modulation of protein function
Oxidation of TNFR-1 increases 125I-TNF-α binding affinity
Scatchard
analysis
Dominici et al.
(2004)
Bound / free 125I-TNFα ratio
0.12
Control
GGT stimulation
=
GGT inhibition
increased affinity
GGT stimulation
0.10
0.08
0.05
0.03
GGT inhibition
=
decreased affinity
0.00
0.0020
0.0045
Bound
0.0070
125
0.0095
I-TNFα (nm)
0.0120
More targets at the cell surface :
GGT prooxidant effects regulate voltage-gated K+ channels
Zheng MQ et al., Am J Physiol Cell Physiol 297: 253-262, 2009
A number of GGT-dependent redox effects
have been documented and published
BIOMARKERS
GGT protein complexes®
Pompella et al., 1997–2011
PAT. PCT/IB2008/052499 - WO2009/001290-A3
GSAO GSNO
ACCUMULATION IN
ATHEROSCLEROTIC
PLAQUES
GSH
shedding
GGT
Cis
Glu + Cis = ϒ-Glu-Cis
GCAO
NO release
Cys-Gly
Cys
DIPEPTIDASE
METAL REDUCTION
REDOX CYCLING
−SH OXIDATION
TNFR1
ROS
Oxidation of
AA to DHA
increased binding affinity
Vitamin C resupply
ASK-1 / p38
phosphorylation
ADDUCTS with CISPLATIN
Gly-Cys-CDDP-Cys-Gly
NF-kB
H2O2
GSH RESYNTHESIS
ANTIOXIDANT ROLE
translocation
& transactivation
induction of
CATALASE
IL-8 expression
SOD CAT DFO BHT Trolox ABBA
GENOMIC INSTABILITY
CANCER
PROGRESSION
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin (CDDP)
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
Cisplatin reacts with gly-cys much faster than with GSH
cell
cell
GSH + Cisplatin
TOXICITY PERSISTS
GGT
gly-cys/cisplatin
complex
H+
gly-cys-S–
gly-cys-SH
+ Cisplatin
HN
gly-cys-S -
S
NH
Pt
gly-cys-S -
GSH/cisplatin
complex
S
EXTRACELLULAR
DETOXICATION
Franzini et al., Eur. J. Cancer (2006)
GGT expression confers cisplatin resistance
Cell growth
Me665/2/60 melanoma cells
+ Cisplatin 2.5 µM
+ ABBA
Pompella et al. (unpublished results)
DRUG ACTIVATION: 4-(N-(S-glutathionyl-acetyl)amino) phenylarsinous acid
GSH
AO
GSAO
a promising anti-angiogenic
γ-glutamyltransferase
cleaved and activated
by γ-glutamyltransferase
GCAO
GGT-expressing cells:
more cisplatin-resistant, more GSAO-sensitive
high GGT cells
high GGT cells
effects of GSAO
effects of cisplatin
Dilda et al. (unpublished results)
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
S-Nitrosoglutathione (GSNO) is the storage and transport form of NO
GSNO is a substrate for GGT
.NO
GGT
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin (CDDP)
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
Tissue areas rich in GGT can retrieve .NO from GSNO
GSNO
.NO
.NO
GGT
.
.NO
GSNO
GSNO
GSNO
.NO
.NO
GGT
.
.NO
.NO
.NO
GGT
.NO .
NO
GSNO
NO
NO
Endothelial GGT mediates the vasorelaxant effect of GSNO in isolated
rat aortic rings – Dahboul et al., PLoS One 2011
AORTIC
WALL
GSNO
released NO
protein nitrosylation
GGT
activity
GSNO
metabolism
GSNO
alone
GSNO
+ GGT substrates
GSNO
+ GGT inhibition
Endothelial GGT mediates the vasorelaxant effect of GSNO in isolated
rat aortic rings – Dahboul et al., PLoS One 2011
GGT
stimulation
% o f relaxation
100
50
GGT
inhibition
0
-10
-9
-8
-7
-6
log [GSNO], M
-5
-4
Incidence (%)
Serum GGT levels are a favouring factor on the development of
hypertension – DH. Lee et al., J.Hum.Hypertens. (2004)
GGT (U/L)
Age(years)
Serum GGT is a factor in utilization of GSNO
Bramanti et al., Arch. Biochem. Biophys. (2009)
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
GGT involved in pathogenesis of atherosclerosis?
Circulation 112: 2078
-80, 2005
2078-80,
Serum and tissue GGT activity occur in the form
of four (macro)-molecular complexes
3
4
1
2
A HIGH PERFORMANCE GEL FILTRATION CHROMATOGRAPHY METHOD
FOR GAMMA-GT FRACTION ANALYSIS - Franzini et al., Anal. Biochem. 2008
GGT of the future – four macromolecular complexes
Size exclusion chromatography with post-column fluorescent reaction®
Franzini et al., Anal. Bioch. 2008
Franzini et al., Clin. Chem. Lab. Med. 2010
Patent pend. PCT2007/IB2008/05499
Sorta srl.
a University of Pisa Spin-off
www.sorta-biomedical.com
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
GGT is contained in PMN granules
FIXED /
γ-Glutamyl-4-methoxy-2-naphthylamide
+ Fast Garnet GBC
Corti et al., PLoS One 2013
Activated PMNs release GGT
UNFIXED:
Control
f-MLP activated
Corti et al., PLoS One 2013
Released GGT promotes NF-kB activation and IL-8 expression
G1
IL-8 expression
NF-kB / DNA
binding
Corti et al., PLoS One 2013
+
+G gly2
GT
+G
SH
G1 : +GSH +GGT
+G
SH
C : Control / C1 : +GSH
+g
l
ro
l
y2
(% of control)
Co
nt
BEAS-2b
human bronchial
epithelial cells
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
GGT in aortic valve disease: calcification and neoangiogenesis
CD68
GGT
CD68
GGT
Cappelli et al., Atherosclerosis (2010)
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
H. pylori GGT-dependent H2O2 generation, NF-kB activation, IL-8 secretion
and DNA damage in AGS gastric cells - Gong et al., Gastroenterology 2010; 139: 564
H2O2
IL-8 secretion
DNA damage
GGT – bioactivity & pathophysiology
• effects in drug resistance: Cisplatin
• effects in drug activation: GSAO
• GGT catalyzes NO release from GSNO
• relationships with vascular tone and hypertension
• relationships with atherosclerosis and CHD
• relationships with neutrophils and inflammation
• GGT protein and activation of osteoclasts
• MORE… Bacterial GGT
• MORE… Plant GGT
GGT in barley root cell wall – Salvage of GSH from the root apoplast
Ferretti et al., New Phytologist 181: 115-126, 2008
GGT:
THIOL METABOLISM
GSH – S-thiolations – S-nitrosoglutathione
PATHOGENESIS
Drug resistance – Inflammation – CHD – Calcifications – H. pylori
BIOMARKER
GGT serum isoforms®
TARGET
Dip. di Ricerca Traslazionale,
Università di Pisa
A. PAOLICCHI
S. DOMINICI
A. CORTI
M. FRANZINI
Dip. di Med. Molecolare,
Dip. di Biotecnologie Mediche,
Università di Siena
E. MAELLARO
P. TANGANELLI
S. CAPPELLI
Istituto Nazionale Tumori, Milano
C. GIOMMARELLI
F. ZUNINO
Lowy Cancer Research Center,
UNSW Sidney, Australia
P. DILDA
P.J. HOGG
Facultés de Pharmacie et de Science,
Université de Lorraine, Nancy (F)
P. LEROY
I. LARTAUD
A. VISVIKIS
Ist. di Chimica dei Composti
Organo-Metallici – CNR, Pisa
E. BRAMANTI
Sorta srl. – a University of Pisa Spin-off
With the support of Sorta Srl.
www.sorta-biomedical.com
How is free iron available for
these reactions ?
Metal cations are physiologically sequestered
in specific transport & storage proteins
• PATHOLOGY !
• PHARMACOLOGY !
Complexed iron can be released
• Breakdown of hemoglobin by H2O2 liberates iron
• Gutteridge JMC, FEBS Lett. 1986
• Puppo et al., Biochem. J. 1988
• Puppo et al., Free Rad. Res. Commun. 1988
• Superoxide induces the release of catalytic iron from ferritin
• Bolann et al., Eur. J. Biochem. 1990
• Superoxide induces iron release from Fe-S proteins
• Liochev SI, Free Rad. Res. 1996
• Imlay et al., Annu. Rev. Biochem. 2008
• GGT itself reductively releases iron from Ferritin & Transferrin
• Paolicchi et al., J. Invest. Med. 1999
• Dominici et al., Cancer Cell. Int. 2003
• Corti et al., Free Rad. Biol. Med. 2005