Download Immunoglobulin Structure

Immunoglobulins:
structure and function
Immunoglobulins
Amount of protein
• Definition:
Glycoprotein molecules that are present on
B cells (BCR) or produced by plasma cells
(antibodies) in response to an immunogen
+
albumin
globulins


1
2

Mobility

Immune serum
Antigen adsorbed
serum
Immunoglobulin Structure
• heavy and light
chains
• disulfide bonds
– inter-chain
– intra-chain
disulfide
bond
carbohydrate
CL
VL
CH1
VH
CH2
hinge region
CH3
Immunoglobulin Fragments:
Structure/Function Relationships
antigen
binding
complement binding site
binding to Fc
receptors
placental
transfer
Immunoglobulin Structure
• variable and
constant regions
• hinge region
disulfide
bond
carbohydrate
• domains
– VL & CL
– VH & CH1 - CH3
(or CH4)
• oligosaccharides
CL
CH1
VH
CH2
hinge region
CH3
Ribbon structure of IgG
Immunoglobulin Fragments
Structure/Function Relationships
• Fab
papain
– antigen binding
– valence = 1
– specificty determined
by VH and VL
• Fc
Fc
– effector functions
Fab
Immunoglobulin Fragments:
Structure/Function Relationships
• Fab
pepsin
– antigen binding
• Fc
– effector functions
• F(ab’)2
- Bivalent!
Fc
peptides
F(ab’)2
Why do antibodies need an Fc region?
the (Fab)2 fragment can •
detect antigen
•
precipitate antigen
•
block the active sites of toxins or pathogen-associated
molecules
•
block interactions between host and pathogen-associated
molecules
but can not activate (role of Fc region)
•
inflammatory and effector functions associated with cells
•
inflammatory and effector functions of complement
•
the trafficking of antigens into the antigen processing
pathways
Immunoglobulin Structure-Function Relationship
• cell surface antigen receptor on B cells
allows B cells to sense their antigenic environment
connects extracellular space with intracellular signalling
machinery
• secreted antibody
neutralization
opsonization
complement fixation
Variability in different regions of the Ig
determines Ig classes or specificity
isotype
allotype
idiotype
(Classes/subclasses)
Sequence variability of H/Lchain constant regions
Allelic variants
Sequence variability of H
and L-chain variable
regions (individual, clonespecific)
Human Immunoglobulin Classes
encoded by different structural gene segments (isotypes)
•
•
•
•
•
IgG - gamma (γ) heavy chains
IgM - mu (μ) heavy chains
IgA - alpha (α) heavy chains
IgD - delta (δ) heavy chains
IgE - epsilon () heavy chains
light chain types
• kappa ()
• lambda ()
PRODUCTION OF IMMUNOGLOBULINS
BEFORE BIRTH
AFTER BIRTH
breast milk
IgA
100%
(adult)
maternal IgG
IgM
IgG
IgA
0
3
month
6
9
1 2 3 4 5 adult
year
Ig. Concentration
level
of antibodies
secondary response against
Szekunder
antigen A ’lasyecondary resp
primary response
against
antigen
A
primer
response
IgG
IgA
IgE
IgM
IgM
primary
response
against
antigen B
5
„A” antig éAn
Antigen
10
15
20
25
„A” és „B”
Antigen
A and
antigén
30
B
napok
days
napok
Polyclonal antibody response
Ag
Immunserum
Polyclonal
antibody
Set of B-cells
Ag
Activated B-cells
Antibodyproducing
plasma-cells
Antigen-specific
antibodies
Ig isotype
Serum
concentration
Characteristics, functions
Trace
amounts
 Major isotype of secondary
(memory) immune response
 Complexed with antigen activates
effector functions (Fc-receptor
binding, complement activation
 The first isotype in B-lymphocyte
membrane
 Function in serum is not known
Trace
amounts
 Major isotype in protection against
parasites
 Mediator of allergic reactions (binds
to basophils and mast cells)
3-3,5 mg/ml
 Major isotype of secretions (saliva,
tear, milk)
 Protection of mucosal surfaces
12-14 mg/ml
1-2 mg/ml
 Major isotype of primary immune
responses
 Complexed with antigen activates
complement
 Agglutinates microbes
 The monomeric form is expressed in
B-lymphocyte membrane as antigen
binding receptor
Protein amounts
Gamma-globulin fraction: mixture of policlonal
antibodies – normal IgG antibodies ~10 mg/ml
albumin
globulins
1
2

Mobility

immune serum
antigen adsorbed
serum
WHICH KIND OF ANTIBODIES?
Memory antibodies produced by environmental
stimuli
REFLECTING TO THE IMMUNE RECORD OF THE
INDIVIDUAL
Which kind of pathogens we met before
+
Case study (Multiple myeloma)
• In 1989, a 55-year-old housewife, who had been in good health her entire life,
began to experience excessive fatigue.
• Her physician did not find abnormalities on physical examination.
• The blood sample revealed mild anemia;
red blood cell count was 3.5 x 106 / ml
white blood cell count was 3600 / ml
(normal 4.2-5.0 x 106 / ml),
(normal 5000 / ml).
• The sedimentation rate of her red blood cells was 32 mm / h (normal <20 mm / h).
(Sedimentation is accelerated when fibrinogen or IgG content of the blood plasma
is elevated.)
• The concentration of IgG was found to be 3790 mg / dl (normal 600 - 1500 mg / dl),
that of IgA 14 mg / dl (normal 150 – 250 mg / dl) and that of IgM 53 mg / dl
(normal 75 -150 mg / dl).
Case study (Multiple myeloma)
• Electrophoresis of her serum revealed the presence of a monoclonal protein, which
on further analysis was found to be IgG with lambda light chains.
normal serum
serum from the patient
• Radiographs of all of her bones did not show any abnormality.
• No treatment was advised.
Case study (Multiple myeloma)
• In April 1991 her serum IgG was 4520 mg / dl, and in January 1992 it was
5100 mg / dl. By November 1992, her anemia had worsened and her red blood
cell count had fallen to 3.0 x 106 / ml. At the same time her white blood count had
fallen to 2600 / ml.
• In December 1992, she experienced the sudden onset of upper arm pain and
headache.
• Radiographs of the skull and the left upper arm showed ‘punched out’ lesions in
the bones.
Case study (Multiple myeloma)
• She was treated with melphalan (methylphenylalanine mustard), corticosteroids,
and irradiation. Her symptoms improved.
• In April 1993, further chemotherapy was given because of the persisting elevation
of her serum IgG. The treatment reduced her serum IgG level from 8200 mg / dl to
6000 mg / dl.
• In February and in May 1995, she was found to have pneumonia. She was treated
successfully with antibiotics. She recovered from this episode in the hospital and
remained fully active. She required blood transfusion for her anemia and complained
at times of bone pain. Her serum IgG was stable at 6200 mg / dl.
Although she was in relative good health as our case history ended, her outlook
for survival was very poor. Recently, bone marrow transplants have been used
to cure patients with multiple myeloma.
/Myeloma proteins have played an important part in the history of immunology.
(Bence-Jones protein, subclasses of IgG, amino acid sequence of immunoglobulin molecule)/
Questions
The serum IgG from her was assumed to be monoclonal because it migrated as
a tight band on electrophoresis in an agarose gel, and because it reacted with
antibodies to lambda but not to kappa chains. What other evidence could be
brought to bear to prove the monoclonality of this IgG?
The IgG could also be shown to belong a single subclass of IgG, that is IgG1,
IgG2, IgG3, or IgG4. Further more, it would be possible to show that a single
variable-region gene was rearranged to form this IgG.
She became anemic (low red blood cell count) and neutropenic (low white blood
cell count). What was the cause of this?
The proliferation of malignant plasma cells in the bone marrow crowded out
blood cell precursors. This creates a limitation on space in the bone marrow.
As her disease progressed, she became susceptible to pyogenic infection;
for example, she had pneumonia twice in a short period. What is the basis of
her susceptibility to these infections?
Although her serum IgG concentration is quite elevated, almost all the IgG is
secreted by the myeloma cells and is monoclonal. In fact, she has very little
normal polyclonal IgG and has been effectively rendered agammaglobulinemic
by her disease. In addition, her white blood cell count is decreased and she
has too few neutrophils (<1000 / ml) to ingest bacteria in the bloodstream and lungs
effectively.
A monoclonal immunoglobulin in the serum is called an M-component (‘M’ for
myeloma). Is the presence of an M-component in serum diagnostic of multiple
myeloma?
No. M-component appear in the blood as people age. About 10% of healthy
individuals in the ninth decade of live have M-component. This is called benign
monoclonal gammopathy. Without bone lesions and presence of many malignant
cells in the bone marrow, the diagnosis of multiple myeloma cannot be made.
Some people have IgM M-components in their blood. This is due to another
malignancy of plasma cells called Waldenström’s macroglobulinemia, which
differs in many ways from multiple myeloma and is a more benign disease.
What happens with the B cells in myeloma multiplex?
Healthy individual
Myeloma multiplex
B cell tumors
Structures of the ABO blood group antigens
Defined by specific enzymes inherited co-dominant genes (Mendelian rules)
Donors and recipients for blood transfusion
-
+
+
+
-
-
+
+
-
+
-
+
-
-
-
-
The produced antibodies against blood group antigens are IgM isotypes
Pathological consequences of placental transport of IgG
(hemolytic disease of the newborn)
Passive anti-D IgG
Features of antibody-antigen interaction
Valency: numbers of antigens
/ antibody
Affinity: the strength of
interaction between a specific
antigen and one binding site
of the antibody
Avidity: sum of affinities of
the binding sites of a a given
antibody
Secretory IgA and transcytosis
S
S
SS
SS
SS
SS
ss
ss
J
J
S
S
S
S
S
S
S
S
S
S
S
S
B
J
ss
SS
Epithelial
cell
pIgR and IgA are
internalised
ss
SS
S
S
J
S
S
J
SS
SS
S
S
ss
IgA and pIgR
are transported
to the apical
surface in
vesicles
SS
‘Stalk’ of the pIgR is degraded to release
IgA containing part of the pIgR - the
secretory component
SS
B cells located in the submucosa
produce dimeric IgA
Polymeric Ig
receptors are
expressed on the
basolateral surface
of epithelial cells to
capture IgA
produced in the
mucosa
Features of polyclonal and monoclonal antibodies
Polyclonal
antibody
Monoclonal
antibody
(low affinity)
Monoclonal
antibody
(high affinity)
Number of recognized
antigen determinants
several (frequent
cross-reactions)
one (but frequent
cross-reactions)
mostly one
Specificity
polyspecific
often polyspecific
monospecific
Affinity
Varying (diverse
antibodies)
low
high
Concentration of nonspecific
immunoglobulines
high
low
low
Cost of preparation
low
high
high
Standardisability
Impossible (or
uneasy)
easy
easy
Amount
limited
unlimited
unlimited
Applicability
method-dependent
low
excellent
Monoclonal antibodies
- product of one B-lymphocyte clone
- homogeneous in antigenspecificity, affinity, and isotype
- can be found in pathologic condition in humans
(the product of a malignant cell clone)
- advantages against polyclonal antibodies: antibodies of a given
specificity and isotype can be produced in high quantity and
assured quality.
-therapeutic usage of monoclonals:
anti-TNF-α therapy in rheumatology,
tumor therapy
Possible use of monoclonal antibodies
- Identifying cell types
Immunohistochemistry
Characterization of lymphomas with CD (cluster of differentiation) markers
- Isolation of cells
Isolation of CD34+ stem cells for autologous/allogeneic transplantation (from peripheral blood!)
- Blood group determination (with anti-A, anti-B, and anti-D monoclonals)
- Identification of cell surface and intracellular antigens
Cell activation state
- Targeted chemotherapy
CD20+ anti-B-cell monoclonals in non-Hodgkin lymphoma
Prevention of organ rejection after transplantation
Monoclonal antibodies as drugs?
Mouse monoclonal antibodies may elicit
an immune response upon administration
in human subjects.
(see immunogenicity-determining factors!)
How can we solve this problem?
Evolution of monoclonal antibodies
Mouse
Chimeric
Human
Humanized
Monoclonals as drugs
- Tumor therapy
Monoclonals can be used for targeted
chemotherapy of tumors. It is cell-type
specific, but not specific to malignant cells!
- Immunsuppressive monoclonals
Cell-type specific immunsuppression
Monoclonal antibody nomenclature
The nomenclature of monoclonal antibodies is a naming scheme for assigning generic,
or nonproprietary names to a group of medicines called monoclonal antibodies.
This scheme is used for the World Health Organization’s International Nonproprietary
Names.
Components of nomenclature:
Prefix Target
Source
Suffix
-ki(n)- interleukin as target -u-human
-ci(r)- cardiovascular
-o-mouse
variable
mab
-co(l)- colonic tumor
-xi-chimeric
-neu(r)- nervous system
Etc.
-zu-humanized
Etc.
Example:Abciximabab- + -ci(r)- + -xi- + -mab, it is a chimeric monoclonal antibody
used on the cardiovascular system
Monoclonals in tumor therapy
1. „Naked MAb”, unconjugated antibody
Anti-CD20 (rituximab – Mabthera/Rituxan, chimeric): B-cell Non-Hodgkin lymphoma
Anti-CD52 (campath – Mabcampath, humanized): chronic lymphoid leukaemia
Anti-ErbB2 (trastuzumab – Herceptin, humanized): breast cancer
Anti-VEGF (bevacizumab – Avastin, humanized): colorectalis tu. (+ Lucentis!)
Anti-EGFR (cetuximab – Erbitux, chimeric): colorectalis tu. (+ Vectibix, rekomb. humán!)
2. Conjugated antibody
Anti-CD20 + yttrium-90 isotope (ibritumomab- Zevalin)
Anti-CD20 + iodine-131 (tositumomab – Bexxar)
Immunsuppressive antibodies 1.
1. Anti-TNF-α antibodies
infliximab (Remicade): since 1998, chimeric
adalimumab (Humira): since 2002, recombinant human
2. Etanercept (Enbrel) – dimer fusion protein,
TNF-α receptor + Ig Fc-part
Not a real monoclonal antibody, no Fab end,
the specificity is given by TNF-receptor!
Indications of anti-TNF-α therapy:
• Rheumatoid arthritis
• Spondylitis ankylopoetica (SPA - M.
Bechterew)
• Psoriasis vulgaris, arthritis psoriatica
• Crohn-disease, colitis ulcerosa
• (usually - still – not in the first line!)
Immunsuppressive antibodies 2.
-
Muromonab-CD3 (OKT-3) egér IgG2a
Against CD3 pan-T-cell antigen, after transplantation; It is rarely (or not) used nowadays (mouse
protein!); ongoing trials in diabetes mellitus, with the humanized version
-
Omalizumab (Xolair):
Anti-IgE humanized IgG1k monoclonal
Ind.: allergic asthma, Churg-Strauss sy.
-
Daclizumab (Zenapax):
anti-IL-2 receptor humanized antibody
Ind.: transplantation
-
basiliximab (Simulect): as daclizumab, but chimeric!
-
efalizumab (Raptiva): anti-CD11a, humanized, used in psoriasis
Molecular targeted drugs
Name
Type
Target
Indications
Alemtuzumab
Monoclonal Ab, humanized
CD52
CLL, CML
Monoclonal IgG1, chimeric
IL-2 R
transplantation
Monoclonal IgG1, chimeric
IL-2 R
transplantation
Monoclonal IgG1, chimeric
CD20
Lymphoma
Monoclonal IgG1, humanized
HER2/neu
Monoclonal IgG4, humanized
CD33
Breast cancer, NSC
lung cancer
leukemia
Monoclonal IgG1, murine
CD20
lymphoma
Monoclonal IgG2, murine
EGFR-TKI
KIT-TKI
EpCAM
EGFR TK
TK
CRC
NSCLC
GIST, CML
(Mabcampath)
Daclizumab
(Zenapax)
Basiliximab
(Simulect)
Rituximab
(Rituxan/Mabthera)
Trastuzumab
(Herceptin)
Gemtuzumab
Calicheamicinnel konjugált
Ibritumomab
(Y90)
Edrecolomab
Gefitinib
Imatinib
Further possibilities with monoclonals
Radioimmunotherapy
As Zevalin, Bexxar – monoclonal + isotope
Antibody-directed enzyme prodrug therapy (ADEPT)
An enzyme is linked to the antibody, and the enzyme will make
citotoxic drug from the later administered prodrug
Immunoliposomes
Targeting nucleotides or drugs in liposomes, linked to an antibody
Non-immunological targets
as abciximab (ReoPro): inhibition of thrombocyte-aggregation
PASSZÍV IMMUNIZÁLÁS
mouse monoclonal
antibodies
immunization
humanized mouse
monoclonal antibodies
immunization
PROTECTED
SUBJECT
serum antibody
ENDANGERED
SUBJECT
Human immunoglobulin
transgenic mouse
human monoclonal
antibodies
immunsystem is not activated
prompt effect
temporary protection/effect
Immunoglobulin degradation
Passive immunization
Type
Application
Intramuscular
(less effective due to lower dose)
HBV-Ig; Varicella-zoster-Ig;
Intravenous (IVIG)
Bruton-agammaglobulinaemia;
variable and mixed
immunodeficiencies with
hypogammaglobulinaemia;
Anti-venom antibody treatment;