Lesson_03_antibody_ODONT_19_20 [Autoguardado].pdf

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Lesson 3:
Immunoglobulins: structure and
function
Generation of B cells repertoire
 Immunoglobulins: molecular structure

The “pattern” immunoglobulin is a
glycoprotein formed by 4 polipeptidic
chains: two heavy (blue) and two light
chains (green)

A light chain and a heavy chain are linked by a
disulfide bond.
Heavy chains are linked together by one (or several)
disulfide bond.

Aproximate image of an IgG molecule structure.
 A) Variable regions (Antigen binding)

HVR (high variable regions) form the antigen
binding surface.
Among them there are framework regions with
more conserved sequences.
The antigen binding site is formed by three
heavy chain loops and three light chain loops.
HVR = CDR
Immunoglobulins: diversity and
specificity
Specificity: each Ig
binds selectively its
specific antigen
Diversity: there are
around 109 different
specificities
B) Constant regions (with effector functions)

ANTIBODY CLASSES (ISOTYPES)
depend on C domains of Ig heavy chain
HEAVY CHAINS:
Gamma (g): IgG
Delta (d): IgD
Epsilon (e): IgE
Alfa (a): IgA
Mu (m): IgM

LIGHT CHAINS:
Kappa (k)
Lambda (l)
Both k or l in every Ig molecule

IgE and IgM have an extra
constant domain in their heavy
chains (4).
IgA and Ig M tend to form
dimers (IgA) or pentamers (IgM),
using the so called J (Joining)
chain
Immunoglobulins: effector functions

Opsonization /
phagocytosis

Antibody-mediated cytotoxicity
Complement
activation
Ig M

5-10% serum Igs (pentamers)
Primary response Ig
Great agregation capacity and complement
activation, but it does not have direct
opsonization capacity.
It does not cross placenta
Membrane IgM: BcR, monomer.
 Ig G

Four subclasses: IgG1-IgG4.
More abundant serum isotype (80%)
Main secondary response Ig
Cross placenta.
Good opsonization capacity and complement activation.
Ig A

Main mucosal Ig, always a dimer. Both IgA
monomers are joined together by the so called
J chain. In secretions, IgA is bound to another
chain called “secretory component” which
protects it from proteases of gut lumen

In blood: monomer or dimer
It is the secretions Ig: Salive, tears, nasal,
bronquial, genitourinary, digestive fluids,
breast milk.
Ig E

Very small amounts in serum, its
concentration increases in parasite
infestations and allergy.

Special Ig in defense against parasites.

It does not activates complement. Its Fc
regions binds membrane receptors is
basophils and masts cells (FcRI).

Role in pathology: allergies.
Ig D

Biological function: BcR
(together with IgM).

The serum free form is very
scarce and without known
function.
GAMDE
ANTIGEN-ANTIBODY
REACTION
 ANTIGENS AND IMMUNOGENS

Immunogenicity is a molecule´s capacity to induce a detectable immune response (to
activate lymphocytes). These substances are called immunogens. Proteins and
glycoproteins are the most potent ones.

Antigenicity. A molecule´s capacity to specifically combine to antibodies or T cell
receptors. In general most of them are immunogens.

Antigen and immunogen: all immunogens are ALSO antigens, but not all antigens are
able to induce an immune response.

Haptens are antigens not immunogens by themselves but they become immunogens if
they associate to another molecule called carrier. They normaly have low molecular
weight and many of them are drugs or antibiotics.

Epitope is the precise part of an antigen that combines with a specific antibody or T cell
receptor. In the past they were called antigenic determinants.
 Main features of antigen-antibody reactions

1. Ag/Ab binding is reversible
2. Antibodies can fix big macromolecules.
3. Antigen-antibody reactions are defined by affinity and avidity
 Affinity:
Strength of union between antibody and antigen

It is defined by the disociation constant (Kd):

Ag concentration needed to occupy the biding sites of half the
antibodies in a solution.
 AVIDITY
GLOBAL STRENGTH OF INTERACTION BETWEEN TWO MOLECULES

It depens on:
Affinity
Valency (number of
binding sites)
Relationship between antibody structure and
function

a) Regarding the antigen recognition:

1.- Specificity: Antibodies are extremely specific (they recognize
very small differences) Exception: Cross-reactivity
phenomenon.
High affinity
2.- Diversity: each individual is able to synthesize 109 different
antibody specificities = antibody repertoire
3.- Affinity maturation: During the humoral response the V regions
slightly change its structure, due to a somatic mutation Low affinity
process in B lymphocytes stimulated by the Ag. This
generates Abs of higher affinity.

b) Regarding the effector functions:

1.- Functions such as phagocytosis, opsonization, complement
fixation, depend on Fc structure.
2.- Effector functions take place only when the Ab is bound to the
During the immune response the
Ag and do not occur with free Ab. antibodies affinity increases and
3.- The activation of a B lymphocyte by an antigen produces isotype
switching:
immunoglobulin class switching occurs
❖ Virgin or naïve B cells--->Membrane IgD and
IgM
❖ B cell activated by an Ag-→IgG, IgE of the
same specificity (V fragments-dependent) and
higher capacity to eliminate antigen (C-
fragments dependent)
4.- Fc dictates the tissular distribution of Abs.
B cells and its antigen
receptor.
 1. B cell: Phenotype, function and differentiation

▪ Most B cells express membrane IgM and
IgD: They are mature lymphocytes that do
not have found yet their specific Ag.

▪ CD19, CD21, CD45 and CD40 are
accessory BcR molecules that help in B
cell activation.

B lymphocytes express in its membrane a protein group
called B cell antigen receptor

BcR complex
 Events after recognition of antigen by the B lymphocyte
1.1
▪ Ag recognition begins an
intracelular activation
signal that includes:
❖ phosphorylation and
dephosphorylation events
❖ membrane
phospholipids hydrolysis
and 2nd mesengers
generation
❖ cytosolic Ca2+
increase

▪ The purpose of this
activation is to modify the B
cell gene expression profile:
mitosis activation
(proliferation), Igs
synthesis and
differentiation.
 T-dependent and T-independent antigens

Proteic antigens need always the T-B cooperation for the production
of antibodies against them.
– High affinity: affinity maturation
– Immune memory
– Isotype switching in secondary response
Non-protein antigens, they do not need T-B cooperation
– Low affinity (affinity maturation does not take place)
– Almost never immunological memory
– Almost never isotype switching: always IgM or limited to IgG2 at most
1.2
▪ B cell recognizes Ag in native
form, procceses and presents it
to T cell, which cooperates
(helps) in activating B cell and
begining the humoral response.

▪B cell internalizes Ag and
presents it to CD4+ T cell, using
a HLA class II molecule, to achieve
T cell collaboration.
Consequences:
▪ Increasing proliferation and
differentiation.
▪ Igs isotype switching
▪ Affinity maturation
 Where do
these events
happen?
 Genesis of Immunoglobulin repertoire

Somatic recombination:
Mechanism that generates diversity: from a relatively limited
number of gene sequences, an almost infinite number of
different proteins are produced.
Together with the somatic recombination, another two
mechanisms amplify Igs diversity:

a) Junctional diversity: VDJ recombinations are unprecise,
several nucleotides are included in each of them (P
nucleotide). On the other hand, terminal deoxinucleotidil
transferase (TdT) enzyme randomly adds nucleotides in the
same regions (N nucleotides). Both mechanisms occur
during the Ig recombination.
b) Somatic hypermutation: new mutations are introduced
after the antigen recognition. They affect the total V domain.
They are responsable for affinity maturation.
 The end

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