Antibody Structure Lec5 PDF

Summary

This document covers the molecular mechanisms of antibody synthesis. It details how genes assemble during B cell development and how affinity maturation and class switching occur. It also describes the role of T cells in immune responses.

Full Transcript

Molecular Mechanism
of Antibody Synthesis
 Ig Genes Are Assembled from Separate Gene Segments
During B Cell Development
After stimulation by antigen and helper T cells, B cells can
switch from making IgM and IgD to making other classes of
Ig—a process called class switching.
In addition, the binding affinity of these Igs for their antigen
progressively increases over time—a process called affinity
maturation.
Each light-chain V region, for example, is encoded by a DNA
sequence assembled from two gene segments—a long V
gene segment and a short joining segment, or J gene
segment.
Each heavy-chain V region is similarly constructed by
combining gene segments, but here an additional diversity
segment, or D gene segment, is also required.
 In the “germ-line” DNA the cluster of five J The V–J joining process involved in
gene segments (green) is separated from making a human k light chain.
the C-region coding sequence (purple) by
a short intron.
During the development of a
B cell, a randomly chosen V gene
segment (V3 in this case) is moved to lie
precisely next to one of the J gene
segments (J3 in this case).
The “extra” J gene segments
(J4 and J5) and the intron sequence are
transcribed (along with the joined V3 and
J3 gene segments and the C-region
coding sequence) and then removed by
RNA splicing to generate mRNA
molecules with contiguous V3, J3, and C
sequences, as shown.
These mRNAs are then translated into κ
light chains.
The human heavy-chain locus.
Each heavy-chain V region is similarly constructed by combining
gene segments, but here an additional diversity segment, or D gene
segment, is also required
V(D)J recombination is mediated by an enzyme complex called V(D)J
recombinase, which recognizes recombination signal sequences in
the DNA that flanks each gene segment to be joined.
Although the process ensures that only appropriate gene segments
recombine, a variable number of nucleotides are often lost from the
ends of the recombining gene segments, and one or more randomly
chosen nucleotides are also inserted.
This random loss and gain of nucleotides at joining sites is called
junctional diversification, and it greatly increases the diversity of V-
region coding sequences created by V(D)J recombination.
Antigen-driven Somatic Hypermutation Fine-Tunes
Antibody Responses
After an infection or vaccination, there is usually a
progressive increase in the affinity of the antibodies
produced against the pathogen.
This phenomenon of affinity maturation is due to the
accumulation of point mutations in both heavy-chain and
light-chain V-region coding sequences.
B cells mutate at the rate of about one mutation per V-
region coding sequence per cell generation.
Because this is about a million times greater than the
spontaneous mutation rate in other genes and occurs in
somatic cells rather than germ cells, the process is called
somatic hypermutation.
 Very few of the altered Igs generated by hypermutation will
have an increased affinity for the antigen.
However, the antigen will stimulate preferentially those few
B cells that do make BCRs with increased affinity for the
antigen.
Most other B cells in the germinal center will die by
apoptosis.
B Cells Can Switch the Class of Ig They Make
When a B cell switches from making IgM and IgD to one of the secondary classes of Ig, an
irreversible change occurs in the DNA—a process called class switch recombination.
The activated B cells are undergoing somatic hypermutation in germinal centers, the
combination of antigen and cytokines derived from helper T cells stimulates many of the B
cells to switch from making membrane-bound IgM and IgD to making IgG, IgE, or IgA, in the
process of class switching.
Activation-induced deaminase (AID) is also required for activated B cells to switch from IgM
and IgD production to the production of the other classes of Ig, as we now discuss.
T lymphocytes
T CELLS AND MHC PROTEINS
Like antibody responses, T cell–mediated immune responses
are exquisitely antigen specific, and they are at least as
important as antibodies in defending vertebrates against
infection.
Indeed, most adaptive immune responses, including most
antibody responses, require helper T cells for their initiation.
Most important, unlike B cells, T cells can help eliminate
pathogens that have entered the interior of host cells,
where they are invisible to B cells and antibodies.
T cell responses differ from B cell responses in at least two crucial
ways.
First, a T cell is activated by foreign antigen to proliferate and
differentiate into effector cells only when the antigen is displayed
on the surface of an antigen-presenting cell (APC), usually a
dendritic cell in a peripheral lymphoid organ.
One reason T cells require APCs for activation is that the form of
antigen they recognize is different from that recognized by the Igs
produced by B cells.
Whereas Igs can recognize antigenic determinants on the surface
of pathogens and soluble folded proteins, for example, T cells can
only recognize fragments of protein antigens that have been
produced by partial proteolysis inside a host cell.
Newly formed MHC proteins capture these peptide fragments and
carry them to the surface of the host cell, where T cells can
recognize them.
 The second difference is that, once activated, effector T cells
act mainly at short range, usually contacting the cells they
influence, either within a secondary lymphoid organ or after
they have migrated to a site of infection.
Effector B cells, by contrast, secrete antibodies that can act
far away.
Effector T cells interact directly with another host cell in the
body, which they either kill (if it is an infected host cell, for
example) or signal in some way (if it is a B cell or
macrophage, for example).
 There are three main classes of T cells—cytotoxic T cells, helper T
cells, and regulatory T cells.
When activated, they develop into effector cells, each class having its
own distinct activities.
Effector cytotoxic T cells directly kill cells that are infected with an
intracellular pathogen.
Effector helper T cells help stimulate the responses of other immune
cells—mainly macrophages, dendritic cells, and B cells.
Effector regulatory T cells suppress the activity of other immune cells.
After functioning, some effector T cells become memory T cells.
T Cell Receptors (TCRs) Are Ig-like Heterodimers
Each chain has a large extracellular part that is folded into two
Ig-like domains one variable and one constant.
A Vα and a Vβ domain form the antigen-binding site. Unlike Igs,
which have two binding sites for antigen, TCRs have only one.
A typical T cell has about 30,000 TCRs on its surface.
Activated Dendritic Cells Activate Naïve T Cells

(A) Immunofluorescence micrograph of a mouse dendritic
cell in culture. These APCs derive their name from their long
processes, or “dendrites.”
(B) Scanning electron micrograph of T cells bound to the
surface of an activated dendritic cell in a mouse lymph
node.
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Activated Dendritic Cells Activate Naïve T Cells
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