Antibodies Pt. 3 PDF - BMS 545 Immunology - October 23, 2024

Summary

These notes cover topics like isotype switching and somatic hypermutation in the context of antibody diversification. They outline the different immunoglobulin types and their roles in the immune response.

Full Transcript

WELCOME!
BMS 545 IMMUNOLOGY
OCTOBER 23, 2024
  Office hours:
 Tues 4-5 pm virtual
 Thurs 4-5 pm 316J

ANNOUNCEMENTS  B cell textbook chapters:
 Chapter 4: Antibody Development
 Chapter 6: B Cell Development
 Chapter 9: B Cell & Antibody Mediated Immunity
WHY
SHOULD YOU
CARE?
 OBJECTIVES
 Define & describe how isotype switching and somatic hypermutation occur & key players
involved in each
 What are the consequences of isotype switching and somatic hypermutation?
 Identify the five types of immunoglobulins, their structure, function, role, & compare & contrast
 Define & use the definitions from today’s class as you talk about BCR development
 List the chromosomes where you can find the light and heavy chains
 Illustrate the flexibility of IgG (aka how does it move & why?)
 Provide examples of the immunoglobulin types (and subtypes) & their effector functions (slide
27)
 Compare & contrast the 4 subtypes of IgG
 List the changes in immunoglobulin genes and whether they are reversible or not
Diversification of antibodies after B cells encounter antigen
4-13 Rearranged V-region sequences are further diversified by
somatic hypermutation

Somatic hypermutation- mutation that occurs at high frequency
in the rearranged variable-region DNA segments of
immunoglobulin genes in activated B cells, resulting in the
production of variant antibodies, some of which have higher
affinity for the antigen
 SOMATIC HYPERMUTATION

 Upon subsequent epitope exposure, B cells may also
accumulate small point mutations in DNA encoding their
VL or VH regions during the rapid proliferation that follows
restimulation

 Provides additional variation to “fine-tune” antibody
responses to antigens that are frequently/chronically present
 Some mutations may increase binding affinity of antibody for
its epitope & increased affinity causes those cells to
proliferate more rapidly after binding to antigen
 Interaction of antibody with a specific epitope become
tighter & more effective over time = affinity maturation

 *Somatic hypermutation occurs only in B cells, not T cells
AFFINITY MATURATION
Figure 4.25 Somatic hypermutation is targeted to the rearranged gene segments that encode immunoglobulin V
regions

 The frequency of mutations at
positions in & around the
rearranged VJ sequence—
which encodes the V region—
of an expressed light-chain
gene is shown here
Figure 4.26 Somatic hypermutation enables selection of B cells making higher-affinity antibodies

 B cells were collected 1 & 2 weeks after immunization with same epitope & used to make hybridomas secreting monoclonal
antibodies
 Amino acid sequences of heavy & light chains of epitope-specific monoclonal antibodies were determined
 Each thick horizontal line represents one variant, & red bars represent amino acid positions that differ from prototypic sequence
 1week after primary immunization, most B cells make IgM, which shows some new sequence variation in V region
 This variation is confined to the CDRs, which form the antigen-binding site
 2 weeks after immunization, both IgG- & IgM-producing B cells are present, & their antibodies show increased variation & higher
affinity that involves all six CDRs of antigen-binding site
Diversification of antibodies after B cells encounter antigen
4-14 Isotype switching produces immunoglobulin with a different
constant region but identical antigen specificity

Isotype switching- process by which a B cell changes the class of
immunoglobulin it makes while preserving antigenic specificity of
the immunoglobulin. Involves a somatic recombination process
that attaches a different heavy-chain constant region gene to the
existing variable region exon (aka “Class switching”)
Figure 4.28 Isotype switching involves recombination between specific switch regions (Part 1)

 Repetitive DNA sequences are
found to the 5ʹ side of each of
the heavy-chain C genes, with
exception of the δ gene
 Immunoglobulin isotype
switching occurs by
recombination between these
switch regions (S), with
deletion of intervening DNA
 Switch regions are targeted by
AID, which leads to nicks being
Activation-induced cytidine deaminase (AID)- enzyme that deaminates DNA made in both strands of the
at cytosine residues converting them to uracil
The activity of AID & consequent repair of damaged DNA are basis of somatic DNA
hypermutation & isotype switching in activated B cells
Figure 4.28 Isotype switching involves recombination between specific switch regions (Part 2)

Continued down from
previous slide  These nicks facilitate recombination
between the switch regions, which
leads to excision of intervening DNA
as a nonfunctional circle of DNA &
brings the rearranged VDJ sequence
into juxtaposition with a different C
gene
 The first switch a clone of B cells
makes is from the μ isotype to
another isotype
 A switch from μ to the γ1 isotype is
shown here
 Further switching to other isotypes
can take place subsequently
ISOTYPE SWITCHING

 https://digital.wwnorton.com/immunesystem5
ISOTYPE SWITCH IN MEMORY B
CELLS
 Antibodies produced by B cells with
prolonged or repeated exposure to same
epitope may undergo an isotype
switch induced by T cell cytokines
 Availability of multiple isotypes having the
same specificity allows humoral response
to initiate various mechanisms (e.g.,
complement activation) to be directed
against the same epitope
 Serial reactivation of memory B cells
allows the isotype switch to occur during
each restimulation
 IgM is predominant isotype seen in
primary responses, while secondary
responses are mostly IgG, with IgA & IgE
 IgM → IgG → IgA → IgE
Diversification of antibodies after B cells encounter antigen
4-15 Antibodies with different constant regions have different effector
functions
 GENE CLUSTERS
ENCODING BCRS

 Gene clusters encoding κ
light chains =
chromosome 2
 Gene clusters encoding λ
light chains =
chromosome 22
 Heavy chain gene cluster
= chromosome 14
 Potential antigen-binding
combinations > 26
MILLION
 REFRESHER FROM EARLIER- IMMUNOGLOBULIN BASIC STRUCTURE
 Light chains, termed κ (kappa) or λ (lambda) are on chromosomes 2 & 22,
respectively
 Five types of heavy chains all encoded on chromosome 14
 Mu (μ)
 Delta (δ)
 Gamma (γ)
 Epsilon (ε)
 Alpha (α)

 Isotypes- genetically different forms of light chains (κ & λ) & of heavy chains (μ,
δ, γ, ε, & α)

 Immunoglobulin class or subclass is determined by the heavy chain isotype
Figure 4.5 The structures of the human immunoglobulin classes

 Note the differences in length of heavy-chain C regions, locations of the disulfide bonds linking the
chains, & presence of a hinge region in IgG, IgA, & IgD, but NOT in IgM & IgE.
 Heavy-chain isotype in each antibody is indicated by the Greek letter (where we get the name)
 The isotypes also differ in distribution of N-linked carbohydrate groups (turquoise)
 All these immunoglobulins occur as monomers in their membrane-bound form
 In their soluble, secreted form, IgD, IgE, & IgG are monomers
 IgA forms monomers & dimers, & IgM forms pentamers
Figure 4.29 The physical properties of the human immunoglobulin isotypes

 Molecular mass given for IgM is the pentamer (the form present in serum)
 Molecular mass given for IgA is the monomer
 Large amounts of IgA are also produced in the form of dimers, which are secreted at mucosal surfaces (i.e. in breast milk)
Figure 4.30 Each human immunoglobulin isotype has specialized functions correlated with distinctive properties
 Major effector functions of each
isotype (+++) are shaded in
dark red; lesser functions (++)
are shown in dark pink, and
minor functions (+) in pale pink
 Opsonization refers to the
ability of the antibody itself to
facilitate phagocytosis
 Antibodies that activate
complement system indirectly
cause opsonization via
complement
-Properties of IgA1& IgA2 are
similar & combined under “IgA”
*IgG2 acts as an opsonin in the
presence of one genetic variant of
its phagocyte Fc receptor, which is
found in ~50% of people of
European origin.
Figure 4.27 IgM is secreted as a pentamer of immunoglobulin monomers

 Schematic diagrams of IgM monomer & pentamer
 IgM pentamer is held together by a polypeptide called the J chain, for joining chain (not to be confused with a
junctional (J) segment)
 Monomers are cross-linked by disulfide bonds to each other & to J chain
 The lack of a hinge region in IgM monomer makes molecule less flexible than others (e.g., IgG) but this is compensated
for by pentamer having five times as many antigen-binding sites as IgG
 With pathogen with multiple identical epitopes on surface, IgM can attach with several binding sites simultaneously
Figure 4.31 IgA molecules can form dimers

 In mucosal lymphoid tissue, IgA is synthesized as a dimer
in association with the same J chain that is present in
pentameric IgM
 In dimeric IgA, the monomers have disulfide bonds to
the J chain but not to each other
Figure 4.32 IgG is a highly flexible molecule

 Most flexible part of IgG molecule = hinge
 Allows Fab arms to wave & rotate & accommodate
antibody to orientation of epitopes on pathogen surfaces
 “Elbow” within the Fab adds more flexibility that
allows variable domains to bend with respect to
constant domains
 Similarly, “wagging” of Fc tail allows IgG molecules that
have bound to antigen to accommodate to binding of
C1q & other effector molecules

*Shown is a molecule of the IgG1 subclass
Diversification of antibodies after B cells encounter antigen
4-16 The four subclasses of IgG have different and complementary
functions
Figure 4.33 Different hinge structures distinguish the four subclasses of IgG

 Relative lengths of hinge & # of disulfide bonds in hinge that cross-link the two heavy chains
are shown
 Not shown are other differences in amino acid sequence, particularly glycine & proline
residues, that influence hinge flexibility
Figure 4.34 The four subclasses of IgG have different and complementary functions
Figure 4.35 IgG4 is present in the circulation in a functionally monovalent form

 Like other IgG subclasses, IgG4 is synthesized in a form that has two heavy chains, two light chains, & two
identical antigen-binding sites
 Unlike other IgGs, molecules of IgG4 can interact in the circulation & exchange one heavy chain & its
associated light chain
 Because of this property, most IgG4 molecules in circulation have TWO different binding sites for antigen
 Thus, they only interact with a pathogen or a protein antigen through one binding site
Figure 4.36 Gene rearrangement and the synthesis of cell-surface IgM in B cells

Summary slide of heavy & light chain
rearrangement & development
 Before immunoglobulin light-chain
(center) & heavy-chain (right) genes
can be expressed, rearrangements
of gene segments are needed to
produce exons encoding V regions
 Once this has been achieved, genes
are transcribed to give primary
transcripts containing both exons &
introns
 The latter are spliced out to
produce mRNAs that are translated
to give κ or λ light chains & μ heavy
chains that assemble inside the cell
& are expressed as membrane-
bound IgM at cell surface
 The main stages in the biosynthesis
of the heavy & light chains are
shown in the panel on the left.
Figure 4.37 Changes in the immunoglobulin genes that occur during a B cell’s lifetime

Summary slide of things that
can happen to
immunoglobulin genes and
consequences (basic summary
of last 3 classes)
ALSO A SCIENTIST

 Winifred Ashby, PhD (1879-1975)
 First researcher to establish the lifespan of red blood cells in humans
was longer than 2-3 weeks
 Using the principle of agglutination, Ashby was able to determine the
lifespan of transfused blood cells was 30+ days – Further research
determined the lifespan we now known as 110 days
 This process, which she used for her PhD dissertation, was coined the
Ashby Method, and was used for years in the treatment of chronic
anemia and revolutionized blood transfusions during WWII
 Her and her family emigrated from England to Chicago when she was 14,
earned her BS at University of Chicago, MS at Washington University of
St. Louis, and completed her doctorate in immunology and pathology at
the Mayo Foundation