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Lecture 6 Antibody genes II

Lecture 6 Antibody genes II. Mechanism of class switching Regulation of class switching Somatic mutation T cell dependent antibody response Affinity maturation T independent antibody responses. Review session Saturday Jan 22 4:00-6:50PM YORK 2722. Next time: Mid term test.

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Lecture 6 Antibody genes II

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  1. Lecture 6 Antibody genes II • Mechanism of class switching • Regulation of class switching • Somatic mutation • T cell dependent antibody response • Affinity maturation • T independent antibody responses Review session Saturday Jan 22 4:00-6:50PM YORK 2722 Next time: Mid term test

  2. The qualities of T cell dependent antibodies change with time Low affinity IgM class High affinity IgG class IgM

  3. VDJ joining here creates heavy chain variable region domain “Switching” to these classes requires DNA recombination and is distinct from V(D)J recombination. V D Note: there are exons encoding the membrane and secreted forms of each of the antibody heavy chains.

  4. Antibody gene One exon is assembled from separate pieces by DNA rearrangement in immature lymphocytes DNA V Naïve B cell IgM, IgD DNA Antigen stimulated B cell C heavy DNA *** ** On the antibody H chain, other exons are swapped in by a DNA rearrangement process distinct from V(D)J recombination Point mutations are introduced

  5. Heavy chain switch changes effector function, not specificity

  6. Sm Sa VDJ Ca Cm • Joining can occur anywhere within the large, repetitive • S-regions. There is no obvious conserved sequence motif. • Unlike V(D)J recombination, this gene splicing occurs • between, rather than within, coding sequences. • Like V(D)J recombination, targeting of elements for • rearrangement is correlated with prior “sterile transcription”

  7. B-cells can change their immunoglobulin class by DNA recombination. This is a distinct process from V(D)J recombination! (from CD4 T cells) +IL4 and CD40L

  8. Like V(D)J recombination, class switch recombination is regulated by 1) expression of a recombination machine 2) targeted “accessibility” mediated by nearby enhancers and promoters

  9. Figure 7-14

  10. Ig isotype class switching

  11. Concepts in class switching • Switching to H chain classes IgG, IgA, and IgE involves irreversible DNA recombination. • During this process the H chain variable region retains the same antigen specificity. • Recombination occurs within S (switch) regions, which are several kilobases in length and highly repetitive (i.e, nothing like the recognition sequences for V(D)J recombination). • Recombination is targeted by DNA "accessibility" that is controlled by sterile transcription starting at the I-region. • I region transcription is regulated by short and long range cytokines provided mainly by T cells. • The specificity of the cytokines determines the H-chain class to be used, and hence, the effector function.

  12. Somatic mutation adds to diversity (specificity) Accumulation of V-region point mutations during the antibody response. Mutations that improve affinity for antigen are selected in a quasi-Darwinian process during the immune response.

  13. Somatic mutations are focussed on the variable region exon Enhancer elements Promoter Different cells carrying the same V gene were compared for sequence changes From Gearhart and Bogenhagen PNAS 80:3439, 1983

  14. Patricia J. Gearhart and Richard D. Wood

  15. Clues from the pattern of somatic mutation Strand bias, transitions>transversions, bias vs pyrimidines (as assessed on coding strand). From Betz et al, PNAS 90:2385.

  16. Honjo's bombshell: Knocking out a single gene blocks both somatic mutation and class switching • A gene specifically expressed in activated B cells undergoing class switching was knocked out. • Mutant has hyper IgM syndrome. • IgM is only antibody class present in blood. • After immunization antibody V-regions have no sign of somatic mutation.

  17. Activation Induced cytidine Deaminase (AID) Mutant mouse has no hypermutation or H-chain class switch Homologous to RNA editase, but can deaminate DNA

  18. Transcription creates transient single stranded DNA which is the substrate of AID

  19. Model to explain how AID-induced mutations do not cause just C-to-T changes. Neuberger et al 2003

  20. Mismatch repair in eukaryotes Msh2,6 +/- linked to hereditary non-polyposis colon cancer (HNPCC) Martin and Scharff Nat. Rev. 2:605 (2002)

  21. -If mutations are routinely removed from replicating DNA, a process that prevents repair locally would target mutation. If so, knockouts of DNA repair genes would have little or no effect. -If mutations are introduced by massive local DNA damage, possibly needed to overwhelm the normal repair mechanisms, then repair mutants would have increased mutation rates in the targeted regions (near assembled VDJs). -Alternatively, DNA repair enzymes may be needed to generate mutations.

  22. While mutations in DNA mismatch repair lead to an overall increase in point mutations in the genome, they suppress V-region point mutation suggesting that the mismatch repair pathway is actively used during somatic mutation. ,i

  23. Mismatches can intitiate "patch" repair that introduces further point mutations by using error-prone DNA polymerases DNA polymerases These three error prone DNA polymerases have been implicated in V-region somatic mutation

  24. AID generates a lesion which is processed in different ways by DNA repair enzymes and cofactors for hypermutation and class switch. AID AID AID H-chain switch Point mutation Honjo et al 2004

  25. Somatic Mutation Concepts • Surprisingly, the diversity generated by V(D)J recombination is insufficient, and is supplemented by somatic point mutation! • Somatic mutation is induced upon antigen activation among mature B cells. • CD4 T cell help is required. • Mutation is localized to antibody V region. • Mutation is initiated by AID at cytidines by deamination (C>U); other repair enzymes extend the mutation. • In class switching, AID appears to generate staggered nicks in S-regions, leading to the recruitment of the non-homologous end joining enzymes (only this part of the mechanism is reminiscent of V(D)J recombination).

  26. Chickens make a single, invariant antibody by V(D)J recombination. This antibody is then massively mutated by the process of gene conversion, in which patches of 15-20 bp from nearby pseudoV genes are substituted. This process also requires AID, but is processed by a different constellation of repair enzymes that point mutation or class switch. Fig 4.6 (left)

  27. Risks and benefits of DNA manipulation by the immune system • Generation of diversity • -RAG1/2 DNA breaks, hairpins • -Terminal nucleotidyl transferase untemplated nucleotide additions • -AID point mutations, error prone repair, DNA breaks • Drawback: These processes probably contribute to cancer • Many (lymphoid) tumors involve somatic mutation and translocation associated with antigen receptor genes

  28. Cell:cell interactions in a T cell dependent antibody response Antigen-specific B cell takes up antigen and presents peptide to antigen-specific T cell. How do rare antigen-reactive B and T cells find each other? Signal 1: Antigen crosslinks sIg, leading to activation Signal 2 T cell help through CD40-ligand and cytokines

  29. Antigen specific B cells move after signal 1 to the T cell zone This interaction leads to proliferation of B cells near the B:T zone border

  30. Germinal centers are prominent in lymph nodes and spleen • They are mainly composed of activated B cells interacting with antigen-specific T cells and follicular dendritic cells • Class switch and somatic mutation occur here B T

  31. Figure 7-9 part 1 of 2

  32. Figure 7-10

  33. Figure 7-11 part 1 of 2

  34. B cell survival and proliferation in the germinal center is highly antigen- dependent. • Cells that mutate to lower affinity die of programmed cell death. • Higher affinity cells have a competitive advantage.

  35. Figure 4-17

  36. T dependent responses generate class switched plasma cells sIg+ memory B cells

  37. Figure 7-6 Many vital antibody responses do not require T cells. But these have limited memory, somatic mutation, and class switching.

  38. Figure 4-12 Fetal derived B-1 type B cells appear to be restricted to T-independent antibody responses

  39. Figure 4-19 B cell tumors mimic their normal counterparts and carry irreversible DNA modifications that aid diagnosis.

  40. Monoclonal antibody gene rearrangements can be detected in tumors by Southern blotting.

  41. Common translocation between Ig and an oncogene in Burkitt's lymphoma.

  42. Modern drug research and development (duration ~10 years): • random screening of millions of compounds in bioassay • to find initial candidates • refining candidates based on minor substitutions and selection • for improved affinity and specificity • toxicity and efficacy trials • The antibody response (duration ~14 days): • select a few thousand (or fewer) cells among millions of B cells • point mutate and select to develop highest affinities* • *Important for recognition of microbes that mutate rapidly • class switch to appropriate effector class End result: a long lived, high affinity antibody in circulation Antibody molecules now behave like preexisting innate immune molecules, allowing an instantaneous response to the specific microbe. Note: a high affinity antibody is effective at lower dose, increasing the lifespan of memory

  43. Summary of lecture 6 • Molecular mechanisms of class switching and somatic hypermutation. AID and DNA repair enzymes. • Mismatch repair system is involved in point mutation. • Double strand break repair is involved in class switch. • CD4 T cells are important for class switch regulation and the initiation of somatic mutation. • The T cell dependent antibody response requires cell migration to bring T and B cells together. • Somatic mutation happens in the germinal center. • Selection in the germinal center favors high affinity cells. • Plasma cells and memory B cells are formed during the T dependent antibody response. Review session Saturday Jan 22 4:00-6:50PM YORK 2722 Next time: Mid term test

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