The intrinsic hypermutability of antibody heavy and light chain genes decays exponentially

Somatic hypermutation, essential for the affinity maturation of antibodies, is restricted to a small segment of DNA. The upstream boundary is sharp and is probably related to transcription initiation. However, for reasons unknown, the hypermutation domain does not encompass the whole transcription unit, notably the C‐region exon. Since analysis of the downstream decay of hypermutation is obscured by sequence‐dependent hot and cold spots, we describe a strategy to minimize these fluctuations by computing mutations of different sequences located at similar distances from the promoter. We pool large databases of mutated heavy and light chains and analyse the decay of mutation frequencies. We define an intrinsic decay of probability of mutation that is remarkably similar for heavy and light chains, faster than anticipated and consistent with an exponential fit. Indeed, quite apart from hot spots, the intrinsic probability of mutation at CDR1 can be almost twice that of CDR3. The analysis has mechanistic implications for current and future models of hypermutation.

[1]  R. S. Harris,et al.  Somatic hypermutation and the three R's: repair, replication and recombination. , 1999, Mutation research.

[2]  J. Bonfield,et al.  A new DNA sequence assembly program. , 1995, Nucleic acids research.

[3]  C. Milstein,et al.  The 5′ hypermutation boundary of x chains is independent of local and neighbouring sequences and related to the distance from the initiation of transcription , 1997, European journal of immunology.

[4]  Danny Reinberg,et al.  RNA polymerase II elongation through chromatin , 2000, Nature.

[5]  B. Rogerson Mapping the upstream boundary of somatic mutations in rearranged immunoglobulin transgenes and endogenous genes. , 1994, Molecular immunology.

[6]  P. Gearhart,et al.  Boundaries of somatic mutation in rearranged immunoglobulin genes: 5' boundary is near the promoter, and 3' boundary is approximately 1 kb from V(D)J gene , 1990, The Journal of experimental medicine.

[7]  K. Rajewsky,et al.  Somatic hypermutation in the heavy chain locus correlates with transcription. , 1998, Immunity.

[8]  T. Manser,et al.  The Transcriptional Promoter Regulates Hypermutation of the Antibody Heavy Chain Locus , 1997, The Journal of experimental medicine.

[9]  R. Staden,et al.  Both DNA strands of antibody genes are hypermutation targets. , 1998, Proceedings of the National Academy of Sciences of the United States of America.

[10]  C. Milstein,et al.  The 5′ boundary of somatic hypermutation in a Vχ gene is in the leader intron , 1994 .

[11]  C. Milstein,et al.  Modifying the sequence of an immunoglobulin V-gene alters the resulting pattern of hypermutation. , 1996, Proceedings of the National Academy of Sciences of the United States of America.

[12]  U. Storb,et al.  The molecular basis of somatic hypermutation of immunoglobulin genes. , 1996, Current opinion in immunology.

[13]  J. Pollard,et al.  Distribution of mutations around rearranged heavy-chain antibody variable-region genes , 1990, Molecular and cellular biology.

[14]  U. Storb,et al.  Somatic hypermutation of immunoglobulin genes is linked to transcription initiation. , 1996, Immunity.

[15]  C. Milstein,et al.  Targeting of non-Ig sequences in place of the V segment by somatic hypermutation. , 1995, Nature.

[16]  P. Casali,et al.  The CDR1 sequences of a major proportion of human germline Ig VH genes are inherently susceptible to amino acid replacement. , 1994, Immunology today.

[17]  C. Milstein,et al.  Hot spot focusing of somatic hypermutation in MSH2-deficient mice suggests two stages of mutational targeting. , 1998, Immunity.

[18]  M. Neuberger,et al.  TdT-accessible breaks are scattered over the immunoglobulin V domain in a constitutively hypermutating B cell line. , 1998, Immunity.

[19]  C. Milstein,et al.  Elements regulating somatic hypermutation of an immunoglobulin κ gene: Critical role for the intron enhancer/matrix attachment region , 1994, Cell.

[20]  M. Wabl,et al.  Mismatch repair co-opted by hypermutation. , 1998, Science.

[21]  Transcription, beta-like DNA polymerases and hypermutation. , 2001, Philosophical transactions of the Royal Society of London. Series B, Biological sciences.

[22]  N. Motoyama,et al.  Somatic mutation in constant regions of mouse lambda 1 light chains. , 1991, Proceedings of the National Academy of Sciences of the United States of America.

[23]  C. Milstein,et al.  Somatic hypermutation of immunoglobulin kappa may depend on sequences 3′ of C kappa and occurs on passenger transgenes. , 1991, The EMBO journal.

[24]  C. Milstein,et al.  Analysis of somatic hypermutation in mouse Peyer's patches using immunoglobulin kappa light-chain transgenes. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[25]  A. Bothwell,et al.  Somatic hypermutation in 5′ flanking regions of heavy chain antibody variable regions , 1993, European journal of immunology.

[26]  J. Weill,et al.  Rearrangement/hypermutation/gene conversion: when, where and why? , 1996, Immunology today.

[27]  T. Manser,et al.  Position of the rearranged V kappa and its 5' flanking sequences determines the location of somatic mutations in the J kappa locus. , 1991, Journal of immunology.

[28]  R. Brezinschek,et al.  Analysis of the frequency and pattern of somatic mutations within nonproductively rearranged human variable heavy chain genes. , 1997, Journal of immunology.

[29]  Aaron J. Shatkin,et al.  The ends of the affair: Capping and polyadenylation , 2000, Nature Structural Biology.

[30]  M. Neuberger,et al.  Rapid methods for the analysis of immunoglobulin gene hypermutation: application to transgenic and gene targeted mice. , 1997, Nucleic acids research.

[31]  C. Milstein,et al.  Targeting of non-lg sequences in place of the V segment by somatic hyper mutation , 1995, Nature.

[32]  A. Kornblihtt,et al.  Coupling of transcription with alternative splicing: RNA pol II promoters modulate SF2/ASF and 9G8 effects on an exonic splicing enhancer. , 1999, Molecular cell.

[33]  C. Milstein,et al.  Passenger transgenes reveal intrinsic specificity of the antibody hypermutation mechanism: clustering, polarity, and specific hot spots. , 1993, Proceedings of the National Academy of Sciences of the United States of America.

[34]  C. Milstein,et al.  Codon bias targets mutation , 1995, Nature.

[35]  P. Gearhart,et al.  The role of promoter-intron interactions in directing hypermutation. , 1998, Current topics in microbiology and immunology.

[36]  D. Schatz,et al.  Cell-cycle-regulated DNA double-strand breaks in somatic hypermutation of immunoglobulin genes , 2000, Nature.

[37]  C. Milstein,et al.  Somatic mutation of immunoglobulin lambda chains: a segment of the major intron hypermutates as much as the complementarity-determining regions. , 1994, Proceedings of the National Academy of Sciences of the United States of America.

[38]  E. Steele,et al.  Mechanism of antigen‐driven somatic hypermutation of rearranged immunoglobulin V(D)J genes in the mouse , 1997, Immunology and cell biology.

[39]  T. Honjo,et al.  Class Switch Recombination and Hypermutation Require Activation-Induced Cytidine Deaminase (AID), a Potential RNA Editing Enzyme , 2000, Cell.

[40]  S. Brenner,et al.  Origin of Antibody Variation , 1966, Nature.

[41]  Thomas B. Kepler,et al.  Enhanced Evolvability in Immunoglobulin V Genes Under Somatic Hypermutation , 1999, Journal of Molecular Evolution.

[42]  F. Delbos,et al.  Transcription, β–like DNA polymerases and hypermutation , 2001 .

[43]  C. Milstein,et al.  Cells strongly expressing Igκ transgenes show clonal recruitment of hypermutation: a role for both MAR and the enhancers , 1997, The EMBO journal.

[44]  M. Diaz,et al.  Evolution of somatic hypermutation and gene conversion in adaptive immunity , 1998, Immunological reviews.

[45]  C. Milstein,et al.  The 5' boundary of somatic hypermutation in a V kappa gene is in the leader intron. , 1994, European journal of immunology.

[46]  K. Rajewsky,et al.  DNA double-strand breaks in immunoglobulin genes undergoing somatic hypermutation. , 2000, Immunity.

[47]  C. Milstein,et al.  Maturation of the immune response. , 1996, Advances in protein chemistry.

[48]  Arthur Kar Keung Ching,et al.  Strand Breaks in Immunoglobulin Gene Hypermutation a , 1997, Annals of the New York Academy of Sciences.

[49]  J. Weitzman,et al.  Somatic hypermutation , 2020, Genome Biology.

[50]  T. Kunkel,et al.  DNA polymerase fidelity and the polymerase chain reaction. , 1991, PCR methods and applications.