Distribution of mutations around rearranged heavy-chain antibody variable-region genes

Multiple sequences from downstream of the J kappa cluster can combine to recruit somatic hypermutation to a heterologous, upstream mutation domain

Recruitment of somatic hypermutation to the Ig kappa locus has previously been shown to depend on the enhancer elements, Ei/MAR and E3'. Here we show that these elements are not sufficient to confer mutability. However, hypermutation is effectively targeted to a chimeric beta-globin/Ig kappa transgene whose 5' end is composed of the human beta-globin gene (promoter and first two exons) and whose 3' end consists of selected sequences derived from downstream of the J kappa cluster (Ei/MAR, C kappa + flank and E3'). Thus, multiple downstream Ig kappa sequences (all derived from 3' of the J kappa cluster) can combine to recruit mutation to a heterologous mutation domain. The location of this hypermutation domain is defined by the position of the transcription start site and this applies even if the Ig kappa Ei/MAR is positioned upstream of the promoter. Hotspots within the mutation domain are, however, defined by local DNA sequence as evidenced by a new hotspot being created within the beta-globin domain by a mutation within the transgene. We propose that multiple, moveable Ig kappa sequences (that are normally located downstream of the transcription start site) cooperate to bring a hypermutation priming factor to the transcription initiation complex; a mutation domain is thereby created downstream of the promoter but the local sequence defines the detailed pattern of mutation within that domain.

The 5' hypermutation boundary of kappa chains is independent of local and neighbouring sequences and related to the distance from the initiation of transcription

The hypermutation of antibody genes targets 1-2 kb of DNA which includes the rearranged V(D)J gene segments. The precise nature, location and limits of the targeted region are of considerable interest in terms of the mechanism of hypermutation. We have analyzed the frequency and distribution of mutations in the 5' region of immunoglobulins using several modified kappa transgenes. We found that the position of the boundary, relative to the transcription initiation site, is not affected by the sequence of the V segment or by substituting the kappa chain promoter for a beta-globin promoter. Furthermore, the deletion of the leader intron (containing the hypermutation boundary) does not affect hypermutation per se, but shifts the boundary from the leader intron to the V region such that the distance between the boundary and the site of initiation of transcription remains constant. These results show that the position of the hypermutation boundary (about 185 bases downstream of the site of initiation of transcription) is not defined by the nucleotide sequence but rather by the distance to a fixed upstream position. Although mutations are also observed in the region upstream of the boundary, the frequency at which they occur is one order of magnitude lower relative to the frequency observed in the V segment. Nonetheless this upstream mutation rate remains more than two orders of magnitude higher than that of somatic genes. We discuss possible mechanisms explaining the nature and position of the boundary in the context of an error-prone DNA repair model.

Molecular analysis of the immunoglobulin VH gene rearrangement in a primary cutaneous immunoblastic B-cell lymphoma by micromanipulation and single-cell PCR

The immunoglobulin VH gene rearrangement in a primary cutaneous, large-cell (centroblastic and immunoblastic) B-cell lymphoma was analyzed using a micromanipulation/single-cell polymerase chain reaction technique. In all single B cells obtained from CD20-stained skin sections that gave a polymerase chain reaction product (eight of 27 in biopsy I), the same VHDJH rearrangement, consisting of DP-54-DIR1-JH3a genes, was detected, with no intraclonal nucleotide diversity. Comparison with the most closely related germline counterpart showed significantly altered complementarity determining gene regions as a result of somatic mutations, suggesting an antigen-driven selection and expansion ofthis particular B-cell clone. Interestingly, in a biopsy obtained from the patient 9 mo later, during disease progression (deep muscle infiltration), the lymphoma cells again contained the same VHDJH gene rearrangement (six of 18 in biopsy II) without any further somatic mutations. Therefore, it is suggested that the cutaneous lymphoma characterized throughout this study descended from postgerminal center B-cells.

Mechanism of antigen-driven somatic hypermutation of rearranged immunoglobulin V(D)J genes in the mouse

Available data relevant to the mechanism of somatic hypermutation have been critically evaluated in the context of alternative models: (i) error-generating reverse transcription (RT) followed by homologous recombination; and (ii) error-prone DNA replication/repair. A set of basic principles concerning somatic hypermutation has also been formulated and a revised and expanded "RT-Mutatorsome" concept (analogous to telomerase) is presented which is consistent with these principles and all data on the distribution of somatic mutations in normal and Ig transgenic mice carrying particular V(D)J and flanking region constructs. It is predicted that in the mouse VH and Vk loci. the J-C intronic Enhancer-Nuclear Matrix Attachment Region (Ei/MAR) contains a unique sequence motif or secondary structure which ensures that only V(D)J sequences mutate whilst other regions of the genome are not mutated.

Differential V region mutation of two transfected Ig genes and their interaction in cultured B cell lines

We have established B cell culture systems in which transfected and stably integrated Ig constructs spontaneously undergo high rates of variable (V) region mutation. Mutation rates were determined using reversion analysis of an Ig V region nonsense codon (Vn). A construct (Vn/gamma2a) in which a Vn was associated with the gamma2a constant region and its intervening and immediate flanking sequences mutated at a high rate of 2.2 x 10(-4)/bp/generation in the NSO myeloma cell line. This same Vn, when associated with the mu constant region (Vn/mu), mutated at a 1000-fold lower rate in NSO. The Vn/gamma2a construct also mutated at high rates in the 18.81 pre-B and the S107 myeloma cell lines and at a low rate in the J558 myeloma cell line. In NSO, the presence of the gamma2a construct raised the mutation rate of the mu construct and the mu decreased the mutation rate of gamma2a. These results suggest that there is both positive and negative regulation of V region mutation and that different cell lines express different combinations and/or amounts of trans-acting factors that are involved in the mutational process.

Somatic hypermutation of immunoglobulin genes

The relationship between somatic hypermutation and affinity maturation in the mouse is delineated. Recent work on the anatomical and cellular site of this process is surveyed. The molecular characteristics of somatic hypermutation are described in terms of the region mutated and the distinctive patterns of nucleotide changes that are observed. The results of experiments utilizing transgenic mice to find out the minimum cis-acting sequences required to recruit hypermutation are summarized. The hypothesis that V gene sequences have evolved in order to target mutation to certain sites but not others is discussed. The use that different species make of somatic hypermutation to generate either the primary or secondary B cell repertoire is considered. Possible molecular mechanisms for the hypermutation process and future goals of research are outlined.

The specificity and orientation of a TCR to its peptide-MHC class II ligands

A T cell-mediated immune response is mainly determined by the 3-5 aa residues that protrude upwards from a peptide bound to an MHC molecule. Alterations of these peptide residues can diminish, eliminate or radically alter the signal that the T cell receives through its T cell receptor (TCR). We have used peptide immunizations of normal mice and mice carrying alpha or beta chain TCR transgenes to identify three distinct peptide contact points. One, near the carboxyl terminus of the peptide, involves the beta chain CDR3 region; the second was centrally located and interacted with both the alpha and beta chain CDR3 loops; the third was near the amino terminus of the peptide, and affected V alpha gene usage, but not the structure of CDR3 of either TCR chain. Based on these results, we propose an orientation for the TCR of this cloned line and argue for its generality.

The molecular basis of somatic hypermutation of immunoglobulin genes

Somatic hypermutation amplifies the variable region repertoire of immunoglobulin genes. Recent experimental evidence has thrown light on various molecular models of somatic hypermutation. A link between somatic hypermutation and transcription coupled DNA repair is shaping up.

The absence of ongoing immunoglobulin gene hypermutation suggests a distinct mechanism for c-myc mutation in endemic Burkitt's lymphoma

PURPOSE

Burkitt's lymphoma is a malignancy of mature, immunoglobulin (Ig)-bearing B cells characterized by translocation between c-myc and Ig gene loci. A role for the juxtaposed Ig genes in the mutation and deregulation of c-myc expression typical of endemic Burkitt's lymphoma (eBL) has been proposed, but never proven. Our objective was to determine whether Ig gene hypermutation is ongoing in eBL.

METHODS

We isolated Ig heavy-chain sequences from K962 eBL tumor cells using reverse transcription and polymerase chain reaction (PCR) amplification. The PCR product was ligated into Bluescript II vectors. Multiple subclones were sequenced and the variable regions were compared for evidence of ongoing Ig hypermutation.

RESULTS

Six total single base substitutions were observed within four of the nine subclones studied. Four substitutions resulted in amino acid changes and two were silent. There was no clustering of mutations in hypervariable regions, or a high incidence of amino acid replacement or link substitutions, all of which are characteristic of Ig hypermutation. The observed mutations occurred at a rate consistent with Taq polymerase error.

CONCLUSIONS

Our data indicate that in the eBL tumor sample K962, the mechanism underlying c-myc mutation is distinct from that which gives rise to Ig hypermutation.

Somatic hypermutation of immunoglobulin genes is linked to transcription initiation

To identify DNA sequences that target the somatic hypermutation process, the immunoglobulin gene promoter located upstream of the variable (V) region was duplicated upstream of the constant (C) region of a kappa transgene. Normally, kappa genes are somatically mutated only in the VJ region, but not in the C region. In B cell hybridomas from mice with this kappa transgene (P5'C), both the VJ region and the C region, but not the region between them, were mutated at similar frequencies, suggesting that the mutation mechanism is related to transcription. The downstream promoter was not occluded by transcripts from the upstream promoter. In fact, the levels of transcripts originating from the two promoters were similar, supporting a mutation model based on initiation of transcripts. Several "hot-spots" of somatic mutation were noted, further demonstrating that this transgene has the hallmarks of somatic mutation of endogenous immunoglobulin genes. A model linking somatic mutation to transcription-coupled DNA repair is proposed.

Chromatin domains and prediction of MAR sequences

Polynuceosomes are constrained into loops or domains and are insulated from the effects of chromatin structure and torsional strain from flanking domains by the cross-complexation of matrix-attached regions (MARs) and matrix proteins. MARs or SARs have an average size of 500 bp, are spaced about every 30 kb, and are control elements maintaining independent realms of gene activity. A fraction of MARs may cohabit with core origin replication (ORIs) and another fraction might cohabit with transcriptional enhancers. DNA replication, transcription, repair, splicing, and recombination seem to take place on the nuclear matrix. Classical AT-rich MARs have been proposed to anchor the core enhancers and core origins complexed with low abundancy transcription factors to the nuclear matrix via the cooperative binding to MARs of abundant classical matrix proteins (topoisomerase II, histone H1, lamins, SP120, ARBP, SATB1); this creates a unique nuclear microenvironment rich in regulatory proteins able to sustain transcription, replication, repair, and recombination. Theoretical searches and experimental data strongly support a model of activation of MARs and ORIs by transcription factors. A set of 21 characteristics are deduced or proposed for MAR/ORI sequences including their enrichment in inverted repeats, AT tracts, DNA unwinding elements, replication initiator protein sites, homooligonucleotide repeats (i.e., AAA, TTT, CCC), curved DNA, DNase I-hypersensitive sites, nucleosome-free stretches, polypurine stretches, and motifs with a potential for left-handed and triplex structures. We are establishing Banks of ORI and MAR sequences and have undertaken a large project of sequencing a large number of MARs in an effort to determine classes of DNA sequences in these regulatory elements and to understand their role at the origins of replication and transcriptional enhancers.

A human follicular lymphoma B cell line hypermutates its functional immunoglobulin genes in vitro

The functional immunoglobulin (Ig) genes of B lymphocytes undergo somatic mutations during immune responses. These mutations modify the antigen binding site of the immunoglobulins, thereby enhancing the average affinity of the antibodies produced. The molecular mechanism underlying these B cell hypermutations remains unresolved, partly because it is difficult to grow normal B cells in long-term cell cultures and because there is no suitable transformed or malignant B cell line which generates mutations in its immunoglobulin genes in vitro. Here, we show that the recently established follicular lymphoma line HF-1.3.4 generates somatic hypermutations in vitro at a high frequency of 0.7 x 10(-6) mutations per base pair per generation in standard cell cultures (RPMI 1640 + 5% fetal calf serum). This shows for the first time that B cell hypermutation can occur without T cells or T cell factors. The mutation frequency increased approximately tenfold to 1 x 10(-5) mutations/base pair/generation with B cell-specific growth factors (interleukins-2 and -4 and three antibodies stimulatory to HF-1.3.4 cells). This HF-1.3.4 lymphoma line may help to elucidate the molecular mechanism of Ig gene hypermutation.

Targeting of non-Ig sequences in place of the V segment by somatic hypermutation

Affinity maturation of antibodies is characterized by localized hypermutation of the DNA around the V segment. Here we show, using mice containing single or multiple transgene constructs, that an immunoglobulin V kappa segment can be replaced by human beta-globin or prokaryotic neo or gpt genes without affecting the rate of hypermutation; the V gene itself is not necessary for recruiting hypermutation. The ability to target hypermutation to heterologous genes in vivo could find more general applications in biology.

Somatic hypermutation

For the generation of secondary response antibodies, immunoglobulin genes are subjected to hypermutation. Cells expressing antibodies with higher affinity are then selected by antigen. Recent clues to the mechanism of hypermutation come from experiments using transgenic mice enabling analysis of the controlling cis-acting elements and the intrinsic features of the hypermutation, dissociated from the effects of antigenic selection.

A lambda 1 transgene under the control of a heavy chain promoter and enhancer does not undergo somatic hypermutation

To identify cis-acting elements responsible for targeting somatic hypermutation to immunoglobulin variable regions, we generated transgenic mice which carry a rearranged lambda 1 gene regulated by the heavy chain intron enhancer, E mu, and the heavy chain promoter PH186.2 from the VH186.2 variable region. C57BL/6 x SJL founders were bred with C57BL/6 mice to establish a line carrying a single copy of the transgene. Somatic hypermutation was studied by generating hybridoma cell lines from mice immunized with the hapten (4-hydroxy-3-nitrophenyl)acetyl (NP) coupled to chicken gamma globulin. The immune response in this transgenic line was dominated by the endogenous VH186.2 heavy chain variable region and the transgenic lambda 1 light chain, and the transgene was actively expressed in all hybridomas analyzed. In this work we show that the transgenic V lambda 1 regions do not undergo hypermutation, despite high levels of expression, while the expressed heavy chain V regions accumulate mutations at a rate typical of the NP response in C57BL/6 mice. Thus, within the same B cell, the PH186.2 promoter in connection with E mu drives efficient expression of both a VH and a V lambda region, but only the VH is a target for somatic hypermutation. Our observations show that cis-acting sequences that activate immunoglobulin gene transcription are not sufficient to target somatic hypermutation.

The 5' boundary of somatic hypermutation in a V kappa gene is in the leader intron

The maturation of the immune response involves the hypermutation of antibody genes and the selection of B cells expressing receptors with improved antigen binding properties. Somatic hypermutation of antibody genes is targeted to a small region approximately 1 kb surrounding the rearranged V gene. The precise definition of the 5' limit is not yet clear since the data base of somatic mutations upstream of the V region is very restricted. The available data suggest that it lies close to the promoter region and this has been used to implicate transcription in the mechanism leading to hypermutation. Here we present an extensive analysis of mutations in the 5' region of a single kappa light chain gene. A large data base from highly mutated sequences was obtained from anti-oxazolone hybridomas expressing the V kappa Ox1-J kappa 5 light chain and from polymerase chain reaction-derived clones from splenic and Peyer's patches of transgenic mice expressing the same V kappa Ox1-J kappa 5 gene combination. Although mutations were found in the 5'-flanking segment, the rate of mutation in the V-J segment was about 20-fold higher. A sharp decline between those two mutation rates is evident but the boundary was found in the leader intron of the V kappa Ox1 gene, about 150 bases downstream of the initiation of transcription site.

Elements regulating somatic hypermutation of an immunoglobulin kappa gene: critical role for the intron enhancer/matrix attachment region

Following encounter with antigen, the immunoglobulin genes in B lymphocytes undergo somatic hypermutation. Most nucleotide substitutions are introduced into a region flanked by the V gene promoter and intron enhancer. Experiments described here using transgenic mice revealed that the V kappa promoter does not contain specific signals since hypermutation was retained on substituting it by a beta-globin promoter. However, both the kappa intron and kappa 3' enhancer regions were found to be essential for full hypermutation. This dependence of hypermutation on both enhancers contrasts with transgene expression in hybridomas in which only the 3' enhancer (and not the intron enhancer) is necessary to achieve high mRNA levels. The results show that full hypermutation depends on multiple elements, removal of some of which may drastically impair but not totally abolish the process.

Mapping the upstream boundary of somatic mutations in rearranged immunoglobulin transgenes and endogenous genes

Mammalian B-cell specific somatic hypermutation contributes to affinity maturation of the antibody response. This mutator activity is highly focused on rearranged immunoglobulin variable regions, but the underlying mechanism remains to be elucidated. In an effort to gain insights into the mechanism of somatic hypermutation, the precise distribution and frequency of mutations upstream of murine immunoglobulin genes was determined by examining the same variable gene segments when mutated in different B-cell lines. Immunoglobulin sequences analysed included kappa light chain transgenes bearing mutated V kappa 24 variable regions, and the endogenous V kappa gene isolated from myeloma MOPC167, which also exhibits mutations in the variable region. In addition, mutated endogenous VH1 gene segments of the S107 heavy chain variable gene family were also examined. For both VH1 and V kappa 24, somatic mutations were generally not found upstream of the leader intron, even in genes which exhibited a high mutation frequency in the variable region itself. The 5' somatic mutation boundary identified in immunoglobulin transgenes overlaps the boundary observed in endogenous genes, suggesting that both share cis-elements required for defining the mutable domain. Furthermore, the location of this 5' boundary appears not to change when these immunoglobulin genes are examined in different cell lines. These data may be indicative of a defined start site for immunoglobulin mutator activity.

Generating the antibody repertoire in rabbit

We describe a model for B cell development and generation of the antibody repertoire in rabbits. In this model, B cells develop early in ontogeny, migrate to GALT, and undergo the first round of diversification by a somatic gene conversion-like process and by somatic mutation. We designate the repertoire developed by this mechanism as the primary antibody repertoire and it is this repertoire that makes the rabbit immunocompetent. We invoke GALT as the site for development of the primary repertoire because (1) surgical removal of GALT from neonatal rabbits results in highly immunocompromised animals, (2) in germfree rabbits essentially no lymphoid development occurs in GALT and the rabbits are immunoincompetent, and (3) the follicular development of rabbit GALT is highly similar to that of the chicken bursa, the site in which the primary antibody repertoire develops by somatic gene conversion in chicken. We suggest that once the primary antibody repertoire is formed, it is maintained by self-renewing CD5+ B cells and is expanded to a secondary antibody repertoire after the B cells encounter antigen.

Molecular characterization of human antibodies to bacterial antigens: utilization of the less frequently expressed VH2 and VH6 heavy chain variable region gene families

Structural analysis of the human immunoglobulin repertoire holds promise for determining the basis of variable region gene usage in response to a variety of auto and exogenous antigens. Here we report the nucleotide sequences of the heavy and light chain variable regions expressed by three human monoclonal antibodies specific for two clinically relevant bacterial pathogens, Bordetella pertussis and Haemophilus influenzae type b. The cell lines were derived by in vitro stimulation of lymphocytes from spleen or tonsillar tissue, respectively, and bind to different antigens from the two organisms. The single B. pertussis antibody is of the IgM lambda isotype and utilizes the single VH6 gene segment in combination with a V lambda 2 gene and demonstrates limited somatic mutation, yet is highly indicative of an antigen-driven immune response. One H. influenzae antibody is of the IgG2 lambda isotype and expresses a VH3 gene segment with a V lambda 1 gene, while the second cell line produces an IgG3 lambda antibody expressing a combination of VH2/V lambda 3. Both molecules show evidence of somatic mutation. The D gene segments of the heavy chains vary in length and display limited sequence homology with known germline D segments. As demonstrated previously, JH4 predominates (two JH4 and one JH3) and all three utilize the J lambda 3 gene segment. In addition, we have isolated and sequenced a number of germline VH2 gene segments in an attempt to better understand the nature of the VH2 germline repertoire. In addition to contributing to the understanding of the human antibody repertoire, such clinically relevant molecules may prove to be a source of passive immunotherapy for those at risk to developing disease.

Affinity maturation of lymphocyte receptors and positive selection of T cells in the thymus

In this review we have re-evaluated the dominant paradigm that TcR V genes do not somatically mutate. We highlight the many structural and functional similarities between Ig and TcR antigen-specific receptors on B and T cells. We have reviewed the factors influencing the somatic and germline evolution of IgV regions in B cells, have evaluated in detail various models which could be invoked to explain the pattern of variation in both transcribed and non-transcribed segments of germline IgV-gene DNA sequences, and applied this perspective to the TcR V beta and V alpha genes. Whilst specific TcRs recognize a complex of a short antigenic peptide bound to MHC Class I or II glycoprotein, and Ig receptors can recognize both oligopeptides and conformational determinants on undegraded polypeptides, they both employ heterodimer variable regions (Fabs) utilizing all three CDRs in epitope binding. We conclude that a plausible case can be made for the possibility that rearranged TcR V genes may undergo some type of somatic hypermutation process during T-cell development in the thymus (concurrent with or after the positive selection phase) thus allowing a repertoire of TvR alpha beta heterodimers to be both positively and negatively selected by the same set of ligands (self MHC + self peptide) in the thymus.

Variable region gene selection of immunoglobulin G-expressing B cells with specificity for a defined epitope on type II collagen

Immunization with type II collagen (CII) induces collagen-induced arthritis (CIA) in animals, and B cells reactive with CII are involved in the induction and manifestation of the disease. In this study, B cell hybridomas producing IgG antibodies specific for a major epitope on mouse CII (the "C1" epitope, amino acid 316-333), were isolated 11 days after immunization from draining lymph nodes in DBA/1 mice. Injection into neonatal mice of purified and biotinylated monoclonal antibodies binding the C1 epitope led to a specific binding to joint cartilage, demonstrating that the antibodies interact with native antigen in vivo. cDNA sequencing of the B cell clones revealed that they all expressed the same combination of a variable heavy chain (VH J558 family) and light chain (V kappa 21 family) germ-line gene, apparently lacking somatic mutations. The presence of isotype-switched B cells expressing a certain combination of V genes encoding antibodies that bind epitopes in vivo, indicates that this B cell population has been peripherally selected.

Somatic hypermutation in 5' flanking regions of heavy chain antibody variable regions

The aim of this study has been to determine the distribution of somatic mutations in the 5' flanking regions of rearranged immunoglobulin heavy chain variable region genes (VDJ). We sequenced the 5' flanking region in 12 secondary immune response antibodies produced in C57BL/6j mice against the hapten (4-hydroxy-3-nitrophenyl)acetyl (NP) coupled to chicken-gamma-globulin. In these and previously published sequences, almost 97% of the mutations occurred in the transcribed region of the gene, and only a minority of genes (5/29) contained mutations upstream of the transcription start (cap) site. No potential germ-line donor was found for a cluster of five base changes previously found in a single heavy chain gene, 3B62. However, the uniqueness of this mutational cluster and its distance from the normally mutated region suggests that the nucleotide changes may not be due to the normal mutator mechanism. Thus, as this was the only instance of somatic mutations that far upstream of the promoter/cap site region, the reverse transcriptase model for somatic hypermutation is still a possibility. The data are consistent with a mutational mechanism that requires transcription of the rearranged target V(D)J gene which appears to result in the generation of a positively skewed asymmetrical distribution of somatic mutations. A single mode is centered near the V(D)J and a long tail extends into the 3' non-translated region of the J-C intron. Two classes of model could explain this mutation distribution pattern: those where transcription products (RNA, cDNA) are the direct mutational substrates, or those that postulate local unfolding of the chromatin around a V(D)J rearrangement directly exposing the DNA of the transcribed region to specific mutational enzymes.

Discriminating intrinsic and antigen-selected mutational hotspots in immunoglobulin V genes

Studies of the antibody hypermutation mechanism have revealed that it is not a random process but exhibits characteristic nucleotide substitution preferences. Here, Alexander Betz and colleagues show that these innate nucleotide substitution preferences can be used to examine databases of antigen-selected V gene sequences and thereby distinguish intrinsic from antigen-selected hotspots. This analysis reveals intrinsic mutational hotspots in both VH and VL genes, reflecting innate features of the hypermutation machinery which may give clues to the enzymatic mechanism.

Hypermutation of the MYC gene in diffuse large cell lymphomas with translocations involving band 8q24

The sequence of the exon 1/intron 1 boundary region of the MYC gene was determined in two diffuse large cell lymphomas (DLCL), one with t(8;14) (q24;q32) and the other with t(8;22) (q24;q11). Both tumors had multiple mutations in this region. Also, both tumors had mutations in the protein binding site in intron 1, which is a frequent target for mutational inactivation in endemic Burkitt's lymphoma (eBL). The translocations at 8q24, and multiple mutations in the exon 1/intron 1 boundary region, are reminiscent of similar findings in eBL. The same underlying oncogenic event that occurs in most eBLs is thus found in some DLCLs.

Somatic point mutations in the translocated bcl-2 genes of non-Hodgkin's lymphomas and lymphocytic leukemias: implications for mechanisms of tumor progression

The t[14;18] chromosomal translocation is the most common cytogenetic abnormality found in hematolymphoid malignancies. The t[14;18] fuses the bcl-2 gene at 18q21 with the immunoglobulin heavy-chain locus at 14q32, resulting in deregulated expression of bcl-2 and production of high levels of its encoded 26-kD protein in the majority of non-Hodgkin lymphomas. Recent data indicate that somatic point mutations frequently occur in translocated bcl-2 alleles, possibly because of the somatic hypermutation mechanism that is associated with the immunoglobulin gene loci and that normally contributes to antibody diversity. In some cases, these mutations can affect the open reading frame of the bcl-2 gene and thereby alter Bcl-2 proteins. Here, we review the currently available data about the incidence, biological effects, and possible clinical importance of somatic mutations within the translocated bcl-2 genes of human lymphomas and leukemias.

Origin and maintenance of germ-line V genes

The distribution of nucleotide variability within the upstream of germ-line VH186.2-related variable genes was studied. The data in this report of work in progress indicate non-random selection for variability in the second antigen-contact or complementarity-determining region (CDR2) for 12 such genes isolated using the polymerase chain reaction (PCR) technique from genomic C57BL/6 mouse liver DNA. The translated protein sequences of these and three additional previously published genes also display a pronounced Wu-Kabat peak of amino acid variability in CDR2. In the CDR1 and CDR2 regions of this set of related germ-line genes, there are few [corrected] silent nucleotide changes, and most amino acid replacements (or non-synonymous changes) are non-conservative. In contrast, there is selection against amino acid replacement in the framework regions (FW), as indicated by the significant number of silent (or synonymous) mutational changes from the VH186.2 reference sequence. This is surprisingly similar to the Wu-Kabat variability patterns observed in somatically mutated immune response antibodies. These data could imply similar diversification mechanisms acting on B cell-expressed V genes in the soma (i.e. in a germinal centre) and in the germ-line DNA of male and/or female germ cells. While always possible, we consider this unlikely. Similarly, we consider as unlikely an explanation based on a classical Darwinian model involving simple stepwise whole animal selection prior to reproduction for each VH and VL gene now phylogenetically stored in the V segment arrays of the genomic DNA.(ABSTRACT TRUNCATED AT 250 WORDS)

c-myc hypermutation in Burkitt's lymphoma

Translocation between the c-myc protooncogene and one of the three immunoglobulin loci is a cytogenetic hallmark of the B cell tumor, Burkitt's lymphoma. The resulting deregulation of c-myc expression is a critical step in tumorigenesis. The translocation breakpoint may lie within c-myc proper, in which case deregulation is due, in part, to dissociation of key 5' regulatory sequences from the protein-coding portions of the gene. Alternatively, the breakpoint may flank c-myc, leaving the gene grossly intact. In these latter cases, mutation, which may be extensive, is usually seen within c-myc, specifically at or near the same key regulatory sequences. The precise contribution of these mutations to c-myc deregulation is gradually being clarified. The mechanisms underlying c-myc mutations are not known. Hypermutation in c-myc may reflect the influence of the juxtaposed immunoglobulin gene, which is subject to hypermutation during an intermediate stage of normal B lymphoid development. This relationship, however, has not been firmly established.

Somatic hypermutagenesis in immunoglobulin genes. II. Influence of neighbouring base sequences on mutagenesis

A new approach for the analysis of hotspots of mutations is described. It is based on the classification of hotspot site sequences. Using this approach, the consensuses RGYW and TAA of hotspot sites were revealed in the V gene. Correlation between somatic mutations and these consensuses is investigated by the statistical weight method in 323 somatic substitutions in 14 V genes. Assuming the absence of any correlation, the probability of observing such data in the sample would be very low (0.0003). These results support the idea that emergence of somatic mutation is significantly influenced by neighbouring base sequences. This idea was also supported by the analysis of 296 somatic mutations in flanking sequences of V genes. It is supposed that this influence is an important feature of somatic hypermutagenesis.

Germ line variable regions that match hypermutated sequences in genes encoding murine anti-hapten antibodies

We asked whether there are germ line immunoglobulin variable (V) segments that match sites of hypermutation in V regions encoding murine antibodies. Murine germ line DNA was probed with a panel of short deoxyoligonucleotides identical in sequence to segments of hypermutated V regions from hybridomas generated in the BALB/c response to the hapten 2-phenyloxazolone (Ox). Germ line sequences that match mutations in both heavy and kappa light chain V regions were identified, and clones of some of these germ line V segments were obtained. Comparison of these clones with hypermutated V regions revealed regions of identity ranging in size from 7 to over 50 nucleotides. In an effort to separate the effects of antigen selection from the mutagenic process, we also searched for matches to a panel of silent mutations in VH regions from germinal center B cells. Fourteen silent mutations occur among a collection of 36 hypermutated VH regions from two separate germinal centers of C57BL/6 mice stimulated with the hapten 4-hydroxy-3-nitrophenyl. Matches to nine of these silent mutations can be found among published sequences of C57BL/6 VH regions of the J558 family. Taken together, these data are consistent with the possibility that a template-dependent mutational process, like gene conversion, may contribute to somatic hypermutation.

A shuttle vector system for the investigation of immunoglobulin gene hypermutation: absence of enhanced mutability in intermediate B cell lines

Somatic hypermutation focused to the rearranged V(D)J segment of the immunoglobulin (Ig) loci contributes substantially to antibody gene diversification. However, neither the precise B cell subset subject to hypermutation nor the molecular mechanism(s) involved is known. One model proposes that Ig segments may be uniquely susceptible to DNA nicking and subsequent error-prone repair during a specific B cell developmental stage. We describe an SV40-based shuttle vector system for testing such a model. Plasmids containing two distinct Ig segments juxtaposed to the supF marker gene have been passaged through cell lines representing intermediate stages of B cell development, rescued and screened for marker gene mutations. To date we have not demonstrated enhanced supF mutation in any cell line examined, irrespective of the adjacent Ig segment. Thus, these cell lines exhibit normal DNA repair mechanisms and no evidence of increased endonuclease activity on the Ig segments tested. The feasibility of this system will allow similar experiments using other Ig target sequences exposed to a broader range of B cells.