Reciprocal homologous recombination in or near antibody VDJ genes

Somatic translocation and differential expression of Ig mu transgene copies implicate a role for the Igh locus in memory B cell development

Memory B cells of mice with Ig mu transgenes often carry transgene copies that have moved into the Igh locus via somatic translocation. This phenomenon has been attributed to a selection pressure for somatic hypermutations, which generally are observed at much higher frequencies in translocated copies than in ectopic copies. We tested this idea by immunizing Ig-mu transgenic mice in a manner designed to select B cells that required only one V(H) mutation for a switch in antigenic specificity and recruitment into the memory pool. Despite the minimal mutation requirement, hybridomas carrying somatic translocations to the Igh locus were obtained. Importantly, this occurred despite the fact that translocated and untranslocated mu-transgenes were mutated comparably. Evidently, a strong selection advantage was conferred upon B cells by the somatic translocations. Among the hybridomas, translocated mu-transgenes were active, while ectopic mu-transgenes were uniformly silent. The translocated copy that had conferred an affinity-based selection advantage was expressed at the highest level. Moreover, translocated copies were differentially expressed among hybridoma members, which belonged to a common post-mutational lineage. This suggests that adjustments in transgene expression levels had occurred during memory cell development. These results indicate that, apart from their potential influences on somatic hypermutagenesis and class switch recombination, elements in the Igh locus promote the selection of memory B cells in another way, possibly by regulating the level of Ig expression at various stages of antigen-driven differentiation.

Gene conversion-like sequence transfers between transgenic antibody V genes are independent of RAD54

Homology-based Ig gene conversion is a major mechanism for Ab diversification in chickens and the Rad54 DNA repair protein plays an important role in this process. In mice, although gene conversion appears to be rare among endogenous Ig genes, Ab H chain transgenes undergo isotype switching and gene conversion-like sequence transfer processes that also appear to involve homologous recombination or gene conversion. Furthermore, homology-based DNA repair has been suggested to be important for somatic mutation of endogenous mouse Ig genes. To assess the role of Rad54 in these mouse B cell processes, we have analyzed H chain transgene isotype switching, sequence transfer, and somatic hypermutation in mice that lack RAD54. We find that Rad54 is not required for either transgene switching or transgene hypermutation. Furthermore, even transgene sequence transfers that are known to require homology-based recombinations are Rad54 independent. These results indicate that mouse B cells must use factors for promoting homologous recombination that are distinct from the Rad54 proteins important in homology-based chicken Ab gene recombinations. Our findings also suggest that mouse H chain transgene sequence transfers might be more closely related to an error-prone homology-based somatic hypermutational mechanism than to the hyperconversion mechanism that operates in chicken B cells.

The reverse transcriptase model of somatic hypermutation

The evidence supporting the reverse transcriptase model of somatic hypermutation is critically reviewed. The model provides a coherent explanation for many apparently unrelated findings. We also show that the somatic hypermutation pattern in the human BCL-6 gene can be interpreted in terms of the reverse transcriptase model and the notion of feedback of somatically mutated sequences to the germline over evolutionary time.

Trans-chromosomal recombination within the Ig heavy chain switch region in B lymphocytes

Somatic DNA rearrangements in B lymphocytes, including V(D)J gene rearrangements and isotype switching, generally occur in cis, i. e., intrachromosomally. We showed previously, however, that 3 to 7% of IgA heavy chains have the VH and Calpha regions encoded in trans. To determine whether the trans-association of VH and Calpha occurred by trans-chromosomal recombination, by trans-splicing, or by trans-chromosomal gene conversion, we generated and analyzed eight IgA-secreting rabbit hybridomas with trans-associated VH and Calpha heavy chains. By ELISA and by nucleotide sequence analysis we found that the VH and Calpha regions were encoded by genes that were in trans in the germline. We cloned the rearranged VDJ-Calpha gene from a fosmid library of one hybridoma and found that the expressed VH and Calpha genes were juxtaposed. Moreover, the juxtaposed VH and Calpha genes originated from different IgH alleles. From the same hybridoma, we also identified a fosmid clone with the other expected product of a trans-chromosomal recombination. The recombination breakpoint occurred within the Smicro/Salpha region, indicating that the trans-association of VH and Calpha genes occurred by trans-chromosomal recombination during isotype switching. We conclude that trans-chromosomal recombination occurs at an unexpectedly high frequency (7%) within the IgH locus of B lymphocytes in normal animals, which may explain the high incidence of B-cell tumors that arise from oncogene translocation into the IgH locus.

A unifying hypothesis for the molecular mechanism of somatic mutation and gene conversion in rearranged immunoglobulin variable genes

We have reviewed available data concerning the mechanism of somatic hypermutation in rearranged variable genes of Ig in B lymphocytes of mice and the gene conversion process which generates diversity in these genes in the B lymphocytes of chickens. In our view, these data are consistent with a unifying hypothesis of diversity generating mechanisms involving reverse transcription to produce cDNA from RNA transcripts followed by homologous recombination into chromosomal DNA. Thus, seemingly different processes in the mouse and chicken may have a common molecular basis.

The signature of somatic hypermutation appears to be written into the germline IgV segment repertoire

We present here a unifying hypothesis for the molecular mechanism of somatic hypermutation and somatic gene conversion in IgV genes involving reverse transcription using RNA templates from the V-gene loci to produce cDNA which undergoes homologous recombination with chromosomal V(D)J DNA. Experimental evidence produced over the last 20 years is essentially consistent with this hypothesis. We also review evidence suggesting that somatically generated IgV sequences from B lymphocytes have been fed back to germline DNA over evolutionary time.

Dual enigma of somatic hypermutation of immunoglobulin variable genes: targeting and mechanism

The immunoglobulin loci are uniquely unstable regions of the genome which undergo as much mutation and selection in a matter of days as a species can undergo in generations of evolution. We have studied the mutational pattern and targeting of this unusual hypermutation process over the past 16 years. The pattern of somatic mutations in rearranged variable (V) genes differs from the pattern of meiotic mutations, indicating that a different mechanism generates hypermutation than generates spontaneous mutation. Hypermutations begin on the 5' end of rearranged V genes downstream of the transcription initiation site and continue through the V exon and into the 3'-flanking region before tapering off. Mutations are located randomly throughout the DNA sequence and exhibit strand bias. The targeting of mutations to the region in and around the rearranged V gene appears to require interactions between the promoter and downstream intronic DNA sequences. The same mechanism that initiates hypermutation around V genes may also produce double-strand breaks that catalyze homologous recombination between rearranged V genes on two chromosomal alleles. With this data we have built a model of hypermutation which predicts that V-region DNA is destabilized at the nuclear matrix during transcription and undergoes strand breaks.

Somatic hypermutation introduces insertions and deletions into immunoglobulin V genes

During a germinal center reaction, random mutations are introduced into immunoglobulin V genes to increase the affinity of antibody molecules and to further diversify the B cell repertoire. Antigen-directed selection of B cell clones that generate high affinity surface Ig results in the affinity maturation of the antibody response. The mutations of Ig genes are typically basepair substitutions, although DNA insertions and deletions have been reported to occur at a low frequency. In this study, we describe five insertion and four deletion events in otherwise somatically mutated VH gene cDNA molecules. Two of these insertions and all four deletions were obtained through the sequencing of 395 cDNA clones (approximately 110,000 nucleotides) from CD38+IgD- germinal center, and CD38-IgD- memory B cell populations from a single human tonsil. No germline genes that could have encoded these six cDNA clones were found after an extensive characterization of the genomic VH4 repertoire of the tonsil donor. These six insertions or deletions and three additional insertion events isolated from other sources occurred as triplets or multiples thereof, leaving the transcripts in frame. Additionally, 8 of 9 of these events occurred in the CDR1 or CDR2, following a pattern consistent with selection, and making it unlikely that these events were artifacts of the experimental system. The lack of similar instances in unmutated IgD+CD38- follicular mantle cDNA clones statistically associates these events to the somatic hypermutation process (P = 0.014). Close scrutiny of the 9 insertion/deletion events reported here, and of 25 additional insertions or deletions collected from the literature, suggest that secondary structural elements in the DNA sequences capable of producing loop intermediates may be a prerequisite in most instances. Furthermore, these events most frequently involve sequence motifs resembling known intrinsic hotspots of somatic hypermutation. These insertion/deletion events are consistent with models of somatic hypermutation involving an unstable polymerase enzyme complex lacking proofreading capabilities, and suggest a downregulation or alteration of DNA repair at the V locus during the hypermutation process.

Ig V region hypermutation in B cell hybrids mimics in vivo mutation and allows for isolation of clonal variants

In order to investigate the regulation of Ig hypermutation, we have established a cell culture system in which reversion of a V region stop codon in a stably transfected Ig gene permits the quantitation of mutation rates by fluctuation analysis. Transfected heavy chain V regions associated with the mu constant region undergo low rates of mutation in the NSO plasmacytoma cell line and a moderate rate of mutation in the 18.81 pre-B cell line. Most of the hybrids created by fusing these two cell lines resembled the non-permissive NSO cell line, though a few hybrids had constitutive V region mutation rates that were even higher than 18.81 and similar to the high rates of mutation that occur in vivo (Green, N. S., Rabinowitz, J. L., Zhu, M., Kobrin, B. J. and Scharff, M. D. (1995) Proc. Nat. Acad. Sci. (USA) 92, 6304 6308). Characterization of these hybrids now demonstrates that the transfected genes were integrated outside of the Ig locus. Mutation was due to multiple single base pair replacements in the V region and not the C region, was ongoing and often arose in hot spot motifs described by V region hypermutation in vivo. Subcloning of unstable hybrids allowed for the isolation of highly related clones with 44-70-fold different mutation rates. These results suggest that V region hypermutation in this mode in vitro systems is under both positive and negative regulation.

Insertion of 2 kb of bacteriophage DNA between an immunoglobulin promoter and leader exon stops somatic hypermutation in a kappa transgene

Somatic hypermutation in rearranged immunoglobulin variable genes occurs in a 2kb region of DNA that is delimited on the 5' side by the promoter and on the 3' side by intron DNA. To identify sequence features that activate the mutation mechanism, we increased the distance between the promoter and the leader region to test whether the spacing of these elements was important. The promoter was separated from the leader sequence by inserting a 2 kb fragment of noncoding bacteriophage lambda DNA between the TATA box and ATG initiator codon in a kappa transgene. Mice from three founder lines were immunized, RNA and DNA were isolated from spleen and Peyer's patch B cells, and transcription of the transgene was confirmed. The frequency of mutation in endogenous heavy chain genes was high, indicating that some B cells underwent hypermutation. However, no hypermutation was found in the transgenic bacteriophage or variable region sequences. Hypermutation did occur in another kappa transgene that had a deletion of the VJ coding sequence, showing that the basic construct is functional and that the VJ exon is not necessary for the mutation mechanism. It is likely that the bacteriophage sequence is a potential substrate for mutation because other heterologous sequences have been shown to undergo mutation if placed downstream of the leader exon. The results suggest that the promoter should be contiguous with the leader exon for the mutation mechanism to function.

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.