Ig VH, DH, and JH germ-line gene segments linked by overlapping cosmid clones of rabbit DNA

Overlapping cosmid clones of rabbit germ-line DNA containing VH, DH and JH gene segments were isolated. The map of this cluster of cosmid clones indicated that the rabbit VH and JH regions were separated by 63 kb. Hybridization of Southern blots of these cosmid clones with two different DH segment probes identified a total of six DH segments within the region between the VH and JH regions. The nucleotide sequences of the JH region and one of the DH segments have been determined. The DH segment has conserved heptamer and nonamer sequences separated by 12 and 11 bp at the 3' and 5' sides, respectively, of the coding region and hence, appears to be a functional gene. The nucleotide sequence of the JH region revealed four functional JH gene segments and one JH pseudogene. Inasmuch as the JH region had previously been linked by contiguous overlapping clones with C mu, C gamma, C epsilon, and one C alpha gene, this VH-DH-JH cluster and the clones containing the Ig H chain C region genes represent 190 kb of contiguous germ-line DNA of the Ig H chain locus.     

Involvement of immunoglobulin heavy- and light-chain (kappa) gene clusters in a human B-cell translocation, t(2;14)

The breakpoints of a translocation, t(2;14)(p11;q32), detected in an Epstein-Barr virus-transformed lymphoid B-cell line were mapped by Southern analysis, field-inversion gel electrophoresis, and in situ hybridisation. The translocation involved the immunoglobulin light-chain (kappa) locus on chromosome 2 and the heavy-chain locus on chromosome 14. The breakpoint on chromosome 2 was between VK and CK, most likely within JK. The chromosome 14 break was located within the VH cluster, no more than 220 kb 5' of the productively rearranged JH locus. The translocation probably resulted from an aberrant rearrangement of the kappa light-chain genes.     

Somatic hyperconversion diversifies the single Vh gene of the chicken with a high incidence in the D region

The chicken heavy chain locus contains a single JH segment and a unique functional VH gene (VH1) 15 kb upstream, with approximately 15 D elements in between. A cluster of pseudogenes (psi VH) spans 60-80 kb, starting 7 kb upstream from VH1, with an average density of one pseudogene per 0.85 kb and an almost systematic alternation of polarity. Diversification of the unique rearranged VH1 gene takes place during bursal ontogeny by the same hyperconversion mechanism that was described for the chicken light chain, with psi VH segments acting as donors. The hyperconversion mechanism also operates within the D region, as all pseudogenes analyzed are fused VD elements; this D region possesses distinct characteristics, allowing higher combinatorial possibilities in the gene conversion process. Allelic exclusion appears to be performed by restriction of a complete VDJ rearrangement to a single allele.     

Organization of variable region segments of the human immunoglobulin heavy chain: duplication of the D5 cluster within the locus and interchromosomal translocation of variable region segments.

We have studied the organization of variable region (V) genes of the human immunoglobulin heavy chain (H) by cosmid cloning. We isolated two independent immunoglobulin D5 clusters (D5-a and D5-b) from cosmid libraries of the human genome. Restriction maps of these two regions showed that downstream 15 kb portions of the 55 kb overlap were different although upstream 40 kb portions were almost identical. Four more D segments, (DM, DXP, DA and DK) were found around the D5 segment in the conserved region of each cluster. Nucleotide sequences of the corresponding D segments from each cluster were almost identical and they encoded potentially functional D regions. Analysis using human-rodent somatic cell hybrids demonstrated that both clusters were located in the immunoglobulin heavy chain (H) locus on chromosome 14, suggesting that the D5-a and D5-b regions evolved by internal duplication within this locus. We also isolated a 60 kb DNA region carrying four VH segments, designated as VH-F region, which was located on chromosome 16. Nucleotide sequences of the four VH segments were determined. Two of them encoded potentially functional VH segments, and the other two were pseudogenes. Some more VH segments were found to be located outside chromosome 14, by Southern blot hybridization of human-rodent hybrid cell DNAs. These results provide further evidence that the human VH locus has undergone recent reorganization.     

Dispersed localization of D segments in the human immunoglobulin heavy-chain locus.

We have studied the organization of the human immunoglobulin heavy-chain genes by pulse field gel electrophoresis as well as by isolation of cosmid clones. The total length of the heavy-chain variable region locus was estimated to be approximately 3000 kb. We found that D segments including a recently isolated D5 segment were dispersed among VH segments. We identified a pseudo V segment 18 kb 3' to the D5 segment in isolated cosmid clones. A 300 kb fragment produced by MluI digestion contained VH, D, JH segments and the distance between VH and D was estimated to be approximately 240 kb. Overlapping cosmid clones containing the human D1, D2, D3, D4, JH, Cmu and C delta genes were isolated. Restriction maps of these regions indicated that the distance between D and JH is about 22 kb. A partial restriction map of the VH locus was constructed using the pulse field gel electrophoresis technique and deletion of VH segments in B cells.     

Recombination events near the immunoglobulin Cmu gene join variable and constant region genes, switch heavy-chain expression, or inactivate the locus

Immunoglobulin heavy-chain expression is initiated by recombination between a variable region (VH) gene and one of several joining region (JH) genes located near the mu constant region (Cmu) gene, and the active VH gene can subsequently switch to another CH gene. That the general mechanism for CH switching involves recombination between sites within the JH-Cmu intervening sequence and the 5' flanking region of another CH gene is supported here by Southern blot hybridization analysis of eight IgG- and IgA-secreting plasmacytomas. An alternative model requiring successive VH linkage to similar JH clusters near each CH gene is shown to be very unlikely since the mouse genome appears to contain only one complement of the JH locus and no JH gene was detectable within large cloned sequences flanking germline C gamma 3 and C gamma 1 genes. Thus, VH-JH joining and CH switching are mediated by separate regions of "the joining-switch" or J-S element. In each plasmacytoma examined, the J-S element had undergone recombination within both the JH locus and the switch region and was shown to be linked to the functional CH gene in an IgG3, and IgG1, and three IgA secretors. Both JH joining and CH switching occurred by deletion of DNA. Switch recombination occurred at more than one site within the J-S element in different lines, even for recombination with the same CH gene. Significantly, although heavy-chain expression is restricted to one allele ("allelic exclusion"), all rearranged in each plasmacytoma. Some rearrangements were aberrant, involving, for example, deletion of all JH genes from the allele. Hence, an error-prone recombination machinery may account for allelic exclusion in many plasmacytomas.     

Deletion mapping of Ig VH gene segments expressed in human CD5 B cell lines. JH proximity is not the sole determinant of the restricted fetal VH gene repertoire.

VH gene segments expressed in a panel of monoclonal human CD5 B cell lines have been positioned on the IgH locus by deletion mapping. The analysis yielded a relative order of VH fragments of the VH2, VH4, VH5, and VH6 gene families that was consistent with, and provided a further refinement of existing maps of the human IgH locus. We demonstrate that four of six VH gene segments expressed in the CD5 B cell lines map > 500 kb from the cluster of JH segments. Two of the gene segments, positioned at approximately 850 kb (58p2) and approximately 500 kb (1-9III) from the JH segments, respectively, belong to the previously identified small cohort of second trimester fetal VH gene segments. The data show that JH proximity is not the sole determinant of restricted VH gene utilization in early human ontogeny.     

Rearrangement of VHa1-encoding Ig gene segment to the a2 chromosome in an a1/a2 heterozygous rabbit. Evidence for trans recombination

VDJ genes were cloned from leukemic B cells of an a1/a2 heterozygous Emu-cmyc transgenic rabbit. Restriction mapping and nucleotide sequence analysis indicated that one clone, 5C3, had a VHa1-encoding gene segment functionally rearranged to a JH gene segment from the a2 chromosome. This VDJ gene may be the result of a trans recombination between a VH gene on the a1 chromosome and a JH gene segment on the a2 chromosome or, it may be the result of a cis recombination if the a2 chromosome contains VHa1-encoding gene segments.     

Inverted duplication of JH associated with chromosome 14 translocation and T-cell leukemia in ataxia-telangiectasia.

A specific 14q32 breakpoint is observed in a homologous chromosome 14 translocation [t(14;14)q12q32] occurring in the T-cells of about 10% of patients with ataxia-telangiectasia (AT). To investigate whether the 14q32 breakpoint in AT occurs within the immunoglobulin gene cluster as is frequently detected in B-cell lymphoma, immunoglobulin clones were hybridized to Southern blots of DNA isolated from the T-cells of two AT patients with this chromosome 14 translocation. The 14q32 translocation breakpoints in these patients are apparently not within JH, S mu, C mu, S alpha-1 or -2, or C alpha-1 or -2, but one of the patients has an inverted duplication of at least 26 kilobases (kb) of the C mu region, with an associated 5' flanking deletion. The point of origin of the inverted duplication is within JH near the recombination signal for the J4 gene. This suggests that normal JH recombination mechanisms may have played a role in the development of this 14q32 chromosomal aberration. The presence of AT chromosomal breakpoints near other rearranging genes suggests a role for exaggerated recombination in the pathogenesis of chromosomal instability in AT.     

An immunoglobulin heavy chain variable region gene is generated from three segments of DNA: VH, D and JH

We have determined the sequences of separate germline genetic elements which encode two parts of a mouse immunglobulin heavy chain variable region. These elements, termed gene segments, are heavy chain counterparts of the variable (V) and joining (J) gene segments of immunoglobulin light chains. The VH gene segment encodes amino acids 1-101 and the JH gene segment encodes amino acids 107-123 of the S107 phosphorylcholine-binding VH region. This JH gene segment and two other JH gene segments are located 5' to the mu constant region gene (Cmu) in germline DNA. We have also determined the sequence of a rearranged VH gene encoding a complete VH region, M603, which is closely related to S107. In addition, we have partially determined the VH coding sequences of the S107 and M167 heavy chain mRNAs. By comparing these sequences to the germline gene segments, we conclude that the germline VH and JH gene segments do not contain at least 13 nucleotides which are present in the rearranged VH genes. In S107, these nucleotides encode amino acids 102-106, which form part of the third hypervariable region and consequently influence the antigen-binding specificity of the immunoglobulin molecule. This portion of the variable region may be encoded by a separate germline gene segment which can be joined to the VH and JH gene segments. We term this postulated genetic element the D gene segment, referring to its role in the generation of heavy chain diversity. Essentially the same noncoding sequences are found 3' to the VH gene segment and as inverse complements 5' to two JH gene segments. These are the same conserved nucleotides previously found adjacent to light chain V and J gene segments. Each conserved sequence consists of blocks of seven and ten conserved nucleotides which are separated by a spacer of either 11 or 22 nonconserved nucleotides. The highly conserved spacing, corresponding to one or two turns of the DNA helix, maintains precise spatial orientations between blocks of conserved nucleotides. Gene segments which can join to one another (VK and JK, for example) always have spacers of different lengths. Based on these observations, we propose a model for variable region gene rearrangement mediated by proteins which recognize the same conserved sequences adjacent to both light and heavy chain immunoglobulin gene segments.     

Analysis of VH gene replacement events in a B cell lymphoma

We have analyzed a series of recombinational events at the IgH chain locus of the B cell lymphoma, NFS-5. Each of these recombinational events results in the replacement of the VH gene segment of the rearranged H chain gene (VhDJh) with that of an upstream germline gene segment. Replacements on the productive and nonproductive alleles have been observed. In each case, the recombination occurs in close proximity to a highly conserved heptameric sequence (5'TACTGTG3') which is located at the 3' end of the VH coding region. In the two examples of recombination on the productive allele that have been analyzed, the initial VHQ52 gene is replaced by different VH7183 genes. On the non-productive allele, sequential replacement events have been analyzed: the initial VHQ52 rearrangement is first replaced by a closely related VHQ52 gene, followed by a second replacement using a VHQ52 pseudogene. Southern blot analysis using VH probes indicates that these recombinations may be accompanied by the deletion of germline VH genes belonging to both the VHQ52 and VH7183 families, suggesting that these gene families are interspersed in the NFS/N mouse.     

Physical map of the 3'' region of the human immunoglobulin heavy chain locus: clustering of autoantibody-related variable segments in one haplotype.

We have constructed the physical map of the 3' region of the human immunoglobulin heavy chain variable region (VH) genes. DNA segments extending to 200 kb upstream of the JH segment were isolated in two YAC clones. Five VH segments were identified in this region in the 5' to 3' order, V(II-5), V(IV-4), V(I-3), V(I-2), and V(VI-1) segments which were all structurally normal and orientated in the same direction as the JH segments. From DNA of a different cell line we have isolated a cosmid contig containing the same DNA region which has extraordinary polymorphism. The YAC and cosmid DNAs were called haplotypes A and B, respectively. Haplotype B contained an additional VH-I segment (V(I-4.1b)) between the V(II-5) and V(IV-4) segments. V(I-4.1b) segment is almost identical to a previously published VH sequence encoding a rheumatoid factor. Another VH segment in the B haplotype (V(I-3b)) corresponding to the V(I-3) segment also showed 99.7% nucleotide sequence homology with an anti-DNA autoantibody VH sequence. However, none of the VH sequences in haplotype A showed such strong homology with autoantibody VH sequences. The results suggest that VH haplotypes may have linkage with autoantibody production.     

The productive gene for alpha-H chain disease protein MAL is highly modified by insertion-deletion processes

alpha-H chain diseases (HCD) is a human lymphoproliferative disorder, characterized by the production of truncated alpha-Ig H chains, without associated L chains. In this study, we have analysed the serum protein, the alpha-HCD mRNA and the rearranged alpha-HCD gene from the leukemic cells of a patient (MAL) with alpha-HCD. The abnormal MAL serum Ig consisted of short alpha 1-chains, lacking VH and CH1 domains (only CH2 and CH3 domains were present). The alpha-HCD mRNA (1.2 kb) was shorter than a normal alpha-mRNA (2 kb); the corresponding cDNA had sequences for the leader, a 84-bp sequence of unknown origin and the CH2 and CH3 exons. The establishment of the sequence of the productive alpha-HCD MAL allele revealed two major deletions; that of the VH region as well as that of the CH1 region. The JH region is altered by multiple mutations, small insertions and a duplication of the psi JH3 region. A large insert (INS1), of 360 bp (containing the 84 bp exon found in the cDNA), replaces the deleted VH region. INS1 is non-Ig related and apparently of nongenomic origin. A large second insert (509 bp), is located between the enhancer and the switch region. Insert2 contains repetitive non-Ig-related sequences and a small Ig-related sequence. All these alterations resulted in an abnormal mRNA, which comprises the leader, a 84-bp alien exon derived from INS1 and the CH2 and CH3 exons of the alpha 1-gene.     

Organization of human immunoglobulin heavy chain diversity gene loci

The variable region of immunoglobulin heavy chain is encoded by three separate genes on the germline genome: variable (VH), diversity (DH) and joining (JH) genes. Most human DH genes are encoded in 9-kb repeating sequences. We determined the nucleotide sequence of a 15-kb DNA fragment containing more than one and a half of these repeating units, and identified 12 different DH genes. Based on the sequence similarities of DH coding and the surrounding regions, they can be classified into six different DH gene families (DXP, DA, DK, DN, DM and DLR). Nucleotide sequences of DH genes belonging to different families diverge greatly, while those belonging to the same families are well conserved. Since the 9-kb DNA containing the six DH genes are multiplied at least five times, the total number of DH genes must be approximately 30. These DH genes are sandwiched by 12-nucleotide spacer signals. Most of the somatic DH sequences found in the published VH-DH-JH structures (the somatic DH segment being defined as the region which is not encoded either by germline VH or JH gene) were assigned to one of the germline DH genes. Other than these typical DH genes, however, we found a new kind of DH gene (which we termed DIR) the spacer lengths of whose neighbouring signals were irregular. The DIR gene appears to be involved in DIR-DH or DH-DIR joining by inversion or deletion. Two of the somatic DH sequences were assigned to the DIR genes. Long N segments might, therefore, originate from DIR genes.