Content and organization of the human Ig VH locus: definition of three new VH families and linkage to the Ig CH locus.

We present a detailed analysis of the content and organization of the human immunoglobulin VH locus. Human VH genes representing five distinct families were isolated, including novel members belonging to two out of three of the known VH gene families (VH1 and VH3) as well as members of three new families (VH4, VH5, and VH6). We report the nucleotide sequence of 21 novel human VH genes, many of which belong to the three new VH gene families. In addition, we provide a preliminary analysis of the organization of these gene segments over the full extent of the locus. We find that the five multi-segment families (VH1-5) have members interspersed over nearly the full 1500-2000 kb of the VH locus, and estimate that the entire heavy chain locus covers 2500 kb or less. Finally, we provide the first report of the physical linkage of the variable and constant loci of a human Ig gene family by demonstrating that the most proximal known human VH segments lie within 100 kb of the constant region locus.     

Structure, map position, and evolution of two newly diverged mouse Ig VH gene families.

We have characterized two novel mouse VH gene families, VH3609N and VHSM7. These VH families have recently diverged from previously defined VH families. The VH3609N family, which may contain only one member in most inbred strains of mice, shares sequence similarity with the VHJ606 family and is located to the 3' side of VHJ606. VHSM7, with at least three members, is related to the VHJ558 family but maps 3' of VHJ558. These findings suggest that physical displacement of VH sequences may facilitate their subsequent divergence. During the early stages of VH gene family evolution that are exemplified by these new families, amino acid replacements have been selected against in frame-work regions and selected for in complementarity-determining regions. This pattern of nucleotide substitution appears to reflect evolutionary pressures to maintain germ-line VH diversity and, possibly, to select for new antibody specificities, as well as to select against mutations resulting in aberrant Ig. The classification of VH sequences with borderline similarity to previously defined VH families is discussed.     

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.     

Eleven MRL-lpr/lpr anti-DNA autoantibodies are encoded by genes from four VH gene families: a potentially biased usage of VH genes

The genes encoding 11 independently derived anti-DNA autoantibodies from the lupus-prone mouse strain, MRL-lpr/lpr, were examined with VH, D, and JH gene probes. These autoantibodies do not define new VH gene families, since all of the autoantibodies were encoded by VH genes from four of the nine known gene families. A minimum of nine different VH genes encoded this panel of 11 anti-DNA autoantibodies. These results are consistent with the stochastic use of the VH gene repertoire and the expression of multiple VH genes. However, the data is also consistent with a biased usage of the VH gene repertoire. First, two pairs of autoantibodies, one from the J558 family and one from the 7183 family, appear to express identical or closely related VH genes as determined by the position of two restriction enzyme sites 5' of the expressed VH genes. In addition, three autoantibodies that appear to be sister clones might define a third VH gene that is used repeatedly. Secondly, about 45% of the panel is encoded by the Q52 and 7183 families, which are the 3' most families. These families have been shown to be preferentially rearranged early in B cell ontogeny. This suggests that some anti-DNA autoantibodies might originate from a population of B cells that predominate early in ontogeny. An alternative hypothesis is that the potential bias in VH gene and gene family usage could be due to antigen selection. All four JH genes are expressed, although the JH1 gene appears to be underutilized in both expressed and unexpressed rearrangements. Two members of the panel that bind double-stranded DNA were encoded by two different VH gene families, the S107 family and the J558 family.     

The physical organization of the human immunoglobulin heavy chain gene complex.

Two dimensional DNA electrophoresis (2D-DE) was used to map the variable (VH) region of the human heavy chain immunoglobulin gene cluster. Seventy-six VH gene segments were mapped to specific SfiI, BssHI and NotI fragments by 2D-DE. We have determined that a common insertion/deletion polymorphism of 80 kb, involving three VH gene segments, occurs in the VH region. The physical map suggests that the evolution of the human IGH gene complex involved duplication of blocks containing different VH families. This physical map will allow comparison of the usage of VH loci in human ontogeny with their proximity to the CH region. Knowledge of the germline repertoire of a particular DNA source studied in essential as the number of the dispersed VH gene segments of VH families, especially of the VH5 family, is variable. 2D-DE, as illustrated here for the IGH gene cluster, has general application in the development of large scale physical maps of gene and repeat families.     

Heavy chain variable region gene families evolved early in phylogeny. Ig complexity in fish

The V regions of channel catfish H chain cDNA clones have been analyzed. Based upon sequence relationships and hybridization analyses, five different groups of VH genes are identified whose definition is consistent with that of five different VH families. Genomic Southern blots indicate that as many as 100 different germ-line VH genes are likely represented by these families. The sequence diversity between identified members of these different families is similar in magnitude to the divergence represented between members of different human or mouse VH families. The FR regions are the most conserved regions when members of different catfish VH families are compared; specific amino acid positions appear to be highly conserved in phylogeny. Equally important is that diversity is represented in complementarity-determining regions CDR1 and CDR2 in members of the different families as well as in members of the same VH family. These results suggest that an extensive repertoire of VH genes can contribute to antibody diversity in this lower vertebrate. Sequence comparisons indicate that one of the catfish VH families shares considerable structural similarity to several higher vertebrate VH gene families--a relationship which suggests that this VH family may be ancestral to some VH gene families of higher vertebrates. Characteristic of the genomic organization of higher vertebrate H chains, catfish appear to have different VH families wherein a VH gene likely undergoes functional recombination with putative DH gene segments and one of apparently several different JH segments. The recombined V region is expressed with the same C region gene. These combined results suggest that bony fishes are the earliest known phylogenetic representatives to have evolved extensive V region gene families.     

High frequency expression of S107 VH genes by peritoneal B cells of B10.H-2aH-4bP/WTS mice

Our previous analyses of peritoneal Ly-1 B cells indicate that a high percentage express VH genes of the VH11 and VH12 families, and that this bias is due to clonal selection. The antibodies encoded by these genes bind the same hapten, phosphatidyl choline (PtC). Twenty-one of 73 hybridomas generated from fusions with peritoneal Ly-1 and Ly-1 sister population B cells of B10.H-2aH-4bp/Wts mice produce anti-PtC specific antibodies. We show here that 19 of these express VH11 and VH12 family genes and two express VH36-60 family genes. To assess whether there is a bias in VH gene use among non-PtC-specific hybridomas we analyzed the remaining 52 hybridomas for VH family expression by using VH family-specific probes in an RNA dot blot assay and by Ig mRNA sequencing. We find a seven-fold increase in the expression of the VHS107 family genes, and only slight differences in the expression of VH genes of other families relative to splenic B cells. We attribute the increase in VHS107 gene expression to clonal selection inasmuch as five of the seven VHS107+ hybridomas express the same VH gene (V11) and VL association is nonrandom. The bias in VH gene use among the entire panel of 73 peritoneal hybridomas is to the extent that approximately one-third express one of three genes: the V11 gene of the S107 family, the CH34 gene of the VH11 family, and the VH12 family gene.     

Direct quantitative in situ hybridization studies of Ig VH utilization. A comparison between unstimulated B cells from autoimmune and normal mice

This study examines Ig VH utilization in murine lupus with emphasis on the relative contribution of 3' and 5' gene families. We used in situ hybridization with 35S-labeled ssRNA probes to detect VH expression in individual spleen cells. Cells were taken from unmanipulated animals, and were not stimulated in vitro. This approach allows analysis of VH usage among only those B cells which have undergone activation in vivo, while minimizing the potential for skewing in vitro. We compared usage of the 3' 7183 and Q52 families with the more 5' J558 family in adult NZB, MRL-lpr/lpr, and nonautoimmune NIH Swiss mice. VH utilization in the autoimmune strains was proportionate to VH family size, and was not biased toward the 3' families when compared with the Swiss repertoire. Moreover, 3' skewing did not develop in NZB mice with increasing age. Thus, systemic autoimmunity is not associated with impaired normalization of the adult repertoire away from the 3' bias of early ontogeny. Instead, our data support a stochastic model for VH gene usage in the activated B cells and plasma cells of adult lupus mice.     

VH gene family utilization in colonies derived from B and pre-B cells detected by the RNA colony blot assay.

The immunoglobulin heavy chain variable region (VH) genes of the mouse have been categorized into families based upon sequence homology. Utilizing the RNA colony blot assay we have determined the expression of eight of these families in B cell colonies derived from either surface immunoglobulin positive (sIg+) adult spleen B cells or sIg- fetal liver pre-B cells. We demonstrate, based upon the analysis of greater than 6000 individual colonies, that VH gene usage is a characteristic of the mouse strain studied. C57BL/6 mice most frequently (45%) utilize family VHJ558, the largest VH family, whereas BALB/c mice most frequently (22%) utilize family VH7183, the most JH proximal family in BALB/c mice. Moreover, colonies derived from sIg- fetal liver derived precursors show similar patterns, suggesting that selection based on exogenous antigen is not an important parameter in determining VH gene family usage.     

Organization of the murine immunoglobulin VH complex in the inbred strains.

Deletion mapping analyses have been employed to order the heavy chain variable region (VH) gene families in three inbred murine strains. These nine VH gene families have been positioned with respect to the J558 and 3660 VH families in A/J (Ighe) as follows: 3609-J558-(J606,VGAM3-8,S107)-3660-(X24,Q52,7183 )-DH. Maps generated with respect to J558 in the BALB/c (Igha) and C57BL/6 (Ighb) strains are consistent with these results. The organization of the VH complex produced by deletion mapping is quite different from the accepted map generated by other methods, particularly in that J558 is more DH distal and 3660 is more DH proximal than previously thought. The order presented here is compatible with VH rearrangement frequencies suggesting preferential utilization of DH-proximal VH gene segments. Our data also indicate that interspersion of some VH family members may be a common feature of the murine VH complex since the 3609 VH family is interdigitated in the three strains and a Q52 VH gene segment is interspersed in C57BL/6.     

Ig H chain variable and C region genes in common variable immunodeficiency. Characterization of two new deletion haplotypes.

Common variable immunodeficiency, a disorder characterized by diminished antibody production, manifests clinically as an increased susceptibility to bacterial infections. We have investigated the Ig H chain V and C region gene segments in 33 patients with common variable immunodeficiency, to identify the possible role these genes may have in the molecular basis of the defect. No major deletions were recognized for the VH gene segments of the VH2, VH5, and VH6 families, nor were there any differences in the RFLP patterns of mu- or alpha- switch regions or of C gamma genes. Two new deletion haplotypes were identified for the C region genes, the first encompassing C gamma 1 on a different haplotype from the C gamma 1 deletion described previously, and the second a novel deletion encompassing both C gamma 2 and C gamma 4. Based on these and previously described deletions in the IGHC region, we postulate that homologous regions are involved in the deletion process and that other new deletions likely exist in the population.     

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.     

Conservation and divergence of immunoglobulin VH pseudogenes.

The 12 immunoglobulin VH pseudogenes, that have been characterized to date, differ from most pseudogenes of other multigene families in two aspects: (i) they carry only one (11 cases) or at the most two (1 case) deleterious mutations and (ii) they show no evidence of increased divergence from intact VH genes. We describe here the first immunoglobulin VH pseudogene that does not have these characteristics. This pseudogene accumulated numerous deleterious mutations and diverged considerably from other genes of the VH gene family to which it belongs. In possible contrast to the other VH pseudogenes, this pseudogene seems to be selectively neutral. We discuss the implications of the characterization of this diverged VH pseudogene in relation to our understanding of the genetic mechanisms that generate diversity among germline immunoglobulin VH genes.     

Coevolution of immunoglobulin heavy- and light-chain variable-region gene families

The gene families encoding the immunoglobulin variable regions of heavy (VH) and light (VL) chains in vertebrates are composed of many genes. However, the gene number and the extent of diversity among VH and VL gene copies vary with species. To examine the causes of this variation and the evolutionary forces for these multigene families, we conducted a phylogenetic analysis of VH and VL genes from the species of amniotes. The results of our analysis showed that for each species, VH and VL genes have the same pattern of clustering in the trees, and, according to this clustering pattern, the species can be divided into two groups. In the first group of species (humans and mice), VH and VL genes were extensively intermingled with genes from other organisms; in the second group of species (chickens, rabbits, cattle, sheep, swine, and horses), the genes tended to form clusters within the same group of organisms. These results suggest that the VH and VL multigene families have evolved in the same fashion: they have undergone coordinated contraction and expansion of gene repertoires such that each group of organisms is characterized by a certain level of diversity of VH and VL genes. The extent of diversity among copies of VH and VL genes in each species is related to the mechanism of generation of antibody variety. In humans and mice, DNA rearrangement of immunoglobulin variable, diversity, and joining-segment genes is a main source of antibody diversity, whereas in chickens, rabbits, cattle, sheep, swine, and horses, somatic hypermutation and somatic gene conversion play important roles. The evolutionary pattern of VH and VL multigene families is consistent with the birth-and-death model of evolution, yet different levels of diversifying selection seem to operate in the VH and VL genes of these two groups of species.      

A novel family of variable region genes of the human immunoglobulin heavy chain

We isolated and sequenced six variable-region (V) gene segments of the human immunoglobulin heavy-chain (H) using the V71-2 segment as probe. These VH segments were more than 90% homologous to each other and less than 65% homologous to members of the three known VH families. The VH fragments hybridized to an identical set of restriction fragments on Southern blots of human placenta DNA. The new family was designated as the VH-IV family. The complexity of the VH-IV family was estimated to be at least nine genes, of which the sequenced seven were functional genes. The VH-IV family is homologous (76%) to the mouse Vh36-60 family.     

Immunoglobulin heavy chain constant and heavy chain variable region genes in phylogenetically diverse species of bony fish

Summary Genomic DNA from 18 phylogenetically diverse species of bony fish was hybridized with probes specific for the channel catfish immunoglobulin heavy chain constant (CH) gene, as well as with immunoglobulin heavy chain variable (VH) probes specific for five channel catfish VH gene families. The results showed that CH probes strongly hybridized only to genomic fragments from other catfish species. In contrast, restricted DNA from most other species hybridized with at least two channel catfish VH probes. In those species whose DNA hybridized with multiple VH probes, the restriction pattern of hybridizing fragments was probe-dependent. These studies suggest that (1) the CH gene defined in channel catfish appears to share similarity only with CH genes in other catfish species, (2) families of VH genes appear to have diverged in early phylogenetic lineages of teleosts, and (3) VH genes similar to those defined in catfish appear to be widely represented in phylogenetically diverse species of teleosts.     

Members of novel VH gene families are found in VDJ regions of polyclonally activated B-lymphocytes.

Four potentially productive and two non-productive VDJ gene segments were isolated from the DNA of mouse B-lymphocytes which had been polyclonally activated by bacterial lipopolysaccharide (LPS). Three VDJ regions exhibit VH genes which stem from two novel VH gene families. The complexity of these families is 5-9 genes. One of the non-productive VDJ regions exhibits a D segment which may have been generated by joining of two DSP2 segments. Both non-productive VDJ regions appear to contain rearranged pseudo VH genes. Three potential somatic mutations distributed over two productive VDJ regions are observed.