Polymorphism of the human Ig VH4 gene family.

In this study, we analyze the human VH4 gene family and find it to exhibit a level of polymorphism similar to that of the much larger VH3 family. A cloned VH4 probe detected an average of 10 hybridizing BgIII restriction fragments in genomic DNA derived from 75 unrelated individuals and a total of 15 distinct bands. Of these 15 restriction fragments, 12 were polymorphic, as demonstrated by band absence in some individuals. Oligonucleotide probes specific to CDR1 and CDR2 sequences of known VH4 genes detected limited numbers of bands and revealed sequence polymorphisms that correlated with several of the RFLP detected by the cloned probe. The prevalence of the individual polymorphic restriction fragments was highly variable, ranging from 1% to 97%, with a mean prevalence of 51%. These values resemble those previously observed among VH3 elements. Analysis of linkage disequilibrium suggests that most VH4 gene segments are in genetic equilibrium. These results indicate that the VH4 loci, like those of VH3, are dominated by relatively few, perhaps two to four, alleles/locus and further suggest that the haplotype organization of the human VH locus is very complex.     

Two new Ig VH gene families in Oncorhynchus mykiss

Genes encoding the immunoglobulin heavy-chain variable region (Ig VH) in rainbow trout (Oncorhynchus mykiss) have been grouped into 11 families. While obtaining a baseline assessment of the various gene families utilized by trout in the production of secreted antibody, we discovered two new families. These proposed Ig VH families, Families XII and XIII, were rarely observed; only two VH sequence types were detected for each new family, suggesting that they may not be commonly used in response to antigens, or that the captive environment may not lead to typical exposures seen in the wild. Additionally, unlike preceding studies, we found at least one representative gene sequence for each of the 11 reported Ig VH gene families, possibly indicating that the repertoire of trout Ig VH gene families may be more universal among different stocks than previously realized. GenBank accession numbers: Family XII—DQ453185 and DQ453150; Family XIII—DQ453153 and DQ453146; others DQ453143, DQ453156, DQ831723, DQ831825.     

Ig VH gene family repertoire of plasma cells derived from lupus-prone MRL/lpr and MRL/++ mice

VH gene family usage was determined in both spontaneous, in vivo activated plasma cells and LPS-induced plasma cells from individual MRL/lpr mice by using in situ hybridization. It was found that VH gene family expression in spontaneous plasma cells varied from mouse to mouse. Some mice expressed VH families in an apparently random manner similar to that obtained with polyclonal activation. Other mice showed an exaggerated expression of particular VH gene families. VH J558 was overrepresented most frequently, but overrepresentation of VH 7183, Q52, and 36-60 was also observed. Importantly, LPS-induced VH gene family expression in these same mice displaying biased VH family usage in spontaneous plasma cells, appeared normal with no evidence for similar biases in the LPS-induced repertoire. Anti-DNA antibody concentrations and the degree of glomerulonephritis were determined for each mouse to measure the severity of disease. The level of expression of the J558 family was positively correlated with disease severity. The results suggest that the initial autoantibody response is highly diverse but becomes more restricted as the disease progresses.     

Sequence analysis of members of the human Ig VH4 gene family derived from a single VH locus. Identification of novel germ-line members.

We have generated a mouse x human heterohybridoma that contains a single copy of chromosome 14 and, thus, a haploid set of Ig VH genes. This cell line was used to investigate the germ-line content and nucleotide sequences of members of the VH4 gene family in a polymerase chain reaction-based approach. The analysis of 58 full-length sequences revealed the presence of 12 different germ-line VH4 genes, each of which is potentially functional. These germ-line VH4 genes were compared with the nucleotide sequences of published VH4 genes. Three VH4 genes were 100% identical to previously published sequences and belong to a group of VH4 genes that are strongly conserved and highly prevalent in the human population. Three VH4 genes in our collection displayed greater than 99.3% sequence identity with reported germ-line VH4 sequences and likely represent allelic counterparts of these genes. Six genes displayed less than 97.2% sequence identity with published VH4 genes and were identified as novel members of the human VH4 gene family or more distantly related alleles of known VH4 genes. Collectively, these data suggest that, overall, the human VH4 gene family may be more diverse than hitherto assumed, whereas a number of individual members are nonpolymorphic and extremely well conserved.     

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.     

Concerted evolution of the immunoglobulin VH gene family

With the aim of understanding the concerted evolution of the immunoglobulin VH multigene family, a phylogenetic tree for the DNA sequences of 16 mouse and five human germ line genes was constructed. This tree indicates that all genes in this family have undergone substantial evolutionary divergence. The most closely related genes so far identified in the mouse genome seem to have diverged about 6 million years (MY) ago, whereas the most distantly related genes diverged about 300 MY ago. This suggests that gene duplication caused by unequal crossing-over or gene conversion occurs very slowly in this gene family. The rate of occurrence of gene duplication in the VH gene family has been estimated to be 5 x 10(-7) per gene per year, which seems to be at least about 100 times lower than that for the rRNA gene family. This low rate of concerted evolution in the VH gene family helps retain intergenic genetic variability that in turn contributes to antibody diversity. Because of accumulation of destructive mutations, however, about one-third of the mouse and human VH genes seem to have become nonfunctional. Many of these pseudogenes have apparently originated recently, but some of them seem to have existed in the genome for more than 10 MY. The rate of nucleotide substitution for the complementarity-determining regions (CDRs) is as high as that of pseudogenes. This suggests that there is virtually no purifying selection operating in the CDRs and that germ line mutations are effectively used for generating antibody diversity.      

Novel secondary Ig VH gene rearrangement and in-frame Ig heavy chain complementarity-determining region III insertion/deletion variants in de novo follicular lymphoma

Human germinal center B cell tumors retain the ability of their nontransformed counterparts to somatically hypermutate Ig V genes by nucleotide substitution. Among a survey of 60 primary previously untreated, clonal, follicular lymphomas we have identified a rare V(H) rearrangement variant and two other in-frame nucleotide insertion/deletion variants within complementarity-determining region III of the Ig heavy chain. The neoplastic origin of the V(H) rearrangement variant was directly demonstrated in cells isolated by microdissection from malignant follicles. In all three cases a common clonal origin for the variants was demonstrated by complementarity-determining region III nucleotide sequence homology and shared somatic mutations in germline encoded positions in framework region IV. The monoclonal nature of the tumors was independently confirmed by demonstrating a single t(14;18) translocation breakpoint in the two cases with a detectable translocation. All the variants occurred in functional V(H) rearrangements, which in two cases were directly shown to encode functional Ab molecules. Both recombination-activating genes 1 and 2 were expressed in lymph node tumor cells containing the V(H) rearrangement variant, although recombination-activating gene expression among a panel of lymphomas was not limited to this variant.     

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.     

Conservation of the most JH proximal Ig VH gene segment (VHVI) throughout primate evolution.

The human VHVI gene segment, the sole member of the VHVI gene family, is remarkable in that it is the most D-proximal VH gene segment and is apparently nonpolymorphic. Here we report that the VHVI gene segment has been remarkably preserved in primate evolution. We were unable to detect RFLP among several primates, and nucleotide sequences of several VHVI gene segments showed remarkable conservation. No differences were detected in the nucleotide sequences of the VHVI gene segment from three unrelated chimpanzees. These findings suggest that the VHVI gene segment has been strongly selected for during primate evolution, suggesting an important immunologic role.     

VH and VL gene usage by murine IgG antibodies that bind autologous insulin

To assess the recognition structures of antibodies that bind a self-Ag, we used mRNA analysis to identify the V region genes of IgG antibodies that bind autologous insulin. Four anti-insulin mAb from primary immunization of BALB/c mice use different combinations of H and L chain V region genes. Two VH genes are from the V-gam 3-2 and V-gam 3-8 families that are infrequently expressed in adult BALB/c mice, and two VH genes are members of the J558 family. Each anti-insulin antibody uses a different Vk gene family. Two antibodies express common Vk genes (Ox1 and Vk21C), whereas two other Vk genes are unusual in BALB/c mice. One Vk gene may represent a BALB/c equivalent of the VkOx2 subfamily and another is identical to a Vk used by anti-idiotypic antibodies from C57Bl/6 mice. When compared with known germ-line counterparts, all of the Vk sequences are close to germ-line configuration. In contrast, the germ-line counterparts for the anti-insulin VH genes are not known, however, they differ only in five to seven predicted amino acids from VH of other expressed antibodies. One antibody (mAb 123) differs in one amino acid in complementarity-determining regions 1 and 2 from the VH of the murine tumor BCL1, and another (mAb 126) employs an unmutated DFL16.1 germ-line D segment. These data suggest that antibodies binding autologous insulin use V gene components that are not extensively mutated, even when derived by immunization with heterologous insulin.     

A single VH gene is utilized predominantly in anti-BrMRBC hybridomas derived from purified Ly-1 B cells. Definition of the VH11 family

By establishing hybridomas from two distinct surface IgM+ splenic B cell populations, Ly-1 B cells and "conventional" (Ly-1-) B cells, we found that the Ly-1 B population includes a 30 to 70 times higher frequency (1 to 2%) of cells with specificity for bromelain treated autologous red blood cells (anti-BrMRBC) when compared with conventional B cells (0.03%). We cloned and sequenced the V genes encoding anti-BrMRBC antibody from two hybridomas made with Ly-1 B cells sorted from the spleen of SM/J mice. The VH sequence (for both) is identical with the previously reported sequence associated with this specificity and belongs to a new VH gene family. This gene family, defined here as VH11, has only two members and is the predominant VH rearranged in a collection of Ly-1 B derived anti-BrMRBC hybridomas, always in association with a single VL gene (a member of the V kappa 9 family). Furthermore, analysis of hybridomas made with Ly-1 B cells sorted from the peritoneum reveals a yet higher increased frequency of VH11-encoded anti-BrMRBC specificity (30%). This variation in frequency of anti-BrMRBC in the Ly-1 population depending on location, together with the repeated association of VH11 with a particular V kappa gene suggest that antigen driven selection is (at least in part) responsible for the biased V gene expression seen in this population. Furthermore, a mechanism that might contribute to biased expression, preferential rearrangement due to close proximity to J (as seen in pre-B lines), is excluded by localization of VH11 5' to several of the more J-proximal families (Q52, 7183).     

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.     

A new Igk-V gene family in the mouse

We have identified and characterized a novel mouse Igk-V gene family, which we have designated Igk-V34. Southern hybridization and nucleotide sequence analysis indicate that this family is comprised of either one or two members in mice of different Igk haplotypes. The gene family members share between 95% and 98% sequence similarity, indicating that they diverged only recently during the evolution of the Igk locus. Sequence relationships between members of this family are discussed.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide sequence database and have been assigned the accession numbers M35154-7. Offprint requests to: A. J. Caton.     

Mouse Ig coded by VH families S107 or J606 bind to protein A

Twenty-five monoclonal mouse Ig (5 IgA, 7 IgM, and 13 IgG1) were tested for binding to staphylococcal protein A. They were allowed to attach to protein A Sepharose column at pH 8.0 and were then eluted with a pH gradient from approximately 7.5 to 3.0. Five of them (IgM or IgA) did not bind. Ten came off with pH approximately 6. They were all IgG1, and were probably bound (weakly) via the Fc portion. The remaining 10 (3 IgA, 4 IgM, and 3 IgG1) were more firmly bound; they came off with pH-values ranging from 5.0 to 3.5. They all expressed VH genes of families J606 or S107, whereas all the 15 Ig that were not firmly bound expressed VH genes of six other families. The VL domains seem to be unimportant for protein A binding inasmuch as a firmly binding and a weakly binding IgG1 antibody share identical VK domains. VH sequences of protein A-binding and nonbinding Ig were compared. No likely peptide sequences were found that might make the ligand for protein A.     

Immunologic memory to PC-KLH: participation of the Q52 VH gene family

BALB/c mice immunized with phosphocholine-conjugated keyhole limpet hemocyanin respond with two major groups of antibodies that differ with respect to fine specificity and idiotype. Group I antibodies predominantly bear the T15 idiotype, and show appreciable affinity for the haptens PC and nitrophenyl PC (NPPC), whereas group II antibodies have appreciable affinity for NPPC only and are T15 idiotype negative. Previous studies indicated that group II binding characteristics may derive from the use of novel V gene segments not observed in group I antibodies. To determine the nature of VH gene usage in the group II antibody response, we examined the VH region of a prototype group II hybridoma, PCG1-1. The nucleotide sequence obtained from the VDJ region indicates that PCG1-1 utilizes a VH gene not observed in the group I response, one that belongs to the Q52 VH family. The PCG1-1 VH nucleotide sequence shares 97% identity with the myeloma M141 VH gene. In addition, PCG1-1 utilizes a D segment most closely related to DSP2.6 rearranged to JH-3. These data indicate that M141, a VH gene not seen in group I anti-PC antibodies is utilized by PCG1-1 to generate a PC-protein-binding group II antibody. PCG1-1 was previously shown to express the V kappa 1-3 light chain, a characteristic shared by several group II hybridomas. Furthermore, here we examined the VH gene rearrangements in four lambda 1-bearing group II hybridomas that share a common JH rearrangement with PCG1-1 by Southern blot analysis. A VH-specific probe that detects M141 VH rearrangements revealed that all four lambda 1 hybridomas as well as PCG1-1 share an identical VH gene rearrangement to JH-3. Thus the M141 VH gene product is able to utilize two distinct light chains to generate group II-like combining sites.     

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.     

Characterization of the murine alpha interferon gene family

Mouse and human genomes carry more than a dozen genes coding for closely related alpha interferon (IFN-alpha) subtypes. IFN-alpha, as well as IFN-beta, IFN-kappa, IFN-epsilon, and limitin, are thought to bind the same receptor, raising the question of whether different IFN subtypes possess specific functions. As some confusion existed in the identity and characteristics of mouse IFN-alpha subtypes, the availability of data from the mouse genome sequence prompted us to characterize the murine IFN-alpha family. A total of 14 IFN-alpha genes were detected in the mouse genome, in addition to three IFN-alpha pseudogenes. Four IFN-alpha genes (IFN-alpha1, IFN-alpha7/10, IFN-alpha8/6, and IFN-alpha11) exhibited surprising allelic divergence between 129/Sv and C57BL/6 mice. All IFN-alpha subtypes were found to be stable at pH 2 and to exhibit antiviral activity. Interestingly, some IFN subtypes (IFN-alpha4, IFN-alpha11, IFN-alpha12, IFN-beta, and limitin) showed higher biological activity levels than others, whereas IFN-alpha7/10 exhibited lower activity. Most murine IFN-alpha turned out to be N-glycosylated. However, no correlation was found between N-glycosylation and activity. The various IFN-alpha subtypes displayed a good correlation between their antiviral and antiproliferative potencies, suggesting that IFN-alpha subtypes did not diverge primarily to acquire specific biological activities but probably evolved to acquire specific expression patterns. In L929 cells, IFN genes activated in response to poly(I*C) transfection or to viral infection were, however, similar.