An experimental approach to enumerate the genes coding for immunoglobulin variable-regions

Critical to our understanding of the immune system diversity is the determination of the number of germ line V genes. The total number of V genes is given by the product: number of subgroups x number of germ line genes per subgroup. Studies of kappa chains and of embryonic DNA indicate 5-10 V genes per subgroup. Statistical analysis of the limited sequence data of mouse kappa chains suggest about 50 V kappa subgroups. We report here a general approach for direct estimation of the number of VL and VH subgroups expressed in normal spleen, and present data for V kappa. The kappa mRNA of the spleen is a heterogeneous population where different V kappa are linked to the same C kappa, i.e. C kappa equals total V kappa. The ratio C kappa/distinct V kappa approximates the number of subgroups since V kappa of the same subgroup cross hybridize while V kappa of different subgroups do not. This ratio was determined by molecular hybridization of cloned C kappa and V kappa DNA probes with spleen mRNA. The results indicate the expression of 280 V kappa subgroups in mouse. Assuming an average of 7 genes per subgroup, we estimate about 2000 V kappa germ line genes.     

Evolutionary relationships and polymorphisms among V κ 10 genes from inbred and wild-derived inbred mice

The V kappa 10 family in BALB/c mice is composed of three members, two of which are utilized in a variety of immune responses. We previously demonstrated that the product of the third gene, V kappa 10C, has never been detected as part of a functional antibody and productive rearrangements are selectively lost during B-cell development. Here we analyzed germline V kappa 10 genes from inbred and wild-derived mice by RFLP and sequencing in order to determine the origin of the V kappa 10C gene, as well as to examine the evolutionary relationships of V kappa 10 genes. Our results demonstrated that the V kappa 10 family is highly conserved across Mus species and subspecies, but that V kappa 10C is rare, being found in only inbred mice of V kappa 10 allelic group b and two of six M. m. domesticus isolates. It was not found in other M. musculus subspecies or M. spretus. V kappa 10A and V kappa 10B were found in all strains, with the exception of one M. m. domesticus isolate, which had only V kappa 10B genes. Overall, V kappa 10A sequences were more highly conserved than V kappa 10B, indicating that different selective pressures may be operating on these genes. The two V kappa 10C sequences from M. m. domesticus were 100% identical to that found in inbred mice. V kappa 10C is more closely related to V kappa 10B than to V kappa 10A and our data suggest that it is a recent duplication of the V kappa 10B gene.     

Organization and evolution of a gene cluster for human immunoglobulin variable regions of the kappa type

An 80,000 base-pair region from the gene locus encoding the variable regions of the human immunoglobulins of the kappa type (V kappa genes) was cloned and analysed. The region comprises five V kappa sequences of subgroup I and one interspersed V kappa pseudogene of subgroup II. The six genes and pseudogenes are arranged at different distances but in the same orientation. The organization of the cluster can be explained by a series of amplification steps; the existence of a V kappa II pseudogene in a V kappa I gene cluster may have been the result of a transposition event; a final duplication step led to a second closely related copy of the cluster. From sequence data for altogether 16,000 base-pairs it appears that gene conversion-like events and subsequent selection contribute to both homogeneity and diversity of the V kappa repertoire.     

Xenogeneic antibodies with apparent public idiotypic specificity for anti-Ia.7 antibodies are directed in part against V kappa 21D and E subgroup marker

Public idiotypes (IdX) expressed on monoclonal antibodies (mAb) against a monomorphic alpha-chain determinant of the I-E molecule (Ia.7 epitope cluster I) have been studied by using xenogeneic anti-Id reagents derived from pig, rabbit, and rat. IdX+ anti-Ia.7 mAb were recently demonstrated to be structurally related by a high frequency expression of the V kappa 21E light chain subgroup. This raised the question of whether V region determinants of the IdX were related to V kappa 21E sequences or whether they were unique to hypervariable regions of Ia.7 binding antibodies. To clarify this question, the possible association between the expression of the public Id (IdX(s)Ia.7) and the presence of V kappa sequences (V kappa 21E and/or J kappa segment) was examined. The reactivity of the anti-Id reagents with a random panel of 28 myeloma products (each containing a light chain from one of the different V kappa 21 subgroups) was studied by assaying the ability of these mAb to inhibit the binding between the anti-Id and anti-Ia.7 mAb. This analysis demonstrates that what has previously been defined as IdX Ia.7 includes determinants shared by V kappa 21E and V kappa 21D light chain V regions. The structures recognized are expressed irrespective of the J kappa segment. In addition, this study demonstrates interspecies variation in immune responses to such V kappa 21E antigenic determinants. Additional IdX components are found on anti-Ia.7 mAb but not on other V kappa 21E or D proteins. Thus V region subgroup considerations have crucial implications for Id characterization. In addition, this work describes the first division of the V kappa 21 subgroup into component parts by a mAb.     

The human V kappa locus. Characterization of extended immunoglobulin gene regions by cosmid cloning

As part of the ongoing work in our laboratory on the structural organization of the human V kappa locus we screened cosmid libraries with V kappa gene probes and obtained numerous V kappa gene-containing cosmid clones. Several genomic regions of the V kappa locus were reconstructed from overlapping cosmid inserts and were extended by one step of chromosomal walking. The regions that are called Wa, Wb, Oa, Ob and Ob' comprise about 370 kb (10(3) bases) of DNA and contain 24 V kappa genes and pseudogenes. The V kappa genes belong to the three dominant subgroups (V kappa I, V kappa II, V kappa III) and are arranged to form mixed clusters with members of the different subgroups being intermingled with each other. The distances between the genes range from 1 to 15 kb. Three genes of the Wa and Wb regions that were sequenced turned out to be pseudogenes. Terminal parts of the regions Wa and Ob that do not contain V kappa genes of one of the known subgroups may represent extended spacer regions within the V kappa locus. Wa and Wb are duplicated regions located at different positions of the locus. Region Wb was found to comprise inversely repeated sections of at least 14 kb each that contain V kappa genes oriented in opposite polarity. This finding is consistent with inversion-deletion models of V-J joining; it also shows that the V kappa locus contains not only unique and duplicated but also triplicated parts. The data on the W and O regions are discussed together with those on the L regions and on other regions established in our laboratory. Although the picture of the human V kappa locus with, to date, about 70 different non-allelic V kappa genes is still incomplete, some general features with respect to the organization of the genes and the limited duplication of genomic regions have emerged.     

The Z family, a group of transposed human immunoglobulin V kappa genes

A group of highly homologous transposed human V kappa I genes, which we call the Z family, was characterized. To date four members, ZI-ZIV, comprising about 230 kb, have been analyzed on cosmid clones. The largest region (ZI) has a length of 85 kb. The Z regions show extensive homology to each other according to restriction maps and hybridization data. In each Z region a solitary V kappa I gene was found. No V kappa genes of other subgroups were detected by hybridization. The nucleotide sequence of the ZI gene revealed a non-processed V kappa I pseudogene. Hybridization experiments with DNAs from rodent/human cell hybrids and other experimental data indicate that some and possibly all members of the Z family lie outside of the kappa locus which is located on chromosome 2; they have been transposed to other chromosomes. Because of their separation from the J kappa C kappa gene segment, the Z genes can be classified as pseudogenes independent of their sequences. We postulate that the Z family arose by amplification event(s). The Z regions can also be regarded as a small family of very long repetitive sequences.     

Two V kappa germ-line genes related to the GAT idiotypic network (Ab1 and Ab3/Ab1') account for the major subfamilies of the mouse V kappa-1 variability subgroup

V kappa Ig germ-line genes have been isolated from recombinant clones prepared in separate libraries constructed from adult BALB/c liver DNA. Three different clones that strongly hybridized with a V kappa-GAT-specific probe were completely characterized and sequenced. All three genes exhibited common characteristic features in their sequences encompassing the 5' to the 3' noncoding region, with coding sections 95% homologous. A comparison with other V kappa genes shows that the size of the first intron is variability subgroup specific. Moreover, a direct correlation exists between the size of this intron and the entire length of the coding region. Nucleotide sequences of these genes were compared with V kappa chains expressed at the Ab1 and Ab1' levels of the GAT idiotypic network: Ag----Ab1----Ab2----Ab3 (Ab1'). K1A5 and K5.1 genes account for V kappa chains in Ab1 and Ab1' hybridomas, respectively. The high conservation of Ab1' sequences in light chain was also recently reported for the heavy chains, suggesting that immunization with Ab2 (anti-idiotypic) antibodies preferentially stimulates the direct expression of germ-line genes. K5.1 and K1A5 genes belong to the V kappa-1 variability subgroup and encode, without any amino acid substitution, V kappa domain in myeloma TEPC 105 and MOPC 467, which are V kappa-1A and V kappa-1C subgroup prototypes, respectively. These genes are extensively used in different mouse strains and in a number of antibodies of discrete specificities, such as anti-GAT, anti-DNP, anti-flagellin, anti-phosphorylcholine, anti-digoxin, anti-phenyloxazolone, and anti-DNA.     

Somatic DNA rearrangement generates functional rat immunoglobulin kappa chain genes: the J kappa gene cluster is longer in rat than in mouse

The kappa immunoglobulin (Ig) genes from rat kidney and from rat myeloma cells were cloned and analyzed. In kidney DNA one C kappa species is observed by Southern blotting and cloning in phage vectors; this gene most likely represents the embryonic configuration. In the IR52 myeloma DNA two C kappa species are observed: one in the same configuration seen in kidney and one which has undergone a rearrangement. This somatic rearrangement has brought the expressed V region to within 2.7 kb 5' of the C kappa coding region; the rearrangement site is within the J kappa cluster which we have mapped. The rat somatic Ig rearrangement, therefore, closely resembles that seen in mouse Ig genes. In the rat embryonic fragment two J kappa segments were mapped at 2 and 4.3 kb 5' from the C kappa coding region. Therefore, the rat J kappa cluster extends over about 2.3 kb, a region much longer than the 1.4 kb of the mouse and human J kappa clusters. In the region between C kappa and the expressed J kappa of IR52 myeloma DNA, and XbaI site present in the embryonic kappa gene has been lost. A somatic mutation has therefore occurred in the intervening sequence DNA approx. 0.7 kb 3' from the V/J recombination site. Southern blots of rat kidney DNA hybridized with different rat V kappa probes showed non-overlapping sets of bands which correspond to different subgroups, each composed of 8-10 closely related V kappa genes.     

Clonal characterization of the human IgG antibody repertoire to Haemophilus influenzae type b polysaccharide. IV. The less frequently expressed VL are heterogeneous

We previously demonstrated that the human anti-Haemophilus influenzae type b polysaccharide (Hib-PS) VL repertoire is dominated by a product of the V kappa II gene, A2, and that V kappa II-A2 anti-Hib-PS antibodies have little or no somatic mutation in VL. To further study this VL repertoire, we studied non-A2 anti-Hib-PS antibodies that were identified either serologically or by amino-terminal amino acid sequence analysis. Of 15 non-A2 anti-Hib-PS antibodies from 12 vaccinated adults, we found four V lambda, five V kappa I, one non-A2 V kappa II, four V kappa III, and one V kappa IV antibodies. As expected, all but two of these subjects also produced V kappa II-A2 antibodies. Interestingly, one of these subjects lacks the A2 gene in the germ line. However, both subjects who did not produce detectable V kappa II antibody did produce normal amounts of total anti-Hib-PS antibody after vaccination. Candidate V kappa genes for the non-A2 antibodies were identified by comparison of up to 60 VL amino acid residues, including CDR1 and CDR2, with all sequenced V kappa genes. V kappa I antibodies appear to be products of three newly sequenced V kappa I genes, O8, O18, and L11, that are reported here. The O8 and O18 genes encode identical amino acid sequences. The non-A2 V kappa II antibody is a likely product of the A1 or A17 genes, the V kappa III antibodies are likely products of the A27 gene, and the V kappa IV antibody is a product of the single V kappa IV gene, B3. Unlike V kappa II-A2 antibodies, the V kappa I, V kappa III, and V kappa IV antibodies differed by one to five CDR residues from the germ line product of the candidate genes, suggesting the presence of somatic mutations. Thus, anti-Hib-PS antibodies can be divided into two types, the most frequently observed A2 antibodies with little or no somatic mutation and non-A2 antibodies that likely contain somatic mutations.     

Of orphons and UHOs. Delimitation of the germline repertoire of human immunoglobulin kappa genes.

Two problems in defining the germline repertoire of immunoglobulin kappa genes were investigated. One concerns putative transposed V kappa genes (orphons), the other one weak hybridization signals which may or may not turn out to be V kappa genes (UHOs). It was shown by sequencing that the three V kappa genes Z2, Z3 and Z4 are very closely related to the Z1 and V118 genes and to two other genes which had been localized on chromosomes 1 and 22, i.e. outside the kappa locus on chromosome 2. It is therefore likely that also the Z2-Z4 genes are orphons and not part of the kappa locus. Two UHOs turned out not to contain V kappa-like structures. This together with previous results makes it likely that we have detected all germline V kappa genes with the available hybridization probes.     

Cloning of V region fragments from mouse liver DNA and localization of repetitive DNA sequences in the vicinity of immunoglobulin gene segments.

Two different kappa light chain genes have previously been isolated from one mouse myeloma. The V (variable, abbreviations in ref. 2) gene segments of the two genes were now used to identify their germline counterparts in EcoRI digests of mouse liver DNA. In addition two sets of related V gene segments were found which hybridize with either of the two DNA probes. Five of the V region fragments of one set were cloned in a lambda phage vector and partially characterized by restriction mapping and Southern blot hybridization. Repetitive DNA sequences were found on each of the five fragments as well as on other cloned immunoglobulin gene containing fragments. Cross-hybridization between some but not all of the regions containing repetitive DNA sequences was observed.     

Novel V genes encode virtually identical variable regions of six murine monoclonal anti-bromelain-treated red blood cell autoantibodies

The variable (V) region sequences of six immunoglobulin M (IgM, kappa) monoclonal autoantibodies that recognize bromelinized isologous red blood cells, obtained by fusions of peritoneal cells from NZB or CBA/J nonimmunized mice with BALB/c myeloma cells, were determined by direct mRNA sequencing. The V regions of the light chains (VL) are almost identical with one another, as are the V regions of the heavy chains (VH), which, however, differ by six linked-base substitutions, depending on the strain of mice producing the autoantibodies. Such variations may reflect allelic differences. The VH segments determined have no obvious correspondence to any VH genes identified so far. They may belong to the small VH group 4, where 73% homology, at the most, can be calculated at the protein level for codons 1 to 94. Alternatively, the VH regions may be members of a new group of VH sequences not previously found. The V kappa regions appear closely homologous to members of the V kappa-9 subgroup of myeloma proteins of unknown antigen-binding specificity. The joining segments, J kappa and JH, used by the autoantibodies investigated, originate from the J kappa 2 and JH1 germ-line gene segments, respectively. The nine base-long diversity segments, D, derive from one member of the germ-line D gene SP2 family.     

Two induced anti-Z-DNA monoclonal antibodies use VH gene segments related to those of anti-DNA autoantibodies

The cDNA for H and L chain V regions of two anti-Z-DNA mAb, Z22 and Z44, were cloned and sequenced. These are the first experimentally induced anti-nucleic acid antibody sequences available for comparison with autoantibody sequences. Z22 and Z44 are IgG2b and IgG2a antibodies from C57BL/6 mice. They recognize different facets of the Z-DNA structure. They both use VH10 family genes and share 95% sequence base sequence identity in the VH and leader sequences; however, they differ in the 5'-untranslated region of the VH mRNA, indicating they arise from different germline genes. Both use JH4 segments. They differ from each other very extensively in the CDR3 of both H and L chains. The most closely related H chains in the current GenBank/EMBL data base are two mouse IgG anti-DNA autoantibodies, one from an MRL-lpr/lpr mouse (MRL-DNA4) and one from an NZB/NZW mouse (BV04-01). Z22 and Z44 share 95% sequence identity with these antibodies in the VH segment. In addition, Z22 is identical to MRL-DNA4 at 91% of the positions in the 5'-untranslated region of the H chain mRNA. The two antibodies share 95% base sequence identity in the V kappa segment. The most closely related L chains, with 97 to 98% sequence identity, are the V kappa 10b germline gene for Z22 and the V kappa 10a germ line gene, which is associated with A/J anti-arsonate antibodies and BALB/c anti-ABO blood group substance antibodies, for Z44. Z22 and Z44 share several structural features (similarities in VH, JH, and V kappa) but differ very markedly in the L chain CDR1 and both H and L chain CDR3 sequences; these regions may determine the differences in their specific interactions with Z-DNA.     

The Unique Envelope Gene of the Subgroup J Avian Leukosis Virus Derives from ev/J Proviruses, a Novel Family of Avian Endogenous Viruses

A new subgroup of avian leukosis virus (ALV), designated subgroup J, was identified recently. Viruses of this subgroup do not cross-interfere with viruses of the avian A, B, C, D, and E subgroups, are not neutralized by antisera raised against the other virus subgroups, and have a broader host range than the A to E subgroups. Sequence comparisons reveal that while the subgroup J envelope gene includes some regions that are related to those found in env genes of the A to E subgroups, the majority of the subgroup J gene is composed of sequences either that are more similar to those of a member (E51) of the ancient endogenous avian virus (EAV) family of proviruses or that appear unique to subgroup J viruses. These data led to the suggestion that the ALV-J env gene might have arisen by multiple recombination events between one or more endogenous and exogenous viruses. We initiated studies to investigate the origin of the subgroup J envelope gene and in particular to determine the identity of endogenous sequences that may have contributed to its generation. Here we report the identification of a novel family of avian endogenous viruses that include env coding sequences that are over 95% identical to both the gp85 and gp37 coding regions of subgroup J viruses. We call these viruses the ev/J family. We also report the isolation of ev/J-encoded cDNAs, indicating that at least some members of this family are expressed. These data support the hypothesis that the subgroup J envelope gene was acquired by recombination with expressed endogenous sequences and are consistent with acquisition of this gene by only one recombination event.     

A rearranged DNA sequence possibly related to the translocation of immunoglobulin gene segments.

A 5.3 kb EcoRI fragment (T3, abbreviations in ref. 2) has been cloned from DNA of a kappa light chain producing mouse myeloma. The fragment hybridizes to the k' flanking sequences of the J1 gene segment but not to C gene sequences of kappa light chain DNA. Restriction nuclease mapping and partial nucleotide sequencing showed that the fragment consists of sequences from the 5' side of the J1 and form the 3' side of a V gene segment, which apparently had been linked in a genomic rearrangement process. These rearranged flanking sequences are not the flanking sequences of the V and J gene segments which had been joined to form the two kappa light chain genes of the myeloma. Fragments with the hybridization properties of T3 have been found also in two other kappa and one lambda chain producing myelomas. The linking of flanking sequences in the myeloma genome is discussed with respect to the mechanism of recombination between V and J gene segments.     

Comparison of variable region primary structures within an anti-fluorescein idiotype family

Previous reports described the properties of a high affinity (Ka = 1.7 X 10(10) M-1) prototype anti-fluorescein monoclonal antibody 4-4-20, an intermediate affinity (Ka = 3.7 X 10(7) M-1) prototype 9-40, and Ig members of the 9-40 idiotype family (comprised of 3-24, 5-14, 5-27, 10-25 and 12-40). Although the seven monoclonal anti-fluorescein antibodies expressed similar active site structural determinants (idiotypes) as determined serologically, each was characterized by different affinities for fluorescein and fine specificity binding patterns. Partial heavy (H)- and light (L)-chain N-terminal amino acid sequence analyses revealed all antibodies (except 5-27) were composed of highly homologous VHIII(C) and V kappa II subgroup genes, respectively. Antibody 5-27 utilized a VHIII(B) and a V kappa V subgroup genes and shared low V-region sequence homology with 4-4-20, 9-40 and the remaining 9-40 idiotype family. In addition, complete 4-4-20, VH- and VL-region primary structures were determined to better understand antibody-antigen interactions. Antibody 4-4-20 utilized a VHIII(C) subgroup VH-gene, a truncated Sp2 D gene segment, JH4, a V kappa II subgroup VL-gene, and J kappa 1. Antibody 4-4-20 VH and VL complementarity-determining regions contained many basic and aromatic amino acid residues capable of interaction with fluorescein. Results are discussed in terms of idiotypic and fluorescein-binding characteristics as well as antibody structural and functional diversity in the immune response.     

Immunoglobulin genes of different subgroups are interdigitated within the VK locus

The variable regions of immunoglobulins are encoded by multigene families which are rearranged during B-cell differentiation. These families were classified in groups and subgroups based on their amino acid sequences. Genes belonging to a distinct subgroup are believed to occur in the genome within clusters. We are investigating the organization of human variable region genes of the kappa type (VK genes, ref. 1) in the germline and found now for the first time that VK sequences of three of the four different subgroups are interdigitated within the VK locus. We present evidence for the interspersion of two VKIII genes and a VKII pseudogene within an array of five VKI genes. All eight VK sequences are arranged in the same orientation. An evolutionary model for the generation of this 'mixed cluster' is discussed.