The rabbit kappa 1 b5 immunoglobulin gene: another J region gene cluster with only one functional J gene segment?

Our previous analysis of an immunoglobulin gene encoding the rabbit kappa chain of b4 allotype revealed that of the five J-like sequences in the J kappa cluster of this gene, only one, J2, appeared to be functional. This unusual ratio of J pseudogenes to functional J genes is unique among all J clusters of light and heavy chain genes of all species examined to date, including the cluster from the rabbit kappa 2 isotype, and must have consequences for diversity generation of b4 immunoglobulins. The fact that the only two known b5 J kappa sequences are different from the functional J2 of the b4 allotype prompted investigation of the b5 J kappa cluster to determine whether it resembled the b4 cluster, or the more typical mouse or human J kappa clusters. Our analysis of the b5 gene reveals a J kappa cluster strikingly similar to that of b4; apparent defects occur in all J sequences except J2. Although J2 is apparently functional, it differs from the J2 of the b4 locus by four nucleotide and three amino acid substitutions. The unusually high degree of sequence similarity previously observed between the b4 and b5 loci in the noncoding (vs the coding) regions extends through the newly sequenced DNA segment and remains an enigma.     

Novel human light chain V kappa segment: serologic and structural analyses of the kappa III-like Bence Jones protein and IgG kappa light chain REE

Immunochemical and sequence analyses of kappa light chain REE (Bence Jones protein REE and the light chain isolated from IgG kappa myeloma protein REE) revealed antigenic and structural features not previously described for human kappa-chains. Although closely related to proteins of the V kappa III subgroup, light chain REE is readily distinguished from light chains classified serologically as members of the kappa IIIa or kappa IIIb sub-subgroups. Light chains REE (Bence Jones protein REE and light chain REE) are identical in sequence and differ from kappa III proteins by at least 10 uncommon amino acid substitutions in the first three framework regions. Further, kappa-chain REE is unique by virtue of a four-residue deletion in the third complementarity-determining region. The deletion encompasses the three carboxyl-terminal residues in the V kappa-encoded segment and the first residue at the site of V-J recombination. Urine specimens from patient REE also contained a light chain fragment that lacked the first (amino-terminal) 85 residues of the native light chain but otherwise was identical in sequence to the light chain REE. The extensive amino acid differences and unique length of the V kappa segment in light chain REE indicate that this kappa-chain is the product of an unusual V kappa III gene or, alternatively, represents a rarely expressed and novel human V kappa gene.     

The structural repertoire of the human V kappa domain.

In humans, the gene for the V kappa domain is produced by the recombination of one of 40 functional V kappa segments and one of five functional J kappa segments. We have analysed the sequences of these germline segments and of 736 rearranged V kappa genes to determine the repertoire of main chain conformations, or canonical structures, they encode. Over 96% of the sequences correspond to one of four canonical structures for the first antigen binding loop (L1) and one canonical structure for the second antigen binding loop (L2). Junctional diversity produces some variation in the length of the third antigen binding loop (L3) and in the identity of residues at the V kappa-J kappa join. However, this is limited and 70% of the rearranged sequences correspond to one of three known canonical structures for the L3 region. Furthermore, we show that the canonical structures selected during the primary response are conserved during affinity maturation: the key residues that determine the conformations of the antigen binding loops are unmutated or undergo conservative mutation. The implications of these results for immune recognition are discussed.     

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.     

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.     

Utilization of V kappa families and V kappa exons. Implications for the available B cell repertoire

A molecular cloning approach was used to determine the relative utilization of 2 individual V kappa 21 genes, 13 V kappa gene families, and the 4 functional J kappa gene segments among splenic B cells of nonimmunized BALB/c mice. Based on the observed frequency of individual V kappa gene expression, we estimate that the mouse genome encodes 150 to 180 functional V kappa genes, and we suggest that most functional V kappa exons are expressed at comparable frequencies in the preimmune antibody repertoire. In contrast, clear differences in J kappa segment utilization were observed, J kappa 4 being consistently underrepresented with respect to the other J kappa segments.     

Structural analysis of a rabbit immunoglobulin kappa 2 J-C locus reveals multiple deletions.

We previously reported that domestic rabbits harbor at least two DNA sequences that hybridize strongly to immunoglobulin kappa C region probes in Southern blots. One of these was cloned from a domestic b4 rabbit and identified as the gene for the nominal b4 allotype kappa chain which is expressed at high levels. We now have cloned (from a b4 rabbit) the other homologous sequence and find that it encodes a kappa chain nearly identical to the kappa 2 chain of "bas" rabbits, which is not normally expressed at detectable levels in domestic rabbits. Sequence analysis of this kappa 2 chain reveals a J kappa -C kappa locus with no obvious coding sequence defects that could explain its low expression. However, several base changes in a putative enhancer region as well as deletions (totalling about 1.5 kb) in the J-C intron might be related to low expression. The comparison between these two kappa genes raises questions about the selective pressures operating during the evolution of this gene system.     

Ig V kappa family repertoire of plasma cells derived from autoimmune MRL mice.

V kappa gene family usage was determined in the resident in vivo-activated plasma cells of individual diseased MRL mice by using in situ hybridization. In this way, the entire autoimmune repertoire could be analyzed. Autoantibody levels and extent of glomerulonephritis were also measured, so that the severity of disease could be assessed. It was found that V kappa expression was highly variable from mouse to mouse. Some animals displayed a V kappa family repertoire similar to mitogen-stimulated cells and consistent with the size of the families. These animals tended to have lower disease indices. Other animals, which had higher disease indices, displayed considerable over- or underutilization of individual V kappa families. However, no particular V kappa families were repeatedly biased in their expression, as was found at the VH level with J558. Importantly, in the 10% of animals that expressed VH J558 exclusively, four or more V kappa families were expressed and multiple antiself specificities were produced. The data are most consistent with a number of J558 genes being expanded in a variety of self-specificities. However, because only VH J558 is expressed in these sicker animals, nonspecific polyclonal activation is highly unlikely. These results underscore the continuing evolution of the autoimmune repertoire, with considerable diversity at early stages followed by a highly selected repertoire in which a potential role for nonspecific polyclonal activation is virtually excluded.     

The V-J-intergenic region of the human kappa locus

The 23-kb region between the V kappa and J kappa gene clusters was investigated in some detail. The region was found to be free of V kappa genes or V kappa gene-like structures, confirming the previous supposition that the V kappa gene B3 is the J kappa proximal V kappa gene. The B3-J kappa distance of 23 kb was found to be the same in the DNAs of several individuals. A HindIII restriction fragment length polymorphism was detected within this region. A sequence of 533 bp located approximately in the middle of the region has a highly homologous counterpart (called homox) on another chromosome. The two sequences are 96% identical. Possible mechanisms for the generation of such a duplicate are discussed.     

Neonatal and adult primary B cells use the same germ-line VH and V kappa genes in their (T,G)-A-L-specific repertoire

Although there is a nonrandom usage of VH gene families by primary B cells early in ontogeny, at issue is whether the preferential rearrangement of 3' germ-line VH genes, e.g., VH7183 and VHQ52 family genes, influences the neonatal B cell repertoire that can be expressed in response to Ag. In order to address this issue, and to determine whether neonatal B cells can use the same germ-line VH and V kappa genes as adult B cells in their primary response, we have analyzed at the molecular level the neonatal antibody response to (T,G)-A-L and compared it with the adult primary response. Among the TGB5 Id+, GT+ antibodies, which dominate the neonatal response to (T,G)-A-L, two VH gene families were used: J558 (high frequency) and 36-60 (low frequency). The majority of Id+ neonatal hybridomas used the same germ-line VH gene (H10, from the VHJ558 family), but with enormous diversity in the D region, and one of two germ-line V kappa 1 genes (V kappa 1A, V kappa 1C). These are the same germ-line V-genes used by most primary adult Id+ hybridomas, and the frequency of expression of this germ-line V-gene combination appears equivalent in the neonatal and adult primary repertoires. Therefore, it is clear from this study that as early as day 5, neonatal B cells can use the same germ-line V-genes as adult primary B cells in their Ag-specific repertoire.     

Partial amino acid sequence of a rabbit immunoglobulin light chain of allotype b5

The amino acid sequence of a rabbit immunoglobulin light chain of allotype b5 has been nearly completed. A comparison of its structure with that of light chains of allotypes b4, b6, and b9 confirms that the constant regions of these various kappa chains differ by 20-35%. The substitutions are clustered in parts of the second half of the chain, and the b5 form bears more resemblance to the b6 chain than to any other, in good agreement with previous serological data. The analysis of the variable region reveals the existence of certain allotype-associated residues which have also been reported in other b5 chains, but not in proteins of the other allotypes. An examination of the rabbit light chain sequences between positions 96 and 107 suggests that this portion of the chain may be encoded separately by a joining "J" DNA segment, as has been described previously for murine and human immunoglobulins. In the rabbit, however, these J kappa regions appear to differ from one allotype to another. Together with the extensive variations of the constant regions, these data suggest that the rabbit kappa gene organization more closely resembles the murine gamma system (four different C gamma genes each flanked by its J segment) than the murine kappa system (a single C kappa gene).     

Characterization of allelic V kappa-1 region genes in inbred strains of mice

Germ line genes encoding mouse Ig kappa-chains belonging to the V kappa-1 group have been isolated from BALB/c, NZB, and CE, three inbred strains of differing kappa haplotype. The V kappa-1A and V kappa-1C germ line genes isolated from BALB/c (Ig kappa c) were identical to those previously described. These are the two major V kappa-1 germ line genes in BALB/c and together account for 40 of the 53 expressed V kappa-1 sequences that have been reported to date. Allelic differences in a single germ line variable region gene (V kappa-1A) in different strains of mice explain the differences in L chain IEF patterns previously associated with the Ig kappa-Ef2 locus. The rearranged kappa-gene expressed in the BALB/c myeloma MOPC-460 has been isolated and found to represent a V kappa-1A somatic variant differing by three nucleotides from the germ line V kappa-1A gene. Germ line genes isolated from NZB (Ig kappa b) and CE (Ig kappa f) show greater than 95% identity with the BALB/c genes over the 1700 nucleotides compared. Comparison by region indicated the greatest conservation of sequence occurs in and around the leader exon followed by the V-region exon. The NZB gene encodes the amino acid sequence found in the myeloma PC-2205, previously designated V kappa-1B. The V kappa-1 gene isolated from CE is likely an allele of the BALB/c V kappa-1C gene as the two share greater than 96% identity over 1700 nucleotides. The CE gene has been designated V kappa-1Cf. Ancient remnants of LINE-1 repetitive elements were detected approximately 400 bp downstream of all of the V kappa-1 genes. These possess greater homology with repetitive elements found near other kappa genes than they do with the native L1Md sequence.     

Ig V region gene expression in small lymphocytic lymphoma with little or no somatic hypermutation

Using the polymerase chain reaction we examined for specific Ig kappa-L chain V region gene (V kappa gene) rearrangement in small lymphocytic non-Hodgkin's lymphomas that express Ig bearing a major kappa-L chain associated cross-reactive Id, designated 17.109. Previously, we identified the 17.109-cross-reactive Id in chronic lymphocytic leukemia as a serologic marker for expression of a highly conserved V kappa gene, designated Humkv325. Using sense-strand oligonucleotides specific for the 5'-end of this V kappa gene and antisense oligonucleotide specific for a J kappa region consensus sequence, we could amplify specifically Humkv325 when juxtaposed with J kappa through Ig gene rearrangement. This allowed us to amplify rearranged V kappa genes from DNA isolated from minute amounts of lymphoma biopsy material for molecular analyses. Our studies demonstrate that 17.109-reactive SL NHL, with or without associated CLL, rearrange, and presumably express, Humkv325 without substantial somatic diversification. Our data suggest that malignant B cells in SL NHL, in contrast to NHL of follicular center cell origin, may express immunoglobulin variable region genes with little or no somatic hypermutation.     

The limited diversity of the mouse gamma-chains anti-GAT repertoire does not seem to be noticeably amplified upon class switch

NH2-terminal sections of H and L chains isolated from five monoclonal anti-GAT antibodies derived from BALB/c mice have been sequenced upon to residue 43. Four among these five antibodies, sharing similar public idiotypic determinants, possess extremely conserved sequences, both for the H, which is apparented to the VH II type, and the L chains, which belong to the V kappa I subgroup. VH sequences are identical up to residue 43 and contain the common sequences (residues 1 to 32) defined for the H chains derived from the DBA/2 IgM anti-GAT monoclonal antibodies. Light chains are also remarkably conserved, a rather unusual situation for kappa-chains. The fifth antibody that expresses only part of the public idiotypic determinants contains very distinctive H and L chains. Its heavy chains are close to the VH I subgroup, whereas its kappa-chains permit definition of a new V kappa subgroup. The repertoire appears to be highly conserved between BALB/c and DBA/2 mice, and does not seem larger in IgG than in IgM antibodies. This latter observation does not speak in favor of a switch-linked amplification of diversity.     

Genetics and primary structure of V kappa gene segments encoding antibody to streptococcal group A carbohydrate. Comparison of V kappa gene structure with idiotope expression

Two gene segments, V kappa-25-39 and V kappa-25-47, that encode antibody to streptococcal group A carbohydrate in A/J mice were found to be more than 95% homologous in nucleotide sequence in both coding and noncoding regions. It was previously shown that V kappa-25-39 encodes immunoglobulins that express the IdX and IdI-1 idiotopes, whereas V kappa-25-47 encodes IdX+, and IdI-1- immunoglobulins. V kappa gene segments that were clearly allelic to V kappa-25-47 are used to encode IdX+, IdI-1- anti-group A carbohydrate antibodies by C.B20 mice and likely by C57BL/6 mice. Murine strains that are deficient in IdI-1 idiotope expression were investigated by Southern blotting with a 5' probe from V kappa-25-39. Two IdI-1-deficient strains, CE/J and C58/J, had a grossly altered V kappa gene segment structure compared with the A/J prototype. In contrast, the IdI-1-deficient strain, C57BL/6, was indistinguishable from A/J with the 5'V kappa-25-39 probe, indicating that more subtle genetic changes account for the loss of IdI-1 expression in C57BL/6 mice. The evolution of V kappa-25-39 and V kappa-25-47 gene segments was deduced by comparison with the homologous V kappa 24B gene segment of Mus pahari. V kappa-25-39 and V kappa-25-47 likely have recently duplicated once in A/J and related strains of laboratory mice and may have duplicated again in CE/J mice. Thus, individual members of the V kappa 24 gene family, to which V kappa-25-39 and V kappa-25-47 belong, are preserved while the number of gene copies expands or contracts. This fact is strong evidence that evolutionary forces have maintained the V kappa 24 gene family, all of which encode antibody specific for carbohydrate found in bacterial pathogens.     

V(D)J recombination: site-specific cleavage and repair

V(D)J recombination is a site-specific gene rearrangement process that contributes to the diversity of antigen receptor repertoires. Two lymphoid-specific proteins, RAG1 and RAG2, initiate this process at two recombination signal sequences. Due to the recent development of an in vitro assay for V(D)J cleavage, the mechanism of cleavage has been elucidated clearly. The RAG complex recognizes a recombination signal sequence, makes a nick at the border between signal and coding sequence, and carries out a transesterification reaction, resulting in the production of a hairpin structure at the coding sequence and DNA double-strand breaks at the signal ends. RAG1 possesses the active site of the V(D)J recombinase although RAG2 is essential for signal binding and cleavage. After DNA cleavage by the RAG complex, the broken DNA ends are rejoined by the coordinated action of DNA double-strand break repair proteins as well as the RAG complex. The junctional variability resulting from imprecise joining of the coding sequences contributes additional diversity to the antigen receptors.     

Comparison of V kappa gene family expression in adult and fetal B cells

The functional B cell repertoires from adult and fetal mice were compared by examining V kappa gene family expression in individual cells. In addition, because little is known about the relative use of the various V kappa gene families in an immune response, adult B cells from several different strains of mice were analyzed. This was accomplished by stimulating B cells with the polyclonal activator, LPS. Activated cells were then analyzed for V kappa gene family expression at the single cell level by in situ hybridization using radiolabeled V kappa gene probes. It was found that all V kappa gene families tested were represented in the LPS-induced adult repertoire with V kappa 1, V kappa 4,5 and V kappa 19 being expressed to the largest degree in all strains tested. The LPS-induced adult V kappa gene family repertoire was then compared to the fetal repertoire and some differences were observed. In particular, a lower proportion of fetal B cells expressed V kappa 1 and a higher proportion of fetal B cells expressed V kappa 4,5 and V kappa 10. Importantly, compared with the adult response there was no evidence in the fetal response for an increased expression of V kappa 21, the family that maps closest to J kappa,C kappa. This is in contrast to what has been shown previously with H chain V region exons in which there was a clear preference for the VH gene families that mapped closest to DH.     

Recognition sequence of a highly conserved DNA binding protein RBP-J kappa.

DNA binding specificity of the RBP-J kappa protein was extensively examined. The mouse RBP-J kappa protein was originally isolated as a nuclear protein binding to the J kappa type V(D)J recombination signal sequence which consisted of the conserved heptamer (CACTGTG) and nonamer (GGTTTTTGT) sequences separated by a 23-base pair spacer. Electrophoretic mobility shift assay using DNA probes with mutations in various parts of the J kappa recombination signal sequence showed that the RBP-J kappa protein recognized the sequence outside the recombination signal in addition to the heptamer but did not recognize the nonamer sequence and the spacer length at all. Database search identified the best naturally occurring binding motif (CACTGTGGGAACGG) for the RBP-J kappa protein in the promoter region of the m8 gene in the Enhancer of split gene cluster of Drosophila. The binding assay with a series of m8 motif mutants indicated that the protein recognized mostly the GTGGGAA sequence and also interacted weakly with ACT and CG sequences flanking this hepta-nucleotide. Oligonucleotides binding to the RBP-J kappa protein were enriched from a pool of synthetic oligonucleotides containing 20-base random sequences by the repeated electrophoretic mobility shift assay. The enriched oligomer shared a common sequence of CGTGGGAA. All these data indicate that the RBP-J kappa protein recognizes a unique core sequence of CGTGGGAA and does not bind to the V(D)J recombination signal without the flanking sequence.     

Mouse V lambda x gene sequence generates no junctional diversity and is conserved in mammalian species

The lambda x, a new mouse Ig lambda L chain, is produced by rearrangement of the V lambda x, J lambda 2, and C lambda 2 gene segments. The V lambda x amino acid sequence is as divergent to other V lambda as to Vk gene sequences. Additionally, its third hypervariable region (CDR3) is four amino acids longer than those of all other variable gene segments of murine L chain. We have cloned and sequenced the germ-line V lambda x gene and found that the unexpected CDR3 length is encoded by the V lambda x gene. Junctional diversity is prevented by a TAA termination codon localized at the V lambda x 3' extremity. Moreover, we show a striking conservation of the V lambda x sequence in various mammalian species. Portions of the V lambda x sequence display more than 70% of nucleotide sequence identity with rabbit and human variable regions. These results suggest that V lambda x predated the divergence of mammalian species.