Rabbit Ig kappa 1b6 gene structure

Previous studies employing Southern blot analyses have detected multiple kappa-homologous sequences within EcoRI-digested DNA isolated from kappa 1b6 homozygous rabbits and kappa 1b6 L chain secreting RMH H158 cell line. These results are very unexpected because the published partial protein sequence for the kappa 1b6 C region is incompatible with an EcoRI restriction endonuclease recognition sequence at the nucleotide level for this allotype. To determine their identity, the kappa-homologous sequences were isolated from DNA extracted from a kappa 1b6 L chain secreting RMH H158 cell line by molecular cloning. Structural analyses demonstrated these sequences to contain genetic information encoding the majority of the kappa 1b6 L chain gene locus. The protein sequence deduced from the kappa 1b6 C region gene was shown to differ from the published partial kappa 1b6 C region protein sequence at five amino acid positions. One of these differences results in a glycine to serine interchange that introduces an EcoRI restriction endonuclease recognition site within the kappa 1b6 C region gene. Subsequent genomic Southern blot analyses confirmed this structural assignment. Based on these data, the EcoRI-sensitive kappa-homologous fragments present within the genomes of the RMH H158 cell line and kappa 1b6 homozygous rabbits represent the nominal kappa 1 gene and not an alternative kappa isotype or kappa pseudogene. Rabbit Ig kappa 1 allelic nucleotide sequence homology comparisons have shown the isolated kappa 1b6 J-C gene locus to display common structural features previously identified in other kappa 1 alleles.     

Evolution of genes for allelic and isotypic forms of immunoglobulin kappa chains and of the genes for T-cell receptor beta chains in rabbits

New insights into the evolution of the families of genes encoding immunoglobulins and T-cell receptors of rabbits (Oryctolagus cuniculus) have come from molecular genetic studies. In contrast to human and mouse, rabbits were shown to have two genes for the constant region of immunoglobulin light chains (C kappa 1 and C kappa 2 isotypes) and complex allelic variants of K1 (allotypes). Although K1 allotype protein sequences differed at up to 41% of the amino acid positions, 3' untranslated, 5', and 3' flanking regions were conserved, and in the coding regions 78-80% of the codons with differences had replacement changes. Proportions of silent changes and changes in noncoding regions were comparable. Thus, in spite of their markedly different protein sequences, the K1b4, b5, and b9 allotypes appeared to be products of allelic genes. Molecular genetic analyses suggested that they may have undergone rapid divergence after an ancestral K2-like gene duplicated. Some rabbits were found to have two similar T-cell receptor C beta genes as do humans and many strains of mice, but others appeared to have three different C beta. In addition, we found allotypic forms of C beta. Some of the C beta allotypic differences occurred at positions where analogous C kappa allotypic differences were found. We also found V beta in mouse and human that were more similar to rabbit V beta than closely linked rabbit genes were to each other. This contrasts with rabbit immunoglobulin VH gene sequences that reflect concerted evolution. The data suggested that T-cell receptor V beta genes duplicated prior to mammalian radiation.     

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).     

Multiple sequences related to a constant-region kappa light chain gene in the rabbit genome

Four allelic genes control kappa light chain allotypes in the rabbit. Amino acid sequence studies have revealed an extensive divergence (22%--33%) in the alternative forms of the kappa constant region (b4, b5, b6 and b9). Furthermore, independent studies have shown that a rabbit could express a wrong allotype. To assess the hypothesis that b allotypes are encoded by duplicated genes with a polymorphic control mechanism, we have analyzed the DNAs of four different homozygous rabbits using the Southern blot hybridization technique, with a cloned b4 C kappa probe. DNAs of individual b4, b5, b6 and b9 rabbits were cleaved with Eco RI, Kpn I and Pst I restriction endonucleases. Comparative analysis of restriction patterns shows that all four rabbit DNAs contain multiple DNA fragments hybridizing with the probe under low- and high-stringency washing conditions. In addition, each restriction pattern is distinct, suggesting that the C kappa genes are organized differently in animals expressing different allotypes.     

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.     

Characterization and DNA sequence of the b6w2 allotype of the rabbit immunoglobulin kappa 1 light chain (b locus)

The b6w2 allotype of the constant region of the rabbit immunoglobulin kappa 1 (k1) light chain (b locus) was discovered in wild populations from northern Spain. At the serological level, the b6w2 allotype is characterized by the presentation of all b6-specific epitopes, while an allotypic determinant which is shared between the nominal b5 and b6 allotypes is lacking. The DNA fragment encoding the b6w2 allotype was amplified by means of the polymerase chain reaction, and sequenced directly by dideoxy-DNA-sequencing. When compared with the sequence of the nominal b6 allele, the b6w2 sequence differs at eleven nucleotide positions (96.5% similarity). This variation corresponds to amino acid replacements at 1) the three positions C-terminal to the peptidyl junction with the variable region (amino acid positions 109–111);2) the four positions N-terminal to the interdomain disulfide bond (167–170); and 3) two positions in the vicinity of the interchain disulfide bond (190 and 210). The nature and distribution of the observed nucleotide substitutions strongly suggest a possible role of the extra interdomain disulfide bond in the unusual evolutionary dynamics of the rabbit K1 light chain.The nucleotide sequence data reported in this paper have been submitted to the EMBL nucleotide sequence database and have been assigned the accession number Z48308     

Comparison of latent and nominal rabbit Ig VHa1 allotype cDNA sequences

The genetic basis for the expression of a latent VH allotype in the rabbit was investigated. VH region cDNA libraries were produced from spleen mRNA derived from a homozygous a2a2 rabbit expressing an induced latent VHa1 allotype and, for comparison, from a normal homozygus a1a1 rabbit expressing nominal VHa1 allotype. The deduced amino acid sequences of the nominal VHa1 cDNA were concordant with previously published VHa1 protein sequences. A comparison of two complete VH-DH-JH and six partial VHa1 sequences reveals highly conserved sequence within VH framework regions (FR) and considerable diversity in complementarity-determining regions and D region sequences. Two functional JH genes or alleles are evident. Amino acid sequencing of the N-terminal 15 residues of pooled affinity-purified latent VHa1 H chain showed complete sequence identity with the nominal VHa1 sequences. Possible latent VHa1-encoding cDNA clones, derived from the a2a2 rabbit, were selected by hybridization with oligonucleotide probes corresponding to the VHa1 allotype-associated segments of the first and third framework regions (FR1 and FR3). cDNA sequence analysis reveals that the 5' untranslated regions of nominal and latent VHa1 cDNA were virtually identical to each other and to previously reported sequences associated with VHa2 and VHa-negative genes. Moreover, some latent VHa1 genes encode FR1 segments that are essentially homologous to the corresponding segment of a nominal VHa1 allotype. In contrast, other putative latent genes display blocks of VHa1 sequence in either FR1 or FR3 that are flanked by blocks of sequence identical to other rabbit VH genes (i.e., VHa2 or VHa-negative). These composite sequences may be directly encoded by composite germ-line VH genes or may be the products of somatically generated recombination or gene conversion between genes encoding latent and nominal allotypes. The data do not support the hypothesis that latent genes are the result of extensive modification by somatic point mutation.     

Evolution of the rabbit immunoglobulin κ chain genes

We have analyzed the organization and the structure of rabbit chain genes encoding b allotypes in wild rabbits. The 1 gene of the b95 allotype was cloned and its structure determined. The J region is composed of five segments but only J2 appears to be functional and is identical to the J2 segment of the b4 allotype. The J region is highly conserved among the various b allotypes, whereas the constant region exon displays a high level of differences when compared with other allotypes (9%–30% of different amino acids). The b95 J region is closer to that of b4^var and the constant region to b5 allotype constant region. Alignment of nucleotide sequences revealed that the constant region exon displays segmental similarities with b4 and bas constant regions. The mosaic structure of b95 allotype gene indicates that complex allotypes of 1 genes may result from genetic exchanges of gene conversion between the different genes.The nucleotide sequence data reported in this paper have been submitted to the GenBank nucleotide database and have been assigned the accession number M22542. Address correspondence and offprint requests to: P.-A. Cazenave.     

The sequences of rabbit kappa light chains of b4 and b5 allotypes differ more in their constant regions than in their 3'' untranslated regions.

We report the sequence of a cDNA clone encoding the entire variable and constant regions of a rabbit kappa light chain of b5 allotype. The deduced amino acid sequence of the variable region (positions 1-95) is 86% homologous to that of a b4 light chain protein [BS-1) (1) but the b4 and b5 constant regions are only 74% homologous. Comparison of this DNA sequence to that of a cDNA clone encoding a b4 constant region shows that the kappa allotypes b4 and b5 have diverged significantly more in their coding region than in the 3' untranslated regions (86% vs 96% nucleotide sequence homologies). This implies either a function for the 3' untranslated region with evolutionary pressures to conserve or an accelerated divergence of the coding regions.     

Identification of rabbit genomic Ig-VH pseudogenes that could serve as donor sequences for latent allotype expression

Synthetic DNA oligomers specific for the VHa allotypes of rabbit Ig genes have been used to identify latent allotypic sequences in homozygous a1 and a2 rabbits. Two Ig VH pseudogenes containing latent a3 regions have been cloned from the genome of a homozygous a2 rabbit. Analysis of the regions associated with allotype expression indicates that these two pseudogenes contain VHa- sequences in framework region 1 (FR1) and VHa3 sequences in FR3. One gene has undergone an unusual rearrangement with a third VH gene, deleting their intervening sequences and recombining in FR3 with sequences 5' to the leader exon. Our results demonstrate the presence of latent VH sequences in the genomic DNA of normal rabbits and suggest that a mechanism such as gene conversion is responsible for expression of genetically-unexpected Ig VH genes.     

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.     

Surface immunoglobulin on rabbit lymphoid cells. III. Double expression and separate endocytosis of surface immunoglobulin allotypes on heterozygous lymphocytes demonstrated by immunoelectron microscopic labeling.

The expression of immunoglobulin b locus (k chain) allotypes on the surface of rabbit peripheral blood lymphocytes (PBL's) is examined using an indirect double immunoelectron microscopic labeling technique. Ferritin and whelk hemocyanin individually conjugated to allotypically specific IgG are used as ultrastructurally identifiable molecular markers. These indicators are coupled to lymphocyte surface immunoglobulin (Ig) allotypic determinants by an antiallotype antibody linkage. Human red blood cells, conjugated with IgG of a specific allotype and used as test cells, demonstrate the absolute specificity and high efficiency of the ultrastructural labeling technique. Specific labeling on rabbit PBL's shows that 65–75% of the cells are positive for surface Ig. Lymphocytes from homozygous donors (b4b4 or b6b6) are labeled specifically with only the appropriate allotypic labeling system. Thirty-three percent of the PBL's from heterozygous donors (b4b6) express both allotypes (allelic inclusion) on the cell surface; the remaining proportion of Ig-bearing cells have only one detectable allotype present (allelic exclusion). We conclude that approximately 50% of the Ig-bearing PBL's demonstrate allelic inclusion for the b locus allotypes. On allelically included heterozygous lymphocytes, both allotypic determinants can undergo specific endocytosis. Endocytosis of one allotype on heterozygous cells can be induced by stimulation with antiallotypic serum without affecting the surface appearance of the other allelic marker (separate endocytosis).     

Genomic DNA encoding rabbit T cell receptor beta-chains: isotypes and allotypes of C beta

We have discovered sequence differences in DNA encoding the first exon of rabbit T cell receptor beta-chains from unrelated rabbits that probably reflect allelic C beta 1 allotypes. Rabbit I was from a colony bred to maintain the K1-expression mutation Basilea, and rabbit II was from a colony bred to maintain the K1b9 allotype. Genomic DNA from rabbits I and II also exhibit restriction fragment length polymorphism of C beta on Southern blots. In addition, several different restriction enzyme digests of DNA from rabbit I give three bands, whereas DNA from rabbit II gives two when probed with C beta. An approximately 14-kb cloned genomic DNA fragment from rabbit I has two copies of C beta exon 1 and a 6-kb fragment has a third copy, suggesting that rabbit I has three different C beta genes. The DNA sequence of a germ-line genomic DNA fragment encoding the first exon of the beta-chain constant region from rabbit I also has an open reading frame encoding 140 amino acids immediately 5' of the C beta sequence. A corresponding sequence had previously been found in a cDNA clone from the second rabbit (rabbit II).     

The allotypic patchwork pattern of the rabbit IGKC1 allele b5wf: genic exchange or common ancestry?

 The protein sequences of different alleles of the rabbit immunoglobulin IGKC1 gene can differ at more than 40% of the amino acid positions. This exceptional degree of allelic divergence raises questions concerning the causal underlying mechanisms. We report the DNA sequence of the coding region of an allotype which is associated with the mitochondrial lineage A (Southwestern Spain). At the serological level, this b5wf allotype presents a patchwork of antigenic determinants which in domestic breeds are characteristic of the b4, b5, and b6 allotypes. The inferred protein sequence of the b5wf allotype was found to differ from that of the b4, b5, and b6 allotypes at 25, 10, and 15% of the amino acid positions, respectively. Sequence comparisons show that the b4-specific epitopes of the b5wf allotype are probably due to a shared ThrThrGlnThr motif at Kabat positions 153–156. Similarly, the shared b5-specific determinants should relate to the motifs 161ThrSerLys163 and/or 182LysSerAspGlu185. A monoclonal antibody binding epitope shared among the b5wf, b5, and b6 sequences appeared to be correlated with the presence of Asp190. Although there is evidence of interallelic genic exchange, sequence comparisons suggest that the apparent mosaic structure of the b5wf allotype is better explained by common ancestry and point mutation. Received: 22 June 1998 / Revised: 18 August 1998     

Expression of group b light chain allotypes in cottontail rabbits.

Group b allotypic determinants (b4, b5, b6, and b9) were detected on cottontail IgG by several assays including immunodiffusion, radioimmune binding, and inhibition of radiobinding. The results indicate that cottontail IgG possess some but not all of the subspecificities present on domestic rabbit IgG. Several cottontail rabbits exhibited three of the four possible allotypic markers. In these instances, however, only two populations of IgG molecules (i.e., phenogroups) could be detected, each bearing one, two, or three of the allotypes. Five separate and distinctive phenogroups were identified. The results suggest that the phenogroups represent products of multiple allelic genes for the constant region of cottontail rabbit kappa light chain.     

Interallelic and intergenic conversion events could induce differential evolution of the two rabbit immunoglobulin kappa light chain genes.

Contrary to the situation in humans or mice, where the constant region (C) of the Immunoglobulin (Ig) kappa (kappa) light chain is encoded by a single gene, the rabbit possesses two C kappa genes: C kappa 1 and C kappa 2. However, in domestic rabbits, the vast majority of the immunoglobulins have a light chain of the kappa 1 isotype, which is expressed under four complex, highly divergent allelic forms: b4, b5, b6 and b9. In previous papers, we have shown that this high level of divergence was due, at least partly, to conversion events of the kappa 1 by the kappa 2 locus. Up to now, little was known about the evolution of the C kappa 2 gene. Here, we report sequences of the C kappa 2 genes in three different haplotypes, and show that, in contrast to the situation in the kappa 1 locus, the three analysed C kappa 2 alleles are identical (or only differing by one silent substitution). This suggests that intergenic conversion, which introduced most of the divergence in the kappa 1 locus, is not reciprocal and is unidirectional from kappa 2 towards kappa 1. To explain the small number of silent substitutions in the C kappa 2 gene and its remarkable conservation, we propose an extended model of multigenic family evolution, which postulates that gene conversion events occur between linked genes as well as between alleles.     

Analyses of the splenic mRNA expressed by rabbits of different immunoglobulin kappa-light chain allotypes: conserved sequences in the 3' untranslated region and allotype-specific probes

The allelism of the structural genes for the complex rabbit b allotypes of immunoglobulin kappa-light chains has been questioned because of observations of unexpected phenotypic expression of "latent" allotypes. We find that the coding sequences of the b4 and b5 "alleles" are only 80% homologous for the last 60 nucleotides but there is a high degree of homology (96%) in the 3' untranslated region (3'DT). The high conservation of 3' DT region sequences enabled us to detect kappa-light chain mRNAs from rabbits of different genetic types (b4, b5, b9 and bbas) on northern blots and dot blots. We can distinguish mRNA encoding b9 and b5 allotypes on dot blots with b5 fragment-probes of known sequence and detect mRNA produced by unstimulated cultured splenic lymphocytes. Analyses of mRNA from cultured cells manipulated to enhance mRNA synthesis and production of unexpected or "latent" b allotypes can now be conducted.     

Molecular basis of the allelic inheritance of rabbit immunoglobulin VH allotypes: implications for the generation of antibody diversity

Rabbits are unique in that their immunoglobulin VH regions bear allotypic markers encoded by allelic genes. The presence of these markers on most serum immunoglobulins is difficult to explain, as the germline contains several hundred VH genes. We cloned VH genes from normal rabbits of the VHa allotypes a1, a2, and a3 and from a mutant a2 rabbit, Alicia, which expresses almost no a2 allotype. The D-proximal VH gene VH1 of normal rabbits encoded prototype a1, a2, or a3 allotype VH regions in a1, a2, or a3 rabbits, respectively; VH1 was shown to be preferentially utilized in leukemic rabbit B cells. This VH1 gene was deleted from the germline of the Alicia rabbit. These data suggest that the allelic inheritance of a allotypes results from preferential utilization of VH1 in VDJ rearrangements. We suggest that antibody diversity in rabbit primarily results from somatic hypermutation and gene conversion.     

Organization and polymorphism of rabbit immunoglobulin heavy chain genes

Germline genes encoding C mu, C gamma, C alpha, and C epsilon heavy chains of rabbit immunoglobulins have been isolated from recombinant phage and cosmid libraries. The JH, C mu, C gamma, and C epsilon are found in a 5'-JH-C mu-C gamma-C epsilon-3' orientation on a 90kb stretch of DNA. Four C alpha genes have been cloned and presumably reside 3' to the other CH genes. Southern blot analysis of rabbit sperm DNA indicates that the rabbit genome contains a single C gamma gene, one C mu gene, and as many as 10 C alpha genes. Restriction site polymorphism is found for C mu, C gamma, and C alpha genes of rabbits of various heavy chain haplotypes. The organization of the rabbit CH genes differs from that of mouse and human CH genes in that the rabbit has multiple C alpha genes, whereas mouse and human have one or two C alpha genes, respectively. In addition, mouse and human have four C gamma genes, whereas rabbit has only one C gamma gene. The presence of a single C gamma gene indicates that at least in the rabbits examined, no germline gene encoding latent or unexpected, C gamma allotypes is present. The genetic control of the expression of latent C gamma allotypes is discussed.     

Serologic and structural characterization of immunoglobulin chains secreted by rabbit-mouse hybridomas

Serologic and primary structural analyses of Ig chains secreted by several rabbit-mouse hybridomas have shown that these hybrid cells produce heavy (H) or light (L) chains identical to those isolated from rabbit sera. Two of the cell lines (7D2, 7D6) secreted rabbit H chains with a m.w. of 55,000 each of which expressed a full complement of variable and constant region allotypes (a3, d11, e15). These apparently normal rabbit H chains were secreted in a complex with a m.w. about 130,000, and serologic studies indicated that this complex contained a covalently linked mouse kappa L chain. Two other cell lines (4C1, 12F2) produced allotype b4 L chains with m.w. of 23,000 and 25,000, and a third (1D4P5) produced an allotype b5 L chain with a m.w. of 23,000. Serologic analyses indicated that the allotypes on these chains are equivalent to those expressed by normal rabbit Ig molecules. Partial amino acid sequence data obtained for the L chain products showed them to be typical of rabbit L chains, and to be significantly different from mouse L chains.