A cDNA sequence encoding a rabbit heavy chain variable region of the VHa2 allotype showing homologies with human heavy chain sequences

Characterization of the gene for the membrane and secretory form of the IgM heavy-chain constant region gene (C mu) of the cow (Bos taurus)

Our present understanding of the evolution of immunoglobulins is derived from a few vertebrate species. In order to obtain additional information on the development of the humoral immune system, we cloned and determined the nucleotide sequence of the bovine cDNA and genomic IgM heavy-chain constant region gene (C mu). The gene contains four constant region domain-encoding exons (CH1 to CH4) and two exons encoding the transmembrane domain (TM1, TM2), expressed in the membrane-bound receptor form of the IgM. The sequence of a cDNA clone encoding the 3' portion of the membrane form of the mu-chain revealed that the TM1 exon is spliced to the CH4 exon, as occurs in other mammals. Comparison of deduced amino acid sequence data from different vertebrates revealed a high similarity to sheep C mu (88%) and a lower degree of similarity to pig (62%), rat (62%), rabbit (58%) human (56%), hamster (55%), mouse (54%), chicken (28%) and horned shark (22%) C mu.

Rabbit IgH sequences in appendix germinal centers: VH diversification by gene conversion-like and hypermutation mechanisms

Although the rabbit IgH locus contains approximately 100 VH genes, the majority of B cells rearrange VH1. To produce a primary repertoire containing a sufficient number of protective antibodies, rearranged VH1-DH-JH sequences may diversify within rabbit B cells in an organ that functions like a chicken bursa, sheep ileal Peyer's patch, or both. It was suggested many years ago that the rabbit appendix could be a bursal equivalent. To reexamine this possibility, we analyzed rearranged heavy chain variable region sequences in B cells from light and dark zones of appendix germinal centers from 6-week-old rabbits. Our findings indicate that antibody diversification occurs by gene conversion-like and somatic hypermutation mechanisms in appendix germinal centers of young rabbits.

Generating the antibody repertoire in rabbit

We describe a model for B cell development and generation of the antibody repertoire in rabbits. In this model, B cells develop early in ontogeny, migrate to GALT, and undergo the first round of diversification by a somatic gene conversion-like process and by somatic mutation. We designate the repertoire developed by this mechanism as the primary antibody repertoire and it is this repertoire that makes the rabbit immunocompetent. We invoke GALT as the site for development of the primary repertoire because (1) surgical removal of GALT from neonatal rabbits results in highly immunocompromised animals, (2) in germfree rabbits essentially no lymphoid development occurs in GALT and the rabbits are immunoincompetent, and (3) the follicular development of rabbit GALT is highly similar to that of the chicken bursa, the site in which the primary antibody repertoire develops by somatic gene conversion in chicken. We suggest that once the primary antibody repertoire is formed, it is maintained by self-renewing CD5+ B cells and is expanded to a secondary antibody repertoire after the B cells encounter antigen.

Molecular analysis of recombination sites within the immunoglobulin heavy chain locus of the rabbit

Previously, recombinations involving genes of the rabbit immunoglobulin heavy chain locus have been documented serologically. These data indicated that the sites at which the causative recombination events occurred could have been anywhere from within the VH gene cluster up to, or 3' of, C mu. Since these sites could not be localized further by serological methods, we attempted to do this using techniques of molecular biology. DNAs from homozygous recombinant rabbits and from the appropriate non-recombinant parental haplotypes were characterized using Southern blots hybridized with a panel of probes derived from cloned regions of the rabbit immunoglobulin heavy chain gene complex. In all three recombinants, the site was downstream of the entire VH cluster and upstream of the JH cluster within an approximately 50 kilobase (kb) region containing expanses of repetitive-sequence DNA as well as DH genes. DH-specific probes further showed that in two of the recombinants, the recombination appears to have occurred within or 5' of DH1 and 5' of DH2 genes; in the third it occurred 3' of the DH2 genes but at least approximately 5 kb 5' of the JH region.

Preferential utilization of conserved immunoglobulin heavy chain variable gene segments during human fetal life

The ability to respond to specific antigens develops in a programmed fashion. Although the antibody repertoire in adults is presumably generated by stochastic combinatorial joining of rearranged heavy variable, diversity, and joining (VH-DH-JH) and light (VL-JL) chains, experimental evidence in the mouse has shown nonrandom utilization of variable gene segments during ontogeny and in response to specific antigens. In this study, we have performed sequence analysis of 104-day human fetal liver-derived, randomly isolated constant region C+ mu transcripts and demonstrate a consistent preference during fetal life for a small subset of three highly conserved VH3 family gene segments. In addition, the data show that this preferential gene segment utilization extends to the DHQ52 and the JH3 and JH4 loci. Sequence analysis of two "sterile" DH-JH transcripts suggests that transcriptional activation of the JH-proximal DHQ52 element may precede initiation of DH-JH rearrangement and influence fetal DH utilization. Sequence comparisons reveal striking nucleotide polymorphism in allelic gene segments which is poorly reflected in the peptide sequence, implying considerable evolutionary selection pressure. Although vertebrate species utilize a variety of strategies to generate their antibody repertoire, preferential utilization of VH3 elements is consistently found during early development. These data support the hypothesis that VH3 gene segments play an essential role in the development of the immune response.

Restricted utilization of VH and DH genes in leukemic rabbit B cells

Polyclonal B cell leukemias have been generated in 17- to 20-day old Emu-myc transgenic rabbits. To analyze the repertoire of VH genes utilized in early B cells, eight VDJ genes were cloned from these leukemic cells. The nucleotide sequences of these genes indicated that seven of the eight VDJ genes encoded prototype VHa1, VHa2 or VHa3 allotypes. The two VDJ genes encoding VHa1 molecules had VH segments with identical nucleotide sequences; similarly, the VH segments of the four VDJ genes encoding VHa2 molecules were identical, with the exception of a single base pair. These data suggest that a limited repertoire of VH genes were utilized in the generation of these VDJ genes. The DH segments of these genes were limited to two DH families, D1 and D2, indicating that a restricted repertoire of DH genes also had been utilized. Since these leukemic cells probably developed early in ontogeny, we suggest that this restricted utilization of VH and DH genes is representative of B cells from developmentally immature rabbits.

Mutation affecting the expression of immunoglobulin variable regions in the rabbit

We have found a variant of the allotype allele a2 in the rabbit, which presumably arose by mutation, that segregates as expected for an allele at the a locus. This allele is called "ali" and the corresponding rabbit strain is called "Alicia." In heterozygous animals (ali/a1 and ali/a3) the concentration of a2 molecules is lower by a factor of 1000 than in standard a2/a2 homozygotes. In homozygous ali/ali individuals the a2 concentration varies with age--i.e., very low in young rabbits and higher in older ones--but it never reaches normal levels. The low level of a2 is compensated by increased amounts of a-negative molecules. Southern blot analysis did not reveal any gross changes in the intron between JH and C mu (joining region of immunoglobulin heavy chain and constant region of immunoglobulin mu chain) or in the number of VH gene segments encoding a locus specificities. We suggest that the ali phenotype is due to a mutation in a control element.

Possible involvement of human D minigenes in the first complementarity-determining region of kappa light chains

The nucleotide sequences of the complementary strands of two human diversity region (D) minigenes, D2 and D4, show stretches of homology with two human variable region kappa chain (V kappa) genes, NG9 and HK101, respectively, in the first complementarity-determining region. In one V kappa sequence, the homology includes the 5' flanking region of D minigenes, which may comprise a recombinase recognition signal. It is thus conceivable that gene conversions involving D minigenes may contribute to V kappa diversity.

The structural and genetic basis for expression of normal and latent VHa allotypes of the rabbit

The immunoglobulin heavy chain variable regions of the rabbit are unusual in having genetically controlled, serologically detectable alternative forms, the VHa allotypes, as well as minor VH allotypes of the x, y and w groups. New insights into the probable structural basis for the VHa allotypes have come from re-examination of earlier protein sequence data in the light of newly deduced protein sequences derived from sequencing cloned cDNAs and genomic DNAs encoding VH regions. Here we review this sequence information, and define the allotype-correlated differences at seven positions in framework region 1 and 10 positions in framework region 3 that may lead to the serologically detectable allotypic determinants (allotopes). Most alternative amino acids at allotype-correlated positions can be derived from each other by single-base changes. Thus somatic mutations and/or gene conversion-like events must be considered along with other serological and genetic explanations for various reported observations of the production of latent VHa allotypes. The proximity of rabbit VH genes (approximately 3 kb apart) might enhance the likelihood of conversion-like events in both germline and somatic cells.

Analysis of the distribution of charged residues in the N-terminal region of signal sequences: implications for protein export in prokaryotic and eukaryotic cells

A statistical analysis of the distribution of charged residues in the N-terminal region of 39 prokaryotic and 134 eukaryotic signal sequences reveals a remarkable similarity between the two samples, both in terms of net charge and in terms of the position of charged residues within the N-terminal region, and suggests that the formyl group on Metf is not removed in prokaryotic signal sequences.

Partial characterization of T cell components related to defined VH (VT) markers

Certain antigen-binding surface molecules and factors of T cells possess serological determinants related to immunoglobulin (Ig)-heavy-chain-variable regions (VH). We obtained sufficient quantities (greater than 100 micrograms) of homogenous VH-related T-cell molecules (VTM) for biochemical studies from normal murine thymocytes and by growing large quantities of monoclonal T-cell leukemia lines expressing the determinants. A solid phase immune adsorbent prepared from the IgG fraction of rabbit anti-IgT serum was used to isolate VTM from formic acid-solubilized T cells. The VTM from murine thymocytes and T-cell lines had Mr of 65,000-68,000. The VTM from distinct cell lines differ by isoelectric focusing and resolution of tryptic peptides indicating clonal restriction. VTM lack conventional light- or heavy-chain-constant region determinants but cross-react with antisera directed against defined VHa allotypes and JH peptides. The detection of a cross-reaction with a synthetic JH peptide is consistent with recently published data identifying JH-related sequences in putative T-cell receptor genes. The amino acid compositions of the VTM were distinct from those of mammalian Ig, major histocompatibility complex (MHC) antigens, and viral glycoproteins, but significant similarities occur with Ig V regions or heavy chains of primitive vertebrates. The results indicate that the VH-bearing T-cell products are not classical Ig, but bear limited VH-cross-reactive determinants.

Rearranged immunoglobulin heavy chain variable region (VH) pseudogene that deletes the second complementarity-determining region

We have cloned two rearranged heavy chain variable region (VH) genes from the IgG-producing human cell line CESS. The VH gene, which is linked to the mu chain constant region (C mu) gene, has two deletions at residues 45-62 and 82A-90, the former of which corresponds closely to the second complementarity-determining region (CDR2). These results could indicate that translocation of CDR2 occurred and could give support to the argument that reassortment of the V mini-genes is involved in the generation of hypervariability during evolution. However, the rearranged pseudogene could have also arisen by fortuitous deletion. The other VH gene of CESS is an expressed form and is probably linked to the C gamma gene. The diversity region (D) segments used in these rearranged V genes are less than 38% homologous to known human germline D segments, indicating the presence of more unknown germline D segments.

Composite human VK genes and a model of their evolution

A phage library and two cosmid libraries were screened for human VK genes. Two recombinant phage and four cosmid clones were analysed in detail by restriction mapping and sequencing. Each one contained a single VKI sequence. Two of these six sequences are potentially functional VK genes and four are pseudogenes. Two pseudogenes derived from different genomic DNAs are highly homologous and are therefore either allelic variants or the products of a recent duplication event. Comparisons of our sequences with all fully determined human VKI amino acid and DNA sequences reveal identical segments which at first sight appear like minigenes. But these segments do not coincide with the subregions and some of the segments include both, framework and complementarity determining regions (FR, CDR, ref. 2). The findings may be explained by an evolutionary model generating composite genes by gene conversion and selection.

Coding strategy differences between constant and variable segments of immunoglobulin genes

Vertebrate immunoglobulin (Ig) mRNAs reveal intraspecies variation in codon usage distinct from that seen with yeast or bacterial genes. Comparison of all available Ig gene sequences shows that %(G + C) in codon position III is consistently lower in variable (V) segments than in constant (C) segments. I find an even lower %(G + C) in the hypervariable domains of V segments. This analysis suggests that base substitution in Ig genes correlates positively with local A + T content.

How signal sequences maintain cleavage specificity

The specificity of the signal sequence cleavage reaction has been postulated to reside in a signal peptidase active site that can bind only to particular (i, i + 2) pairs of amino acids. In this paper, we present further patterns of non-random amino acid utilization in a region around in vivo cleavage sites, and show that they can be interpreted in terms of selection acting to reduce the number of potential competing sites in the vicinity of the correct one.

Nucleotide sequence of a rabbit IgG heavy chain from the recombinant F-I haplotype

We report the sequence of a cDNA encoding a rabbit immunoglobulin gamma heavy chain of d12 and e14 allotypes with high homology to partial cDNA sequences from rabbits of d11 and e15 allotypes. The encoded rabbit protein shows homologies with human (68-70%) and mouse (60-63%) gamma chains. The nucleotide sequence homologies of the CH domains range from 76-84% with human and 64-76% with mouse sequences. Comparison of the portion of VH encoding amino acid positions 34-112 with a previously determined VH sequence of the same allotype shows high conservation of sequences in the second and third framework segments but more marked differences both in length and encoded amino acids of the second and third complementarity-determining regions (CDRs). We also found a high degree of homology with a human genomic V-region, VH26 (77%) and a remarkable similarity between rabbit and human second CDR sequences and human genomic D minigenes. These results provide additional evidence that D minigene sequences share information with the CDR2 portion of VH regions.

Amino acid sequence of the Fv region of a human monoclonal IgM (protein WEA) with antibody activity against 3,4-pyruvylated galactose in Klebsiella polysaccharides K30 and K33

We have determined the amino acid sequence of the Fv [variable heavy (VH) and variable light (VL)] region of a human monoclonal IgM-kappa with antibody activity against 3,4-pyruvylated galactose, isolated from the plasma of patient WEA with Waldenström macroglobulinemia. The VH region has 114 residues, belongs to subgroup III, and has a very short third complementarity-determining region (CDR3), probably due to a small D segment/or an unusual D-J rearrangement (D, diversity; J, joining). The VL region has 108 residues and belongs to subgroup V kappa I. Compared to other members of the human VHIII and V kappa I families, WEA Fv does not appear to have significant differences within the framework residues but has unique CDRs that might be responsible for the particular antibody activity. Another IgM-kappa (GAL), which has an as-yet-undetermined antibody activity, shares a striking homology in V kappa with WEA, including an identical CDR1.

Complete sequence of a chicken lambda light chain immunoglobulin derived from the nucleotide sequence of its mRNA

Recombinant cDNA plasmids have been constructed from chicken spleen poly(A)-containing RNA. Two clones have been selected and provide the sequence determination of a chicken lambda immunoglobulin light chain: they include the complete variable, constant, and 3' untranslated regions of the chicken lambda light chain mRNA and part of the leader sequence. Comparison of the chicken light chain constant region with both human and mouse lambda constant sequences indicates 61% homology at the amino acid level. Unexpectedly, the chicken variable sequence is 53-63% homologous to human variable sequences when it is compared to the various lambda subgroups and only 42% homologous to the mouse V lambda 1 sequence. The degree of homology between the variable regions of these three species does not easily correlate with their phylogenetic relationship.

cDNA clone encoding a complete rabbit immunoglobulin kappa light chain of b4 allotype

We have cloned a cDNA encoding a kappa light chain of the b4 allotype. The clone, pB4D5, was derived from the allotype-specific mRNA of a rabbit-mouse hybridoma 12F2, which secretes a monoclonal rabbit b4 kappa chain. Nucleotide sequence analysis of the entire pB4D5 insert reveals complete variable (V) and constant (C) regions and portions of the signal peptide and 3' untranslated region. The translated pB4D5 region amino acid sequence matches the NH2-terminal sequence of the kappa chain secreted by 12F2 and is similar, though not identical, to several other b4 kappa sequences. A V region-specific probe isolated from pB4D5 hybridizes to more than 25 bands on a genomic Southern blot of b4 rabbit DNA and yields a similar pattern with DNA from other allotypes. Sequence comparisons between pB4D5, a cloned germ-line precursor of the pB4D5 joining (J) region, and published b4 amino acid sequences reveal a peculiar feature of rabbit kappa V-J recombination in which this system resembles mouse and human heavy chain recombination more than any known kappa system.