Localization, analysis and evolution of transposed human immunoglobulin V kappa genes

The localization of V kappa gene regions to chromosome 2, on which the kappa locus is located, and to other chromosomes is described. The V kappa genes that have been transposed to other chromosomes are called orphons. The finding of two new V kappa genes on chromosome 22 is reported. A V kappa II gene of this region and two V kappa I genes of the Chr1 and the cos 118 regions were sequenced. The two V kappa I orphon sequences and two others that had been determined previously were 97.5% identical, indicating that they may have evolved from a common ancestor by amplification. A model of the evolution of the human V kappa orphons is discussed.     

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.     

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.     

Genes encoding Xenopus laevis Ig L chains. Implications for the evolution of kappa and lambda chains.

Xenopus laevis Ig contain two distinct types of L chains, designated rho or L1 and sigma or L2. We have analyzed Xenopus genomic DNA by Southern blotting with cDNA probes specific for L1 V and C regions. Many fragments hybridized to the V probe, but only one or two fragments hybridized to the C probe. Corresponding C, J, and V gene segments were identified on clones isolated from a genomic library prepared from the same DNA. One clone contains a C gene segment separated from a J gene segment by an intron of 3.4 kb. The J and C gene segments are nearly identical in sequence to cDNA clones analyzed previously. The C segment is somewhat more similar and the J segment considerably more similar in sequence to the corresponding segments of mammalian kappa chains than to those of mammalian lambda chains. Upstream of the J segment is a typical recombination signal sequence with a spacer of 23 bp, as in J kappa. A second clone from the library contains four V gene segments, separated by 2.1 to 3.6 kb. Two of these, V1 and V3, have the expected structural and regulatory features of V genes, and are very similar in sequence to each other and to mammalian V kappa. A third gene segment, V2, resembles V1 and V3 in its coding region and nearby 5'-flanking region, but diverges in sequence 5' to position -95 with loss of the octamer promoter element. The fourth V-like segment is similar to the others at the 3'-end, but upstream of codon 64 bears no resemblance in sequence to any Ig V region. All four V segments have typical recombination signal sequences with 12-bp spacers at their 3'-ends, as in V kappa. Taken together, the data suggest that Xenopus L1 L chain genes are members of the kappa gene family.     

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.     

Three transposed elements in the intron of a human VK immunoglobulin gene.

Two gene segments coding for the variable region of human immunoglobulin light chains of the kappa type (VK genes, ref. 2) were found to have unusual structures. The two genes which are called A6 and A22 are located in duplicated gene clusters. Their restriction maps are very similar. About 4 kb of the A22 gene region were sequenced. It turned out that the intron contains an insert with the characteristics of a transposed element. The inserted DNA of 1.2 kb length contains imperfect direct and inverted repeats at its ends; at the insertion site a duplication of five nucleotides was found. Within the inserted DNA one copy each of an Alu element and of the simple sequence motif (T-G)17 were identified. Also these two repetitive sequences are themselves flanked by short direct repeats. The major inserted DNA has no significant homology to published human nucleic acid sequences. The whole structure is interpreted best by assuming a sequential insertion of the three elements. The coding region of the VK gene itself has several mutations which by themselves would render it a pseudogene; we assume that the insertion event(s) occurred prior to the mutations. According to mapping and hybridization data A6 is very similar to A22.     

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.     

The human immunoglobulin κ locus on yeast artificial chromosomes (YACs)

The human immunoglobulin κ locus is a duplicated structure. Contigs of 600 kb with 40 Vκ genes and 440 kb with 36 Vκ genes had been established for the Cκ proximal (p) and distal (d) copies, respectively. In addition the human genome contains more than 24 dispersed Vκ genes, called orphons. In the present study, 22 κ-locus derived YACs were analyzed in detail, while 30 orphon-derived YACs were characterized only with respect to some parameters. The κ-locus derived YACs allowed three gaps to be closed which previously could not be bridged by cosmid and phage λ cloning. At the 5′ side, the p contig was extended in the YACs by 50 kb and the d contig by 16 kb. At the 3′side, the d contig was extended by 11.5 kb. Beyond the 3′ end of the d contig a new Vκ gene was found, which is located, according to pulsed field gel electrophoresis (PFGE) experiments, at a distance of at least 140 kb from the last Vκ gene of the contig. This Vκ gene, which was termed Z0, occurred on three YACs, albeit at distances smaller than 140 kb; this was probably due to deletions in the YACs caused by abundant repetitive sequences at the borders of the locus. According to its sequence and to the restriction map of its surroundings, Z0 is an orphon gene of the so-called Z family, of which several members are known to be dispersed throughout the genome. The possibility that Z0 has been the parent of the other Z orphons is discussed.     

Characterization of new mouse V kappa groups

A lambda gt10 BXSB spleen cDNA library was screened with a DNA probe for the C kappa region. Forty individual C kappa+ phages were tested for hybridization with DNA probes representing 11 V kappa region groups. Of the phage inserts large enough to contain V kappa region sequences, 3 were negative for hybridization with all 11 V kappa region probes. The inserts from those three were subcloned, sequenced, and compared with V kappa region sequences in the gene bank. One was identical to 87.92.6 for the region sequenced (a member of V kappa RF). The second showed 93.8% sequence similarity with AN04 and called V kappa 32. The third called V kappa 33 showed 76% sequence similarity with the human sequence V52 and 73.2% sequence similarity with the mouse sequence L6. An insert from V kappa 32 containing the 5' untranslated regions through the codon for Cys 88 of the V kappa region was used as a probe in Southern blot analysis of genomic DNA from inbred and congenic strains of mice. V kappa 32 is a four to eight member group and some of the members are retained in the B6.PL-Ly2a congenic and missing from the B6.PL (85NS) congenic consistent with a map location near V kappa 28. The same filters were hybridized with the insert from V kappa 33 containing 5' untranslated region through the codon for Ser 93 of the V kappa region. V kappa 33 is a one to three member group and using the B6.PL congenics maps with the polymorphic fragments of V kappa 32 and V kappa 28.     

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.     

Transposition of human immunoglobulin V kappa genes within the same chromosome and the mechanism of their amplification.

The variable, joining and constant gene segments of the human immunoglobulin kappa locus (V kappa, J kappa and C kappa) are located on the short arm of chromosome 2 at 2p11-2p12. Here we describe a cluster of 11 V kappa genes on the long arm of chromosome 2 at 2cen-q11. By pulsed-field gel electrophoresis, cosmid cloning and DNA sequencing the cluster was shown to consist of four amplified units (amplicons). The amplicons, each 110-160 kb in size, are organized within 650 kb as an array of inverted repeats with short stretches of non-amplified DNA in between. Cloning and sequencing of three different joints between amplified and non-amplified DNA revealed the existence of parts of Alu repeats at each of the analysed joints. It is suggested that during evolution a group of five V kappa genes was transposed from the short to the long arm of chromosome 2 by a pericentric inversion. Three of the five V kappa genes were then amplified in two subsequent steps to yield the structure found in the majority of the present day population. The possible relation of this structure to a pericentric inversion of chromosome 2 that is seen cytogenetically in a small fraction of today's population is discussed.     

Analysis of the regions flanking the human insulin gene and sequence of an Alu family member.

The regions around the human insulin gene have been studied by heteroduplex, hybridization and sequence analysis. These studies indicated that there is a region of heterogeneous length located approximately 700 bp before the 5' end of the gene; and that the 19 kb of cloned DNA which includes the 1430 bp insulin gene as well as 5650 bp before and 11,500 bp after the gene is single copy sequence except for 500 bp located 6000 bp from the 3' end of the gene. This 500 bp segment contains a member of the Alu family of dispersed middle repetitive sequences as well as another less highly repeated homopolymeric segment. The sequence of this region was determined. This Alu repeat is bordered by 19 bp direct repeats and also contains an 83 bp sequence which is present twice. The regions flanking the human and rat I insulin genes were compared by heteroduplex analysis to localize homologous sequences in the flanking regions which could be involved in the regulation of insulin biosynthesis. The homology between the two genes is restricted to the region encoding preproinsulin and a short region of approximately 60 bp flanking the 5' side of the genes.     

Genomic and phylogenetic analysis of the S100A7 (Psoriasin) gene duplications within the region of the S100 gene cluster on human chromosome 1q21

Abstract The human S100 gene family encodes the EF-hand superfamily of calcium-binding proteins, with at least 14 family members clustered relatively closely together on chromosome 1q21. We have analyzed the most recently available genomic sequence of the human S100 gene cluster for evidence of tandem gene duplications during primate evolutionary history. The sequences obtained from both GenBank and GoldenPath were analyzed in detail using various comparative sequence analysis tools. We found that of the S100A genes clustered relatively closely together within a genomic region of 260 kb, only the S100A7 (psoriasin) gene region showed evidence of recent duplications. The S100A7 gene duplicated region is composed of three distinct genomic regions, 33, 11, and 31 kb, respectively, that together harbor at least five identifiable S100A7-like genes. Regions 1 and 3 are in opposite orientation to each other, but each region carries two S100A7-like genes separated by an 11-kb intergenic region (region 2) that has only one S100A7-like gene, providing limited sequence resemblance to regions 1 and 3. The duplicated genomic regions 1 and 3 share a number of different retroelements including five Alu subfamily members that serve as molecular clocks. The shared (paralogous) Alu S insertions suggest that regions 1 and 3 were probably duplicated during or after the phase of AluS amplification some 30–40 mya. We used PCR to amplify an indel within intron 1 of the S100A7a and S100A7c genes that gave the same two expected product sizes using 40 human DNA samples and 1 chimpanzee sample, therefore confirming the presence of the region 1 and 3 duplication in these species. Comparative genomic analysis of the other S100 gene members shows no similarity between intergenic regions, suggesting that they diverged long before the emergence of the primates. This view was supported by the phylogenetic analysis of different human S100 proteins including the human S100A7 protein members. The S100A7 protein, also known as psoriasin, has important functions as a mediator and regulator in skin differentiation and disease (psoriasis), in breast cancer, and as a chemotactic factor for inflammatory cells. This is the first report of five copies of the S100A7 gene in the human genome, which may impact on our understanding of the possible dose effects of these genes in inflammation and normal skin development and pathogenesis.     

Characterization ofAlu family repetitive sequences which flank human β-type globin genes

Heteroduplex mapping has determined the size, location, and orientation of three Alu family sequences from the human beta-type globin gene cluster. Two of these sequences have the same orientation. One (231 bp long) is 2 kb to the 5' side of the B gamma-globin gene and the other (222 bp) is l kb 5' to the pseudo-beta-l-globin gene. The third (300 bp), 3-4 kb 3' to the pseudo-beta-l-globin gene, has the opposite orientation. Their orientations relative to five previously characterized Alu sequences from this cluster have been established. One of these, 2.5 kb 5' to the epsilon-globin gene, was shown by Southern blot hybridization to be similar but not identical to other family members, whereas the region separating it from a neighbouring inverted repeat is not widely distributed in the human genome.