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.     

Inferring the history of interchromosomal gene transposition in Drosophila using n-dimensional parsimony

Gene transposition puts a new gene copy in a novel genomic environment. Moreover, genes moving between the autosomes and the X chromosome experience change in several evolutionary parameters. Previous studies of gene transposition have not utilized the phylogenetic framework that becomes possible with the availability of whole genomes from multiple species. Here we used parsimonious reconstruction on the genomic distribution of gene families to analyze interchromosomal gene transposition in Drosophila. We identified 782 genes that have moved chromosomes within the phylogeny of 10 Drosophila species, including 87 gene families with multiple independent movements on different branches of the phylogeny. Using this large catalog of transposed genes, we detected accelerated sequence evolution in duplicated genes that transposed when compared to the parental copy at the original locus. We also observed a more refined picture of the biased movement of genes from the X chromosome to the autosomes. The bias of X-to-autosome movement was significantly stronger for RNA-based movements than for DNA-based movements, and among DNA-based movements there was an excess of genes moving onto the X chromosome as well. Genes involved in female-specific functions moved onto the X chromosome while genes with male-specific functions moved off the X. There was a significant overrepresentation of proteins involving chromosomal function among transposed genes, suggesting that genetic conflict between sexes and among chromosomes may be a driving force behind gene transposition in Drosophila.     

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.     

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.     

A human immunoglobulin kappa orphon without sequence defects may be the product of a pericentric inversion.

The VK gene segments that have been transposed from the kappa locus on the short arm of chromosome 2 at 2p11-12 to other chromosomal sites are called orphons. The 18 VK orphons sequenced up to now carry defects and are to be considered pseudogenes. We now describe the VKI gene segment V108 whose sequence is without any defects and which was localized to the long arm of chromosome 2 at 2q12-14 by in situ hybridization. The V108 region may have been transposed from the short to the long arm of chromosome 2 by a pericentric inversion. Possible reasons for the conservation of its sequence are discussed. In spite of its bona fide sequence V108 is considered to be an unlikely candidate for a VK-JK rearrangement and subsequent functional expression.     

Molecular footprints of human immunoglobulin gene evolution: a new sequence family.

Analysis of the human VK (ref. 2) gene locus led to the detection of a new sequence family (L sequences). Its copy number is in the range of 10(2). The L sequences, which are about 500 bp long, are found as part of the 3' flanking regions of a clustered set of human VKI genes but they occur also separate from the genes. Models are discussed in which L sequences are viewed as molecular footprints of amplification and transposition processes of VK genes.     

The transposition pattern of the Ac element in tobacco cultured cells.

We investigated physical distances and directions of transposition of the maize transposable element Ac in tobacco cultured cells. We introduced a T-DNA construct that carried a non-autonomous derivative of Ac (designated dAc-I-RS) that included sites for cleavage by restriction endonuclease MluI. Another cleavage site was also introduced into the T-DNA region outside of the dAc-I-RS transposable element. The tobacco cultured cell line BY-2 was transformed with the T-DNA and several transformed lines that had a single copy of the T-DNA at a different chromosomal location were isolated. These lines were co-cultured with Agrobacterium tumefaciens cells that carried a cDNA for the Ac transposase gene under the control of various promoters. Sublines of cultured cells in which dAc-I-RS had been transposed, were isolated. The genomic DNAs of these sublines were isolated and digested with MluI. Sizes of DNA segments generated by digestion were determined by pulse-field gel electrophoresis. Our results showed that 20 to 70% of transposition events had occurred within several hundreds kilo-base pairs (kb) on the same chromosome. These results demonstrate that the Ac-Ds element preferentially transposed to regions near the original site in a tobacco chromosome. In addition, the present results are an example of asymmetric transposition as demonstrated by the distance of transposition on the chromosome.     

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.     

Involvement of immunoglobulin heavy- and light-chain (kappa) gene clusters in a human B-cell translocation, t(2;14)

The breakpoints of a translocation, t(2;14)(p11;q32), detected in an Epstein-Barr virus-transformed lymphoid B-cell line were mapped by Southern analysis, field-inversion gel electrophoresis, and in situ hybridisation. The translocation involved the immunoglobulin light-chain (kappa) locus on chromosome 2 and the heavy-chain locus on chromosome 14. The breakpoint on chromosome 2 was between VK and CK, most likely within JK. The chromosome 14 break was located within the VH cluster, no more than 220 kb 5' of the productively rearranged JH locus. The translocation probably resulted from an aberrant rearrangement of the kappa light-chain genes.     

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.     

Characterization of a human orphon 28 S ribosomal DNA

We have isolated clones in which two regions of the human genome are represented, each containing an orphon: a dispersed copy of 28S rDNA. Nucleotide (nt) sequence analysis established that one of these, H28S-O1, corresponds to nt 3627-4105 of human 28S rDNA, but in a mutated form. The orphon was flanked on one side by a portion of the L1Hs long interspersed repeat family of the human genome. Although H25S-O1 is not flanked by the terminal direct repeats characteristic of transposed DNA, it is possible that it is a processed pseudogene.     

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.     

A ribosomal orphon sequence from Xenopus laevis flanked by novel low copy number repetitive elements

We have used a differential cloning approach to isolate ribosomal/non-ribosomal frontier sequences from Xenopus laevis. A ribosomal intergenic spacer sequence (IGS) was cloned and shown not to be physically linked with the ribosomal locus. This ribosomal orphon contained the IGS sequences found immediately downstream of the 28S gene and included an array of enhancer repetitions and a non-functional spacer promoter. The orphon sequence was flanked by a member of the novel 'Frt' low copy repetitive element family. Three individual Frt repeats were sequenced and all members of this family were shown to lie clustered at two chromosomal sites, one of which contained the ribosomal orphon. One of the Frt elements contained an insertion of 297 bp that showed extensive homology to sequences within at least three other Xenopus genes. Each homology region was flanked by members of the T2 family of short interspersed repetitive elements, (SINEs), and by its target insertion sequence, suggesting multiple translocation events. The data are discussed in terms of the evolution of the ribosomal gene locus.     

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.     

Duplicative and conservative transpositions of larval serum protein 1 genes in the genus Drosophila

Interspecific comparative molecular analyses of transposed genes and their flanking regions can help to elucidate the time, direction, and mechanism of gene transposition. In the Drosophila melanogaster genome, three Larval serum protein 1 (Lsp1) genes (alpha, beta and gamma) are present and each of them is located on a different chromosome, suggesting multiple transposition events. We have characterized the molecular organization of Lsp1 genes in D. buzzatii, a species of the Drosophila subgenus and in D. pseudoobscura, a species of the Sophophora subgenus. Our results show that only two Lsp1 genes (beta and gamma) exist in these two species. The same chromosomal localization and genomic organization, different from that of D. melanogaster, is found in both species for the Lsp1beta and Lsp1gamma genes. Overall, at least two duplicative and two conservative transpositions are necessary to explain the present chromosomal distribution of Lsp1 genes in the three Drosophila species. Clear evidence for implication of snRNA genes in the transposition of Lsp1beta in Drosophila has been found. We suggest that an ectopic exchange between highly similar snRNA sequences was responsible for the transposition of this gene. We have also identified the putative cis-acting regulatory regions of these genes, which seemingly transposed along with the coding sequences.