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.

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.

Two unusual human immunoglobulin V kappa genes.

The V kappa genes A10 and A14 which have been previously localized within the human kappa locus were analysed now. A10 hybridizes under stringent conditions only weakly or not at all to probes characteristic for the four V kappa subgroups. According to their DNA sequences and the derived amino-acid sequences A10 and A14 do not fit well into the subgroup classification. They seem to be about as closely related to the subgroup I and III genes and less related to those of subgroups II and IV. Hybridization experiments indicate that A10 and A14 belong to a small V kappa gene family. After discussing the various features of the sequences we suggest neither to assign A10 and A14 to one of the existing subgroups nor to establish a new one but to apply to them the subgroup designation N which may be changed when all V kappa genes are known and can be classified together.

The human VK locus. Characterization of a duplicated region encoding 28 different immunoglobulin genes.

Two large regions of the human multigene family coding for the variable parts of the immunoglobulin light chains of the K type (VK) have been characterized on cosmid clones. The two germline regions, called Aa and Ab, span together 250,000 base-pairs and comprise 28 different VK gene segments, nine of which have been sequenced. There is a preponderance of VKII genes but genes belonging to subgroups I and III, and genes that cannot be easily assigned to one of the known subgroups, are interspersed within the VKII gene clusters. A number of pseudogenes have been identified. Within the Aa and Ab regions, all gene segments are organized in the same transcriptional orientation. The regions Aa and Ab, whose restriction maps are highly homologous, were shown not to be allelic structures; they must have arisen by a duplication event. Taken together with previous results, one can conclude that the major part of the VK locus exists in duplicated form. One individual has been found who has only one copy of some of the duplicated regions. By chromosomal walking, the A regions could be linked to the O regions, an analysis of which has been reported. The A regions contribute about one-third of the VK genes so far identified.

Physical map of the human immunoglobulin K locus and its implications for the mechanisms of VK-JK rearrangement.

Genomic regions containing numerous cloned VK genes (abbreviations in ref. 2) were investigated by pulsed-field gel electrophoresis. 31 and 32 genes were linked within 1.0 and 1.3 Mb NotI fragments, respectively; the latter fragment includes also the JKCK gene segment. A 0.25 Mb NotI fragment comprises further 10 VK genes. Since the transcriptional polarities of the VK genes within the genomic regions are known the linking of the regions allows us now to answer unequivocally some longstanding questions concerning the mechanism of VK-JK rearrangement. The VK genes of the 1.3 Mb NotI fragment except for the two JK proximal ones (accompanying paper) are arranged in the same transcriptional polarity as JKCK and therefore must rearrange by a deletion mechanism. The VK genes of the 1.0 Mb NotI fragment which has not yet been linked to VKJK have identical polarity within the fragment. They should be arranged in opposite polarity to JKCK since reciprocal recombination products derived from them are known to exist; such recombination products must have been formed by inversion of oppositely oriented gene segments.

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.

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.

Dispersed human immunoglobulin kappa light-chain genes.

The gene segments encoding the constant and variable regions of human immunoglobulin light chains of the kappa type (C kappa, V kappa) have been localized to chromosome 2. The distance between the C kappa and V kappa genes and the number of germline V kappa genes are unknown. As part of our work on the human V kappa locus, we have now mapped two solitary V kappa gene and a cluster of three V kappa genes to chromosomes 1, 15 and 22, respectively. The three genes that have been sequenced are nonprocessed pseudogenes, and the same may be true for the other two genes. This is the first time that V-gene segments have been found outside the C-gene-containing chromosomes. Our finding is relevant to current estimates of the size of the V kappa-gene repertoire. Furthermore, the dispersed gene regions have some unusual characteristics which may help to clarify the mechanism of dispersion.

A large section of the gene locus encoding human immunoglobulin variable regions of the kappa type is duplicated.

The structure of a new segment of the gene locus encoding the variable regions of human immunoglobulins of the Kappa type (VK) has been elucidated. This segment (cluster B) encompasses six VK sequences, which belong to three different subgroups and which are arranged in the same transcriptional orientation. Part of cluster B was found to be very similar to another region of the VK gene locus, which was cloned previously (cluster A). Sequence differences between the homologous region of clusters A and B range from 0.2% to 3.7% depending on the position of the VK sequences. The divergence is in the same range for genes and pseudogenes. Hybridization experiments with DNAs from different individuals clearly demonstrate that the two segments are located at different positions within the VK locus and do not represent allelic variants. The sequence homology between clusters A and B is higher than the homology of both clusters to an allelic variant, which is represented by a DNA segment that had been isolated from another individual. These results, together with a report in the literature of two other homologous regions in the VK locus, make it very likely that a major part of even the whole locus is duplicated. In this case, VK gene numbers would be higher than previously estimated on the basis of hybridization studies. An inverse orientation of VK gene clusters would explain published data on rearrangement products in B-cells if an inversion-deletion mechanism is assumed.

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.