Structure and expression of the excision repair gene ERCC6, involved in the human disorder Cockayne's syndrome group B.

The human repair gene ERCC6--a presumed DNA (or RNA) helicase--has recently been found to function specifically in preferential nucleotide excision repair (NER). This NER subpathway is primarily directed towards repair of (the transcribed strand of) active genes. Mutations in the ERCC6 gene are responsible for the human hereditary repair disorder Cockayne's syndrome complementation group B, the most common form of the disease. In this report, the genomic organization and expression of this gene are described. It consists of at least 21 exons, together with the promoter covering a region of 82-90 kb on the genome. Postulated functional domains deduced from the predicted amino acid sequence, including 7 distinct helicase signatures, are--with one exception--encoded on separate exons. Consensus splice donor and acceptor sequences are present at all exon borders with the exception of the unusual splice donor at the end of exon VII. The 'invariable' GT dinucleotide in the consensus (C,A)AG/GTPuAGT is replaced by the exceptional GC. Based on 42 GC splice donor sequences identified by an extensive literature search we found a statistically highly significant better 'overall' match of the surrounding nucleotides to the consensus sequence compared to normal GT-sites. This confirms and extends the observation made recently by Jackson (Nucl. Acids Res., 19, 3795-3798 (1991)) derived from analysis of 26 cases. Analysis of ERCC6 cDNA clones revealed the occurrence of alternative polyadenylation, resulting in the (differential) expression of two mRNA molecules (which are barely detectable on Northern blots) of 5 and 7 kb in length.     

Structure of the Human Type IV CollagenCOL4A6Gene, Which Is Mutated in Alport Syndrome-Associated Leiomyomatosis

Basement membrane (type IV) collagen, a subfamily of the collagen protein family, is encoded by six distinct genes in mammals. Three of those,COL4A3, COL4A4,andCOL4A5,are linked with Alport syndrome (hereditary nephritis). Patients with leimoyomatosis associated with Alport syndrome have been shown to have deletions in the 5′ end of theCOL4A6gene, in addition to having deletions inCOL4A5(Zhouet al., Science261: 1167–1169, 1993). The humanCOL4A6gene is reported to be 425 kb as determined by mapping of overlapping YAC clones by probes for its 5′ and 3′ ends. In the present study we describe the complete exon/intron size pattern of the humanCOL4A6gene. The 12 λ phage clones characterized in the study spanned a total of 110 kb, including 85 kb of the actual gene and 25 kb of flanking sequences. The overlapping clones contained all 46 exons of the gene and all introns, except for intron 2. Since the total size of the exons and all introns except for intron 2 is about 85 kb, intron 2 must be about 340 kb. All exons of the gene were assigned toEcoRI restriction fragments to facilitate analysis of the gene in patients with leiomyomatosis associated with Alport syndrome. The exon size pattern ofCOL4A6is highly homologous with that of the human and mouseCOL4A2genes, with 27 of the 46 exons ofCOL4A6being identical in size between the genes.     

Genomic Organization and Complete Nucleotide Sequence of the HumanPWP2Gene on Chromosome 21

The humanPWP2gene is the human homologue of the yeast periodic tryptophan protein 2 (PWP2) gene and is a member of the gene family that contains tryptophan-aspartate (WD) repeats. Genomic sequencing revealed that the humanPWP2gene consists of 21 exons spanning approximately 24 kb and locates just between the two genes EHOC-1 and KNP-I and distal to aNotI site of LJ104 (D21S1460) on chromosome 21q22.3. Analysis of the 5′-flanking DNA sequence revealed that the upstream region of thePWP2gene is associated with a CpG island containing theNotI site of LJ104. SincePWP2is considered to be a candidate for genetic disorders mapped in the 21q22.3 region, the information including nucleotide sequence and genomic organization of thePWP2gene should be invaluable for the mutation analysis of the corresponding genetic disorders.     

Human ERCC5 cDNA-cosmid complementation for excision repair and bipartite amino acid domains conserved with RAD proteins of Saccharomyces cerevisiae and Schizosaccharomyces pombe.

Several human genes related to DNA excision repair (ER) have been isolated via ER cross-species complementation (ERCC) of UV-sensitive CHO cells. We have now isolated and characterized cDNAs for the human ERCC5 gene that complement CHO UV135 cells. The ERCC5 mRNA size is about 4.6 kb. Our available cDNA clones are partial length, and no single clone was active for UV135 complementation. When cDNAs were mixed pairwise with a cosmid clone containing an overlapping 5'-end segment of the ERCC5 gene, DNA transfer produced UV-resistant colonies with 60 to 95% correction of UV resistance relative to either a genomic ERCC5 DNA transformant or the CHO AA8 progenitor cells. cDNA-cosmid transformants regained intermediate levels (20 to 45%) of ER-dependent reactivation of a UV-damaged pSVCATgpt reporter plasmid. Our evidence strongly implicates an in situ recombination mechanism in cDNA-cosmid complementation for ER. The complete deduced amino acid sequence of ERCC5 was reconstructed from several cDNA clones encoding a predicted protein of 1,186 amino acids. The ERCC5 protein has extensive sequence similarities, in bipartite domains A and B, to products of RAD repair genes of two yeasts, Saccharomyces cerevisiae RAD2 and Schizosaccharomyces pombe rad13. Sequence, structural, and functional data taken together indicate that ERCC5 and its relatives are probable functional homologs. A second locus represented by S. cerevisiae YKL510 and S. pombe rad2 genes is structurally distinct from the ERCC5 locus but retains vestigial A and B domain similarities. Our analyses suggest that ERCC5 is a nuclear-localized protein with one or more highly conserved helix-loop-helix segments within domains A and B.     

Refined mapping of the three DNA repair genes, ERCC1, ERCC2, and XRCC1, on human chromosome 19

Three DNA repair genes, ERCC1, ERCC2, and XRCC1, have been regionally mapped on human chromosome 19. ERCC2 and XRCC1 have been assigned to bands q13.2----q13.3 by in situ hybridization using fluorescently-labeled cosmid probes. ERCC1 and ERCC2 have been found to be separated by less than 250 kb by large fragment restriction enzyme site mapping.     

Linkage assignment of a DNA sequence (ERCC2L1) homologous to a human DNA repair gene in Xiphophorus fishes: Implications for the evolutionary derivation of human chromosome 19

Fish gene mapping studies have identified several syntenic groups showing conservation over more than 400 million years of vertebrate evolution. In particular, Xiphophorus linkage group IV has been identified as a homolog of human chromosomes 15 and 19. During mammalian evolution, loci coding for glucosephosphate isomerase, peptidase D, muscle creatine kinase, and several DNA repair genes (ERCC1, ERCC2, and XRCC1) appear as a conserved syntenic group on human chromosome 19. When X. clemenciae and X. milleri PstI endonuclease-digested genomic DNA was used in Southern analysis with a human ERCC2 DNA repair gene probe, a strongly cross-hybridizing restriction fragment length polymorphism was observed. Backcrosses to X. clemenciae from X. milleri × X. clemenciae F₁ hybrids allowed tests for linkage of the ERCC2-like polymorphism to markers covering a large proportion of the genome. Statistically significant evidence for linkage was found only for ERCC2L1 and CKM (muscle creatine kinase), with a total of 41 parents and 2 recombinants (4.7% recombination, χ² = 35.37, P < 0.001); no evidence for linkage to GPI and PEPD in linkage group IV was detected. The human chromosome 19 synteny of ERCC2 and CKM thus appears to be conserved in Xiphophorus, while other genes located nearby on human chromosome 19 are in a separate linkage group in this fish. If Xiphophorus gene arrangements prove to be primitive, human chromosome 19 may have arisen from chromosome fusion or translocation events at some point since divergence of mammals and fishes from a common ancestor.     

Genomic sequence analysis of the 238-kb swine segment with a cluster of TRIM and olfactory receptor genes located, but with no class I genes, at the distal end of the SLA class I region

Continuous genomic sequence has been previously determined for the swine leukocyte antigen (SLA) class I region from the TNF gene cluster at the border between the major histocompatibility complex (MHC) class III and class I regions to the UBD gene at the telomeric end of the classical class I gene cluster (SLA-1 to SLA-5, SLA-9, SLA-11). To complete the genomic sequence of the entire SLA class I genomic region, we have analyzed the genomic sequences of two BAC clones carrying a continuous 237,633-bp-long segment spanning from the TRIM15 gene to the UBD gene located on the telomeric side of the classical SLA class I gene cluster. Fifteen non-class I genes, including the zinc finger and the tripartite motif (TRIM) ring-finger-related family genes and olfactory receptor genes, were identified in the 238-kilobase (kb) segment, and their location in the segment was similar to their apparent human homologs. In contrast, a human segment (alpha block) spanning about 375 kb from the gene ETF1P1 and from the HLA-J to HLA-F genes was absent from the 238-kb swine segment. We conclude that the gene organization of the MHC non-class I genes located in the telomeric side of the classical SLA class I gene cluster is remarkably similar between the swine and the human segments, although the swine lacks a 375-kb segment corresponding to the human alpha block. The nucleotide sequence data reported in this paper have been submitted to DDBJ, EMBL, and GenBank databases under accession numbers AB158486 and AB158487