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.     

Molecular cloning of the human DNA excision repair gene ERCC-6.

The UV-sensitive, nucleotide excision repair-deficient Chinese hamster mutant cell line UV61 was used to identify and clone a correcting human gene, ERCC-6. UV61, belonging to rodent complementation group 6, is only moderately UV sensitive in comparison with mutant lines in groups 1 to 5. It harbors a deficiency in the repair of UV-induced cyclobutane pyrimidine dimers but permits apparently normal repair of (6-4) photoproducts. Genomic (HeLa) DNA transfections of UV61 resulted, with a very low efficiency, in six primary and four secondary UV-resistant transformants having regained wild-type UV survival. Southern blot analysis revealed that five primary and only one secondary transformant retained human sequences. The latter line was used to clone the entire 115-kb human insert. Coinheritance analysis demonstrated that five of the other transformants harbored a 100-kb segment of the cloned human insert. Since it is extremely unlikely that six transformants all retain the same stretch of human DNA by coincidence, we conclude that the ERCC-6 gene resides within this region and probably covers most of it. The large size of the gene explains the extremely low transfection frequency and makes the gene one of the largest cloned by genomic DNA transfection. Four transformants did not retain the correcting ERCC-6 gene and presumably have reverted to the UV-resistant phenotype. One of these appeared to have amplified an endogenous, mutated CHO ERCC-6 allele, indicating that the UV61 mutation is leaky and can be overcome by gene amplification.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide exicision repair gene ERCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

UV mutagenesis, cytotoxicity and split-dose recovery in a human-CHO cell hybrid having intermediate (6-4) photoproduct repair

Somatic cell hybrids constructed between UV-hypersensitive Chinese hamster ovary cell line UV20 and human lymphocytes were used to examine the influence of a human DNA repair gene, ERCC1, on UV photoproduct repair, mutability at several drug-resistance loci, UV cytotoxicity and UV split-dose recovery. In hybrid cell line 20HL21-4, which contains human chromosome 19, UV-induced mutagenesis at the APRT, HPRT and Na+/K+-ATPase loci was comparable to that in repair-proficient CHO AA8 cells, whereas cell line 20HL21-7, a reduced human-CHO hybrid not containing human chromosome 19, exhibited a hypermutable phenotype at all 3 loci indistinguishable from that of UV20 cells. The response of 20HL21-4 cells to UV cytotoxicity reflected substantial but incomplete restoration of wild-type UV cytotoxic response, whereas responses of UV20 and 20HL21-7 cell lines to UV cytotoxicity were essentially the same, reflecting several-fold UV hypersensitivity. Repair of UV-induced (5-6) cyclobutane dimers and (6-4) photoproducts was examined by radioimmunoassay; (6-4) photoproduct repair was deficient in UV20 and 20HL21-7 cell lines, and intermediate in 20HL21-4 cells relative to wild-type CHO AA8 cells. UV split-dose recovery in 20HL21-4 cells was also intermediate relative to AA8 cells. These results show that the human ERCC1 gene on chromosome 19 is responsible for substantial restoration of UV survival and mutation responses in repair-deficient UV20 cells, but only partially restores (6-4) UV photoproduct repair and UV split-dose recovery.     

Transfection of the cloned human excision repair gene ERCC-1 to UV-sensitive CHO mutants only corrects the repair defect in complementation group-2 mutants

The human DNA-excision repair gene ERCC-1 is cloned by its ability to correct the excision-repair defect of the ultraviolet light- and mitomycin-C-sensitive CHO mutant cell line 43-3B. This mutant is assigned to complementation group 2 of the excision-repair-deficient CHO mutants. In order to establish whether the correction by ERCC-1 is confined to CHO mutants of one complementation group, the cloned repair gene, present on cosmid 43-34, was transfected to representative cell lines of the 6 complementation groups that have been identified to date. Following transfection, mycophenolic acid was used to select for transferants expressing the dominant marker gene Ecogpt, also present on cosmid 43-34. Cotransfer of the ERCC-1 gene was shown by Southern blot analysis of DNA from pooled (500-2000 independent colonies) transformants of each mutant. UV survival and UV-induced UDS showed that only mutants belonging to complementation group 2 and no mutants of other groups were corrected by the ERCC-1 gene. This demonstrates that ERCC-1 does not provide an aspecific bypass of excision-repair defects in CHO mutants and supports the assumption that the complementation analysis is based on mutations in different repair genes.     

Analyses of mutation in pSV2gpt-transformed CHO cells

We have developed a system to study mutations which affect expression of the E. coli xanthine-guanine phosphoribosyl transferase (XPRT) gene (gpt) in hypoxanthine-guanine phosphoribosyl transferase-deficient (HPRT-) Chinese hamster ovary (CHO) cells that have been transformed by the plasmid pSV2gpt. Several gpt-transformed cell lines have been isolated and characterized with respect to integrated pSV2gpt sequences, expression of the gpt gene, and cytotoxic and mutagenic responses to UV light. While the gpt-transformed CHO and wild-type CHO-K1-BH4 cell lines have similar cytotoxic responses to UV light, the gpt-transformed cell lines respond differently from the parental CHO-K1-BH4 cell line in terms of mutation induction. As with CHO-K1-BH4 HPRT mutants, spontaneous or induced XPRT mutants derived from the gpt+ cell lines can be selected for 6-thioguanine resistance (TGr). Analysis of cell-free extracts from a number of these TGr clones indicates that the mutant phenotype is due to the absence of XPRT activity. One transformant, designated AS52, has previously been described in limited detail. Here we describe additional characteristics of this cell line, as well as several related transformants.     

Isolation of the functional human excision repair gene ERCC5 by intercosmid recombination

The complete human nucleotide excision repair gene FRCC5 was isolated as a functional gene on overlapping cosmids. ERCC5 corrects the excision repair deficiency of Chinese hamster ovary cell line UV135, of complementation group 5. Cosmids that contained human sequences were obtained from a UV-resistant cell line derived from UV135 cells transformed with human genomic DNA. Individually, none of the cosmids complemented the UV135 repair defect; cosmid groups were formed to represent putative human genomic regions, and specific pairs of cosmids that effectively transformed UV135 cells to UV resistance were identified. Analysis of transformants derived from the active cosmid pairs showed that the functional 32-kbp ERCC5 gene was reconstructed by homologous intercosmid recombination. The cloned human sequences exhibited 100% concordance with the locus designated genetically as ERCC5 located on human chromosome 13q. Cosmid-transformed UV135 host cells repaired cytotoxic damage to levels about 70% of normal and repaired UV-irradiated shuttle vector DNA to levels about 82% of normal.     

Properties and applications of human DNA repair genes

The importance of understanding DNA repair processes is discussed in terms of the origins of human cancer. Several human repair genes have been mapped to specific human chromosomes using somatic cell hybrids. It is noteworthy that 3 of these genes lie in the same region of chromosome 19: genes ERCC1 and ERCC2, which are involved in nucleotide excision repair, and XRCC1, which is involved in the repair of strand breaks. The genes XRCC1 and ERCC2 were cloned from cosmid libraries prepared from DNA transformants of the CHO mutants EM9 and UV5, respectively. Analysis of the cDNA sequence of ERCC2 showed that the protein encoded by this gene is highly homologous (73%) to the RAD3 repair protein in the yeast Saccharomyces cerevisiae. Thus, the known properties of RAD3 combined with the high homology provide the first insight about the biochemical role of a human repair protein involved in the incision step of nucleotide excision repair. So far XRCC1 is the only cloned mammalian gene involved in repairing damage from ionizing radiation. The UV5 mutant line was also applied to problems in environmental mutagenesis by introducing the mouse cytochrome P(3)450 (P450IA2 subfamily) gene for metabolic activation of aromatic amines. We show in a rapid differential cytotoxicity assay with 2 compounds found in cooked beef (IQ, 2-amino-3-methylimidazo[4,5-f]quinoline and PhIP, 2-amino-1-methyl-6-phenylimidazo[4,5-b]pyridine) that this gene is efficiently expressed in the transformed UV5P3 cells. Reversion of the repair deficiency in these cells will give a matched pair of cell lines that are metabolically proficient and repair deficient. Such lines will provide a rapid assay for genotoxic heterocyclic amines requiring activation.     

Differential repair and replication of damaged DNA in ribosomal RNA genes in different CHO cell lines

We studied the repair of psoralen adducts in the pol I-transcribed ribosomal RNA (rRNA) genes of excision repair competent Chinese hamster ovary (CHO) cell lines, their UV sensitive mutant derivatives, and their UV resistant transformants, which express a human excision repair gene. In the parental cell line CHO-AA8, both monoadducts and interstrand crosslinks are removed efficiently from the rRNA genes, whereas neither adduct is removed in the UV sensitive derivative UV5; removal of both adducts is restored in the UV resistant transformant CHO-5T4 carrying the human excision repair gene ERCC-2. In contrast, removal of psoralen adducts from the rRNA genes is not detected in another parental CHO cell line CHO-9, neither in its UV sensitive derivative 43-3B, nor in its UV resistant transformant 83-G5 carrying the human excision repair gene ERCC-1. In contrast to such intergenomic heterogeneity of repair, persistence of psoralen monoadducts during replication of the rRNA genes occurs equally well in all CHO cell lines tested. From these data, we conclude that: 1) the repair efficiency of DNA damage in the rRNA genes varies between established parental CHO cell lines; 2) the repair pathways of intrastrand adducts and interstrand crosslinks in mammalian cells share, at least, one gene product, i.e., the excision repair gene ERCC-2; 3) replicational bypass of psoralen monoadducts at the CHO rRNA locus occurs similarly on both DNA strands.     

Transformation of UV-hypersensitive Chinese hamster ovary cell mutants with UV-irradiated plasmids

Transfection of UV-hypersensitive, DNA repair-deficient Chinese hamster ovary (CHO) cell lines and parental, repair-proficient CHO cells with UV-irradiated pHaprt-1 or pSV2gpt plasmids resulted in different responses by recipient cell lines to UV damage in transfected DNA. Unlike results that have been reported for human cells, UV irradiation of transfecting DNA did not stimulate the genetic transformation of CHO recipient cells. In repair-deficient CHO cells, proportionally fewer transformants were produced with increasing UV damage than in repair-proficient cells in transfections with the UV-irradiated hamster adenine phosphoribosyltransferase (APRT) gene contained in plasmid pHaprt-1. However, transfection of CHO cells with UV-irradiated pSV2gpt resulted in neither decline in transformation frequencies in repair-deficient cell lines relative to repair-proficient cells nor stimulation of genetic transformation by UV damage in the plasmid. Blot hybridization analysis of DNA samples isolated from transformed cells showed no dramatic changes in copy number or arrangement of transfected plasmid DNA with increasing UV dose. We conclude that the responses of recipient cells to UV-damaged transfecting plasmids depend both on the type of recipient cell and the characteristics of the genetic sequence used for transfection.     

Intermediate (6-4) photoproduct repair in Chinese hamster V79 mutant V-H1 correlates with intermediate levels of DNA incision and repair replication

A DNA-repair mutant isolated from Chinese hamster V79 cells, V-H1, has been characterized as having only slightly reduced unscheduled DNA synthesis (UDS) and intermediate levels of DNA incision and repair replication after UV exposure. This observation was unexpected, since V-H1 has been shown by genetic complementation analysis to belong to the UV5 complementation class (i.e., class 2), exhibiting equivalent UV hypersensitivity and hypermutability as UV5 cells, which are defective in incision, UDS and repair replication. We have examined the repair of cyclobutane dimers and (6-4) photoproducts in V-H1 and V79 cells and shown that V-H1 cells are deficient in cyclobutane dimer repair, but exhibit intermediate (6-4) photoproduct repair, unlike UV5 cells which are completely deficient in (6-4) photoproduct repair. Our results confirm observations made in other UV-hypersensitive Chinese hamster cell mutants in CHO complementation class 2, and suggest that the gene affected in these mutants (ERCC2) may be involved in at least two distinct repair pathways in hamster cells.     

A yeast DNA repair gene partially complements defective excision repair in mammalian cells.

The RAD10 gene of Saccharomyces cerevisiae is required for nucleotide excision repair of DNA. Expression of RAD10 mRNA and Rad10 protein was demonstrated in Chinese hamster ovary (CHO) cells containing amplified copies of the gene, and RAD10 mRNA was also detected in stable transfectants without gene amplification. Following transfection with the RAD10 gene, three independently isolated excision repair-defective CHO cell lines from the same genetic complementation group (complementation group 2) showed partial complementation of sensitivity to killing by UV radiation and to the DNA cross-linking agent mitomycin C. These results were not observed when RAD10 was introduced into excision repair-defective CHO cell lines from other genetic complementation groups, nor when the yeast RAD3 gene was expressed in cells from genetic complementation group 2. Enhanced UV resistance in cells carrying the RAD10 gene was accompanied by partial reactivation of the plasmid-borne chloramphenicol acetyltransferase (cat) gene following its inactivation by UV radiation. The phenotype of CHO cells from genetic complementation group 2 is also specifically complemented by the human ERCC1 gene, and the ERCC1 and RAD10 genes have similar amino acid sequences. The present experiments therefore indicate that the structural homology between the yeast Rad10 and human Ercc1 polypeptides is reflected at a functional level, and suggest that nucleotide excision repair proteins are conserved in eukaryotes.     

Vector-mediated DNA double-strand break repair analysis in normal, and radiation-sensitive, Chinese hamster V79 cells

DNA double-strand break repair was assessed in 2 new radiation-sensitive V79 hamster cell lines (irs1 and irs2) by their ability to rejoin restriction endonuclease cuts in a transferred selectable SV40--E. coli gpt recombinant gene. The studied gene was carried in the vector pPMH16 which also contained a second selectable HSVtk-neo recombinant gene which acted as a control for DNA transformation. The parental V79 cells showed correct rejoining of KpnI and EcoRV double-strand breaks in approximately 18% and 36% of transformants respectively (correcting for the expression of undamaged gpt in neo+ transformants). irs1 shows a significantly reduced (approximately 3-fold) ability to rejoin correctly such double-strand scissions. However, irs2 rejoined such lesions as correctly as the V79 cells. The data are discussed in the context of the assay and the possible repair deficiencies of these radiosensitive mutant cells.     

Complementation of repair gene mutations on the hemizygous chromosome 9 in CHO: a third repair gene on human chromosome 19

A human DNA repair gene, ERCC2 (Excision Repair Cross Complementing 2), was assigned to human chromosome 19 using hybrid clone panels in two different procedures. One set of cell hybrids was constructed by selecting for functional complementation of the DNA repair defect in mutant CHO UV5 after fusion with human lymphocytes. In the second analysis, DNAs from an independent hybrid panel were digested with restriction enzymes and analyzed by Southern blot hybridization using DNA probes for the three DNA repair genes that are located on human chromosome 19: ERCC1, ERCC2, and X-Ray Repair Cross Complementing 1 (XRCC1). The results from hybrids retaining different portions of this chromosome showed that ERCC2 is distal to XRCC1 and in the same region of the chromosome 19 long arm (q13.2-q13.3) as ERCC1, but on different MluI macrorestriction fragments. Similar experiments using a hybrid clone panel containing segregating Chinese hamster chromosomes revealed the hamster homologs of the three repair genes to be part of a highly conserved linkage group on Chinese hamster chromosome number 9. The known hemizygosity of hamster chromosome 9 in CHO cells can account for the high frequency at which genetically recessive mutations are recovered in these three genes in CHO cells. Thus, the conservation of linkage of the repair genes explains the seemingly disproportionate number of repair genes identified on human chromosome 19.     

Activated c-raf gene in a rat hepatocellular carcinoma induced by 2-amino-3-methylimidazo[4,5-f]quinoline

A rat hepatocellular carcinoma, IQ7, induced by 2-amino-3-methylimidazo[4,5-f]quinoline (IQ) gave two transformants of NIH 3T3 cells on DNA mediated gene transfer. One of these transformants was examined further and secondary and tertiary transformants were obtained. The secondary transformant was tumorigenic in nude mice. The activated oncogene in this primary transformant was identified as rat c-raf by Southern blot analysis.     

Molecular cloning and biological characterization of the human excision repair gene ERCC-3.

In this report we present the cloning, partial characterization, and preliminary studies of the biological activity of a human gene, designated ERCC-3, involved in early steps of the nucleotide excision repair pathway. The gene was cloned after genomic DNA transfection of human (HeLa) chromosomal DNA together with dominant marker pSV3gptH to the UV-sensitive, incision-defective Chinese hamster ovary (CHO) mutant 27-1. This mutant belongs to complementation group 3 of repair-deficient rodent mutants. After selection of UV-resistant primary and secondary 27-1 transformants, human sequences associated with the induced UV resistance were rescued in cosmids from the DNA of a secondary transformant by using a linked dominant marker copy and human repetitive DNA as probes. From coinheritance analysis of the ERCC-3 region in independent transformants, we deduce that the gene has a size of 35 to 45 kilobases, of which one essential segment has so far been refractory to cloning. Conserved unique human sequences hybridizing to a 3.0-kilobase mRNA were used to isolate apparently full-length cDNA clones. Upon transfection to 27-1 cells, the ERCC-3 cDNA, inserted in a mammalian expression vector, induced specific and (virtually) complete correction of the UV sensitivity and unscheduled DNA synthesis of mutants of complementation group 3 with very high efficiency. Mutant 27-1 is, unlike other mutants of complementation group 3, also very sensitive toward small alkylating agents. This unique property of the mutant is not corrected by introduction of the ERCC-3 cDNA, indicating that it may be caused by an independent second mutation in another repair function. By hybridization to DNA of a human x rodent hybrid cell panel, the ERCC-3 gene was assigned to chromosome 2, in agreement with data based on cell fusion (L. H. Thompson, A. V. Carrano, K. Sato, E. P. Salazar, B. F. White, S. A. Stewart, J. L. Minkler, and M. J. Siciliano, Somat. Cell. Mol. Genet. 13:539-551, 1987).     

Biochemical and cytogenetical characterization of Chinese hamster ovary X-ray-sensitive mutant cells xrs 5 and xrs 6. VI. The correlation between UV-induced DNA lesions and chromosomal aberrations, and their modulations with inhibitors of DNA repair synthesis

The role of UV-induced DNA lesions and their repair in the formation of chromosomal aberrations in the xrs mutant cell lines xrs 5 and xrs 6 and their wild-type counterpart, CHO-K1 cells, were studied. The extent of induction of DNA single-strand breaks (SSBs) and DNA double-strand breaks (DSBs) due to UV irradiation in the presence or absence of 1-beta-D-arabinofuranosylcytosine (ara-C) and hydroxyurea (HU) was determined using the alkaline and neutral elution methods. Results of these experiments were compared with the frequencies of induced chromosomal aberrations in UV-irradiated G1 cells treated under similar conditions. Xrs 6 cells showed a defect in their ability to perform the incision step of nucleotide repair after UV irradiation. Accumulation of breaks 2 h after UV irradiation in xrs 6 cells in the presence of HU and ara-C remained at the level of incision breaks estimated after 20 min, which was about 35% of that found in wild-type CHO-K1 cells. In UV-irradiated CHO-K1 and xrs 5 cells, more incision breaks were present after 2 h compared with 20 min post-treatment with ara-C, a further increase was evident when HU was added to the combined treatment. The level of incision breaks induced under these conditions in xrs 5 was about 80% of that observed in CHO-K1 cells. UV irradiation itself did not induce any detectable DNA strand breaks. Accumulation of SSBs in UV-irradiated cells post-treated with ara-C and HU coincides with the increase in the frequency of chromosomal aberrations. These data suggest that accumulated SSBs when converted to DSBs in G1 give rise to chromosome-type aberrations, whereas strand breaks persisting until S-phase result in chromatid-type aberrations. Xrs 6 appeared to be the first ionizing-radiation-sensitive mutant with a partial defect in the incision step of DNA repair of UV-induced damage.