Isolation by polymerase chain reaction of a cDNA whose product partially complements the ultraviolet sensitivity of xeroderma pigmentosum group C cells

A xeroderma pigmentosum (XP) cell line from complementation group C has been complemented to attain ultraviolet (UV) resistance and DNA repair proficiency, by transfection with a human expression cDNA library, followed by selection to UV resistance. We now show that the transfected cDNAs can be rescued from cellular DNA of a secondary transformant by its in vitro amplification using expression-vector-specific oligodeoxyribonucleotides as primers in a polymerase chain reaction. The amplified cDNAs were cloned into a mammalian expression vector. Their transfection into XP cells identified a single cDNA which specifically complemented the UV sensitivity of a group-C-derived cell line to the same partial UV-resistance levels exhibited by the transformant from which the cDNAs were rescued.     

Ultraviolet light-resistant primary transfectants of xeroderma pigmentosum cells are also DNA repair-proficient

In a previous work, an immortal xeroderma pigmentosum cell line belonging to complementation group C was complemented to a UV-resistant phenotype by transfection with a human cDNA clone library. We now report that the primary transformants selected for UV-resistance also acquired normal levels of DNA repair. This was assessed both by measurement of UV-induced [3H]thymidine incorporation and by equilibrium sedimentation analysis of repair-DNA synthesis. Therefore, the transduced DNA element which confers normal UV-resistance also corrects the excision repair defect of the xeroderma pigmentosum group C cell line.     

UV-induced base substitution mutations in a shuttle vector plasmid propagated in group C xeroderma pigmentosum cells.

To assess the contribution to mutagenesis of human DNA repair defects, the UV-irradiated shuttle vector plasmid pZ189 was propagated in fibroblasts derived from a xeroderma pigmentosum (XP) patient in DNA repair complementation group C. In comparison to results with DNA repair-proficient human cells (WI-38 VA13), UV-irradiated pZ189 propagated in the XP-C (XP4PA(SV)) cells showed fewer surviving plasmids and a higher frequency of mutated plasmids. Base sequence analysis of 67 mutated plasmids recovered from the XP-C cells revealed similar classes of point mutations and mutation spectrum, and a higher frequency of G:C to A:T transitions along with a lower frequency of transversions among plasmids with single or tandem mutations compared to plasmids recovered from the normal line. Most single-base substitution mutations (83%) occurred at G:C base pairs in which the 5'-adjacent base of the cytosine was thymine or cytosine. These results indicate that the DNA repair defects in XP-C, in comparison to data previously reported for XP-A, XP-D and XP-F, result in different UV survival and mutation frequency but in similar types of base substitution mutations.     

Levels of DNA polymerases alpha, beta, and gamma in control and repair-deficient human diploid fibroblasts 1.

The activities of DNA polymerases alpha, beta, and gamma were determined in control and repair-deficient human fibroblasts (xeroderma pigmentosum complementation groups A, C, and D; Fanconi's Anemia; and Bloom's syndrome). Assays were done on 103,000XG supernatants which had been chromatographed on DEAE cellulose to remove nucleic acids and on fractions containing polymerase activities which had been separated from one another on a second DEAE cellulose column. All repair-deficient cell types contained all three DNA polymerase activities. Caffeine, which has been observed to inhibit some DNA-repair processes in intact cells, had no effect on DNA polymerase activities from XP-A, XP-C, XP-D or XP-variant cells. These data indicate that all three polymerases are present in cells which have reduced or absent repair functions and that the caffeine effects observed in living cells are probably not due to the direct action of caffeine on DNA polymerases.     

DNA repair investigations in nine Italian patients affected by trichothiodystrophy.

Trichothiodystrophy (TTD) is a rare autosomal recessive disorder characterized by brittle hair, mental and growth retardation, peculiar face, ichthyosis, and in 20% of the reported cases photosensitivity. Cellular photosensitivity due to the same genetic defect present in xeroderma pigmentosum group D (XP-D) has been described in several patients. Nine patients with clinical symptoms diagnostic for TTD have been identified in Italy to date. We report the results of DNA repair investigations performed in cultured fibroblasts from these patients and 8 TTD parents. Survival, DNA repair synthesis and RNA synthesis following UV irradiation were all normal in the 8 TTD heterozygous cell strains. Among the 9 TTD-affected individuals, normal cellular UV sensitivity was observed in the 2 patients without signs of clinical photosensitivity. In contrast, the other 7 TTD cell strains showed a notable reduction in UV-induced DNA repair synthesis (UDS) levels, ranging between 40% and 5-15% of normal values. Complementation analysis indicated that in the repair-deficient TTD cell strains the genetic defect is the same as that present in XP-D cells. The biochemical heterogeneity of the XP-D defect in TTD patients characterized by different degrees of defective UDS results in different patterns of response to the killing effect of UV light in non-proliferating cells.     

Purification and cloning of a nucleotide excision repair complex involving the xeroderma pigmentosum group C protein and a human homologue of yeast RAD23.

Complementation group C of xeroderma pigmentosum (XP) represents one of the most common forms of this cancer-prone DNA repair syndrome. The primary defect is located in the subpathway of the nucleotide excision repair system, dealing with the removal of lesions from the non-transcribing sequences ('genome-overall' repair). Here we report the purification to homogeneity and subsequent cDNA cloning of a repair complex by in vitro complementation of the XP-C defect in a cell-free repair system containing UV-damaged SV40 minichromosomes. The complex has a high affinity for ssDNA and consists of two tightly associated proteins of 125 and 58 kDa. The 125 kDa subunit is an N-terminally extended version of previously reported XPCC gene product which is thought to represent the human homologue of the Saccharomyces cerevisiae repair gene RAD4. The 58 kDa species turned out to be a human homologue of yeast RAD23. Unexpectedly, a second human counterpart of RAD23 was identified. All RAD23 derivatives share a ubiquitin-like N-terminus. The nature of the XP-C defect implies that the complex exerts a unique function in the genome-overall repair pathway which is important for prevention of skin cancer.     

Human chromosome 15 confers partial complementation of phenotypes to xeroderma pigmentosum group F cells.

Microcell-mediated transfer of a single human chromosome from repair-proficient human cells to genetic complementation group F cells from the hereditary disease xeroderma pigmentosum (XP) results in partial complementation of repair-defective phenotypes. The complementing chromosome was identified by cytogenetic and molecular analysis as human chromosome 15. Transfer of this chromosome to XP-F cells restores approximately 20% of the resistance of wild-type cells to killing by UV radiation or by the UV-mimetic chemical 4-nitroquinoline-1-oxide (4NQO), as well as partial repair synthesis of DNA measured as unscheduled DNA synthesis. Additionally, complemented XP-F cells have an enhanced capacity for reactivation of the plasmid-borne E. coli cat gene following its inactivation by UV radiation. Phenotypic complementation of XP cells by chromosome 15 is specific to genetic complementation group F; no effect on the UV sensitivity of XP-A, XP-C, or XP-D cells was detected. The observation that phenotypic complementation is partial is open to several interpretations and does not allow the definitive conclusion that the XP-F locus is carried on chromosome 15.     

Defective recovery of semi-conservative DNA synthesis in xeroderma pigmentosum cells following split-dose ultraviolet irradiation.

In normal human fibroblasts we observe an enhancement of the recovery of the rate of semi-conservative DNA synthesis after split-dose UV-irradiation relative to a single total UV dose. The enhanced recovery is totally absent in both a xeroderma pigmentosum variant line and two xeroderma pigmentosum lines belonging to complementation groups A and C.     

Complementation of the xeroderma pigmentosum DNA repair synthesis defect with Escherichia coli UvrABC proteins in a cell-free system.

A newly developed cell-free system was used to study DNA repair synthesis carried out by extracts from human cell lines in vitro. Extracts from a normal human lymphoid cell line and from cell lines established from individuals with hereditary dysplastic nevus syndrome perform damage-dependent repair synthesis in plasmid DNA treated with cis- or trans-diamminedichloro-platinum(II) or irradiated with ultraviolet light. Cell extracts of xeroderma pigmentosum origin (complementation groups A, C, D, and G) are deficient in DNA repair synthesis. When damaged plasmid DNA was pretreated with purified Escherichia coli UvrABC proteins, xeroderma pigmentosum cell extracts were able to carry out DNA repair synthesis. The ability of E. coli UvrABC proteins to complement xeroderma pigmentosum cell extracts indicates that the extracts are deficient in incision, but can carry out later steps of repair. Thus the in vitro system provides results that are in agreement with the incision defect found from studies of xeroderma pigmentosum cells.     

Identification and characterization of xpac protein, the gene product of the human XPAC (xeroderma pigmentosum group A complementing) gene

We have cloned human xeroderma pigmentosum group A complementing (XPAC) cDNA that encodes a "zinc finger" protein with a predicted size of 31 kDa. To detect the xpac protein in cells, we raised antibody against a recombinant human xpac protein. Using this antibody, we identified the xpac protein in the nucleus of cells. In normal human cells, 40- and 38-kDa proteins were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A reduced amount of the smaller protein was detected in XP 39OSSV cells, which show low UV sensitivity, and no xpac proteins were detected in XP 2OSSV cells, which show high UV sensitivity. These levels of xpac proteins in xeroderma pigmentosum cells were determinants of heterogeneity of the DNA repair defect in group A xeroderma pigmentosum. Synthesis of the xpac protein did not increase after UV irradiation.     

Defects in the DNA repair and transcription gene ERCC2(XPD) in trichothiodystrophy.

Trichothiodystrophy (TTD) is a rare autosomal recessive disorder characterized by brittle hair with reduced sulfur content, ichthyosis, peculiar face, and mental and growth retardation. Clinical photosensitivity is present in approximately 50% of TTD patients but is not associated with an elevated frequency of cancers. Previous complementation studies show that the photosensitivity in nearly all of the studied patients is due to a defect in the same genetic locus that underlies the cancer-prone genetic disorder xeroderma pigmentosum group D (XP-D). Nucleotide-sequence analysis of the ERCC2 cDNA from three TTD cell strains (TTD1V1, TTD3VI, and TTD1RO) revealed mutations within the region from amino acid 713-730 and within previously identified helicase functional domains. The various clinical presentations and DNA repair characteristics of the cell strains can be correlated with the particular mutations found in the ERCC2 locus. Mutations of Arg658 to either His or Cys correlate with TTD cell strains with intermediate UV-sensitivity, mutation of Arg722 to Trp correlates with highly UV-sensitive TTD cell strains, and mutation of Arg683 to Trp correlates with XP-D. Alleles with mutation of Arg616 to Pro or with the combined mutation of Leu461 to Val and deletion of 716-730 are found in both XP-D and TTD cell strains.     

Biological and biochemical characterization of an SV40-transformed xeroderma pigmentosum cell line

We have isolated a subclone of the SV40-transformed xeroderma pigmentosum (XP) cell line SV40XP12RO. The cell line, designated M1, is highly sensitive to ultraviolet light and is deficient in unscheduled DNA synthesis. The isoenzyme, HLA profile and karyotype of the cell line is presented. The structure and function of the resident SV40 genome is analysed. The M1 clone contains a complete copy of the SV40 genome flanked by partial SV40-DNA copies in a head-to-tail arrangement. The large T-antigen is defective in the ability to induce SV40-DNA replication. The M1 subclone is an efficient recipient of DNA in transfection experiments. Transfection of these cells with the pSV₂gpt plasmid shows that the M1 subclone is as efficient as the NIH 3T3 cell line in uptake and expression of foreign DNA. This cell line should be suitable for genetic analysis of the xeroderma pigmentosum defect. It should also be useful for the study of gene expression in human cells.     

UV damage causes uncontrolled DNA breakage in cells from patients with combined features of XP-D and Cockayne syndrome

Nucleotide excision repair (NER) removes damage from DNA in a tightly regulated multiprotein process. Defects in NER result in three different human disorders, xeroderma pigmentosum (XP), trichothiodystrophy (TTD) and Cockayne syndrome (CS). Two cases with the combined features of XP and CS have been assigned to the XP-D complementation group. Despite their extreme UV sensitivity, these cells appeared to incise their DNA as efficiently as normal cells in response to UV damage. These incisions were, however, uncoupled from the rest of the repair process. Using cell-free extracts, we were unable to detect any incision activity in the neighbourhood of the damage. When irradiated plasmids were introduced into unirradiated XP-D/CS cells, the ectopically introduced damage triggered the induction of breaks in the undamaged genomic DNA. XP-D/CS cells thus have a unique response to sensing UV damage, which results in the introduction of breaks into the DNA at sites distant from the damage. We propose that it is these spurious breaks that are responsible for the extreme UV sensitivity of these cells.     

A re-examination of the intragenome distribution of repaired sites in proliferating xeroderma pigmentosum complementation group C fibroblasts.

We find that rapidly proliferating fibroblasts from xeroderma pigmentosum complementation group C (XP-C) patients, cells that have a small residual DNA excision repair capacity, repair DNA in localized regions of the genome in a clustered pattern rather than at single sites in dispersed locations. This finding is similar to that observed earlier for nondividing cells but is in contrast to published results that indicate that the residual repair in proliferating XP-C cells is dispersed throughout the genome in a non-clustered pattern. While we detect the same amount of repair in both proliferating and nondividing cells, we also observe no shift from the clustered pattern of repair to a more dispersive pattern when nondividing cells are stimulated to proliferate by fresh serum addition. We have no obvious explanation for these discrepancies with the published results. We have noted previously that proliferating XP-C cells are very UV sensitive relative to normal cells while nondividing cells that exhibit the same amount of repair activity are relatively UV resistant. There is no satisfactory explanation for this change in relative response to the lethal effects of UV, a change not observed for cell strains from other XP complementation groups. However, we argue that clustered repair in specific genomic regions promotes survival in nondividing XP-C cells but does not promote survival in proliferating cells.     

A new nucleotide-excision-repair gene associated with the disorder trichothiodystrophy

The sun-sensitive, cancer-prone genetic disorder xeroderma pigmentosum (XP) is associated in most cases with a defect in the ability to carry out excision repair of UV damage. Seven genetically distinct complementation groups (i.e., A–G) have been identified. A large proportion of patients with the unrelated disorder trichothiodystrophy (TTD), which is characterized by hair-shaft abnormalities, as well as by physical and mental retardation, are also deficient in excision repair of UV damage. In most of these cases the repair deficiency is in the same complementation group as is XP group D. We report here on cells from a patient, TTD1BR, in which the repair defect complements all known XP groups (including XP-D). Furthermore, microinjection of various cloned human repair genes fails to correct the repair defect in this cell strain. The defect in TTD1BR cells is therefore in a new gene involved in excision repair in human cells. The finding of a second DNA repair gene that is associated with the clinical features of TTD argues strongly for an involvement of repair proteins in hair-shaft development.     

An SV40-transformed xeroderma pigmentosum group D cell line: establishment, ultraviolet sensitivity, transfection efficiency and plasmid mutation induction

Fibroblasts from a patient with xeroderma pigmentosum complementation group D were treated with Simian virus 40 to establish a transformed cell line suitable for studies of DNA-mediated gene transfer. After progressing through 2 crises, a stable line, XP6Be(SV40), was established and cultured for more than 1 year. This line retains the characteristic xeroderma pigmentosum ultraviolet hypersensitivity and is able to complement a SV40-transformed group A line when fused and assayed for ultraviolet radiation inhibition of colony-forming ability. XP6Be(SV40) expressed high levels of transfected chloramphenicol acetyltransferase activity (0.1 nmole X mg-1 X min-1) in a transient expression assay, showed stable expression of transfected gpt or neo genes (frequency 1-20 X 10(-5)), and permitted replication of the mutagenesis shuttle vector plasmid, pZ189. Ultraviolet treatment (500 J X m-2) of pZ189 prior to replication in XP6Be(SV40) resulted in a large reduction in plasmid yield (5% survival) and a 60-fold increase in the mutation frequency, reflecting the reduced ability of these cells to repair ultraviolet-damaged transfecting DNA. This cell line provides the opportunity to utilize transfection studies in cells with the xeroderma pigmentosum group D defect in excision repair.