Preferential repair of nuclear matrix associated DNA in xeroderma pigmentosum complementation group C

The distribution of ultraviolet-induced DNA repair patches in the genome of xeroderma pigmentosum cells of complementation group C was investigated by determining the molecular weight distribution of repair labeled DNA and prelabeled DNA in alkaline sucrose gradients after treatment with the dimerspecific endonuclease V of bacteriophage T4. The results were consistent with the data reported by Mansbridge and Hanawalt (1983) and suggest that DNA-repair synthesis in xeroderma pigmentosum cells of complementation group C occurs in localized regions of the genome. Analysis of the spatial distribution of ultraviolet-induced repair patches in DNA loops attached to the nuclear matrix revealed that in xeroderma pigmentosum cells of complementation group C repair patches are preferentially situated near the attachment sites of DNA loops at the nuclear matrix. In normal human fibroblasts we observed no enrichment of repair-labeled DNA at the nuclear matrix and repair patches appeared to be distributed randomly along the DNA loops. The enrichment of repair-labeled DNA at the nuclear matrix in xeroderma pigmentosum cells of complementation group C may indicate that the residual DNA-repair synthesis in these cells occurs preferentially in transcribing regions of the genome.     

Alteration of a DNA-dependent ATPase activity in xeroderma pigmentosum complementation group C cells.

DNA-dependent ATPase activities in crude extracts prepared from HeLa cells were separated into five peaks by fast protein liquid chromatography Mono Q column chromatography. Similar elution profiles were observed with the extracts from human cells normal in repair and xeroderma pigmentosum cells belonging to complementation groups A through G except for group C. An alteration in elution of one of the five ATPases, designated DNA-dependent ATPase Q1, was observed with a cell line of complementation group C. This alteration was observed with all tested cell lines that belonged to group C. ATPase Q1 in HeLa cell extracts exhibited about 2-fold higher activity with ultraviolet light-irradiated DNA as compared to that with non-irradiated DNA, whereas little difference in the effects of two DNAs was observed with the ATPase activities in the extract from group C cells.     

Biochemical and structural domain analysis of xeroderma pigmentosum complementation group C protein

XPC is a 940-residue multidomain protein critical for the sensing of aberrant DNA and initiation of global genome nucleotide excision repair. The C-terminal portion of XPC (residues 492-940; XPC-C) has critical interactions with DNA, RAD23B, CETN2, and TFIIH, whereas functional roles have not yet been assigned to the N-terminal portion (residues 1-491; XPC-N). In order to analyze the molecular basis for XPC function and mutational defects associated with xeroderma pigmentosum (XP) disease, a series of stable bacterially expressed N- and C-terminal fragments were designed on the basis of sequence analysis and produced for biochemical characterization. Limited proteolysis experiments combined with mass spectrometry revealed that the full XPC-C is stable but XPC-N is not. However, a previously unrecognized folded helical structural domain was found within XPC-N, XPC(156-325). Pull-down and protease protection assays demonstrated that XPC(156-325) physically interacts with the DNA repair factor XPA, establishing the first functional role for XPC-N. XPC-C exhibits binding characteristics of the full-length protein, including stimulation of DNA binding by physical interaction with RAD23B and CETN2. Analysis of an XPC missense mutation (Trp690Ser) found in certain patients with XP disease revealed that this mutation is associated with a diminished ability to bind DNA. Evidence of contributions to protein interactions from regions in both XPC-N and XPC-C along with recently recognized homologies to yeast PNGase prompted construction of a structural model of a folded XPC core. This model offers key insights into how domains from the two portions of the protein may cooperate in generating specific XPC functions.     

A seventh complementation group in excision-deficient xeroderma pigmentosum.

Cells from a xeroderma pigmentosum patient XP2BI who has reached 17 years of age with no keratoses or skin tumours constitute a new, 7th complementation group G. These cells exhibit a low residual level of excision repair, 2% of normal after a UV dose of 5 J/m2 and an impairment of post-replication repair characteristic of excision-defective XPs. They are also sensitive to the lethal effects of UV and defective in host-cell reactivation of UV-irradiated SV40 DNA.     

Biochemical heterogeneity in xeroderma pigmentosum complementation group E.

Cells from two patients with xeroderma pigmentosum complementation group E (XP-E) have been shown to lack an activity which binds specifically to UV-irradiated DNA (Chu and Chang, 1988). We investigated the occurrence of this binding activity in cell strains from nine additional, unrelated XP-E patients and found that all but one of these strains contained normal levels of the binding protein. Furthermore, the binding activity from these XP-E strains was indistinguishable from that of normal controls in thermal stability, behavior on ion-exchange chromatography, and electrophoretic mobility of protein-DNA complexes, indicating that there were no gross structural alterations in the protein. The association of XP-E with a deficiency in DNA-damage binding protein in cells from 3 of 12 XP-E patients (compared to 0 of 20 non-XP-E controls) is statistically significant (p less than 0.05), but there is no obvious correlation between the biochemical defect and the clinical or cellular characteristics of individual patients. Implications of these findings for the role of the binding protein in XP-E are discussed.     

A further definition of characteristics of DNA-excision repair in xeroderma pigmentosum complementation group A strains

The location in the genome of excision repair following exposure to UV (254 nm) of two XP complementation group A strains, XP12BE and XP8LO, that differ considerably in their excision-repair rates, have been determined. Capacity for repair in XP8LO has also been determined. Sites repaired in DNA in a 24-h post-UV period were located relative to the remaining pyrimidine dimers using the M. luteus UV-endonuclease to nick partially repaired DNA and sedimentation in alkaline sucrose to size the resulting DNA. Repair in group A occurs randomly throughout the genome in a manner similar to that observed for normal cells but in contrast to domain-limited repair in group C strains. This observation defines a further similarity of the excision repair detected in group A compared to normal cells that is in addition to the previously reported related characteristics of the respective excision rate curves. A reduced repair capacity in XP8LO relative to normal cells was detected. This strain, which repairs DNA at an initial rate identical to that of normal strains when irradiated with doses of 5 J/m2 or less, repairs DNA at a slower than normal but constant rate at higher doses. This leads to the suggestion that XP8LO is defective in the number of repair enzyme complexes compared to normal cells.     

A ninth complementation group in xeroderma pigmentosum, XP I

A new complementation group of excision-deficient xeroderma pigmentosum (XP) is described in 2 patients living in the F.R.G. Dermatological, ophthalmological and neurological symptoms of XP are presented together with DNA repair characteristics such as unscheduled DNA synthesis, colony-forming ability and alkaline elution studied in cultured fibroblasts. The results are compared to normal controls.     

UV damage-specific DNA-binding protein in xeroderma pigmentosum complementation group E

The gel mobility shift assay method revealed a specifically ultraviolet (UV) damage recognizing, DNA-binding protein in nuclear extracts of normal human cells. The resulted DNA/protein complexes caused the two retarded mobility shifts. Four xeroderma pigmentosum complementation group E (XPE) fibroblast strains derived from unrelated Japanese families were not deficient in such a DNA damage recognition/binding protein because of the normal complex formation and gel mobility shifts, although we confirmed the reported lack of the protein in the European XPE (XP2RO and XP3RO) cells. Thus, the absence of this binding protein is not always commonly observed in all the XPE strains, and the partially repair-deficient and intermediately UV-hypersensitive phenotype of XPE cells are much similar whether or not they lack the protein.     

Repair of ultraviolet radiation damage in xeroderma pigmentosum cells belonging to complementation group F

DNA-repair characteristics of xeroderma pigmentosum belonging to complementation group F were investigated. The cells exhibited an intermediate level of repair as measured in terms of (1) disappearance of T4 endonuclease-V-susceptible sites from DNA, (2) formation of ultraviolet-induced strand breaks in DNA, and (3) ultraviolet-induced unscheduled DNA synthesis during post-irradiation incubation. The impaired ability of XP3YO to perform unscheduled DNA synthesis was restored, to half the normal level, by the concomitant treatment with T4 endonuclease V and ultraviolet-inactivated Sendai virus. It is suggested that xeroderma pigmentosum cells of group F may be defective, at least in part, in the incision step of excision repair.     

Cell lines from xeroderma pigmentosum complementation group A lack a single-stranded-DNA-binding activity

Human fibroblasts and HeLa cells contain two major DNA-binding activities for superhelical DNA, which can be separated by phosphocellulose chromatography. The DNA-binding activity which elutes first from the column coelutes with and is probably identical to a single-stranded-DNA-binding activity. The second activity has been characterized previously. It binds preferentially to super-helical DNA containing DNA damage, but does not bind to single-stranded DNA. Five cell lines derived from patients with the repairdeficiency syndrome xeroderma pigmentosum (XP) were analyzed for the presence of these binding activities. Four of the cell lines were from the A-complementation group and one was from the D-complementation group of XP. The binding activity with preference for damaged DNA was present in all cell lines. The single-stranded-DNA-binding activity was present in the XP-D cell line but was absent or reduced in all of the four XP-A cell lines tested.     

Cockayne syndrome complementation group B associated with xeroderma pigmentosum phenotype

Two siblings have been reported whose clinical manifestations (cutaneous photosensitivity and central nervous system dysfunction) are strongly reminiscent of the DeSanctis-Cacchione syndrome (DCS) variant of xeroderma pigmentosum (XP), a severe form of XP. Fibroblasts from the siblings showed UV sensitivity, a failure of recovery of RNA synthesis (RRS) after UV irradiation, and a normal level of unscheduled DNA synthesis (UDS), which were, unexpectedly, the biochemical characteristics usually associated with Cockayne syndrome (CS). However, no complementation group assignment in these cells has yet been performed. We here report that these patients can be assigned to CS complementation group B (CSB) by cell fusion complementation analysis. To our knowledge, these are the first patients with defects in the CSB gene to be associated with an XP phenotype. The results imply that the gene product from the CSB gene must interact with the gene products involved in excision repair and associated with XP.     

Excision repair in xeroderma pigmentosum group C cells is regulated differently in transformed cells and primary fibroblasts

Excision repair in xeroderma pigmentosum group C cells occurs at about 20-30% of normal levels. In confluent fibroblasts a unique characteristic of this low repair is that it is clustered, representing very efficient repair in a small region of the genome. In SV40-transformed fibroblasts and Epstein-Barr virus-transformed lymphocytes of complementation group C, however, excision repair is randomly distributed. This may be a consequence of the high rate of proliferation of both of these cell types, because random repair is also observed in rapidly proliferating group C fibroblasts. The distribution of sites that can be mended in group C cells, therefore, varies according to the transformed and proliferative state of the cells, demonstrating that transformed cells do not always exhibit repair characteristics identical to those of primary fibroblasts.     

Evidence that xeroderma pigmentosum cells from complementation group E are deficient in a homolog of yeast photolyase.

Xeroderma pigmentosum (XP) patients are deficient in the excision repair of damaged DNA. Recognition of the DNA lesion appears to involve a nuclear factor that is defective in complementation group E (XPE binding factor). We have now identified a factor in the yeast Saccharomyces cerevisiae that shares many properties with XPE binding factor, including cellular location, abundance, magnesium dependence, and relative affinities for multiple forms of damaged DNA. Yeast binding activity is dependent on photolyase, which catalyzes the photoreactivation of pyrimidine dimers. These results suggest that yeast photolyase may also function as an auxiliary protein in excision repair. Furthermore, XPE binding factor appears to be the human homolog of yeast photolyase.     

Five complementation groups in xeroderma pigmentosum.

A collaborative study was undertaken to determine the relationship between the three DNA repair complementation groups in xeroderma pigmentosum found at Erasmus University, Rotterdam, and the four groups found at the National Institutes of Health, Bethesda. The results of this study reveal that there are five currently known complementation groups in xeroderma pigmentosum.     

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.     

Mutation spectra induced by alpha-acetoxytamoxifen-DNA adducts in human DNA repair proficient and deficient (xeroderma pigmentosum complementation group A) cells

Tamoxifen, a breast cancer drug, has recently been approved for the chemoprevention of this disease. However, tamoxifen causes hepatic carcinomas in rats through a genotoxic mechanism and increases the risk of endometrial tumors in women. DNA adducts have been detected at low levels in human endometrium, and there is much interest in determining whether DNA damage plays a role in tamoxifen-induced endometrial carcinogenesis. This study investigates the mutagenicity of tamoxifen DNA adducts formed by alpha-acetoxytamoxifen, a reactive ester producing the major DNA adduct formed in livers of tamoxifen-treated rats. pSP189 plasmid DNA containing the supF gene was treated with alpha-acetoxytamoxifen and adduct levels (0.5-8.0 adducts per plasmid) determined by (32)P-postlabeling. Adducted plasmids were transfected into nucleotide excision repair proficient (GM00637) or deficient (GM04429, XPA) human fibroblasts. After replication, plasmids were recovered and screened in indicator bacteria. Relative mutation frequencies increased with the adduct level, with 1.3-3.6-fold higher numbers of mutations in the XP cells compared to the GM00637 cells, indicating that NER plays a significant role in the removal of these particular tamoxifen DNA adducts. The majority of sequence alterations (91-96%) occurred at GC base pairs, as did mutation hotspots, although the type and position of mutations was cell-specific. In both cell lines, as the adduct level increased, the proportion of GC --> AT transitions decreased and GC --> TA transversions, mutations known to arise from the major tamoxifen adducts, increased. Given the high mutagenicity of dG-N(2)-tamoxifen adducts, if not excised, they may potentially contribute to the initiation of endometrial cancer in women.     

Clonal chromosome rearrangements in a fibroblast strain from a patient affected by xeroderma pigmentosum (complementation group C)

We report the results of DNA repair studies and cytogenetic investigations in a patient presenting acute phothosensitivity and cancerous skin lesions. In lymphocytes and fibroblasts a reduced level of unscheduled DNA synthesis after UV irradiation was found and the presence of xeroderma pigmentosum, complementation group C, mutation was demonstrated by complementation analysis. In lymphocyte and fibroblast cultures the frequency of spontaneous chromosome gaps and breaks was normal, whereas the frequency of chromosome rearrangements was higher than expected. In fibroblasts from the 4th to the 18th passage of the culture, 4 reciprocal translocations with a clonal distribution were identified. The rearranged chromosomes were Nos. 2, 13, 14 and 15, Nos. 2 and 13 being both involved in 3 different translocations with breakpoints at 2q21, 2q31, 2p23 and 13q31, 13q12 or 3. The biological significance of this finding is discussed in view of a possible correlation with the DNA repair defect and a possible relevance in tumor development of specific chromosome rearrangements.