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.     

Xeroderma pigmentosum complementation group G associated with Cockayne syndrome.

Xeroderma pigmentosum (XP) and Cockayne syndrome (CS) are two rare inherited disorders with a clinical and cellular hypersensitivity to the UV component of the sunlight spectrum. Although the two traits are generally considered as clinically and genetically distinct entities, on the biochemical level a defect in the nucleotide excision-repair (NER) pathway is involved in both. Classical CS patients are primarily deficient in the preferential repair of DNA damage in actively transcribed genes, whereas in most XP patients the genetic defect affects both "preferential" and "overall" NER modalities. Here we report a genetic study of two unrelated, severely affected patients with the clinical characteristics of CS but with a biochemical defect typical of XP. By complementation analysis, using somatic cell fusion and nuclear microinjection of cloned repair genes, we assign these two patients to XP complementation group G, which previously was not associated with CS. This observation extends the earlier identification of two patients with a rare combined XP/CS phenotype within XP complementation groups B and D, respectively. It indicates that some mutations in at least three of the seven genes known to be involved in XP also can result in a picture of partial or even full-blown CS. We conclude that the syndromes XP and CS are biochemically closely related and may be part of a broader clinical disease spectrum. We suggest, as a possible molecular mechanism underlying this relation, that the XPGC repair gene has an additional vital function, as shown for some other NER genes.     

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.     

The XPD complementation group. Insights into xeroderma pigmentosum, Cockayne's syndrome and trichothiodystrophy.

The xeroderma pigmentosum complementation group D is defined by more than 30 unrelated individuals of whom less than half show major abnormalities of the central nervous system, once considered to be the hallmark of the group. Fibroblasts from the great majority of these individuals show very considerable sensitivity to UV light in vitro despite the fact that the cells carry out what appears to be substantial excision repair, as judged from repair synthesis and incision activity. This article reviews the XPD group and the defects in cellular DNA repair and examines the lack of correlation between repair and the appearance of neurological abnormalities. The article also discusses the recent awareness that at least some members of two other inherited conditions, trichothiodystrophy and Cockayne's Syndrome, carry mutations in the XPD gene.     

Oxidative damage-induced PCNA complex formation is efficient in xeroderma pigmentosum group A but reduced in Cockayne syndrome group B cells.

Proliferating cell nuclear antigen (PCNA), a processivity factor for DNA polymerases delta and epsilon, is essential for both DNA replication and repair. PCNA is required in the resynthesis step of nucleotide excision repair (NER). After UV irradiation, PCNA translocates into an insoluble protein complex, most likely associated with the nuclear matrix. It has not previously been investigated in vivo whether PCNA complex formation also takes place after oxidative stress. In this study, we have examined the involvement of PCNA in the repair of oxidative DNA damage. PCNA complex formation was studied in normal human cells after treatment with hydrogen peroxide, which generates a variety of oxidative DNA lesions. PCNA was detected by two assays, immunofluorescence and western blot analyses. We observed that PCNA redistributes from a soluble to a DNA-bound form during the repair of oxidative DNA damage. PCNA complex formation was analyzed in two human natural mutant cell lines defective in DNA repair: xeroderma pigmentosum group A (XP-A) and Cockayne syndrome group B (CS-B). XP-A cells are defective in overall genome NER while CS-B cells are defective only in the preferential repair of active genes. Immunofluorescent detection of PCNA complex formation was similar in normal and XP-A cells, but was reduced in CS-B cells. Consistent with this observation, western blot analysis in CS-B cells showed a reduction in the ratio of PCNA relocated as compared to normal and XP-A cells. The efficient PCNA complex formation observed in XP-A cells following oxidative damage suggests that formation of PCNA-dependent repair foci may not require the XPA gene product. The reduced PCNA complex formation observed in CS-B cells suggests that these cells are defective in the processing of oxidative DNA damage.     

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.     

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.     

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.     

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.     

A C. elegans homolog of the Cockayne syndrome complementation group A gene

Cockayne syndrome (CS) is a debilitating and complex disorder that results from inherited mutations in the CS complementation genes A and B, CSA and CSB. The links between the molecular functions of the CS genes and the complex pathophysiology of CS are as of yet poorly understood and are the subject of intense debate. While mouse models reflect the complexity of CS, studies on simpler genetic models might shed new light on the consequences of CS mutations. Here we describe a functional homolog of the human CSA gene in Caenorhabditis elegans. Similar to its human counterpart, mutations in the nematode csa-1 gene lead to developmental growth defects as a consequence of DNA lesions.     

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.     

Spontaneous chromosomal anomalies in lymphocytes from xeroderma pigmentosum. A study of ten patients

A cytogenetic study of the lymphocytes from 6 classic and 4 variant forms of xeroderma pigmentosum is reported. This study performed on 978 R-banded metaphases shows that there is no specific chromosomal rearrangement in this disorder. In UDS-deficient forms, the rates of deletions, chromatid gaps and chromosome gaps are significantly increased. The preferential involvement of G-bands is discussed.     

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.     

Normal rate of DNA breakage in xeroderma pigmentosum complementation group E cells treated with 8-methoxypsoralen plus near-ultraviolet radiation

Treatment of normal and xeroderma pigmentosum complementation group E skin fibroblasts with 8-methoxypsoralen plus repeated doses of near-ultraviolet radiation elicited a marked increase in DNA strand breakage during a subsequent incubation. No such induction of breaks was noted with cells from xeroderma pigmentosum groups A and D. The results suggest that the gene product which is deficient in xeroderma pigmentosum group E cells is involved in a critical step of DNA repair of far-ultraviolet photoproducts but not so in the repair of psoralen cross-links.     

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.