Cockayne Syndrome Cells Research Articles

Clustered Sites of DNA Repair Synthesis during Early Nucleotide Excision Repair in Ultraviolet Light-Irradiated Quiescent Human Fibroblasts

The ubiquitous process of nucleotide excision repair includes an obligatory step of DNA repair synthesis (DRS) to fill the gapped heteroduplex following excision of a short (∼30-nucleotide) damaged single-strand fragment. Using 5-iododeoxyuridine to label repair patches during the first 10–60 min after UV irradiation of quiescent normal human fibroblasts we have visualized a limited number of discrete foci of DRS. These must reflect clusters of elementary DRS patches, since single patches would not be detected. The DRS foci are attenuated in normal cells treated with α-amanitin or in Cockayne syndrome (CS) cells, which are specifically deficient in the pathway of transcription-coupled repair (TCR). It is therefore likely that the clusters of DRS arise in chromatin domains within which RNA polymerase II transcription is compartmentalized. However, we also found significant suppression of DRS foci in xeroderma pigmentosum, complementation group C cells in which global genome repair (GGR) is defective, but TCR is normal. This suggests that the TCR is responsible for the DRS cluster formation in the absence of GGR. The residual foci detected in CS cells indicate that, even at early times following UV irradiation, GGR may open some chromatin domains for processive scanning and consequent DRS independent of transcription.

Phenotypic consequences of mutations in the conserved motifs of the putative helicase domain of the human Cockayne Syndrome Group B gene

Cockayne syndrome (CS) is a human genetic disorder characterized by several neurological and developmental abnormalities. Two genetic complementation groups, CS-A and CS-B, have been identified. The CSB protein belongs to helicase superfamily 2, and to the SWI/SNF family of proteins. The CSB protein is implicated in transcription-coupled repair (TCR), basal transcription and chromatin remodeling. In addition, CS cells undergo UV-induced apoptosis at much lower doses than normal cells. However, the molecular function of the CSB protein in these biological pathways has remained unclear. Evidence indicates that the integrity of the Walker A and B boxes (motifs I and II) are important for CSB function, but the functional significance of the helicase motifs Ia, III–IV has not been previously examined. In this study, single amino acid changes in highly conserved residues of helicase motifs Ia, III, V, VI and a second putative nucleotide-binding motif (NTB) of the CSB protein were generated by site-directed mutagenesis to analyze the genetic function of the CSB protein in survival, RNA synthesis recovery and apoptosis after UV treatment. The survival analysis of these CS-B mutant cell lines was also performed after treatment with the chemical carcinogen, 4-nitroquinoline-1-oxide (4-NQO). The lesions induced by UV light, cyclobutane pyrimidine dimers, are known to be repaired by TCR whereas the lesions induced by 4-NQO are repaired by global genome repair. The results of this study demonstrate that the point mutations in highly conserved residues of helicase motifs Ia, III, V and VI abolished the genetic function of the CSB protein in survival, RNA synthesis recovery and apoptosis after UV treatment. Similarly, the same mutants failed to complement the sensitivity toward 4-NQO. Thus, the integrity of these helicase motifs is important for the biological function of the CSB protein. On the contrary, a point mutation in a C-terminal, second, NTB motif of the CSB protein showed full complementation in the ability to repair damage induced by UV light or 4-NQO, suggesting that this motif is not important for the CSB repair function.

Ultraviolet radiation alters the phosphorylation of RNA polymerase II large subunit and accelerates its proteasome-dependent degradation.

It has been shown that ultraviolet (UV) radiation induces the ubiquitination of the large subunit of RNA polymerase II (RNAP II-LS) as well as its proteasomal degradation. Studies in mammalian cells have indicated that highly phosphorylated forms of RNAP II-LS are preferentially ubiquitinated, but studies in Saccharomyces cerevisiae have provided evidence that unphosphorylated RNAP II-LS is an equally suitable substrate. In the present study, an antibody (ARNA-3) that recognizes all forms of RNAP II-LS, regardless of the phosphorylation status of its C-terminal domain (CTD), was utilized to evaluate the degradation of total cellular RNAP II-LS in human fibroblasts under basal conditions or after UV-C (10J/m(2)) irradiation. It was found that UV radiation rapidly shifted the phosphorylation profile of RNAP II-LS from a mixture of dephosphorylated and phosphorylated forms to entirely more phosphorylated forms. This shift in phosphorylation status was not blocked by pharmacologic inhibition of either the ERK or p38 pathways, both of which have been implicated in the cellular UV response. In addition to shifting the phosphorylation profile, UV radiation led to net degradation of total RNAP II-LS. UV-induced degradation of RNAP II-LS was also greatly reduced in the presence of the transcriptional and CTD kinase inhibitor DRB. Using a panel of protease inhibitors, it was shown that the bulk of UV-induced degradation is proteasome-dependent. However, the UV-induced loss of hypophosphorylated RNAP II-LS was proteasome-independent. Lastly, UV radiation induced a similar shift to all hyperphosphorylated RNAP II-LS in Cockayne syndrome (CS) cells of complementation groups A or B (CSA or CSB) when compared to appropriate controls. The UV-induced degradation rates of RNAP II-LS were not significantly altered when comparing CSA or CSB to repair competent control cells. The implications for the cellular UV response are discussed.

Cerebro-Oculo-Facio-Skeletal Syndrome with a Nucleotide Excision–Repair Defect and a Mutated XPD Gene, with Prenatal Diagnosis in a Triplet Pregnancy

Cerebro-oculo-facio-skeletal (COFS) syndrome is a recessively inherited rapidly progressive neurologic disorder leading to brain atrophy, with calcifications, cataracts, microcornea, optic atrophy, progressive joint contractures, and growth failure. Cockayne syndrome (CS) is a recessively inherited neurodegenerative disorder characterized by low to normal birth weight, growth failure, brain dysmyelination with calcium deposits, cutaneous photosensitivity, pigmentary retinopathy and/or cataracts, and sensorineural hearing loss. Cultured CS cells are hypersensitive to UV radiation, because of impaired nucleotide-excision repair (NER) of UV-induced damage in actively transcribed DNA, whereas global genome NER is unaffected. The abnormalities in CS are caused by mutated CSA or CSB genes. Another class of patients with CS symptoms have mutations in the XPB, XPD, or XPG genes, which result in UV hypersensitivity as well as defective global NER; such patients may concurrently have clinical features of another NER syndrome, xeroderma pigmentosum (XP). Clinically observed similarities between COFS syndrome and CS have been followed by discoveries of cases of COFS syndrome that are associated with mutations in the XPG and CSB genes. Here we report the first involvement of the XPD gene in a new case of UV-sensitive COFS syndrome, with heterozygous substitutions-a R616W null mutation (previously seen in patients in XP complementation group D) and a unique D681N mutation-demonstrating that a third gene can be involved in COFS syndrome. We propose that COFS syndrome be included within the already known spectrum of NER disorders: XP, CS, and trichothiodystrophy. We predict that future patients with COFS syndrome will be found to have mutations in the CSA or XPB genes, and we document successful use of DNA repair for prenatal diagnosis in triplet and singleton pregnancies at risk for COFS syndrome. This result strongly underlines the need for screening of patients with COFS syndrome, for either UV sensitivity or DNA-repair abnormalities.

Deletion of the CSB homolog, RAD26, yields Spt(-) strains with proficient transcription-coupled repair.

It has been previously shown that disruption of RAD26 in yeast strain W303-1B results in a strain that is deficient in transcription-coupled repair (TCR), the preferential repair of the transcribed strand of an expressed gene over the non-transcribed strand and the rest of the genome. RAD26 encodes a protein that is homologous to Cockayne syndrome group B protein (CSB) and is a member of the SWI2/SNF2 family of DNA-dependent ATPases involved in chromatin remodeling. Like the rad26 mutant, cells from Cockayne syndrome patients are defective in TCR. We examined the role of Rad26 in TCR by disrupting RAD26 in two repair-proficient laboratory strains and, remarkably, observed no effect upon TCR. Our results indicate that disruption of RAD26 alone is insufficient to impair TCR. Thus, W303-1B must already possess a mutation that, together with disruption of RAD26, causes a deficiency in TCR. We suggest that other genes are mutated in Cockayne syndrome cells that contribute to the deficiency in TCR. Surprisingly, deletion of RAD26 results in expression of genes that are repressed by flanking transposon delta elements, an Spt(-) phenotype. The delta elements appear to perturb local chromatin structure. Expression of genes flanked by delta elements in rad26Delta mutants is consistent with a role for Rad26 in chromatin remodeling.

Cyclobutane Pyrimidine Dimers and Bulky Chemical DNA Adducts Are Efficiently Repaired in Both Strands of Either a Transcriptionally Active or Promoter-deleted APRT Gene

Both prokaryotic and eukaryotic cells have the capacity to repair DNA damage preferentially in the transcribed strand of actively expressed genes. However, we have found that several types of DNA damage, including cyclobutane pyrimidine dimers (CPDs) are repaired with equal efficiency in both the transcribed and nontranscribed strands of the adenine phosphoribosyltransferase (APRT) gene in Chinese hamster ovary cells. We further found that, in two mutant cell lines in which the entire APRT promoter region has been deleted, CPDs are still efficiently repaired in both strands of the promoterless APRT gene, even though neither strand appears to be transcribed. These results suggest that efficient repair of both strands at this locus does not require transcription of the APRT gene. We have also mapped CPD repair in exon 3 of the APRT gene in each cell line at single nucleotide resolution. Again, we found similar rates of CPD repair in both strands of the APRT gene domain in both APRT promoter-deletion mutants and their parental cell line. Our findings suggest that current models of transcription-coupled repair and global genomic repair may underestimate the importance of factors other than transcription in governing the efficiency of nucleotide excision repair.

Cockayne syndrome and xeroderma pigmentosum.

To review genetic variants of Cockayne syndrome (CS) and xeroderma pigmentosum (XP), autosomal recessive disorders of DNA repair that affect the nervous system, and to illustrate them by the first case of xeroderma pigmentosum-Cockayne syndrome (XP-CS) complex to undergo neuropathologic examination. Published reports of clinical, pathologic, and molecular studies of CS, XP neurologic disease, and the XP-CS complex were reviewed, and a ninth case of XP-CS is summarized. CS is a multisystem disorder that causes both profound growth failure of the soma and brain and progressive cachexia, retinal, cochlear, and neurologic degeneration, with a leukodystrophy and demyelinating neuropathy without an increase in cancer. XP presents as extreme photosensitivity of the skin and eyes with a 1000-fold increased frequency of cutaneous basal and squamous cell carcinomas and melanomas and a small increase in nervous system neoplasms. Some 20% of patients with XP incur progressive degeneration of previously normally developed neurons resulting in cortical, basal ganglia, cerebellar, and spinal atrophy, cochlear degeneration, and a mixed distal axonal neuropathy. Cultured cells from patients with CS or XP are hypersensitive to killing by ultraviolet (UV) radiation. Both CS and most XP cells have defective DNA nucleotide excision repair of actively transcribing genes; in addition, XP cells have defective repair of the global genome. There are two complementation groups in CS and seven in XP. Patients with the XP-CS complex fall into three XP complementation groups. Despite their XP genotype, six of nine individuals with the XP-CS complex, including the boy we followed up to his death at age 6, had the typical clinically and pathologically severe CS phenotype. Cultured skin and blood cells had extreme sensitivity to killing by UV radiation, DNA repair was severely deficient, post-UV unscheduled DNA synthesis was reduced to less than 5%, and post-UV plasmid mutation frequency was increased. The paradoxical lack of parallelism of phenotype to genotype is unexplained in these disorders. Perhaps diverse mutations responsible for UV sensitivity and deficient DNA repair may also produce profound failure of brain and somatic growth, progressive cachexia and premature aging, and tissue-selective neurologic deterioration by their roles in regulation of transcription and repair of endogenous oxidative DNA damage.

UV-induced inhibition of transcription involves repression of transcription initiation and phosphorylation of RNA polymerase II.

Cells from patients with Cockayne syndrome (CS) are hypersensitive to DNA-damaging agents and are unable to restore damage-inhibited RNA synthesis. On the basis of repair kinetics of different types of lesions in transcriptionally active genes, we hypothesized previously that impaired transcription in CS cells is a consequence of defective transcription initiation after DNA damage induction. Here, we investigated the effect of UV irradiation on transcription by using an in vitro transcription system that allowed uncoupling of initiation from elongation events. Nuclear extracts prepared from UV-irradiated or mock-treated normal human and CS cells were assayed for transcription activity on an undamaged beta-globin template. Transcription activity in nuclear extracts closely mimicked kinetics of transcription in intact cells: extracts from normal cells prepared 1 h after UV exposure showed a strongly reduced activity, whereas transcription activity was fully restored in extracts prepared 6 h after treatment. Extracts from CS cells exhibited reduced transcription activity at any time after UV exposure. Reduced transcription activity in extracts coincided with a strong reduction of RNA polymerase II (RNAPII) containing hypophosphorylated C-terminal domain, the form of RNAPII known to be recruited to the initiation complex. These results suggest that inhibition of transcription after UV irradiation is at least partially caused by repression of transcription initiation and not solely by blocked elongation at sites of lesions. Generation of hypophosphorylated RNAPII after DNA damage appears to play a crucial role in restoration of transcription. CS proteins may be required for this process in a yet unknown way.

Molecular characterization of an acidic region deletion mutant of Cockayne syndrome group B protein.

Cockayne syndrome (CS) is a human genetic disorder characterized by post-natal growth failure, neurological abnormalities and premature aging. CS cells exhibit high sensitivity to UV light, delayed RNA synthesis recovery after UV irradiation and defective transcription-coupled repair (TCR). Two genetic complementation groups of CS have been identified, designated CS-A and CS-B. The CSB gene encodes a helicase domain and a highly acidic region N-terminal to the helicase domain. This study describes the genetic characterization of a CSB mutant allele encoding a full deletion of the acidic region. We have tested its ability to complement the sensitivity of UV61, the hamster homolog of human CS-B cells, to UV and the genotoxic agent N-acetoxy-2-acetylaminofluorene (NA-AAF). Deleting 39 consecutive amino acids, of which approximately 60% are negatively charged, did not impact on the ability of the protein to complement the sensitive phenotype of UV61 cells to either UV or NA-AAF. Our data indicate that the highly acidic region of CSB is not essential for the TCR and general genome repair pathways of UV- and NA-AAF-induced DNA lesions.

Transcription-coupled repair in yeast is independent from ubiquitylation of RNA pol II: implications for Cockayne's syndrome.

Cockayne's syndrome cells lack transcription-coupled nucleotide excision repair (TCR) and ubiquitylation of RNA polymerase II large subunit (RNA pol II LS), suggesting that ubiquitylation of RNA pol II LS may be necessary for TCR in eukaryotes. Rsp5 is the sole yeast ubiquitin-protein ligase that ubiquitylates RNA pol II LS in cells exposed to DNA-damaging agents. In yeast lacking functional Rsp5, there is no ubiquitylation of RNA pol II LS. We show here that removal, repression, or over-expression of Rsp5 has no effect on TCR, demonstrating that ubiquitylation of the RNA pol II LS is not required for TCR. We infer that the lack of ubiquitylation of RNA pol II LS in Cockayne's syndrome cells does not cause their defect in TCR.

Manitoba Aboriginal Kindred with Original Cerebro-Oculo-Facio-Skeletal Syndrome Has a Mutation in the Cockayne Syndrome Group B ( CSB) Gene

Cerebro-oculo-facio-skeletal (COFS) syndrome is a rapidly progressive neurological disorder leading to brain atrophy with calcification, cataracts, microcornea, optic atrophy, progressive joint contractures, and growth failure. Cockayne syndrome (CS) is a recessively inherited neurodegenerative disorder characterized by low-to-normal birth weight; growth failure; brain dysmyelination with calcium deposits; cutaneous photosensitivity; pigmentary retinopathy, cataracts, or both; and sensorineural hearing loss. CS cells are hypersensitive to UV radiation because of impaired nucleotide excision repair of UV radiation-induced damage in actively transcribed DNA. The abnormalities in CS are associated with mutations in the CSA or CSB genes. In this report, we present evidence that two probands related to the Manitoba Aboriginal population group within which COFS syndrome was originally reported have cellular phenotypes indistinguishable from those in CS cells. The identical mutation was detected in the CSB gene from both children with COFS syndrome and in both parents of one of the patients. This mutation was also detected in three other patients with COFS syndrome from the Manitoba Aboriginal population group. These results suggest that CS and COFS syndrome share a common pathogenesis.

Role of the ATPase domain of the Cockayne syndrome group B protein in UV induced apoptosis.

Cockayne syndrome (CS) is a human autosomal recessive disorder characterized by many neurological and developmental abnormalities. CS cells are defective in the transcription coupled repair (TCR) pathway that removes DNA damage from the transcribed strand of active genes. The individuals suffering from CS do not generally develop cancer but show increased neurodegeneration. Two genetic complementation groups (CS-A and CS-B) have been identified. The lack of cancer formation in CS may be due to selective elimination of cells containing DNA damage by a suicidal pathway. In this study, we have evaluated the role of the CSB gene in UV induced apoptosis in human and hamster cells. The hamster cell line UV61 carries a mutation in the homolog of the human CSB gene. We show that both human CS-B and hamster UV61 cells display increased apoptotic response following UV exposure compared with normal cells. The increased sensitivity of UV61 cells to apoptosis is complemented by the transfection of the wild type human CSB gene. In order to determine which functional domain of the CSB gene participates in the apoptotic pathway, we constructed stable cell lines with different CSB domain disruptions. UV61 cells were stably transfected with the human CSB cDNA containing a point mutation in the highly conserved glutamic acid residue in ATPase motif II. This cell line (UV61/ pc3.1-CSBE646Q) showed the same increased apoptosis as the UV61 cells. In contrast, cells containing a deletion in the acidic domain at the N-terminal end of the CSB protein had no effect on apoptosis. This indicates that the integrity of the ATPase domain of CSB protein is critical for preventing the UV induced apoptotic pathway. In primary human CS-B cells, the induction and stabilization of the p53 protein seems to correlate with their increased apoptotic potential. In contrast, no change in the level of either p53 or activation of mdm2 protein by p53 was observed in hamster UV61 cells after UV exposure. This suggests that the CSB dependent apoptotic pathway can occur independently of the transactivation potential of p53 in hamster cells.

Transcription-coupled repair: a multifunctional signaling pathway.

It is well established that certain types of DNA damage, for example, UV-induced pyrimidine dimers, blockthe progression of RNA polymerase. Evidence suggesting a relationship between DNA repair and transcriptionwas presented by Mayne and Lehmann (1982), who observed that the recovery of RNA synthesis was morerapid than the overall time course of DNA repair in UVirradiated human cells. In addition, it was found that although Cockayne syndrome (CS) cells were able to carryout normal levels of repair synthesis, they were unable torecover their RNA synthesis after UV irradiation. Thus, itwas suggested that the defect in CS cells resides in the repair of damage in transcribed genes. There is now a largebody of evidence showing that damage produced by UVand certain chemical carcinogens is repaired more rapidlyin transcriptionally active DNA compared to the genomeas a whole. This rapid repair was originally shown to bedue to a faster repair of damage in the transcribed strandthan in the nontranscribed strand in both hamster and human genes (Mellon et al. 1987; Leadon and Lawrence1991). Although strand-specific repair of UV damagewas originally demonstrated in mammalian cells, it hasnow also been confirmed in Escherichia coli (Mellon andHanawalt 1989) and Saccharomyces cerevisiae (Smerdon et al. 1990; Leadon and Lawrence 1992; Sweder andHanawalt 1992) and hence appears to be a highly conserved pathway for excision repair...

Alterations in the CSB gene in three Italian patients with the severe form of Cockayne syndrome (CS) but without clinical photosensitivity.

Cockayne syndrome (CS) is a rare autosomal recessive disorder characterized by postnatal growth failure, mental retardation and otherwise clinically heterogeneous features which commonly include cutaneous photosensitivity. Cultured cells from sun-sensitive CS patients are hypersensitive to ultraviolet (UV) light and, following UV irradiation, are unable to restore RNA synthesis rates to normal levels. This has been attributed to a specific deficiency in CS cells in the ability to carry out preferential repair of damage in actively transcribed regions of DNA. We report here a cellular and molecular analysis of three Italian CS patients who were of particular interest because none of them was sun-sensitive, despite showing most of the features of the severe form of CS, including the characteristic cellular sensitivity to UV irradiation. They all were altered in the CSB gene. The genetically related patients CS1PV and CS3PV were homozygous for the C1436T transition resulting in the change Arg453opal. Patient CS2PV was a compound heterozygote for two new causative mutations, insertions of an A at position 1051 and of TGTC at 2053, leading to truncated proteins of 367 and 681 amino acids. These mutations result in severely truncated proteins, as do many of those that we previously identified in several sun-sensitive CS-B patients. These observations confirm that the CSB gene is not essential for viability and cell proliferation, an important issue to be considered in any speculation on the recently proposed additional function of the CSB protein in transcription. Our investigations provide data supporting the notion that other factors, besides the site of the mutation, influence the type and severity of the CS clinical features.

Repair of 8-oxoguanine in DNA is deficient in Cockayne syndrome group B cells.

The incision of the 8-oxoguanine in DNA by normal and Cockayne Syndrome (CS) cell extracts has been investigated. The incision in extracts derived from CS cells was approximately 50% of the incision level compared with extracts prepared from normal cells. In contrast, the incision rate of uracil and thymine glycol was not defective in CS cells. The deficiency in 8-oxoguanine incision was also demonstrated in a CS family. Whereas the proband had markedly less incision compared with the normal siblings, the parents had intermediate levels. The low level of 8-oxoguanine-DNA glycosylase in CS extracts correlates with the reduced expression of the 8-oxoguanine-DNA glycosylase gene (hOGG1) in CS cells. Both the levels of expression of the hOGG1 gene and the incision of 8-oxoguanine in DNAincreased markedly after transfection of CS-B cells with the CSB gene. We suggest that the CSB mutation leads to deficient transcription of the hOGG1 gene and thus to deficient repair of 8-oxoguanine in DNA.

High sensitivity of the ultraviolet-induced p53 response in ultraviolet-sensitive syndrome, a photosensitive disorder with a putative defect in deoxyribonucleic acid repair of actively transcribed genes

Previously, we reported a new category of photosensitive disorder named ultraviolet-sensitive syndrome (UVs S) [T. Itoh, T. Fujiwara, T. Ono, M. Yamaizumi, UVs syndrome, a new general category of photosensitive disorder with defective DNA repair, is distinct from xeroderma pigmentosum variant and rodent complementation group 1, Am. J. Hum. Genet. 56 (1995) 1267–1276.]. Cells derived from these patients show impaired recovery of RNA synthesis (RRS) after UV-irradiation irrespective of having a normal level of unscheduled DNA synthesis (UDS). These characteristics are reminiscent of Cockayne syndrome (CS) cells. By comparing sensitivity of the UV-induced p53 response in cells with different types of defects in nucleotide excision repair, we hypothesized that the UV-induced p53 response is triggered by inhibition of RNA synthesis [M. Yamaizumi, T. Sugano, UV-induced nuclear accumulation of p53 is evoked through DNA damage of actively transcribed genes independent of the cell cycle, Oncogene 9 (1994) 2775–2784.]. To test this hypothesis, we determined sensitivity of the p53 response in UVs S cells by immunostaining, Western blotting, and FACScan analysis. Maximal nuclear accumulation of p53 in the UVs S cells was observed with a one-third UV dose required for that in normal cells, while almost identical p53 responses were observed in UVs S and normal cells following treatment with heat or α-amanitin. Recovery of RNA synthesis after a low dose of UV-irradiation was impaired in UVs S cells to the same extent as seen in CS cells. These results provide further evidence to support our previous hypothesis regarding the mechanism of the p53 response induced by DNA damage.

Enhancement of XPG mRNA transcription by human interferon-beta in Cockayne syndrome cells with complementation group B.

Human interferon-beta (HuIFN-beta) confers UV-refractoriness in association with increased DNA repair capacity to human cells. We examined the modulation of XPG gene expression by HuIFN-beta in UV-sensitive cells from Cockayne syndrome complementation B (CSB), xeroderma pigmentosum complementation A (XPA) and normal control cells. Northern blot analysis revealed that XPG mRNA was more extensively transcribed in CSB cells treated with HuIFN-beta than in those without HuIFN-beta treatment. XPG mRNA from XPA cells and normal control cells was not markedly transcribed by HuIFN-beta treatment compared to that from CSB cells. The findings suggested that different mechanisms of UV-refractoriness by HuIFN-beta exist between CS and XP.

Detection of UV-induced K-ras codon 12 mutation by PCR and differential dot-blot hybridization in cells from Down syndrome and Cockayne syndrome.

By means of the polymerase chain reaction (PCR) and differential dot-blot hybridization, base substitution mutations of K-ras codon 12 were investigated in skin fibroblast cells from Down syndrome (DS) patients. Mutations were identified in DS cells after UV irradiation, predominantly in cells from younger patients. In contrast, no mutation was detected in cells from Cockayne syndrome (CS) patients who had the same features of premature aging as in DS but were not prone to cancer. This association of DS cells, but not CS cells, with inducibility of the K-ras codon 12 mutation may imply the proneness of DS patients to cancer development but a lack of proneness of CS patients.

Cockayne syndrome without typical clinical manifestations including neurologic abnormalities

Although patients with mild symptoms of atypical Cockayne syndrome (CS) have been described, there has not been a report of a patient with CS whose only clinical manifestation was cutaneous photosensitivity. Cells from patients with CS show UV sensitivity, reduced recovery of RNA synthesis, but normal UV-induced unscheduled DNA synthesis. On the other hand, the patients with UV-sensitive syndrome have only cutaneous photosensitivity and skin freckles, whereas those cells respond to UV radiation in a similar fashion to the CS cells. We describe a patient with CS who showed only photosensitivity without typical clinical manifestations of CS, but his cells showed UV sensitivity, reduced recovery of RNA synthesis, and normal unscheduled DNA synthesis after UV radiation similar to CS cells. Furthermore, the patient was assigned to complementation group B of CS on the basis of the results of complementation analysis. The present report suggests that CS has a wider spectrum than that considered previously. (J Am Acad Dermatol 1998;39:565-70.)

Enhancement of XPG mRNA expression by human interferon-beta in Cockayne syndrome cells.

Using PCR-differential display, we have searched for genes expressed specially in human interferon (HuIFn)-beta-treated Cockayne syndrome (CS) fibroblast cells. Eighteen expressed genes induced by HuIFN-beta were identified, the sequences of seven of which were highly homologous to previously cloned sequences. The cDNAs of six of these seven clones were similar to expression tagged sequences from unknown genes in databases and the remaining one was identical to the cDNA of the xeroderma pigmentosum XPG gene. These results, together with our previous finding of increased resistance to ultraviolet (UV) cell-killing of CS cells pretreated with HuIFN-beta prior to UV irradiation suggest that XPG might be one of the genes possibly involved in the HuIFN-beta-induced UV-resistance.