Three complementation groups in Cockayne syndrome

After 16 Jm-2 of UV-irradiation non-dividing normal cells recover normal rates of RNA synthesis within 24 h, whereas in cells from donors with Cockayne syndrome (CS) the rate of RNA synthesis gradually declines. Cultures of a mixed population from 2 CS donors were fused with polyethylene glycol; subsequently they were UV-irradiated and RNA synthesis was measured autoradiographically in mono-, bi-, and multinuclear cells. Genetic complementation was indicated by high levels of RNA synthesis in bi- and multinuclear cells when compared with mononuclear cells. Using this assay, 11 CS strains have been assigned to three complementation groups: 2 into group A, 8 into group B and 1 into group C. The strain in group C is derived from an individual who also had xeroderma pigmentosum (XP), and was the sole known representative of XP-complementation group B.     

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.     

Clinical and biochemical studies in three patients with severe early infantile Cockayne syndrome

Summary We present clinical and biochemical data from three patients with severe Cockayne syndrome (CS) of very early onset. Unlike in classic CS, signs became evident in the first weeks of life and led to unusually early death. Fibroblasts from two of the patients showed a complete defect of the repair of UV-induced thymine dimer lesions. They were unable to remove thymine dimer lesions from their DNA, had a severe reduction of the RNA synthesis rates after UV irradiation, and showed no reactivation of an UV-inactivated indicator gene and no DNA recondensation after UV irradiation. DNA repair investigated in these two fibroblast cell strains resembled that of xeroderma pigmentosum cells of complementation group A. In contrast, fibroblasts from the third patient showed the same in vitro repair characteristics as classic CS cells.     

Complementation analysis of xeroderma pigmentosum variants

DNA repair after UV exposure was studied in multinucleate cells, obtained after fusion of excision-defective and variant xeroderma pigmentosum fibroblasts. Optimal fusion conditions were determined, facilitating the measurement of DNA replication in heterokaryons. In unirradiated multikaryons, entry into the S phase was depressed, when compared with unfused cells. The extent of the depression of S phase entry was dependent on the fusion conditions. In heterokaryons obtained after fusion of XP variant (6 different strains) with excision-defective XP (three cell strains from complementation groups A, C and D) both unscheduled DNA synthesis and postreplication repair after UV irradiation were restored to normal levels. In contrast, complementation was not observed after pairwise fusion of the XP variant cell strains. These results suggest that the XP variants comprise a single complementation group, different from complementation groups A, C and D.     

Repair of DNA damage after exposure to 4-nitroquinoline-1-oxide in heterokaryons derived from xeroderma pigmentosum cells

Xeroderma pigmentosum (XP) cells are dificient in the repair of damage induced by ultraviolet irradiation. Excision-repair-deficient XP cell strains have been classified into 7 distinct complementation groups, according to results of studies on cell fusion and UV irradiation. XP cells are not only abnormally sensitive to UV, but also to a variety of chemical carcinogens, including 4-nitroquinoline-1-oxide (4NQO). Complementation analysis with XP strains from 4 different complementation groups with respect to the repair of 4NQO-induced DNA damage revealed that the classification of the strains into complementation groups with respect to 4NQO-induced repair coincides with the classification based on the repair of UV damage.     

Abnormal sensitivity of some Cockayne's syndrome cell strains to UV- and gamma-rays. Association with a reduced ability to repair potentially lethal damage

Cockayne's syndrome (CS) is a rare autosomal recessive genetic disease characterized by mental and physical retardation, microcephaly, dwarfism, retinitis pigmentosa and a hypersensitivity to sunlight. Cells originating from patients also exhibit, in vitro, a hypersensitivity to UV radiation. Using a colony assay in vitro, we studied the sensitivity of 5 CS cell strains (GM739, BOR, CS697, CS698 and KA) and two normal ones (HF19 and GP) to UV- and gamma-irradiation. The 5 CS strains appear to be UV-hypersensitive but the sensitivity varies widely from one strain to another. Hypersensitivity to gamma-rays has been reported for 4 out of the 5 CS cell strains investigated. However, these CS cell strains are less sensitive to gamma-rays than are ataxia telangiectasia cells. The KA cell strain exhibits a normal response to gamma-irradiation. Repair of potentially lethal damage (PLD) after UV- and gamma-irradiation was investigated by using unfed plateau-cell cultures. Under these conditions, control cells show a great capacity to repair PLD (10- to 30-fold survival increase at 1% survival level). The two CS strains (GM739 and BOR), which are hypersensitive to both UV- and gamma-irradiation, exhibit no or only little PLD repair after treatment. In contrast, the normal response of KA cells to gamma-rays is associated with a normal PLD repair capability. This latter cell strain exhibits an intermediate sensitivity to UV and shows an intermediate PLD repair capacity. The response of CS cell strains after gamma-irradiation suggests a genetic heterogeneity. Three complementation groups are described in CS cells when dealing with UV radiosensitivity. However, variations in gamma-ray sensitivity are reported for cells within the same UV complementation group.     

Complementation between uvr mutants of Streptococcus pyogenes

Summary From the group A streptococcal strains K 56 and 56 188, respectively 13 and 6 nitrosoguanidine-induced uvr mutants were isolated and used in complementation experiments employing strain 56 188 and its derivatives as donors in phage A 25-mediated heterologous transductions. When A 25 propagated on wild type or on 2 of the six 56 188-derived uvr mutants was used to infect 4 of the uvr recipient strains, a substantial increase in survivors of UV irradiation was found over those observed in selfing experiments or control experiments without phage. Less than 1% of the UV survivors had stably integrated the uvr ⁺ allele. The remaining 4 uvr donors failed to complement the 4 above-mentioned recipients, indicating that the strains in question fell into 2 complementation groups.Nine of the 13 K 56-derived mutants, which in contrast to the others were characterized by non-reversibility to UV resistance, did not even show an increase in UV survivors when infected with phage grown on wild type. The possibility is discussed that these strains might carry second mutations affecting UV sensitivity which, however, did not appear to be of the rec type.     

Dose-dependent increase in repair of 1-β-d-arabinofuranosylcytosinedetectable DNA lesions in UV-treated xeroderma pigmentosum (group A) fibroblasts

The extent of DNA-excision repair was determined in human fibroblast strains from clinically normal and xeroderma pigmentosum complementation group A (XP-A) donors after irradiation with 254-nm ultraviolet (UV) light. Repair was monitored by the use of 1-β-d-arabinofuranosylcytosine (araC), a potent inhibitor of DNA synthesis, and alkaline sucrose velocity sedimentation to quantitate DNA single-strand breaks. In this approach, the number of araC-accumulated breaks in post-UV incubated cultures becomes a measure of the efficiency of a particular strain to perform long-patch excision repair. The maximal rate of removal of araC-detectable DNA lesions equalled ∼ 1.8 sites/10⁸ dalton/h in the normal strains (GM38, GM43), while it was more than 10-fold lower in both XP-A strains (XP4LO, XP12BE) examined. In normal fibroblasts the number of lesions removed during the first 4 h after irradiation saturated at ∼ 10 J/m². In contrast, the residual amount of repair in the excision-deficient cells increased as a linear function of UV fluence over a range 5–120 J/m². Thus we conclude that the repair of araC-detectable UV photoproducts in XP group A fibroblasts is limited by availability of damaged regions in the genome to repair complexes.     

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 alpha-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.     

Complementing xeroderma pigmentosum fibroblasts restore biological activity to UV-damaged DNA.

UV survival curves of adenovirus 2 using fused, complementing xeroderma pigmentosum (XP) fibroblast strains as virus hosts showed a component with an inactivation slope identical to that given by normal cells. This component was not observed when the fibroblasts were not fused or when fusion involved strains in the same complementation group. Extrapolation of this component indicated that at zero dose 3% of the viral plaque-forming units had infected cells capable of normal repair. These results suggest that 3% of the cells were complementing heterokaryons, a value similar to that actually observed by autoradiographic analysis of UV-induced unscheduled DNA synthesis. Thus, heterokaryons formed from XP fibroblasts belonging to different complementation groups are as capable of restoring biological activity to UV-damaged adenovirus 2 as are normal cells.     

Cellular and genetic studies in three UV-sensitive Chinese hamster mutants

Three UV sensitive (UV^s) mutants (CHO43RO, CHO423PV, CHO30PV), characterized by different levels of reduction in their ability to perform unscheduled DNA synthesis (UDS), were analysed for spontaneous and UV-induced frequency of chromosomal aberrations and for sensitivity to alkylating agents. The baseline frequency of chromosomal aberrations was in the normal range, whereas after UV irradiation a positive correlation between the degree of UV sensitivity and the rate of chromosomal breakage was observed. Survival experiments after mutagen exposure indicated that the UV^s clones are characterized by different levels of hypersensitivity to bifunctional alkylating agents whereas the sensitivity to monofunctional alkylating agents is in the normal range. Genetic analysis performed by measuring the survival after UV in hybrids produced by fusing UV^s cells with wild-type or UV^s cells belonging to the six Chinese hamster complementation groups, indicated that the three clones carry recessive mutations and belong to c.g. 2. These findings suggest that defects in the same gene may result in different degrees of phenotypic alterations.Abbreviations CG complementation group - EMS ethyl methane sulfonate - MMS methyl methane sulfonate - MMC mitomycin C - UV ultraviolet - UDS unscheduled DNA synthesis     

Relationship between pyrimidine dimers, 6-4 photoproducts, repair synthesis and cell survival: studies using cells from patients with trichothiodystrophy

Trichothiodystrophy is a genetic disease which in the majority of cases studied is associated with a deficiency in the ability to repair UV damage in cellular DNA. Three categories of UV response have been identified. In type 1 the response is completely normal, whereas type 2 cells are deficient in excision-repair, with properties indistinguishable from those of XP complementation group D. Type 3 cells have normal survival following UV-irradiation and normal rates of removal of cyclobutane pyrimidine dimer sites. Nevertheless repair synthesis is reduced by 50% in these cell strains and this is associated with a marked reduction in the repair of 6-4 photoproducts from cellular DNA. The present results show that 50% or more of repair synthesis at early times after irradiation of normal primary human fibroblasts is attributable to repair of 6-4 products. They also suggest that repair of cyclobutane dimers is crucial for cell survival.     

Dose-dependent increase in repair of 1-beta-D-arabinofuranosylcytosine-detectable DNA lesions in UV-treated xeroderma pigmentosum (group A) fibroblasts

The extent of DNA-excision repair was determined in human fibroblast strains from clinically normal and xeroderma pigmentosum complementation group A (XP-A) donors after irradiation with 254-nm ultraviolet (UV) light. Repair was monitored by the use of 1-beta-D-arabinofuranosylcytosine (araC), a potent inhibitor of DNA synthesis, and alkaline sucrose velocity sedimentation to quantitate DNA single-strand breaks. In this approach, the number of araC-accumulated breaks in post-UV incubated cultures becomes a measure of the efficiency of a particular strain to perform long-patch excision repair. The maximal rate of removal of araC-detectable DNA lesions equalled approximately 1.8 sites/10(8) dalton/h in the normal strains (GM38, GM43), while it was more than 10-fold lower in both XP-A strains (XP4LO, XP12BE) examined. In normal fibroblasts the number of lesions removed during the first 4 h after irradiation saturated at approximately 10 J/m2. In contrast, the residual amount of repair in the excision-deficient cells increased as a linear function of UV fluence over a range 5-120 J/m2. Thus we conclude that the repair of araC-detectable UV photoproducts in XP group A fibroblasts is limited by availability of damaged regions in the genome to repair complexes.     

Reduced DNA repair in progeria cells and effects of gamma-ray irradiation on UV-induced unscheduled DNA synthesis in normal and progeria cells

A reduction in the amount of UV-induced unscheduled DNA synthesis (UDS), and reduced cell survival and host-cell reactivation against UV exposure in Hutchinson-Gilford progeria syndrome cell strains were shown. UV-induced UDS in 4 progeria cell strains was 33-50% of the normal level. A similar reduction in the UV-induced UDS in normal cells was caused by gamma-ray irradiation to the cells before UV irradiation. The dose of gamma-rays required to cause a reduction in UDS of normal cells to the level of progeria cells was 40 Gy and the reduction was reversible after 2 days. In progeria cells, gamma-ray irradiation further reduced UDS with a lower gamma-ray dose required than in normal cells, and the reduction was also reversible but with less relative recovery than in normal cells. The presence of a 'built-in' defect in progeria cells responsible for the reduced DNA-repair capacity was suggested, and such defect may share a common mechanism with the reduction of UV-induced UDS in normal cells caused by gamma-ray irradiation.