Photoreactivation of pyrimidine dimers in the DNA of normal and xeroderma pigmentosum cells.

Photoproducts formed in the DNA of human cells irradiated with ultraviolet light (uv) were identified as cyclobuytl pyrimidine dimers by their chromatographic mobility, reversibility to monomers upon short wavelength uv irradiation, and comparison of the kinetics of this monomerization with that of authentic cis-syn thymine-thymine dimers prepared by irradiation of thymine in ice. The level of cellular photoreactivation of these dimers reflects the level of photoreactivating enzyme measured in cell extracts. Action spectra for cellular dimer photoreactivation in the xeroderma pigmentosum line XP12BE agree in range (300 nm to at least 577 nm) and maximum (near 400 nm) with that for photoreactivation by purified human photoreactivating enzyme. Normal human cells can also photoreactivate dimers in their DNA. The action spectrum for the cellular monomerization of dimers is similar to that for photoreactivation by the photoreactivating enzyme in extracts of normal human fibroblasts.     

The rate of removal of pyrimidine dimers in quiescent cultures of normal human and xeroderma pigmentosum cells

The rate of removal of pyrimidine dimers from DNA of UV (254 nm)-irradiated (1 J/m2) normal and xeroderma pigmentosum (XP) cells maintained in culture as nondividing populations was determined. Several normal and XP strains from complementation groups A, C and D were studied. The excision rates and survival ability of nondividing cells were examined to determine if an abnormal sensitivity was associated with a decreased rate of dimer excision. The results show that all normal strains studied excise pyrimidine dimers at the same rate, with the rate curve characterized by two components. All 'excision-deficient' XP strains excise dimers at a slower-than-normal rate, with the rate curves also characterized by two components. The rate constants for the first components of all of the XP strains (group A, C and D) are the same, one tenth of the normal rate constant, except for XP8LO (group A). XP8LO has a first-component rate constant similar to that of normal strains and a second component rate constant similar to that of other group A strains (XP12BE, XP25RO). Thus, the slower rate of dimer excision in XP8LO is due to a defect in the mechanism responsible for the second component of the excision-rate curve. In general, an abnormal sensitivity of nondividing cells to UV is associated with a reduced dimer-excision rate. A notable exception to this is the group C strain XP1BE which has an initial repair rate similar to that of group A XP12BE but is considerably more resistant when survival is measured.     

Regulation of DNA repair in serum-stimulated xeroderma pigmentosum cells

The regulation of DNA repair during serum stimulation of quiescent cells was examined in normal human cells, in fibroblasts from three xeroderma pigmentosum complementation groups (A, C, and D), in xeroderma pigmentosum variant cells, and in ataxia telangiectasia cells. The regulation of nucleotide excision repair was examined by exposing cells to ultraviolet irradiation at discrete intervals after cell stimulation. Similarly, base excision repair was quantitated after exposure to methylmethane sulfonate. WI-38 normal human diploid fibroblasts, xeroderma pigmentosum variant cells, as well as ataxia telangiectasia cells enhanced their capacity for both nucleotide excision repair and for base excision repair prior to their enhancement of DNA synthesis. Further, in each cell strain, the base excision repair enzyme uracil DNA glycosylase was increased prior to the induction of DNA polymerase using the identical cells to quantitate each activity. In contrast, each of the three xeroderma complementation groups that were examined failed to increase their capacity for nucleotide excision repair above basal levels at any interval examined. This result was observed using either unscheduled DNA synthesis in the presence of 10 mM hydroxyurea or using repair replication in the absence of hydroxyurea to quantitate DNA repair. However, each of the three complementation groups normally regulated the enhancement of base excision repair after methylmethane sulfonate exposure and each induced the uracil DNA glycosylase prior to DNA synthesis. These results suggest that there may be a relationship between the sensitivity of xeroderma pigmentosum cells from each complementation group to specific DNA damaging agents and their inability to regulate nucleotide excision repair during cell stimulation.     

Semiautomated autoradiographic measurement of DNA repair in normal and xeroderma pigmentosum cultured human fibroblasts

Summary Assessment of DNA repair in cultured human fibroblasts by autoradiography may be facilitated by using semiautomated grain counting instruments. The instrument-determined number of autoradiographic grains per nucleus in cultured human skin fibroblasts was found to be linear in comparison to visual counts up to only 30 grains per nucleus. However, with two different instruments a greater range of linearity (to 100 to 120 grains per nucleus) was attained by measuring the grain surface area per nucleus. Semiautomated analysis of the grain surface area per nucleus yielded measurements of relative rates of unscheduled DNA synthesis after ultraviolet irradiation in xeroderma pigmentosum and normal human fibroblasts, which were reproducible and rapid.     

Fluorescent-light-induced lethality and DNA repair in normal and xeroderma pigmentosum fibroblasts

Cell survival and induction of endonuclease-sensitive sites in DNA were measured in human fibroblast cells exposed to fluorescent light or germicidal ultraviolet light. Cells from a xeroderma pigmentosum patient were hypersensitive to cell killing by fluorescent light, although less so than for germicidal ultraviolet light. Xeroderma pigmentosum cells were deficient in the removal of fluorescent light-induced endonuclease sites that are probably pyrimidine dimers, and both the xeroderma pigmentosum and normal cells removed these sites with kinetics indistinguishable from those for ultraviolet light-induced sites. A comparison of fluorescent with ultraviolet light data demonstrates that there are markedly fewer pyrimidine dimers per lethal event for fluorescent than for ultraviolet light, suggesting a major role for non-dimer damage in fluorescent light lethality.     

Mechanisms of impairment of DNA repair in human cells. Interferons stimulated DNA repair in xeroderma pigmentosum cells

DNA repair synthesis and strand break DNA repair induced by 4-nitroquinoline-1-oxide and UV-irradiation in Xeroderma pigmentosum lymphocytes and fibroblasts pretreated by leucocyte interferons were studied. Stimulation of DNA repair synthesis in interferon-pretreated Xeroderma pigmentosum cells, defective in incision, was detected. No such effect was noted for strand break DNA repair. Hence, antimutagenic activity of interferons in human cells is connected with their modificating effect on DNA repair.     

Induction and repair of psoralen cross-links in DNA of normal human and xeroderma pigmentosum fibroblasts

Skin fibroblasts from normal human subjects were exposed in vitro to long-wave ultraviolet radiation (UVA, 320–400 nm) alone, or in combination with 8-methoxypsoralen (8-MOP). DNA damage was analysed with the alkaline elution technique before and after post-treatment incubation of the cells at 37°C for various times.Cells treated with UVA at 1.1 J/cm² showed an increased DNA elution rate, which returned to the normal level within 30 min of post-treatment incubation. In cells treated with PUVA (8-MOP at 20 μg/ml plus UVA at 0.04 J/cm²), the alkaline elution rate was not different from untreated control cells, either before or after post-treatment incubation for times up to 7 days.When the PUVA treatment was followed first by a washing, to remove any unbound 8-MOP, and then by UVA (PUVA + UVA) at 1.1 J/cm², the alkaline elution rate decreased below the control level. During the post-treatment incubation of the PUVA + UVA-treated cells there was a gradual increase of the alkaline elution rate to a level significantly above that in control cells. This increase was observed after 30 min. It reached a miaximum after 24 h and remained after 7 days of post-treatment incubation. Cells from a patient with xeroderma pigmentosum of complementation group A, which were given the same PUVA + UVA treatment, did not show any change in the alkaline elution rate during the post-treatment incubation.If, as seems likely, an increased alkaline elution rate indicates an increase of DNA breaks, and a decreased alkaline elution rate indicates the sealing of breaks and/or the formation of cross-links, the results would suggest the following: (1) UVA irradiation in itself is capable of inducing DNA breaks, which are rapidly sealed during post-treatment incubation; (2) PUVA treatment induces mono-adducts, some of which appear to remain in the DNA for at least 7 days of post-treatment incubation and can be activated to form DNA cross-links by a second dose of UVA; (3) DNA cross-links induced by PUVA + UVA can be recognized by a repair process that involves the formation of DNA breaks. This process is not observed in xeroderma pigmentosum cells of group A.     

Low-level DNA exchanges in normal human and xeroderma pigmentosum cells after UV irradiation

We have used a T4 endonuclease V assay method for UV-induced pryrimidine dimers in cellular DNA in vivo to obtain evidence for recombinational DNA exchanges after UV irradiation of normal human and Xeroderma pigmentosum (XP) cells. Our data indicate that the endonuclease-sensitive sites in excision-defective XP cells are removed very slowly from the irradiated parental strands and appear concomitantly in daughter strands newly synthesized during post-UV incubation. In the defective XP cells, the extent of appearance of sensitive sites in daughter strands synthesized during a period of 24 h after 10 J/m² appears to be small, probably less than 15% of the initial number of sensitive sites detected in cellular parental strands. Demonstration of such exchanges between normal-density parental and 5-bromodeoxyuridine-labeled daughter strands by alkaline CsCl isopycnic centrifugation was unsuccessful. Further, the extent is much lower in normal human cell because of their efficiet excision repair of the dimers before and after exchanges than in the defective XP cells.     

Effects of inhibitors on repair of DNA in normal human and xeroderma pigmentosum cells after exposure to x-rays and ultraviolet irradiation

Experiments were carried out to obtain direct evidence for the hypothesis that in human cells the repair of UV-damaged DNA is initiated by an incision step, and that this step is defective in cells from patients having Xeroderma pigmentosum (XP). The alkaline sucrose gradient centrifugation technique was used to detect breaks in the DNA.A decreased sedimentation velocity of the DNA was found after exposure of normal and XP cells to high doses of UV (5000 erg/mm²). Breaks were induced in the DNA by the UV irradiation without the action of an enzyme. After exposure of both types of cell to UV doses of 100–500 erg/mm², breaks that might occur by enzymic incision were not observed, possibly because of immediate rejoining.After single-strand breaks had been induced by X-rays, rejoining did not occur at temperatures lower than 22°. Rejoining was inhibited by KCN, 2,4-dinitrophenol, EDTA, iodoacetate and crystal violet. Actinomycin D, acriflavine and phleomycin, also tested as potential inhibitors of the repair process, induced breaks or conformational changes in the DNA of unirradiated normal and XP cells.Application to UV-exposed cells of conditions that inhibit the rejoining of breaks did not cause accumulation of breaks in the DNA. The results suggest a coordinated and sequential performance of the steps in the repair of each UV lesion by repair enzymes which may act as a complex.     

Efficient repair of cyclobutane pyrimidine dimers at mutational hot spots is restored in complemented Xeroderma pigmentosum group C and trichothiodystrophy/xeroderma pigmentosum group D cells

Xeroderma pigmentosum (XP) and trichothiodystrophy (TTD) are rare heritable diseases. Patients suffering from XP and 50% of TTD afflicted individuals are photosensitive and have a high susceptibility to develop skin tumors. One solution to alleviating symptoms of these diseases is to express the deficient cDNAs in patient cells as a form of gene therapy. XPC and TTD/XPD cell lines were complemented using retroviral transfer. Expressed wild-type XPC or XPD cDNAs in these cells restored the survival to UVC radiation to wild-type levels in the respective complementation groups. Although complemented XP cell lines have been studied for years, data on cyclobutane pyrimidine dimer (CPD) repair in these cells at different levels are sparse. We demonstrate that CPD repair is faster in the complemented lines at the global, gene, strand specific, and nucleotide specific levels than in the original lines. In both XPC and TTD/XPD complemented lines, CPD repair on the non-transcribed strand is faster than that for the MRC5SV line. However, global repair in the complemented cell lines and MRC5SV is still slower than in normal human fibroblasts. Despite the slower global repair rate, in the complemented XPC and TTD/XPD cells, almost all of the CPDs at "hotspots" for mutation in the P53 tumor database are repaired as rapidly as in normal human fibroblasts. Such evaluation of repair at nucleotide resolution in complemented nucleotide excision repair deficient cells presents a crucial way to determine the efficient re-establishment of function needed for successful gene therapy, even when full repair capacity is not restored.     

DNA strand breaking and rejoining in response to ultraviolet light in normal human and xeroderma pigmentosum cells.

We describe a reproducible technique for measuring DNA strand breaking and rejoining in cells after treatment with U.V.-light. Results obtained with normal human cells, xeroderma pigmentosum cells (XP, complementation group A) and XP variant cells suggest that all three of these cell-types can carry out single-strand incision with equal rapidity. However, the breaks so induced appeared to be only slowly rejoined in the XP variant cells and rejoined not at all in XP complementation group A cells. Furthermore, parental strand rejoining was inhibited by caffeine in XP variant cells but not in normal cells.     

Defective repair of gamma-ray induced DNA damage in xeroderma pigmentosum cells.

We used the bromouracil-photolysis technique to estimate the sizes of the repaired regions in normal human and xeroderma pigmentosum (XP) cells irradiated by gamma-rays aerobically or anoxically. After 1 1/2 hours of incubation, single-strand breaks were repaired and the repaired regions were small--one to two BrUra residues--for cells irradiated aerobically or anoxically. After a 20-hour incubation, the repaired region in normal cells showed a component mimicking U.V.-repair. There were large patches (approximately 30 BrUra residues) in the approximate ratios of one per six chain breaks for aerobic irradiation and one per three chain breaks for anoxic irradiation. XP cells, however, only showed large patches at 20 hours if they had been irradiated aerobically. We could not detect such regions in XP cells irradiated anoxically. These results indicate (1) that some part of ionizing damage mimics excision of U.V. damage in that the repair patches are large and the repair takes an appreciable time; (2) the types of such damage depend on whether the irradiation is done aerobically or anoxically; and (3) XP cells are defective in repairing a component of anoxic damage.     

Excision repair characteristics of denV-transformed xeroderma pigmentosum cells

Introduction of the denV gene of phage T4, encoding the pyrimidine dimer-specific endonuclease V, into xeroderma pigmentosum cells XP12RO(M1) was reported to result in partial restoration of colony-forming ability and excision repair synthesis. We have further characterized 3 denV-transformed XP clones in terms of rates of excision of pyrimidine dimers and size of the resulting resynthesized regions following exposure to 100 J/m2 from an FS-40 sunlamp. In the denV-transformed XP cells we observed 50% dimer removal within 3-6 h after UV exposure as compared to no measurable removal in the XP12RO(M1) line and 50% dimer excision after 18 h in the GM637A human, control cells. Dimer removal was assayed with Micrococcus luteus UV-endonuclease in conjunction with sedimentation of treated DNA in alkaline sucrose gradients. The size of the resulting repaired regions was determined by the bromouracil photolysis technique. Based on the photolytic sensitivity of DNA repaired in the presence of bromodeoxyuridine, we calculated that the excision of a dimer in the GM637A cells appears to be accompanied by the resynthesis of a region approximately 95 nucleotides in length. Conversely, the resynthesized regions in the denV-transformed clones were considerably smaller and were estimated to be between 13 and 18 nucleotides in length. These results may indicate that either the endonuclease that initiated dimer repair dictated the size of the resynthesized region or that the long-patch repair observed in the normal cells resulted from the repair of non-dimer DNA lesions.     

Defective repair of mitomycin C crosslinks in Fanconi's anemia and loss in confluent normal human and xeroderma pigmentosum cells

Crosslink repair of mitomycin C-induced interstrand crosslinks was studied in exponentially growing and confluent normal human, transformed WI38CT-1, Fanconi's anemia (FA) and xeroderma pigmentosum (XP) group-A fibroblasts by the assay methods of alkaline sucrose centrifugation, hydroxyapatite column chromatography and S₁-nuclease digestion. These three methods demonstrated unequivocally that crosslinking occurred at a rate of 0.13 crosslinks/10⁸ Da per μg per ml mitomycin C ( 10 μg/ml) and the first half-excision of crosslinks followed the rapid first-order kinetics of 2–3 h half-life in exponentially-growing normal, WI38CT-1 and XP group-A cells. However, the first half-excision was completely defective in three out of the four FA strains tested and severely retarded in an FA strain. These results strongly support our previous observations in different strains of normal human, FA and XP group-A cells. An important new addition is that confluent, otherwise proficient, normal and XP cells almost completely lost the ability of the first, rapid half-excision of mitomycin C crosslinks in their DNA. This probably suggests that the enzyme or regulatory factor responsible for the half-excision, which differs from that for nucleotide excision repair, present constitutively in confluent cells, may be induced or activated only in the cycling cells. However, its relation to a defective FA factor is not clear at present.     

Defective repair of mitomycin C crosslinks in Fanconi's anemia and loss in confluent normal human and xeroderma pigmentosum cells

Crosslink repair of mitomycin C-induced interstrand crosslinks was studied in exponentially growing and confluent normal human, transformed W138CT-1, Fanconi's anemia (FA) and xeroderma pigmentosum (XP) group-A fibroblasts by the assay methods of alkaline sucrose centrifugation, hydroxyapatite column chromatography and S1-nuclease digestion. These three methods demonstrated unequivocally that crosslinking occurred at a rate of 0.13 crosslinks/10(8) Da per microgram per ml mitomycin C (less than or equal to 10 micrograms/ml) and the first half-excision of crosslinks followed the rapid first-order kinetics of 2-3 h half-life in exponentially-growing normal, WI38CT-1 and XP group-A cells. However, the first half-excision was completely defective in three out of the four FA strains tested and severely retarded in an FA strain. These results strongly support our previous observations in different strains of normal human, FA and XP group-A cells. An important new addition is that confluent, otherwise proficient, normal and XP cells almost completely lost the ability of the first, rapid half-excision of mitomycin C crosslinks in their DNA. This probably suggests that the enzyme or regulatory factor responsible for the half-excision, which differs from that for nucleotide excision repair, present constitutively in confluent cells, may be induced or activated only in the cycling cells. However, its relation to a defective FA factor is not clear at present.     

Defective repair replication of DNA in xeroderma pigmentosum. 1968

Most forms of the human hereditary disease xeroderma pigmentation (XP) are due to a defect in nucleotide excision repair of DNA damage in skin cells associated with exposure to sunlight. This discovery by James Cleaver had an important impact on our understanding of nucleotide excision repair in mammals.