XERODERMA PIGMENTOSUM COMPLEMENTATION GROUP F: MORE ASSIGNMENTS AND REPAIR CHARACTERISTICS

Abstract— The specific heterodikaryon complementation method enabled us to assign three patients with mild xeroderma pigmentosum (XP) symptoms (XP25KO, XP27KO, XP28KO) to complementation group F. UV-induced unscheduled DNA synthesis (UDS) remained unnormalized in the heterodikaryons between either of the above three XP strains and the reference group F XP3YO. All these particular XP strains as well as XP3YO exhibited an equally low level of10–15% UDS by a 3 h [³H]-thymidine labeling following 10 J/m² 254 nm UV, while they attained 60% UDS of normal at an extended time of 25 h. The present group F strains were 3 and 1.5 times as sensitive to the lethal effect of UV as normal and XP group E cells, respectively, based on the mean lethal dose ( Do ) comparison. Normal cells had the biphasic time-UDS kinetics of early rapid and late slow repair. Characteristically, however, all of the present group F strains were defective in only early rapid repair, but normally proficient in slow repair.     

REDUCED REPAIR OF NON-DIMER PHOTOPRODUCTS IN A GENE TRANSFECTED INTO XERODERMA PIGMENTOSUM CELLS

Abstract— 4ells from patients with the sun sensitive cancer-prone disease, xeroderma pigmentosum (XP) have defective repair of UV damaged DNA with reduced excision of the major photoproduct, the cyclobutane type pyrimidine dimer. Other (non-dimer) photoproducts, have recently been implicated in UV mutagenesis. Utilizing an expression vector host cell reactivation assay, we studied UV damaged transfecting DNA that was treated by in vitro photoreactivation to reverse pyrimidine dimers while not altering other photoproducts. We found that the reduced expression of a UV damaged transfecting plasmid in XP complementation group A cells is only partially reversed by photoreactivation. E. coli photolyase treatment of pSV2catSVgpt exposed to 100 or 200 J m⁻² of 254 nm radiation removed 99% of the T4 endonuclease V sensitive sites. Transfection of XP12BE(SV40) cells with photoreactivated pSV2catSVgpt showed residual inhibition corresponding to 25 to 37% of the lethal hits to the cat gene. This residual inhibition corresponds to the fraction of non-dimer photoproducts induced by UV. This result implies that XP12BE(SV40) cells do not repair most of the non-dimer photoproducts in DNA.     

REPAIR OF THYMINE DIMERS AND (6–4) PHOTOPRODUCTS IN GROUP A XERODERMA PIGMENTOSUM CELL LINES HARBORING A TRANSFERRED NORMAL CHROMOSOME 9

Transfer of a normal chromosome 9 into a xeroderma pigmentosum (XP)-A cell line partially restored its DNA repair activity. XP-A cell lines harboring a transferred chromosome were much more UV-resistant than parental XP-A cells but still more UV-sensitive than normal cells. The amount of UV-induced unscheduled DNA synthesis was only one-third of that in normal cells. The repair of thymine dimers and (6-4) photoproducts in these cell lines was analyzed by using monoclonal antibodies raised against them. Although these XP-A cell lines carrying a normal chromosome 9 could repair (6-4) photoproduct with a little lower efficiency than normal cells, the repair of thymine dimers was completely absent in these cells. The present results suggest a gene-dosage effect in DNA excision repair mechanisms in human cells or a rather complicated mechanism which involves two or more pathways.     

EFFICIENCY OF REPAIR OF PYRIMIDINE DIMERS AND PSORALEN MONOADDUCTS IN NORMAL AND XERODERMA PIGMENTOSUM HUMAN CELLS

Abstract —Repair of DNA damage produced by ultraviolet light or 5-methylisopsoralen in normal and xeroderma pigmentosum human cells involves many similar steps. Aphidicolin and cytosine arabinoside block repair of both kinds of damage with similar efficiency, indicating that DNA polymerase a has a major role in repair for these lesions. In xeroderma pigmentosum cells of various complementation groups, the relative efficiency of excision repair for both ultraviolet- and 5-methylisopsoralen-induced damage was group A < C < D, indicating a close resemblance between both kinds of lesions in relation to the repair deficiencies in these groups. At high doses, the maximum rate of repair of damage by ultraviolet light was about twice that for methylisopsoralen damage, possibly because ultraviolet-induced damage forms a substrate that is more readily recognized and excised than that of the psoralen adducts. Differences in the structural distortions to DNA caused by these kinds of damage could be detected using single strand specific nucleases which excised dimers but not 5-MIP adducts from double strand DNA.     

INHIBITION OF DNA SYNTHESIS BY PSORALEN-INDUCED LESIONS IN XERODERMA PIGMENTOSUM AND FANCONI''S ANEMIA FIBROBLASTS

Abstract— Exposure of human cells to psoralens and near-UV light produces a mixture of monoadducts and crosslinks in DNA, which inhibit DNA synthesis by blocking replicon initiation and chain elongation. 8-Methoxypsoralen (8-MOP) has a greater effect than angelicin in normal, xeroderma pigmentosum, and Fanconi's anemia cells. Recovery of DNA synthesis is not detectable up to 8 h after exposure. The average distance between lesions that block replication in individual replicons was measured by means of bromodeoxyuridine photolysis. After exposure to 10 μg/mℓ of 8-MOP and 7500 J/m² of near-UV light, blocks were formed every 20 μm. Replicon initiation was inhibited by exposure to near-UV light alone in normal and xeroderma pigmentosum. Exposure to low concentrations of angelicin or 8-MOP plus near-UV light inhibited replicon initiation in normal and Fanconi's anemia cells, but not in xeroderma pigmentosum cells. Inhibition of initiation was not obvious after treatment with high concentrations of 8-MOP or angelicin because of the dominant effect of crosslinks in blocking chain elongation.     

EXCISION REPAIR OF UVR-INDUCED PYRIMIDINE DIMERS IN CORNEAL DNA

Abstract— We measured excision repair of ultraviolet radiation (UVR)-induced pyrimidine dimers in DNA of the corneal epithelium of the marsupial, Monodelphis domestica , using damage-specific nucleases from Micrococcus luteus in conjunction with agarose gel electrophoresis. We observed that 100 J ^-2 of UVR from aFS–40 sunlamp(280–400 nm) induced an average of 2.2 ± 0.2 times 10^-2 endonuclease-sensitive sites per kilobase (ESS/kb) (pyrimidine dimers) and that ∼ 50% of the dimers were repaired within 12 h after exposure. We also determined that an exposure of 400 J m^-2 was needed to induce comparable numbers of pyrimidine dimers (2.5 times 10^-2) in the DNA of skin of M. domestica in vivo . In addition, we found that 50% of the dimers were also removed from the epidermal cells of M. domestica within 12 h after exposure. A dose of 100 J m^-2 was necessary to induce similar levels of pyrimidine dimers (2.0 ± 0.2 times 10^-2) in the DNA of the cultured marsupial cell line Pt K2 ( Potorous tridactylus ).     

DNA BREAKS CAUSED BY MONOCHROMATIC 365 nm ULTRAVIOLET-A RADIATION OR HYDROGEN PEROXIDE and THEIR REPAIR IN HUMAN EPITHELIOID and XERODERMA PIGMENTOSUM CELLS

The induction and repair of DNA single-strand breaks (SSB) assayed by alkaline filter elution was compared in human epithelioid P3 and xeroderma pigmentosum (XP) cells exposed to monochromatic 365-nm UV-A radiation and H2O2. Initial yields of SSB were measured with the cells held at 0.5 degrees C during exposure. The yield from exposure to 365-nm radiation was slightly greater in XP than in P3 cells, whereas H2O2 produced more than three times as many SSB in P3 compared with XP cells. o-Phenanthroline (50 mM) markedly inhibited the yields of SSB induced in XP cells by H2O2, but had no effect on those produced by 365-nm UV-A. These results are consistent with the fact that P3 cells, unlike XP cells, have undetectable levels of catalase. The measured production of trace amounts of H2O2 by the actual 365-nm UV-A exposures was not sufficient to account for the numbers of breaks that were observed. Single-strand breaks produced by both agents were completely repaired after 50 min in P3 cells, as were H2O2-induced SSB in XP cells. However, 25% of the 365-nm UV-A-induced SSB in XP cells remained refractory to repair after 60 min. The results show that SSB produced by these two agents are different and that 365 nm radiation produces most SSB in cells by mechanisms other than by production of H2O2.     

LETHALITY AND THE INDUCTION AND REPAIR OF DNA DAMAGE IN FAR, MID OR NEAR UV-IRRADIATED HUMAN FIBROBLASTS: COMPARISON OF EFFECTS IN NORMAL, XERODERMA PIGMENTOSUM AND BLOOM'S SYNDROME CELLS

Abstract Using normal human fibroblasts we have determined the ability of far (254 nm), mid (310 nm) or near (365 nm) UV radiation to: (i) induce pyrimidine dimers (detected as UV endonuclease sensitive sites) and DNA single-strand breaks (detected in alkali); (ii) elicit excision repair, monitored as unscheduled DNA synthesis (UDS); and (iii) reduce colony-forming ability. Unscheduled DNA synthesis studies were also performed on dimer excision-defective xeroderma pigmentosum (XP) cells, and the survival studies were extended to include XP and Bloom's syndrome (BS) strains. UV-induced cell killing in normal, BS and XP cells was found to relate to an equivalent dimer load per genome after 254 or 310 nm exposure, whereas at 365 nm the lethal effects of non-dimer damage appeared to predominate. Lethality could not be correlated with DNA strand breakage at any wavelength. The two XP strains examined showed the same relative UDS repair deficiency at the two shorter wavelengths in keeping with a predominant role for pyrimidine dimer repair in the expression of UDS. However, UDS was not detected in 365 nm UV-irradiated normal and XP cells despite dimer induction; this effect was due to the inhibition of DNA repair functions since 365 nm UV-irradiated normal cells showed reduced capacity to perform UDS subsequent to challenge with 254 nm UV radiation.
In short, the near UV component of sunlight apparently induces biologically important non-dimer damage in human cells and inhibits DNA repair processes, two actions which should be considered when assessing the deleterious actions of solar UV.     

DNA EXCISION REPAIR IN LYMPHOCYTES FOLLOWING PHOTOAFFINITY LABELING WITH ETHIDIUM MONOAZIDE

Irradiation of ethidium monoazide by fluorescent light promotes a chemical decomposition of the azide into a highly reactive nitrene intermediate. Covalent bonding of this electrophile to the DNA in the cell provokes repair of damage which can be monitored by incorporation of [³H]-thymidine. Human lymphocytes were labeled with [¹⁴C]-ethidium azide and then allowed to undergo DNA repair. Repair incorporation of [³H]-thymidine showed saturation at 5 µM ethidium azide, but excision of the labeled drug failed to saturate at 20 µM, suggesting that excision and resynthesis are two separate events. Cells were also labeled with the photosensitive drug and/or exposed to UV radiation, and then allowed to undergo a period of DNA repair. The tritium incorporation for the combined insults was less than the sum of the two insults. Quinacrine, progesterone and chloroquine inhibited repair incorporation of [³H]-thymidine, but had no effect on the excision of the drug from the DNA. After damage by ethidium azide, chromatin was isolated from lymphocytes which had been allowed to repair label with [³H]-thymidine. Partial digestion of the chromatin with micrococcal nuclease released 80% of the tritium when approximately 40% of the DNA had been hydrolyzed by the enzyme.     

XERODERMA PIGMENTOSUM FIBROBLASTS INCLUDING CELLS FROM XP VARIANTS ARE ABNORMALLY SENSITIVE TO THE MUTAGENIC AND CYTOTOXIC ACTION OF BROAD SPECTRUM SIMULATED SUNLIGHT

Abstract— The cytotoxic and mutagenic effects of broad spectrum simulated sunlight, as delivered by a Westinghouse Sun Lamp FS 20 filtered to eliminate wavelengths below 290 nm, were determined in diploid human skin fibroblasts which differ in their ability to repair pyrimidine dimers, and compared with results obtained with UV 254 nm radiation. The cell strains tested included normal fibroblasts; excision repair-deficient xeroderma pigmentosum (XP) cells from patients XP12BE (complementation group A). XP7BE (group D). and XP2BI (group G): and an XP variant patient (XP4BE) whose cells excise pyrimidinc dimers at a normal rate, but exhibit abnormal replication of DNA containing unexcised lesions. Cytotoxicity was assayed from loss of colony-forming ability. The group A cells were most sensitive to the killing effect of the Sun Lamp; the group D and G cells were slightly less sensitive; the XP variant cells showed intermediate sensitivity; and normal cells were most resistant. When the Sun Lamp survival curves for the group A, group D, the XP variant and normal cells were compared with their respective UV 254 nm survival curves, the relationships between the strains were virtually identical (i. e. the curves were related by a constant fluence modification factor). suggesting a common lesion for cell killing. The marker for mutagenesis was resistance to 6-thioguanine. The group A XP cells proved most sensitive to mutations induced by the simulated sunlight: the variant cells were intermediate; and the normal cells were the most resistant. Again, when the curves for mutations induced in these cell strains by simulated sunlight were compared with their respective 254 nm UV mutation curves, these were related by a constant fluence modification factor. suggesting a common lesion for mutagenesis. These results. taken together with published data indicating that at equicytotoxic levels of UV254 nm radiation and the filtered Sun Lamp. the number of pyrimidine dimers in the DNA of XP12BE cells was equal. support the hypothesis that the dimer is the lesion principally involved in both effects. Our data also support the hypothesis that mutations are involved in the sunlight-induced skin cancer of XP patients.     

MORE EFFICIENT EXCISION REPAIR OF PYRIMIDINE DIMERS IN THE SPECIFIC DNA SEQUENCE THAN IN THE GENOME OVERALL IN GOLDFISH CELLS

Excision repair of pyrimidine dimers induced by 254 nm UV was examined in the genome overall and in a specific sequence containing a transfected gene for hygromycin B resistance, in RBCF-1 cells derived from a goldfish, by the use of UV endonuclease of Micrococcus luteus and alkaline agarose gel electrophoresis. More than 40% of dimers were removed from the specific sequence, while about 20% were removed from the genome overall, within 24 h after exposure to UV (2.5-7.5 J/m2).     

THE TIME SEQUENCE OF EVENTS DURING EXCISION REPAIR IN TETRAHYMENA PYRIFORMIS

Abstract— The time sequence of events during excision repair of DNA in Tetrahymena pyriformis was investigated after sublethal dose of u.v. radiation. Buoyant-density analysis of the DNA from repairing cells grown in medium containing 5'-bromodeoxyuridine makes it possible to distinguish repair synthesis from normal synthesis. Analysis of the DNA synthesized at various times after irradiation clearly indicates that repair synthesis starts very quickly after irradiation and is completed within 3 to 4 hr. Immediately after irradiation, normal DNA synthesis is greatly depressed but gradually resumes until it predominates after 3 to 4 hr. The molecular weight of DNA strands is reduced and the net rate of DNA synthesis is depressed immediately after irradiation. Both of these parameters are restored to their pre-irradiation values by 3 to 4 hr after irradiation. During the repair period the majority of the pyrimidine dimers are removed. All of the data indicate that repair begins immediately after irradiation and is completed in 3 to 4 hr (about two thirds of a generation period).     

RELATIVE REPAIR OF ADENOVIRUS DAMAGED BY SUNLAMP, UV AND γ-IRRADIATION IN COCKAYNE SYNDROME FIBROBLASTS IS DIFFERENT FROM THAT IN XERODERMA PIGMENTOSUM FIBROBLASTS

The DNA repair capacities of three unrelated Cockayne syndrome (CS) fibroblast strains were compared to that of three unrelated xeroderma pigmentosum (XP) strains for three different DNA damaging agents using a sensitive host cell reactivation (HCR) technique. Adenovirus type 2 (Ad 2) was treated with either UV light, gamma-rays or sunlamp-irradiation and subsequently assayed for its ability to form viral structural antigens (Vag) in the CS and XP strains using immunofluorescent straining. D37 values for the survival of Ad 2 Vag synthesis in the CS and XP strains, expressed as a percentage of those obtained in normal strains, were used as a measure of DNA repair capacity. Percent HCR values in the XP strains XP25RO, XP2BE and XP5BE respectively were lowest for UV (6, 14 and 6%), intermediate for sunlamp-irradiation (18, 32 and 10%) and highest for gamma-irradiation (65, 61 and 60%), whereas for the CS strains CS1BE, CS3BE and CS278CTO respectively, percent HCR values were lowest for UV (26, 30 and 34%), intermediate for gamma-irradiation (61, 64 and 69%) and near normal for sunlamp-irradiation (82, 73 and 89%). These results suggest that the 'spectrum of lesions' which is defectively repaired in CS is not the same as that which is defectively repaired in XP.     

THE EFFECT OF TEMPERATURE AND WAVELENGTH ON PRODUCTION AND PHOTOLYSIS OF A UV-INDUCED PHOTOSENSITIVE DNA LESION WHICH IS NOT REPAIRED IN XERODERMA PIGMENTOSUM VARIANT CELLS

Abstract— Ultraviolet light causes a type of damage to the DNA of human cells that results in a DNA strand break upon subsequent irradiation with wavelengths around 300 nm. This DNA damage disappears from normal human fibroblasts within 5 h, but not from pyrimidine dimer excision repair deficient xeroderma pigmentosum group A cells or from excision proficient xeroderma pigmentosum variant cells. The apparent lack of repair of the ultraviolet light DNA damage described here may contribute to the cancer prone nature of xeroderma pigmentosum variant individuals. These experiments show that the same amount of damage was produced at 0^°C and 37^°C indicating a photodynamic effect and not an enzymatic reaction. The disappearance of the photosensitive lesions from the DNA is probably enzymatic since none of the damage was removed at 0^°C. Both the formation of the lesion and its photolysis by near ultraviolet light were wavelength dependent. An action spectrum for the formation of photosensitive lesions was similar to that for the formation of pyrimidine dimers and(6–4) photoproducts and included wavelengths found in sunlight. The DNA containing the lesions was sensitive to wavelengths from 304 to 340 nm with a maximum at 313 to 317 nm. This wavelength dependence of photolysis is similar to the absorption and photolysis spectra of the pyrimidine(6–4) photoproducts     

REPAIR OF ULTRAVIOLET-DAMAGED TRANSFORMING DNA IN A MISMATCH REPAIR-DEFICIENT STRAIN OF HAEMOPHILUS INFLUENZAE

Abstract— Ultraviolet inactivation of Haemophilus influenzae transforming DNA followed inverse square root kinetics in both mismatch repair-proficient(hex₊) and deficient (hex-1) recipients. No DNA concentration effect was seen with UV-excision repair-deficient(uvr_-) strains. Low-efficiency genetic markers remained more sensitive than high-efficiency ones when they were assayed on excision repair-deficienthex₊ uvr_- strains. They were equally resistant whenhex₊ uvr_- recipients were used. We explain this by assuming that recombinational repair of UV lesions in the donor strand and mismatch repair of the recipient strand may overlap and cause double strand interruptions. This will eliminate low-efficiency transformants.     

IS DNA TOPOISOMERASE INVOLVED IN THE UV EXCISION REPAIR PROCESS? NEW EVIDENCE FROM STUDIES WITH DNA INTERCALATING AND NON-INTERCALATING ANTITUMOR AGENTS

Abstract— The effects of selected DNA intercalating and non-intercalating drugs on the UV excision repair process in human fibroblasts have been examined. 9-Amino acridine, acridine orange, quinacrine, doxorubicin (adriamycin), ethidium bromide and actinomycin-D all inhibited the removal of pyrimidine dimers from cellular DNA by inhibiting the incision process as monitored by the nick translation assay and by an endonuclease-sensitive site assay. These agents also partially inhibited incision by the M. luteus endonuclease in an in vitro system. This is the only class of compounds tested to date that appears to block this early step of repair in mammalian cells. The DNA topoisomerase inhibitors, m -amsacrine and VP-16 (etoposide) and the bacterial gyrase inhibitors nalidixic acid and oxolinic acid were shown not to inhibit UV repair. As shown previously, however, novobiocin does block dimer removal and we show here that it is a potent inhibitor of the M. luteus UV endonuclease. While it has recently been demonstrated that many DNA intercalating agents block the strand-passing activity of DNA topoisomerase II giving rise to protein associated DNA strand breaks, the finding that the specific inhibitors of topoisomerase, m -AMSA and VP-16, do not inhibit repair, even though they block this strand passing activity, strongly suggests that inhibition of DNA topoisomerase is not associated with inhibition of DNA repair.     

EXCISION OF PYRIMIDINE DIMERS FROM THE NUCLEAR DNA OF A HAPLOID RESPIRATION-DEFICIENT (ρ) STRAIN OF SACCHAROMYCES CEREVISIAE

Abstract— A haploid respiration-deficient (ρ^-) mutant of Saccharomyces cerevisiae exhibits a lower ability to excise ultraviolet-induced pyrimidine dimers in various post-irradiation treatments as compared to the original respiration-competent wild-type strain. This decrease in excision may account for the inability of ρ^- strains to show liquid-holding recovery.     

CHARACTERIZATION OF RAD4 GENE REQUIRED FOR ULTRAVIOLET-INDUCED EXCISION REPAIR OF Saccharomyces cerevisiae PROPAGATED IN Escherichia coli WITHOUT INACTIVATION

The previously isolated RAD4 gene designated as pPC1 from the genomic library of Saccharomyces cerevisiae (Yoon et al., 1985, Korean J. Genetics 7, 97-104) appeared to propagate in Escherichia coli and yet retained its complementing activity to rad4 mutants without inactivation. The subcloned RAD4 gene was found to be localized within a 2.5 kb DNA fragment flanking Bg1II and BamHI sites in the insert DNA, and was shown to have the same restriction map as a yeast chromosomal DNA, as determined by Southern hybridization. Tetrad analysis and pulse-field chromosome mapping have revealed that the cloned RAD4 gene can be mapped and integrated into the yeast chromosome V, the actual site of this gene. DNA-tRNA hybridization has shown that the isolated RAD4 gene did not contain a suppressor tRNA gene. These results have indicated that the pPC1 is a functional RAD4 gene playing a unique role involved in the nucleotide excision repair of yeast without any genetic change during amplification in E. coli.     

DELAY OF CELL DIFFERENTIATION IN Anabaena aequalis CAUSED BY UV-B RADIATION AND THE ROLE OF PHOTOREACTIVATION AND EXCISION REPAIR

The effect of ultraviolet light on cell differentiation was studied in the cyanobacterium Anabaena aequalis. Exposure of cells to UV-B wavelengths (280-320 nm) significantly delayed the differentiation of vegetative cells into heterocysts and akinetes at doses up to 56 kJ m^-2. Heterocyst differentiation was essentially stopped at all exposure levels when photoreactivation was prevented, even when excision repair was available to the cells. Photoreactivated samples produced heterocysts at doses through 28 kJ m^-2, after which differentiation dropped steeply to near zero levels. Some recovery of differentiation was evident at higher doses but at levels much below that of controls. Akinete differentiation was only slightly delayed by the exposures when cells were photoreactivated. Samples then showed rapid differentiation with the numbers of akinetes significantly greater than controls. Cells that did not receive photoreactivating light showed a greater initial delay in differentiation but 2 weeks after the exposures had recovered to control levels. Caffeine had more effect on the differentiation of akinetes than heterocysts. Inhibition of excision repair greatly reduced differentiation in photoreactivated samples and essentially eliminated differentiation in the nonphotoreactivated samples.     

USE OF METABOLIC INHIBITORS TO INVESTIGATE THE EXCISION REPAIR OF PYRIMIDINE DIMERS AND NON-DIMER DNA DAMAGES INDUCED IN HUMAN AND ICR 2A FROG CELLS BY SOLAR ULTRAVIOLET RADIATION

Abstract— ICR 2A frog and normal human skin fibroblasts were exposed to either 5 J/m² of 254 nm UV or 50 kJ/m² of the Mylar-filtered solar UV wavelengths produced by a fluorescent sunlamp. Following these approximately equitoxic treatments, cells were incubated in medium containing the DNA synthesis inhibitors hydroxyurea (HU) and 1–β-D-arabinofuranosyl cytosine (ara C) for 0–20 min (human fibroblasts) or 0–4 h (frog cells) to accumulate DNA breaks resulting from enzymatic incision during excision repair. It was found that breaks were formed in human cells at about a 200-f-old higher rate compared with the ICR 2A cells indicating a relatively low capacity for excision repair in the frog cells. In addition, the rate of DNA break formation in solar UV-irradiated cells was only one-third of the level detected in 254 nm-irradiated cells. This result is consistent with the conclusion that the pathway(s) involved in the repair of solar UV-induced DNA damages differs from the repair of lesions produced in cells exposed to 254 nm UV.