Enhanced mutagenesis parallels enhanced reactivation of herpes virus in a human cell line.

U.v. irradiation of human NB-E cells results in enhanced mutagenesis and enhanced reactivation of u.v.-irradiated H-1 virus grown in those cells ( Cornelis et al., 1982). This paper reports a similar study using herpes simplex virus (HSV) in NB-E cells. The mutation frequency of HSV (resistance of virus plaque formation to 40 micrograms/ml iododeoxycytidine ) increased approximately linearly with exposure of the virus to u.v. radiation. HSV grown in unirradiated cells gave a slope of 1.8 X 10(-5)m2/J, with 3.2 X 10(-5)m2/J for HSV grown in cells irradiated (3 J/m2) 24 h before infection. There was no evidence for mutagenesis of unirradiated virus by irradiated cells, as seen with H-1 virus. Enhanced reactivation of irradiated HSV in parallel cultures increased virus survival, manifested as a change in slope of the final component of the two-component survival curve from a D0 of 27 J/m2 in unirradiated cells to 45 J/m2 in irradiated cells. Thus, enhanced mutagenesis and enhanced reactivation occurred for irradiated HSV in NB-E cells. The difference in the enhanced mutagenesis of HSV (dependent on damaged DNA sites) and of H-1 virus (primarily independent of damaged DNA sites) is discussed in terms of differences in DNA polymerases.     

Gamma endonuclease of Micrococcus luteus: action on irradiated DNA

Gamma endonuclease is a Mg2+-independent enzyme of Micrococcus luteus that recognizes and cleaves DNA at a variety of altered pyrimidines produced by ionizing radiation. The production of enzyme-recognizable sites (ERS) by ionizing radiation under different irradiation conditions was measured. Ionizing radiation produced the greatest number of ERS when irradiations were performed under anoxic conditions in the presence of the free radical scavenger KI. Since dihydrothymine is a major pyrimidine lesion produced in DNA during anoxic irradiation, the ability of gamma endonuclease to excise this lesion was assessed. Dihydrothymine was released from DNA irradiated under anoxic conditions in a radiation dose-dependent manner, consistent with gamma endonuclease's known DNA glycosylase activity. Gamma endonuclease was also shown to cleave heavily uv-irradiated DNA. When the sequence specificity of gamma-endonuclease cleavage was studied using uv-irradiated DNA, cleavage was seen specifically at cytosines. The identity of this enzyme-recognizable cytosine photoproduct is not known.     

Measurement of the kinetics of DNA repair synthesis after uv irradiation using immunochemical staining of incorporated 5-bromo-2'-deoxyuridine and flow cytometry

The kinetics of unscheduled DNA synthesis in normal human fibroblasts was characterized by flow cytometry utilizing the immunofluorescent detection of 5-bromo-2'-deoxyuridine (BrdUrd) incorporated into cellular DNA during the repair process. Quiescent normal human fibroblasts were irradiated with ultraviolet light and incubated in the presence of BrdUrd during a postirradiation repair period. The amount of unscheduled DNA synthesis was then quantified in the quiescent cells by immunofluorescence staining using monoclonal antibodies against BrdUrd incorporated into the DNA. Significant amounts of unscheduled DNA synthesis were measured after doses as low as 0.1 J/m2 and for time periods as short as 15 min. The initial repair rate was found to be linear with time at all doses tested until repair neared completion. Interestingly, the initial repair rate was constant for doses over the range of 5 to 40 J/m2, whereas the time to completion of repair was dose dependent. These results suggest that above 5 J/m2 in normal human fibroblasts, the repair process is saturated but continues to function until all available regions are repaired. Using this methodology for measuring unscheduled DNA synthesis in combination with second and third flow markers, it is now possible to measure unscheduled DNA synthesis in heterogeneous mixtures of cells.     

Nuclear DNA synthesis is blocked by UV irradiation in Dictyostelium discoideum

We have used a thymidine auxotroph of the simple eukaryote, Dictyostelium discoideum and alkaline sucrose gradients of isolated nuclei to study alterations in DNA synthesis following irradiation of replicating haploid cells with 254 nm UV light. Three responses were characterized using pulse-chase protocols: (1) Lags in DNA synthesis as measured by the amount of label incorporated were 4, 9, and 20 h after 10, 50, and 200 J/m2. (2) The DNA synthesized during a 15-min pulse immediately after irradiation was of lower single strand molecular weight: 7, 3.5, and 3 x 10(6) dalton after 0, 50, and 200 J/m2. (3) The time required for maturation of the nascent DNA to full-sized single strands of about 2 x 10(8) dalton was 45-50 min for unirradiated cells, 3 h after 10 J/m2, and 20 h after 200 J/m2. The DNA of the irradiated cells did not mature uniformly during these delays; instead, a period of no increase in size was followed by a rapid, nearly control rate of maturation. We conclude: (a) at least some UV lesions block elongation of replicons; (b) the elongation of the replicons and their subsequent joining to yield mature high molecular weight DNA occurs after most of the lesions are repaired; (c) the timing of the different aspects of recovery suggest that initiation of replication is also inhibited.     

Pyrimidine dimer excision in surviving and nonsurviving cells of ultraviolet-irradiated cultures of Escherichia coli.

We compared dimer excision in viable and nonviable cells fractions separated from Escherichia coli B/r cultures exposed to ultraviolet (UV) irradiation. For cells grown on minimal medium with glycerol as a carbon source, both fractions from the irradiated (20 J/m2, 5% survival) culture excised 60 to 70% of the thymine dimers from prelabeled DNA within 120 min. This percentage was, within experimental error, the same as that obtained from unseparated cultures. When isolated viable and nonviable populations were given a second UV exposure (20 J/m2) both types of cells were again able to excise dimers. The UV survival curve for the isolated viable population indicates that these cells are no more sensitive to radiation than exponentially growing cells not previously exposed to UV. The extent of dimer excision after UV irradiation was also the same in viable and nonviable cells separated from cultures grown on a glucose minimal medium in which both populations excised about 85% of the dimers within 120 min. These results show that the extent of removal of pyrimidine dimer from deoxyribonucleic acid is not precisely correlated with survival of repair-competent bacterial cells after exposure to UV light.     

Formation of DNA strand breaks in UV-irradiated human fibroblast preparations

The formation of DNA strand breaks was characterized in human fibroblasts prepared by several methods. In quiescent monolayer cultures of normal human fibroblasts (NHF), exposure to 254 nm radiation (UV) caused the rapid appearance of DNA strand breaks as monitored by alkaline elution analysis. Maximal levels of DNA breaks were seen 30 min after 10 J/m2; thereafter, strand breaks disappeared. Breakage soon after irradiation appeared to saturate at fluences above 10 J/m2. Xeroderma pigmentosum fibroblasts belonging to complementation group A (XPA) did not display this response which reflects operations of the nucleotidyl DNA excision repair pathway. When fibroblast strains were released from culture dishes by enzymatic digestion with trypsin or by scraping with a rubber policeman, UV-dependent DNA breakage displayed altered dose and time responses. Few breaks were detected in detached preparations of NHF after 10 J/m2 indicating inactivation of nucleotidyl DNA excision repair. The fluence response in detached fibroblasts was linear up to an incident fluence of 100 J/m2. Moreover, after 25 or 50 J/m2, strand breaks accumulated as a linear function of time for up to 2 h after irradiation. This UV-dependent and time-dependent incision activity was also observed in XPA monolayers and released-cell preparations. In permeable fibroblast preparations, DNA breaks accumulated in unirradiated cells that had been released with trypsin or by scraping. Permeabilization in situ saponin to open the plasma membrane produced a cell preparation that accumulated fewer UV-independent breaks. In saponin-permeabilized NHF that were irradiated with 10 J/m2, UV-dependent strand incision activity occurred at about 30% of the rate of incision seen in intact monolayer NHF. These results reveal at least 3 DNA strand incision activities in human fibroblast preparations of which only one reflects operation of the nucleotidyl DNA excision repair pathway.     

Purified scrapie prions resist inactivation by UV irradiation.

The development of effective purification protocols has permitted evaluation of the resistance of isolated scrapie prions to inactivation by UV irradiation at 254 nm. Prions were irradiated on ice with doses of UV light ranging up to 120,000 J/m2. UV dosimetry experiments, performed with Saccharomyces cerevisiae plasmid DNA or eucaryotic cells, indicated that under these experimental conditions an incident UV dose of 10 J/m2 formed 2 thymine dimers per 5.1 X 10(6) daltons of eucaryotic cell DNA. The D37 values for scrapie prions ranged from 17,000 to 22,000 J/m2; D37 values were also determined for virus, viroid, and enzyme controls. The number of pyrimidine dimers formed was correlated with the D37 values obtained for irradiated prions and target nucleic acids. The D37 value for bacteriophage M13, 6.5 J/m2, occurred at a dose that would form 0.56 dimers per target genome; the D37 for potato spindle tuber viroid, 4,800 J/m2, occurred at a dose that would form about 24 dimers per target viroid. The D37 value for an EcoRI restriction site, a target of 12 bases, occurred at a dose that would correspond to the formation of 0.89 thymine dimers per target site. The D37 value for prions occurred at a dose that would form 1 dimer in every 4 bases of single-stranded target nucleic acid. If the putative scrapie nucleic acid were double-stranded and readily repairable after UV damage, then the prion D37 value could reflect a nucleic acid molecule of 30 to 45 base pairs. While the D37 value for prions fell within the range of pure protein targets, our experiments cannot eliminate the possibility that a prion contains a small, highly protected nucleic acid molecule.     

Inhibition of DNA replication by ultraviolet light.

DNA replication in ultraviolet-irradiated HeLa cells was studied by two different techniques: measurements of the kinetics of semiconservative DNA synthesis, and DNA fiber autoradiography. In examining the kinetics of semiconservative DNA synthesis, density label was used to avoid measuring the incorporation due to repair replication. The extent of inhibition varied with time. After doses of less than 10J/m2 the rate was initially depressed but later showed some recovery. After higher doses, a constant, low rate of synthesis was seen for at least the initial 6 h. An analysis of these data indicated that the inhibition of DNA synthesis could be explained by replication forks halting at pyrimidine dimers. DNA fiber autoradiography was used to further characterize replication after ultraviolet irradiation. The average length of labeled segments in irradiated cells increased in the time immediately after irradiation, and then leveled off. This is the predicted pattern if DNA synthesis in each replicon continued at its previous rate until a lesion is reached, and then halted. The frequency of lesions that block synthesis is approximately the same as the frequency of pyrimidine dimers.     

Inhibition of postbinding target cell lysis and of lymphokine-induced enhancement of human natural killer cell activity by in vitro exposure to ultraviolet B radiation

In vitro exposure of human peripheral blood mononuclear cells (PBMC) to ultraviolet B (uvB) radiation has been shown to inhibit natural killer (NK) cell-mediated cytotoxicity in a dose-dependent fashion. The purpose of this study was to examine the manner by which uvB produced these deleterious effects. Inhibition of NK activity was not due to lethal injury to NK cells since the viability of cell populations enriched for NK activity was greater than 90% with the uvB doses employed. uvB appeared to directly affect NK cells since procedures which removed suppressor mechanisms, such as removal of monocytes and pharmacologic inhibition of the cyclooxygenase pathway, failed to reverse the response. Furthermore, no suppression of activity of unirradiated NK cells could be produced by coincubation of unirradiated NK cells with uv-irradiated NK cells. When the single cell assay for binding and killing was employed to determine at which stage in the lytic sequence inhibition occurred, it was found that binding was normal but lysis of bound targets and the recycling capacity of active NK cells were markedly reduced. At uvB doses above 50 J/m2, both interferon alpha (IFN-alpha) and interleukin 2 (IL-2) were ineffective in augmenting NK cell-mediated cytotoxic reactions after cells had been irradiated with uvB. Furthermore, incubation of NK cells with IFN-alpha prior to irradiation failed to protect against the inhibitory effects. These studies provide evidence that in vitro exposure of NK cells to uvB radiation inhibits their function by a direct nonlethal effect and that this inhibition occurs selectively at the postbinding stage of target cell lysis.     

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.     

Increased DNA single-strand break joining activity in UV-irradiated CD34+ versus CD34- bone marrow cells

The kinetics of UV-irradiation-induced (254 nm) DNA single-strand breaks (SSBs) were studied in single human hematopoietic cells using alkaline comet assay. Three cell populations were investigated: (i) Bone marrow mononuclear cells (BMMNCs) isolated by density gradient centrifugation, (ii) CD34- cells, and (iii) CD34+ cells. The two latter populations were purified from BMMNCs by negative and positive selection, respectively, using anti-CD34 immunobeads. SSBs were induced faster by 10 and 50 J/m2 than by 2 J/m2 and those caused by 2 J/m2 were joined faster that those caused by 10 or 50 J/m2. During the first 1.5 h after irradiation with a dose of 10 J/m2, CD34+ cells joined SSBs faster than did BMMNCs. The superior joining capacity of CD34+ cells was further substantiated with a higher UV dose. The comet lengths, indicating the extent of DNA repair, among 8/8 study subjects were shorter in CD34+ than in CD34- cells when assessed 24 h after a dose of 50 J/m2. Overall, the comet lengths at 24 h after irradiation were: CD34+ cells; 39+/-12 *m, and CD34- cells; 65+/-18 *m (8 subjects, 50 cells measured from each donor, mean+/-S.D.; p=0.0087, Mann-Whitney U-test). These results strongly suggest that nucleotide excision repair, the major mechanism responsible for the repair of UV-irradiation-induced DNA lesions in mammalian cells, is increased in CD34+ cells compared with CD34- cells and with BMMNCs. These results may have implications in stem cell purging, clinical chemotherapy and carcinogenesis.     

Effects of ultraviolet irradiation on the rate and sequence of DNA replication in synchronized Chinese hamster cells.

The effects of ultraviolet light (UV) irradiation on the rate of DNA replication in synchronized Chinese hamster ovary (CHO) cells were investigated. A technique for measuring semiconservative DNA replication was employed that involved growing the cells in medium containing 5-bromodeoxyuridine and subsequently determining the amount of DNA that acquired hybrid buoyant density in CsCl density gradients. One of the advantages of this technique was that it allowed a characterization of the extent of DNA replication as well as rate after irradiation. It was found that while there was a dose-dependent reduction in the rate of DNA replication following UV-irradiation, doses of up to 10 J/m2 (which produce many dimers per replication) did not prevent the ultimate replication of the entire genome. Hence, we conclude that dimers cannot be absolute blocks to DNA replication. In order to account for the total genome replication observed, a mechanism must exist that allows genome replication between dimers. The degree of reduction in the rate of replication by UV was the same whether the cells were irradiated at the G1-S boundary or 1 h into S-phase. Previous work had shown that cells in early S-phase are considerably more sensitive to UV than cells at the G1-S boundary. Experiments specifically designed to test for reiterative replication showed that UV does not induce a second round of DNA replication within the same S-phase.     

The binding of SSB-proteins with DNA in chromatin of Ehrlich ascites carcinoma cells]

Using UV-induced cross-linking between proteins and DNA, the contacts between single-stranded DNA-binding proteins (SSB proteins) and chromatin DNA have been demonstrated. Ehrlich ascites tumour DNA was labeled in vivo by inoculation of tumour-bearing mice with 3H-thymidine. The cells were irradiated with the UV light dose of 3000 J/m2, destroyed in a Triton X-100-containing hypotonic medium, and separated by centrifugation into the extrachromatin fraction and chromatin. Chromatin DNA was digested with DNAase 1, and the chromatin proteins were extracted with 2 M NaCl-polyethyleneglycol. SSB proteins from the extrachromatin fraction and chromatin were purified. Only SSB proteins from UV-irradiated cell chromatin appeared to possess a high specific radioactivity which exceeded 7.5-fold that of non-irradiated cells. There were no differences between chromatin SSB proteins in control and irradiated cells as could be evidenced from SDS electrophoresis data. It is assumed that in irradiated cells SSB proteins of DNA-digested chromatin are covalently cross-linked with DNA fragments.     

The distribution of DNA excision-repair sites in human diploid fibroblasts following ultraviolet irradiation

Using the technique for separating DNA fragments containing excision-repair sites from total genomic DNA as described in the previous paper (Cohn, S. M., and Lieberman, M. W. (1984) J. Biol. Chem. 259, 12456-12462), we have developed a method for directly determining the distribution of excision-repair sites in the genome. DNA was prepared from confluent, diploid human fibroblasts which had been irradiated with ultraviolet light and incubated in the presence of 5-bromo-2'-deoxyuridine (BrdUrd), repaired fragments were isolated, and the dependence of the fraction of total DNA fragments containing excision-repair sites on DNA fragment length was determined by electrophoretic analysis. The observed dependence was compared to the relationship expected for a random distribution of repair sites. At 36 h following 3 J/m2 UV, the distribution of repair sites was indistinguishable from a random distribution; however, at doses of UV above 6 J/m2, the observed dependence indicated that the distribution of repair sites was nonrandom. A time course of the distribution of repair sites following 12 J/m2 UV was clearly nonrandom from 4 h after irradiation until at least 36 h following irradiation. By 72 h, however, the distribution had become random. In cells treated with hydroxyurea, a reduced number of excision-repair sites were present, but the distribution of repair sites was also nonrandom. Autoradiographic analysis of the amount of unscheduled DNA synthesis in individual nuclei suggested that the nonrandom distribution of repair sites did not result from variable extents of repair synthesis in different cell populations or from cell death.     

Non-targeted mutagenesis of unirradiated lambda phage in Escherichia coli host cells irradiated with ultraviolet light

Non-targeted mutagenesis of lambda phage by ultraviolet light is the increase over background mutagenesis when non-irradiated phage are grown in irradiated Escherichia coli host cells. Such mutagenesis is caused by different processes from targeted mutagenesis, in which mutations in irradiated phage are correlated with photoproducts in the phage DNA. Non-irradiated phage grown in heavily irradiated uvr+ host cells showed non-targeted mutations, which were 3/4 frameshifts, whereas targeted mutations were 2/3 transitions. For non-targeted mutagenesis in heavily irradiated host cells, there were one to two mutant phage per mutant burst. From this and the pathways of lambda DNA synthesis, it can be argued that non-targeted mutagenesis involves a loss of fidelity in semiconservative DNA replication. A series of experiments with various mutant host cells showed a major pathway of non-targeted mutagenesis by ultraviolet light, which acts in addition to "SOS induction" (where cleavage of the LexA repressor by RecA protease leads to din gene induction): (1) the induction of mutants has the same dependence on irradiation for wild-type and for umuC host cells; (2) a strain in which the SOS pathway is constitutively induced requires irradiation to the same level as wild-type cells in order to fully activate non-targeted mutagenesis; (3) non-targeted mutagenesis occurs to some extent in irradiated recA recB cells. In cells with very low levels of PolI, the induction of non-targeted mutagenesis by ultraviolet light is enhanced. We propose that the major pathway for non-targeted mutagenesis in irradiated host cells involves binding of the enzyme DNA polymerase I to damaged genomic DNA, and that the low polymerase activity leads to frameshift mutations during semiconservative DNA replication. The data suggest that this process will play a much smaller role in ultraviolet mutagenesis of the bacterial genome than it does in the mutagenesis of lambda phage.     

The need for protein synthesis in UV-irradiated Escherichia coli cells for fixation of induced Str mutations

The kinetics of accumulation of fixed Str mutations was determined during incubation in nutritional medium of Escherichia coli WP2 irradiated with 6.8 J/m2 either at log growth phase or after completion of DNA replication. Those Str mutations which lost ability for photoreactivation (fixation I) or susceptibility to antimutagenic activity of mfd-type (fixation II) were considered as fixed mutations. It was shown that both fixations occurred synchronously, starting in about 10 min after irradiation and being over in 40-50 min. In cells irradiated after completion of replication, fixation depended on protein synthesis de novo: chloramphenicol added to irradiated culture blocked fixation. An attempt to study the effect of chloramphenicol on fixation in a culture irradiated at the log phase failed, because of high lethal action of the antibiotic on such cells. Fixation could proceed in the presence of acriflavine. Possible mechanisms for fixation of Str mutations are discussed in connection with the fact of its dependence on protein synthesis.     

DNA repair endonuclease activity during synchronous growth of diploid human fibroblasts.

DNA-repair endonuclease activity in response to UV-induced DNA damage was quantified in diploid human fibroblasts after synchronizing cell cultures to selected stages of the cell cycle. Incubation of irradiated cells with aphidicolin, an inhibitor of DNA polymerases alpha and delta, delayed the sealing of repair patches and allowed estimation of rates of strand incision by the repair endonuclease. The apparent Vmax for endonucleolytic incision and Km for substrate utilization were determined by Lineweaver-Burk and Eadie-Hofstee analyses. For cells passing through G1, S or G2, Vmax for reparative incision was, respectively, 7.6, 8.4 and 8.4 breaks/10(10) Da per min, suggesting that there was little variation in incision activity during these cell-cycle phases. The Km values of 2.4-3.1 J/m2 for these cells indicate that the nucleotidyl DNA excision-repair pathway operates with maximal effectiveness after low fluences of UV that are in the shoulder region of survival curves. Fibroblasts in mitosis demonstrated a severe attenuation of reparative incision. Rates of incision were 11% of those seen in G2 cells. Disruption of nuclear structure during mitosis may reduce the effective concentration of endonuclease in the vicinity of damaged chromatin. The extreme condensation of chromatin during mitosis also may restrict the accessibility of reparative endonuclease to sites of DNA damage. Confluence-arrested fibroblasts in G0 expressed endonuclease activity with Vmax of 5.5 breaks/10(10) Da per min and a Km of 5.5 J/m2. The greater condensation of chromatin in quiescent cells may restrict the accessibility of endonuclease to dimers and so explain the elevated Km. When fibroblasts were synchronized by serum-deprivation, little variation in reparative endonuclease activity was discerned as released cells transited from early G1 through late G1 and early S. Proliferating fibroblasts in G1 were shown to express comparatively high numbers of reparative incision events in the absence of aphidicolin which was normally used to inhibit DNA polymerases and hold repair patches open. It was calculated that in G0, S and G2 phase cells, single-strand breaks at sites of repair remained open for 30, 19 and 14 sec, respectively. In G1 phase cells, repair sites remained open for 126 sec. Addition of deoxyribonucleosides to G1 cells reduced this time to 42 sec suggesting that the slower rate of synthesis and ligation of repair patches in G1 was due to a relative deficiency of deoxyribonucleotidyl precursors for DNA polymerase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Differential repair of 1-beta-D-arabinofuranosylcytosine-detectable sites in DNA of human fibroblasts exposed to ultraviolet light and 4-nitroquinoline 1-oxide

The extent of DNA excision repair was determined in dermal fibroblast strains from clinically normal and xeroderma pigmentosum (XP; complementation group A) human donors after single or combined exposures to 254-nm ultraviolet light and 4-nitroquinoline 1-oxide (4NQO). The repair was monitored by incubation of the treated cultures in the presence of 1-beta-D-arabinofuranosylcytosine (araC), a potent inhibitor of long-patch excision repair, followed by quantitation of araC-accumulated DNA single-strand breaks (representing repair events) by velocity sedimentation analysis in alkaline sucrose gradients. The amount of repair in normal fibroblast strains increased as a function of UV fluence and reached a plateau at 15 J/m2; strand breaks were not detected when these same cultures were irradiated with as much as 60 J/m2 UV and incubated in the absence of araC, implying that an initial (incision) step is rate-limiting in the repair of UV damage. In normal fibroblasts (i) the incidence of araC-detectable lesions removed during fixed intervals following exposure to 4NQO (4 microM; 30 min) was approximately 2.5 times greater than that seen following irradiation with repair-saturating fluences (greater than or equal to 15 J/m2) of UV-rays; and (ii) the amount of repair in cultures treated simultaneously with 4NQO (0.5-6 microM; 30 min) and a repair-saturating fluence of UV (20 J/m2) was found to approach the sum of that arising from exposure to each separately. The XP cells (XP12BE) exhibited a deficiency in the removal of araC-detectable DNA lesions following exposure to either of the carcinogens. Since araC is known to inhibit the repair of alkali-stable 4NQO-DNA adducts (i.e., lesions assumed to be removed by the UV-like excision pathway) but not that of alkali-labile sites (i.e., DNA lesions operated on by the X-ray-like repair pathway), our results strongly imply that the multistep excision-repair pathway operative on UV photoproducts in human fibroblasts differs from that responsible for removing alkali-stable (araC-detectable) 4NQO adducts by at least one step, presumably the rate-limiting incision reaction mediated by a lesion-recognizing endonuclease.