Excision repair of DNA base damage in human cells treated with the chemical carcinogen 4-nitroquinoline 1-oxide.

Excision repair of DNA damage produced by 4-nitroquinoline 1-oxide (4NQO), a potent chemical carcinogen, was compared in a normal human amnion FL cell line and a xeroderma pigmentosum (XP) cell line unable to repair ultraviolet-induced pyramidine dimers. The main objective of this study was to investigate, by a direct assay of the loss of damage from DNA, whether DNA damage induced by 4NQO in human cells is repaired by the excision-repair system as in Escherichia coli cells. DNA was extracted from FL and XP cells treated with [³H]4NQO, hydrolyzed and subjected to radiochromatographic analysis in order to quantitate the initial formation of 4NQO damage and subsequent disappearance during post-incubation. Two peaks of stable 4NQO-quanine adducts appeared on the chromatogram, together with one peak of stable 4NQO-adenine adduct and a peak due to 4-aminoquinoline 1-oxide (4AQO) released from a labile fraction of 4NQO-guanine adduct during hydrolysis. The three kinds of stable 4NQO-purine adduct disappeared from DNA of the FL cells at almost the same rate of about 60% during 24-h post-incubation in culture medium, and 4AQO disappeared somewhat faster. In the XP cells, however, the stable adducts did not disappear from DNA, whereas about 40% of the 4AQO-releasing adduct disappeared from DNA. These findings at the molecular level quantitatively parallel the previous findings at the cellular level that the XP cells are several times as sensitive as normal cells to killing by 4NQO. These results lead to the conclusion that in human cells 4NQO-induced lethality is mainly due to the four kinds of 4NQO-purine adduct as it is in E. coli, and that the adducts are excisable by the same excision-repair mechanism that works on pyramidine dimers.     

The repair of large DNA adducts in mammalian cells.

This paper describes experiments involving the measurement of DNA damage and repair after treatment with 4-nitroquinoline 1-oxide (4NQO) or aflatoxin B1 (AFB1) epoxide in a number of mammalian cell cultures primarily associated with defects in the excision repair of UV-induced DNA damage. The results with transformed derivatives of XP cells belonging to different complementation groups showed that the extent of repair of 4NQO adducts at the N2 or C8 of guanosine did not correlate to the extent of repair reported by others after UV-irradiation. An examination of 4NQO repair in rodent UV-sensitive cell lines from different ERCC groups indicated that again there was little correlation between the extent of 4NQO and UV repair. However, regardless of complementation group those mutants that were defective in the repair of pyrimidine dimers and 6,4-photoproducts did exhibit a reduced ability to repair the 4NQO N2 guanosine adduct, whereas those mutants defective in pyrimidine dimer repair alone were able to repair this lesion as normal. In all of these cell lines there was a normal capacity to repair the 4NQO C8 guanosine adduct. Less extensive experiments involving AFB1 epoxide showed an XPC-transformed cell line was able to repair 40% of lesions after 6 h, whereas only 20% of repair is seen after UV. The rodent mutant V-C4 which belongs to the same ionising radiation group as irs2, was partially defective in repairing AFB1-induced damage. These experiments highlight the fact that although there are many commonalities between the repair of UV damages and lesions classed as large DNA adducts differences clearly exist, the most striking example here being the repair of the C8 guanosine 4NQO adduct which rarely correlates with a defect in UV repair.     

The action of 4-hydroxyaminobiphenyl in Escherichia coli: cytotoxic and mutagenic effects in DNA repair deficient strains

The cytotoxic and mutagenic effects of 4-hydroxyaminobiphenyl (N-OH-ABP) were studied using Escherichia coli strains with different repair capacities. N-OH-ABP was equally cytotoxic for uvrA and recA mutants as well as in wild-type cells while polA mutants strains proved particularly sensitive to its toxicity. In contrast, the mutation frequency in the uvrA strains tested was elevated to 30–400-fold the wild-type values. We suggest that aminobiphenyl-DNA adducts responsible for mutation are repaired by UVR endonuclease but different pathways exist for removal of DNA lesions responsible for bacterial killing. From the ³²P-postlabelling analysis, it was concluded that ABP-DNA adducts can be relatively rapidly repaired in wild-type strains, while persisting in the uvrA strains.     

Cyanobacteria toxins in the Salton Sea

Background

Sequenced archaeal genomes contain a variety of bacterial and eukaryotic DNA repair gene homologs, but relatively little is known about how these microorganisms actually perform DNA repair. At least some archaea, including the extreme halophile Halobacterium sp. NRC-1, are able to repair ultraviolet light (UV) induced DNA damage in the absence of light-dependent photoreactivation but this 'dark' repair capacity remains largely uncharacterized. Halobacterium sp. NRC-1 possesses homologs of the bacterial uvrA, uvrB, and uvrC nucleotide excision repair genes as well as several eukaryotic repair genes and it has been thought that multiple DNA repair pathways may account for the high UV resistance and dark repair capacity of this model halophilic archaeon. We have carried out a functional analysis, measuring repair capability in uvrA, uvrB and uvrC deletion mutants.

Results

Deletion mutants lacking functional uvrA, uvrB or uvrC genes, including a uvrA uvrC double mutant, are hypersensitive to UV and are unable to remove cyclobutane pyrimidine dimers or 6–4 photoproducts from their DNA after irradiation with 150 J/m² of 254 nm UV-C. The UV sensitivity of the uvr mutants is greatly attenuated following incubation under visible light, emphasizing that photoreactivation is highly efficient in this organism. Phylogenetic analysis of the Halobacterium uvr genes indicates a complex ancestry.

Conclusion

Our results demonstrate that homologs of the bacterial nucleotide excision repair genes uvrA, uvrB, and uvrC are required for the removal of UV damage in the absence of photoreactivating light in Halobacterium sp. NRC-1. Deletion of these genes renders cells hypersensitive to UV and abolishes their ability to remove cyclobutane pyrimidine dimers and 6–4 photoproducts in the absence of photoreactivating light. In spite of this inability to repair UV damaged DNA, uvrA, uvrB and uvrC deletion mutants are substantially less UV sensitive than excision repair mutants of E. coli or yeast. This may be due to efficient damage tolerance mechanisms such as recombinational lesion bypass, bypass DNA polymerase(s) and the existence of multiple genomes in Halobacterium. Phylogenetic analysis provides no clear evidence for lateral transfer of these genes from bacteria to archaea.     

Induction of phr gene expression by irradiation of ultraviolet light in Escherichia coli

Summary To measure the degree of phr gene induction by DNA-damaging agents, the promoter region was fused to the coding region of the lacZ gene in plasmid pMC1403. The new plasmids were introduced into Escherichia coli cells having different repair capabilities. More efficient induction of phr gene expression was detected in a uvrA ^– strain as compared with the wild-type strain. In addition, obvious induction was detected in uvrA ^– cells treated by 4-nitroquinoline 1-oxide and mitomycin C. Nalidixic acid, an inhibitor of DNA gyrase, also induced phr gene expression. In contrast, little induced gene expression was noted in UV-irradiated lexA ^– and recA ^– strains. It is suggested from these results that induction of the phr gene is one of the SOS responses. Possible nucleotide sequences which could be considered to constitute an SOS box were found at the regulator region of the phr gene.Abbreviations phr photoreactivation - UV ultraviolet light - 4NQO 4-nitroquinoline 1-oxide - MMC mitomycin C - PRE photoreactivating enzyme - E. coli Escherichia coli     

Characteristics of DNA repair of a UV-sensitive mutant (radC) of Dictyostelium discoideum

Summary A radiation-sensitive mutant, TW8(radC), of Dictyostelium discoideum is more sensitive to ultraviolet light (UV) killing than the parental wild strain NC4(RAD ⁺), but is resistant to 4-nitroquinoline 1-oxide (4NQO) at almost the same level as NC4. In TW8 amoebae, single-strand breaks of DNA molecules were hardly detectable immediately after UV irradiation, and the removal of pyrimidine dimers was depressed during the postirradiation incubation when compared with that of NC4 amoebae. After treatment with 4NQO, however, single-strand breaks were detected in TW8 amoebae. The almost complete rejoining of these breaks was also detected after the removal of 4HAQO-adducts. The TW8 amoebae have an efficient repair capacity against DNA damage caused by 4NQO, MMS, MMC and MNNG but not UV.Abbreviations 4NQO 4-nitroquinoline 1-oxide - MMS methyl methanesulphonate - MMC mitomycin C - MNNG N-methyl-N-nitro-N-nitrosoguanidine     

Sequence effect on incision by (A)BC excinuclease of 4NQO adducts and UV photoproducts.

Nucleotide excision repair in Escherichia coli is initiated by (A)BC excinuclease, an enzyme which incises DNA on both sides of bulky adducts and removes the damaged nucleotide as a 12-13 base long oligomer. The incision pattern of the enzyme was examined using DNA modified by 4-nitroquinoline 1-oxide (4NQO) and UV light. Similar to the cleavage pattern of UV photoproducts and other bulky adducts, the enzyme incises the 8th phosphodiester bond 5' and 5th phosphodiester bond 3' to the 4NQO-modifed base, primarily guanine. The extent of DNA damage by these agents was determined using techniques which quantitatively cleave the DNA or stop at the site of the adduct. By comparison of the intensity of gel bands created by (A)BC excinuclease and the specific cleavage at the damaged site, the efficiency of (A)BC excinuclease incision at 13 different 4NQO-induced adducts and 13 different photoproducts was determined by densitometric scanning. In general, incisions made at 4NQO-induced adducts are proportional to the extent of damage, though the efficiency of cutting throughout the sequence tested varies from 25 to 75%. Incisions made at pyrimidine dimers are less efficient than at 4NQO-adducts, ranging from 13 to 65% incision relative to modification, though most are around 50%. The two (6-4) photoproducts within the region tested are incised more efficiently than any pyrimidine dimer.     

Mutation frequency decline following chemical mutagenesis of Salmonella typhimurium

The occurrence is reported of a mutation frequency decline process (MFD) following treatment of Salmonella typhimurium strain trpC₃ with two chemical mutagens which give rise predominantly to suppressor revertants. With the carcinogen 4-nitroquinoline-N-oxide (4NQO) the results are analogous to those obtained for UV-mutagenesis. In the case of methoxynamine, the process is due to specific excision of premutational lesions, since lethality is low and lethal lesions are non-excisable. Mutants are described which cannot perform MFD of lesions induced by one or both of the chemical mutagens, indicating that the loss of revertants is in each case due to a bacteial repair system rather than to spontaneous degradation of the induced lesion. The mutants, however, were isolated because of an altered response to UV mutagenesis, viz., their ability to express UV-induced mutants in the absence of amino acids to stimulate active post-irradiation protein synthesis. In all other respects tested, their response to UV is identical with that of the parent strain. The hypothesis is discussed that the total absence of UV-induced revertants of the strain S. typhimurium trpC₃ when active protein synthesis is inhibited is due to two processes, first, rapid MFD due to the specific excision of pyrimidine dimers (the predominant UV-lesion) and secondly, the slow excision of other premutational damage which may be other photoproducts or secondary distortions caused by close juxtaposition of several pyrimidine dimers.     

Determination of Pyrimidine Dimers in Escherichia coli and Cryptosporidium parvum during UV Light Inactivation, Photoreactivation, and Dark Repair

UV inactivation, photoreactivation, and dark repair of Escherichia coli and Cryptosporidium parvum were investigated with the endonuclease sensitive site (ESS) assay, which can determine UV-induced pyrimidine dimers in the genomic DNA of microorganisms. In a 99.9% inactivation of E. coli, high correlation was observed between the dose of UV irradiation and the number of pyrimidine dimers induced in the DNA of E. coli. The colony-forming ability of E. coli also correlated highly with the number of pyrimidine dimers in the DNA, indicating that the ESS assay is comparable to the method conventionally used to measure colony-forming ability. When E. coli were exposed to fluorescent light after a 99.9% inactivation by UV irradiation, UV-induced pyrimidine dimers in the DNA were continuously repaired and the colony-forming ability recovered gradually. When kept in darkness after the UV inactivation, however, E. coli showed neither repair of pyrimidine dimers nor recovery of colony-forming ability. When C. parvum were exposed to fluorescent light after UV inactivation, UV-induced pyrimidine dimers in the DNA were continuously repaired, while no recovery of animal infectivity was observed. When kept in darkness after UV inactivation, C. parvum also showed no recovery of infectivity in spite of the repair of pyrimidine dimers. It was suggested, therefore, that the infectivity of C. parvum would not recover either by photoreactivation or by dark repair even after the repair of pyrimidine dimers in the genomic DNA.     

Increased sensitivity of xeroderma pigmentosum cells to some chemical carcinogens and mutagens

The clone-forming capacity and level of DNA repair was examined on normal human cells and repair-deficient Xeroderma pigmentosum (XP) fibroblasts exposed to various chemical carcinogens and mutagens.The cultured fibroblasts were treated for 90 min with the carcinogenic and mutagenic 4-nitroquinoline 1-oxide (4NQO), 4-hydroxyaminoquinoline 1-oxide (4HAQO), 2-methyl-4-nitroquinoline 1-oxide (2-Me-4NQO), 3-methyl-4-nitropyridine 1-oxide 3-Me-4NPO) and the non-carcinogenic 6-nitroquinoline 1-oxide (6NQO). The response of the cells to the N-oxides was compared to that induced by the mutagen and carcinogen N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) and UV-irradiation.The XP cells showed (1) a reduced level of DNA repair synthesis when exposed to various carcinogenic N-oxides, (2) no unscheduled DNA synthesis following 6NQO and (3) a normal degree of DNA repair synthesis after treatment with MNNG.When the clone-forming capacity was examined the XP cells exhibited (1) a higher increased sensitivity to the various carcinogenic N-oxides, (2) no reduction in the clone formation following 6NQO and (3) a sensitivity virtually comparable to that of normal cells after treatment with MNNG.The results suggest a link between extent of DNA damage, level of DNA repair and degree of sensitivity in human cells exposed to various chemical carcinogens and which induce DNA alterations that cannot be repaired by DNA repair synthesis.     

Bacterial mutagenicity tests on 4-chloromethylbiphenyl and 2 structural analogues

4CMB, 4HMB and BC were tested in 5 strains of S. typhimurium and 2 strains of E. coli without S9. 4HMB was negative in all strains. 4CMB was a strong positive mutagen in TA1535, TA1537, TA1538, TA98, TA100 and WP2uvrA⁻(pKM101), and BC was a weak mutagen in TA100 and WP2uvrA⁻(pKM101). Positivity was determined as a dose response over 3 or more points, in repeat experiments, giving a significant correlation coefficient.     

Alteration of plasmid DNA-mediated transformation and mutation induced by covalent binding of benzo[a]pyrene- 7,8-dihydrodiol-9,10-oxide in Escherichia coli

Plasmid-mediated transformation and mutagenesis induced by (±)-trans- benzo[a]pyrene-7,8-dihydrodiol-9,10-oxide (BP-DEI) in recipient Escherichia coli (E. coli) have been studied. Because plasmid DNA is used, the system is entirely free from direct toxic effects of BP-DEI on the recipient cells. Plasmid pK0482 DNA, which has two dominant genes, β-lactamase (amp-r) and galactokinase (galK) was modified with BP-DEI prior to its transformation of E. coli N99, AB1157, AB2463(recA^?) and AB1886(uvrA^?). Transformants were selected by ampicillin resistance and mutations were analyzed simultaneously by the altered expression of the galK gene. (1) Approx. 3 molecules of BP-DEI per molecule of pK0482 DNA decreased the transformation efficiency to 37% in AB1157 and the mutation frequency in this strain was proportional to the amount of BP-DEI covalently bound to pK0482 DNA. (2) In AB1886(uvrA^?) a 37% transformation efficiency was produced by only 1 molecule of BP-DEI per molecule of pK0482 DNA, and the mutation frequency in this strain was higher than in AB1157. (3) In AB2463(recA^?), the transformation efficiency was similar to that obtained with AB1157, but mutagenesis was clearly suppressed. (4) Polyacrylamide gel patterns of restriction digests of the pK0482 mutated at the galK gene were indistinguishable from those of the unmutated plasmid DNA.     

Nucleotide excision repair and recombination are engaged in repair of trans-4-hydroxy-2-nonenal adducts to DNA bases in Escherichia coli

One of the major products of lipid peroxidation is trans-4-hydroxy-2-nonenal (HNE). HNE forms highly mutagenic and genotoxic adducts to all DNA bases. Using M13 phage lacZ system, we studied the mutagenesis and repair of HNE treated phage DNA in E. coli wild-type or uvrA, recA, and mutL mutants. These studies revealed that: (i) nucleotide excision and recombination, but not mismatch repair, are engaged in repair of HNE adducts when present in phage DNA replicating in E. coli strains; (ii) in the single uvrA mutant, phage survival was drastically decreased while mutation frequency increased, and recombination events constituted 48 % of all mutations; (iii) in the single recA mutant, the survival and mutation frequency of HNE-modified M13 phage was slightly elevated in comparison to that in the wild-type bacteria. The majority of mutations in recA^- strain were G:C → T:A transversions, occurring within the sequence which in recA⁺ strains underwent RecA-mediated recombination, and the entire sequence was deleted; (iv) in the double uvrA recA mutant, phage survival was the same as in the wild-type although the mutation frequency was higher than in the wild-type and recA single mutant, but lower than in the single uvrA mutant. The majority of mutations found in the latter strain were base substitutions, with G:C → A:T transitions prevailing. These transitions could have resulted from high reactivity of HNE with G and C, and induction of SOS-independent mutations.     

Reaction of phenylmercury acetate with Lewis bases

Phenylmercury acetate reacts with tributylphosphine in benzene solution to form a 3-coordinate 1:1 adduct of high stability with a large negative enthalpy of formation (K>10⁴ l mol⁻¹, 2^H = −66 kJ mol⁻¹). Similar adducts of lower stability (K<50) are formed by triphenylphosphine, unidentate aliphatic amines and heterocylic bases and pyridine-N-oxide. The bidentate bases tetramethyl-1,2-diaminoethane and 1,10-phenanthroline form chelate, 4-coordinate 1:1 adducts of greater stability than the unidentate N-bases, but no reaction is evident with 2,2′-bipyridine. The reuslts show the ‘soft’ character of the mercury atom and its reluctance to adopt a coordination number greater than three.     

Characterization of a UV-resistant strain,UVr-10, established from a human clonal cell line,RSb, with high sensitivity to UV, 4NQO,MNNG and interferon

Characterization was performed of a UV-resistant variant strain, UV^r-10, derived from a human clonal cell line, RSb, with high sensitivity not only to the lethal effect of 254-nm far-ultraviolet (UV) irradiation but also to the effects of 4-nitroquinoline 1-oxide (4NQO) and N-methyl-N′-nitro-N-nitrosoguanidine (MNNG), and to the cell proliferation inhibition (CPI) effect of human leukocyte interferon (HuIFN-α) preparations.Colony-formation assays confirmed the increased resistance of UV^r-10 cells to both UV and 4NQO, but no increased resistance to MNNG. The marked recovery from the inhibition of the total cellular DNA synthesis of UV^r-10 cells, estimated by [methyl-³H]thymidine ([³H]dThd) uptake into the cellular DNA materials, was seen during 6 h after irradiation or 4NQO treatment even under the conditions without the recovery uptake into those of the parent RSb cells, but not during 6 h after MNNG treatment. Comparative studies on the activity of DNA repair synthesis between UV^r-10 and RSb cells, by measuring the extent of UV-, 4NQO- or MNNG-induced unscheduled DNA synthesis (UDS) and DNA repair replication, revealed an increased activity of UV^r-10 cells to UV and 4NQO but no significant increase of the activity to MNNG. These results suggest that increased DNA repair activities of a UV^r-10 cell line may account for its becoming resistant to the lethal effect of UV and 4NQO.Concerning the CPI effect of HuIFN-α, UV^r-10 cells showed increased resistance. Further, the DNA synthesis activity of UV^r-10 cells was not so inhibited by HuIFN-α exposure as that of RSb cells. However, HuIFN-α-exposed UV^r-10 cells showed more enhanced levels of activity of pppA(2′p5′A)_n synthetase (2–5A synthetase) than the exposed RSb, thus suggesting that HuIFN-α could exert enough intracellular effect even in UV^r-10 cells.The implication of the increased resistance of UV^r-10 cells to the effects of UV, 4NQO and HuIFN-α, but not to those of MNNG, is discussed.     

Further characterization of an E. coli strain resistant to the toxic and mutagenic action of cis-diamminedichloroplatinum(II)

An increased resistance to the toxic and mutagenic activity of the antitumor drug cis-diamminedichloroplatinum(II) (cis-DDP) in the E. coli strain BS21 compared to its wild-type parent, F26, has been reported. This resistance was neither due to different binding of cis-DDP to DNA nor to adaptive DNA repair (Germanier et al., 1984) In the present work, we found that mutation of the uvrA, recA and polA genes did not abolish the resistance of BS21 to the toxic action of cis-DDP. The lower mutability of BS21 was not influenced by the polA mutation, while uvrA greatly reduced and recA eliminated the mutagenic activity of cis-DDP in both strains. Treatment of BS21 and F26 with equal doses of cis-DDP produced the same initial number of platinum-DNA lesions. Little excision repair was detected in vivo in either strain during 6-h post-treatment incubation, the F26 strain being the most efficient of the two for this process. In contrast, F26 and BS21 were transformed identically by pBR322 DNA which had been treated with cis-DDP in vitro. Analysis of the platinum-DNA adducts which were formed between cis-DDP and salmon sperm DNA in the buffer conditions of this experiment suggests that plasmid DNA contains 80% monofunctional adducts and 20% bifunctional bis-guanine adducts.These data indicate that the selective toxicity and mutagenicity of these two strains in vivo are neither a result of different numbers of Pt-DNA lesions nor of their repair. The selectivity disappeared when the two bacterial strains were transformed by pBR322 DNA containing identical platinum-DNA lesions, suggesting that the biochemical events which process platinum-DNA lesions are the same in both strains. Hence, it appears that cis-DDP may form qualitatively different platinum-DNA adducts in the BS21 and F26 strains which are responsible for the different toxicity and mutagenicity.     

Proceedings: Differential induction of chromosome aberrations in mammalian cell lines.

Mutagenesis was studied in repair- and recombination-deficient strains of Haemophilus influenzae after treatment with N-nitrosocarbaryl (NC). Three different strains of H. influenzae carrying mutations affecting excision-repair of UV-induced pyrimidine dimers exhibited normal repair of premutational lesions (as detected by decreased mutation yield resulting from post-treatment DNA synthesis delay) and normal nonreplicative mutation fixation. This indicates that neither of these phenomena are caused by the same repair mechanism that removes UV-induced pyrimidine dimers from the DNA.The recombination-deficient mutant rec1 is apparently deficient in the replication-dependent mode of NC-induced mutation fixation. This conclusion is based on the following results: (1) NC-induced mutagenesis is lower in the rec1 strain than in rec⁺ cells. (2) Repair of premutational lesions (which depends on the existence of replication-dependent mutation fixation for its detection) was not detected in the rec1 strain. (3) When nonreplicative mutation fixation and final mutation frequency were measured in the same experiment, about $\text{1}\text{4}$ to $\text{1}\text{3}$ of the final mutation yield could be accounted for by nonreplicative mutation fixation in the rec⁺ strain, whereas all of the mutation could be accounted for in the rec1 strain by the nonreplicative mutation fixation. (4) When mutation fixation in strain dna9 rec1 was followed at the permissive (36°) and nonpermissive (41°) temperatures, it became apparent that in the rec1 strain replication-dependent mutation fixation occurs at early times, but these newly fixed mutations are unstable and disappear at later times, leaving only the mutations fixed by the nonreplicative process.The rec1 strain exhibits normal repair of NC-induced single-strand breaks or alkali-labile bonds in the DNA labeled before treatment, but is slow in joining discontinuities present in DNA synthesized after treatment. The results are consistent with the idea that in NC-treated H. influenzae cells the replication-dependent mode of mutation fixation occurs by error-prone joining of interruptions present in the DNA synthesized after treatment. The possibility still exists, however, that during DNA replication mispairing occurs opposite certain alkylation-induced lesions and that mutations arising during replication of strain rec1 later disappear as a result of degradation of newly synthesized DNA, which is excessive in this strain.     

Recombination between Homologous Chromosomes Induced by Unrepaired UV-Generated DNA Damage Requires Mus81p and Is Suppressed by Mms2p

DNA lesions caused by UV radiation are highly recombinogenic. In wild-type cells, the recombinogenic effect of UV partially reflects the processing of UV-induced pyrimidine dimers into DNA gaps or breaks by the enzymes of the nucleotide excision repair (NER) pathway. In this study, we show that unprocessed pyrimidine dimers also potently induce recombination between homologs. In NER-deficient rad14 diploid strains, we demonstrate that unexcised pyrimidine dimers stimulate crossovers, noncrossovers, and break-induced replication events. The same dose of UV is about six-fold more recombinogenic in a repair-deficient strain than in a repair-proficient strain. We also examined the roles of several genes involved in the processing of UV-induced damage in NER-deficient cells. We found that the resolvase Mus81p is required for most of the UV-induced inter-homolog recombination events. This requirement likely reflects the Mus81p-associated cleavage of dimer-blocked replication forks. The error-free post-replication repair pathway mediated by Mms2p suppresses dimer-induced recombination between homologs, possibly by channeling replication-blocking lesions into recombination between sister chromatids.     

UV-B-induced DNA damage and repair pathways in polar Pseudogymnoascus sp. from the Arctic and Antarctic regions and their effects on growth,pigmentation and conidiogenesis

Solar radiation regulates most biological activities on Earth. Prolonged exposure to solar UV radiation can cause deleterious effects by inducing two major types of DNA damage, namely, cyclobutane pyrimidine dimers (CPDs) and pyrimidine 6-4 pyrimidone photoproducts. These lesions may be repaired by the photoreactivation (Phr) and nucleotide excision repair (NER) pathways; however, the principal UV-induced DNA repair pathway is not known in the fungal genus Pseudogymnoascus. In this study, we demonstrated that an unweighted UV-B dosage of 1.6 kJ m⁻² d⁻¹ significantly reduced fungal growth rates (by between 22% and 35%) and inhibited conidia production in a 10 d exposure. The comparison of two DNA repair conditions, light or dark, which respectively induced photoreactivation (Phr) and NER, showed that the UV-B-induced CPDs were repaired significantly more rapidly in light than in dark conditions. The expression levels of two DNA repair genes, RAD2 and PHR1 (encoding a protein in NER and Phr respectively), demonstrated that NER rather than Phr was primarily activated for repairing UV-B-induced DNA damage in these Pseudogymnoascus strains. In contrast, Phr was inhibited after exposure to UV-B radiation, suggesting that PHR1 may have other functional roles. We present the first study to examine the capability of the Arctic and Antarctic Pseudogymnoascus sp. to perform photoreactivation and/or NER via RT-qPCR approaches, and also clarify the effects of light on UV-B-induced DNA damage repair in vivo by quantifying cyclobutene pyrimidine dimers and pyrimidine 6-4 pyrimidone photoproducts. Physiological response data, including relative growth rate, pigmentation and conidia production in these Pseudogymnoascus isolates exposed to UV-B radiation are also presented.     

Interplay of DNA repair,homologous recombination,and DNA polymerases in resistance to the DNA damaging agent 4-nitroquinoline-1-oxide in Escherichia coli

Escherichia coli has three DNA damage-inducible DNA polymerases: DNA polymerase II (Pol II), DNA polymerase IV (Pol IV), and DNA polymerase V (Pol V). While the in vivo function of Pol V is well understood, the precise roles of Pol IV and Pol II in DNA replication and repair are not as clear. Study of these polymerases has largely focused on their participation in the recovery of failed replication forks, translesion DNA synthesis, and origin-independent DNA replication. However, their roles in other repair and recombination pathways in E. coli have not been extensively examined. This study investigated how E. coli's inducible DNA polymerases and various DNA repair and recombination pathways function together to convey resistance to 4-nitroquinoline-1-oxide (NQO), a DNA damaging agent that produces replication blocking DNA base adducts. The data suggest that full resistance to this compound depends upon an intricate interplay among the activities of the inducible DNA polymerases and recombination. The data also suggest new relationships between the different pathways that process recombination intermediates.