The enzymatic properties of Arabidopsis thaliana DNA polymerase λ suggest a role in base excision repair.

Base excision repair (BER) generates gapped DNA intermediates containing a 5'-terminal 2-deoxyribose-5-phosphate (5'-dRP) group. In mammalian cells, gap filling and dRP removal are catalyzed by Pol ß, which belongs to the X family of DNA polymerases. In higher plants, the only member of the X family of DNA polymerases is Pol λ. Although it is generally believed that plant Pol λ participates in BER, there is limited experimental evidence for this hypothesis. Here we have characterized the biochemical properties of Arabidopsis thaliana Pol λ (AtPol λ) in a BER context, using a variety of DNA repair intermediates. We have found that AtPol λ performs gap filling inserting the correct nucleotide, and that the rate of nucleotide incorporation is higher in substrates containing a C in the template strand. Gap filling catalyzed by AtPol λ is most efficient with a phosphate at the 5'-end of the gap and is not inhibited by the presence of a 5'-dRP mimic. We also show that AtPol λ possesses an intrinsic dRP lyase activity that is reduced by mutations at two lysine residues in its 8-kDa domain, one of which is present in Pol λ exclusively and not in any Pol ß homolog. Importantly, we also found that the dRP lyase activity of AtPol λ allows efficient completion of uracil repair in a reconstituted short-patch BER reaction. These results suggest that AtPol λ plays an important role in plant BER.

The C-terminal domain of Arabidopsis ROS1 DNA demethylase interacts with histone H3 and is required for DNA binding and catalytic activity.

Active DNA demethylation plays an important role in controlling methylation patterns in eukaryotes. In plants, the DEMETER-LIKE (DML) family of 5-methylcytosine DNA glycosylases initiates DNA demethylation through a base excision repair pathway. However, it is poorly understood how these DNA demethylases are recruited to their target loci and the role that histone marks play in this process. Arabidopsis REPRESSOR OF SILENCING 1 (ROS1) is a representative enzyme of the DML family, whose members are uniquely characterized by a basic amino-terminal domain mediating nonspecific binding to DNA, a discontinuous catalytic domain, and a conserved carboxy-terminal domain of unknown function. Here, we show that ROS1 interacts with the N-terminal tail of H3 through its C-terminal domain. Importantly, phosphorylation at H3 Ser28, but not Ser10, abrogates ROS1 interaction with H3. Conserved residues at the C-terminal domain are not only required for H3 interaction, but also for efficient DNA binding and catalytic activity. Our findings suggest that the C-terminal domain of ROS1 may function as a histone reader module involved in recruitment of the DNA demethylase activity to specific genomic regions.

Direct-acting mutagenic activity in white, rosé, and red wines with the Ara test of Salmonella typhimurium.

Thirty-two commercially produced white, rosé, and red wines from Spain were assayed for genotoxicity. The Ara forward mutagenicity assay with Salmonella typhimurium served as the test system. All the wines were mutagenic in the absence of mammalian microsomal activation (S9 mix) and/or glycosidase activities with the exception of one rosé wine which gave a clear dose-response relationship, although its mutagenic potency was considered statistically nonsignificant. The mutagenic activity covered nearly a 30-fold range. Compared to white and rosé wines, red wines showed the highest levels of mutagenicity; this wine type included four "very potent" (greater than 3,000 AraR mutants/ml) mutagenic wines. The level of wine mutagenicity did not correlate with either the region or the year of production (vintage). Individual winery methods are suggested as primarily responsible for variations in mutagenic activity. The present study with the Ara test supports the possibility that wine components other than the flavonols quercetin and rutin are the major putative mutagens: (1) white wines, as well as rosé or red wines, were detected as being mutagenic; (2) in no case was activation required for the detection of mutagenicity; (3) mutagen(s) were detected mainly (red wine) when not exclusively (white and rosé wine) in the polar fraction from XAD-2 chromatography. The high sensitivity of the Ara test has allowed the screening of the mutagenicity of a variety of wines with no previous process of extraction or concentration. The comparison of the mutagenic activity of the entire complex mixture to that of its lyophilized residue has revealed a positive synergistic role for ethanol in the mutagenicity of certain wines. Finally, this work suggests that the Ara test is a useful tool for mutagenicity screening in wines. Thus, this test might play an important role in elucidating the genotoxic mechanism of action of alcoholic beverages, and for studying optional production methods to decrease the mutagenicity of commercial wines.

The involvement of reactive oxygen species in the direct-acting mutagenicity of wine.

The Ara forward mutagenicity assay with Salmonella typhimurium detected wine as a strong mutagen in the absence of mammalian microsomal activation and/or glycosidase activities, in agreement with previous findings. The standard amount (50 microliters) of S9 fraction in the preincubation mutagenesis test abolished most of the mutagenic activity of red wine in the Ara assay. The S9 fraction exerted the same inactivating capacity on hydrogen peroxide and coffee, a complex mixture generating H2O2. Catalase was identified as the putative S9 component responsible for its inactivating capacity. This specific scavenger for H2O2 abolished around 90% of the mutagenicity of red wine. The suppressing effect of catalase was much less noticeable in white and rose wines. Phenolics are proposed to be responsible for the direct-acting mutagenicity of wine through an auto-oxidative process leading to the production of H2O2.

Study of the causes of direct-acting mutagenicity in coffee and tea using the Ara test in Salmonella typhimurium.

The mutagenic activities of 6 of the chemicals identified in coffee solutions were assayed with the Salmonella Ara test, under experimental conditions optimized for coffee mutagenicity. Caffeine was the only non-mutagenic compound. Among the other 5 chemicals, hydrogen peroxide was the strongest mutagen and chlorogenic acid the weakest; methylglyoxal, glyoxal and caffeic acid exhibited intermediate mutagenicities. The minimal mutagenic doses of these components correlated negatively with their relative concentrations in coffee. It was concluded that chlorogenic acid, caffeic acid, glyoxal and methylglyoxal cannot contribute alone to the mutagenicity of coffee in the Ara test, since their minimal mutagenic concentrations were much higher than their respective levels in the coffee samples assayed. By contrast, 40-60% of the mutagenic activity in coffee and also in tea could be attributed to their H2O2 contents. Catalase abolished more than 95% of the mutagenic activity of coffee, as detected by the Ara test. A similar sensitivity to catalase has been reported by other authors in relation to the coffee mutagenicity identified by the Salmonella His test. Nevertheless, the results presented in this paper suggest that the Ara forward and the His reverse mutation tests are sensitive to the mutagenicity of different constituents in coffee solutions. We propose that the His test, sensitive at high coffee doses, mainly recognizes the mutagenicity of methylglyoxal, whilst the Ara test, sensitive at low coffee doses, mainly detects the mutagenic activity of hydrogen peroxide. The data reported also suggest that the direct-acting mutagenicity(ies) detected by the Ara test in tea solutions is (are) based on similar, if not identical, mechanisms.

Activation of multiple antibiotic resistance and binding of stress-inducible promoters by Escherichia coli Rob protein.

Multiple antibiotic resistance in Escherichia coli can be mediated by induction of the SoxS or MarA protein, triggered by oxygen radicals (in the soxRS regulon) or certain antibiotics (in the marRAB regulon), respectively. These small proteins (SoxS, 107 residues; MarA, 127 residues) are homologous to the C terminus of the XylS-AraC family of proteins and are more closely related to a approximately 100-residue segment in the N terminus of Rob protein, which binds the right arm of the replication origin, oriC. We investigated whether the SoxS-MarA homology in Rob might extend to the regulation of some of the same inducible genes. Overexpression of Rob indeed conferred multiple antibiotic resistance similar to that known for SoxS and MarA (against chloramphenicol, tetracycline, nalidixic acid, and puromycin), as well as resistance to the superoxide-generating compound phenazine methosulfate. The Rob-induced antibiotic resistance depended only partially on the micF antisense RNA that down-regulates the OmpF outer membrane porin to limit antibiotic uptake. Similar antibiotic resistance was conferred by expression of a Rob fragment containing only the N-terminal 123 residues that constitute the SoxS-MarA homology. Both intact Rob and the N-terminal fragment activated expression of stress genes (inaA, fumC, sodA) but with a pattern distinct from that found for SoxS and MarA. Purified Rob protein bound a DNA fragment containing the micF promoter (50% bound at approximately 10(-9) M Rob) as strongly as it did oriC, and it bound more weakly to DNA containing the sodA, nfo, or zwf promoter (50% bound at 10(-8) to 10(-7) M). Rob formed multiple DNA-protein complexes with these fragments, as seen previously for SoxS. These data point to a DNA-binding gene activator module used in different protein contexts.

Mutagenicity of red wine in the L-arabinose resistance test with Salmonella typhimurium.

The forward mutation assay to L-arabinose resistance (Ara test) in Salmonella typhimurium detected a Spanish red table wine (Rioja) as a direct-acting mutagen. The best mutagenic response was obtained by preincubating strain BA13 with the wine sample in the presence of sodium phosphate buffer and in the absence of any external metabolic activation. In fact, the S9 mixture abolished most of the mutagenic activity of red wine in the Ara test. Such an inactivating capacity seems to be independent of microsomal enzymes and mediated through some kind of heat-stable component(s) in the S9 fraction. Both regular wine (directly from the bottle) and lyophilized wine were strong mutagens in the Ara test, inducing 4914 and 2739 AraR mutants/ml. Both pKM101 and delta uvrB were critical factors in the detection of the mutagenicity of wine, exhibiting a synergic effect in strain BA13. The mutagenicity of red wine was somehow pH-dependent, increasing with the pH value of the preincubation mixture. In comparison with the Ara test, the His reverse mutation assay (Ames test) was much less sensitive to the mutagenicity of lyophilized red wine, TA102 being the most (448 His+/ml) and TA98 the least (38 His+/ml) sensitive strain. TA100, TA104 and TA97 manifested intermediate mutagenicities to red wine. Previous reports have identified strain TA98 as the His strain most sensitive to the apolar fraction (e.g. XAD-2-bound) of red wine. Based on these results we propose that TA98 mainly detects glycosides of mutagenic flavonols present in red wine (quercetin, rutin, etc.), which do not constitute the major direct-acting mutagens detected with the Ara test.(ABSTRACT TRUNCATED AT 250 WORDS)

Study on the mutagenicity of brandy with the Ara test.

The forward mutation assay to L-arabinose resistance (Ara test) in Salmonella typhimurium was used to demonstrate that evaporated residues of brandy had direct-acting mutagenic activity. The mutagenicity covered a 100-fold range, from 13482 to 127 AraR induced mutants/ml brandy equivalent. Rat liver S9 mix suppressed the mutagenic activity of brandy in the Ara test. The inactivating capacity was independent of microsomal monoxygenase enzymes and appeared to be mediated through a heat stable component of the S9 fraction. Catalase was identified as the putative S9 component responsible for its inactivating capacity. The implication of reactive oxygen species in the direct-acting mutagenicity of brandy was supported by the higher sensitivity of Escherichia coli bacterial strains deficient in two major cellular antioxidant defense (glutathione and/or catalase) compared to their parental wild-type. Phenolic compounds of a polar nature could be responsible for the mutagenicity through the production of reactive oxygen intermediates. Non-matured beverages (gin and non-matured rum) were non-mutagenic. It is conceivable that mutagenic phenolics might be extracted from the wood during maturation in the barrel. Autoxidation of phenolic compounds could be a common mechanism in the mutagenicity of complex mixtures of plant origin.

A method for selection of forward mutations in supF gene carried by shuttle-vector plasmids.

The supF gene of Escherichia coli has been widely used as a mutagenic target in several shuttle-vector plasmids. Mutations in this gene are usually screened by a colony colour assay based on the suppression of a lacZ amber mutation in an appropriate bacterial indicator strain. This screening method cannot measure the low mutation frequencies usually detected in prokaryotes, and therefore precludes the use of supF gene for studying mutational spectra in bacteria. In this paper we report the development of a simple method for the selection of supF forward mutations in shuttle-vector plasmids. The method has implied the construction of an araD- araC(Am) mutant strain (MBL50) of E.coli. The L-arabinose sensitivity caused by the accumulation of a toxic intermediate in araD- mutants is abolished in MBL50 because the araC(Am) mutation blocks the L-arabinose catabolic pathway. Strain MBL50 becomes sensitive to L-arabinose when transformed with a supF+ plasmid but remains resistant upon transformation with a supF- mutant. This new L-arabinose resistance selection method was able to detect supF- mutant fractions up to three orders of magnitude below those determined with the colony colour screening assay. The method was further validated by carrying out in vivo mutagenesis experiments with N-methyl-N-nitrosourea (MNU) and a shuttle-vector-bearing strain (UC2109) completely defective in O6-methylguanine (O6meG) alkyltransferase repair capacity. The DNA sequence alterations of 22 independent supF- mutants induced by MNU were determined. All mutations were G:C-->A:T transitions in agreement with the predicted significance of the mispairing potential of the O6meG lesion. A preference for the sequence 5'-GG-3' was detected, revealing a 5'-flanking base influence. The accumulation of all 22 MNU-induced mutations in three sites of the supF genes might be related to the lack of O6meG alkyltransferase repair capacity of strain UC2109. The L-arabinose resistance method described in this paper allows rapid scoring and sequencing of forward mutations in the supF gene on shuttle-vectors, thus permitting its use as a genetic target for repair and mutagenesis studies in bacteria. Since shuttle-vectors replicate both in bacteria and mammalian cells, this method makes it possible to compare prokaryotic and eukaryotic mutational spectra.

Influence of DNA repair by ada and ogt alkyltransferases on the mutational specificity of alkylating agents.

We investigated the influence of the alkyltransferases (ATases) encoded by the ada and ogt genes of Escherichia coli on the mutational specificity of alkylating agents. A new mutational assay for selection of supF- mutations in shuttle-vector plasmids was used. Treating plasmid-bearing bacteria with N-methyl-N-nitrosourea (MNU), N-ethyl-N-nitrosourea (ENU), and ethyl methanesulfonate (EMS) dramatically increased the mutation frequency (from 33-fold to 789-fold). The vast majority of mutations (89-100%) were G:C-->A:T transitions. This type of mutation increased in ada- (MNU) or ogt- (ENU) bacteria, suggesting that repair of O6-methylguanine by ada ATase and repair of O6-ethylguanine by ogt ATase contribute mainly to the decrease in G:C-->A:T transitions. The analysis of neighboring base sequences revealed an overabundance of G:C-->A:T transitions at 5'-GG sequences. The 5'-PuG bias increased in ATase-defective cells, suggesting that these sequences were not refractory to repair. G:C-->A:T transitions occurred preferentially in the untranscribed strand after in vivo exposure. That this strand specificity was detected even in bacteria devoid of ATase activity (ada- ogt-) and not after in vitro mutagenesis suggests a bias for damage induction rather than for DNA repair. Highly significant differences were found between the in vivo and in vitro incidences of G:C-->A:T substitutions at the two major hotspots, positions 123 (5'-GGG-3'; antisense strand) and 168 (5'-GGA-3'; sense strand). These results are explained by differences in the probability of formation of stem-loop structures in vivo and in vitro.

Fpg protein protects Escherichia coli K-12 from mutation induction by the carcinogen 4-nitroquinoline 1-oxide.

This paper investigates the role of the fpg gene product in protecting Escherichia coli cells against the lethal and mutagenic effects of 4-nitroquinoline 1-oxide (4NQO). To this end, the araD81 mutation which make the cells sensitive to L-arabinose was combined with an fpg-1::Knr allele, in either an uvrA+ or uvrA-, umuC+ or umuC-, genetic background. Mutation induction was monitored by selecting forward mutations to L-arabinose resistance (Arar). The formamidopyrimidine-DNA glycosylase (Fpg protein) protected bacteria from 4NQO-induced mutagenesis since Fpg- defective cells showed greater Arar mutation induction than fpg+ bacteria did. This was confirmed since the increased sensitivity of the fpg- cells to mutagenesis by 4NQO was suppressed when the Fpg protein was overproduced by placing the fpg gene in a multicopy plasmid vector. The fpg- mutation had no detectable influence on 4NQO mutagenesis in a uvrA- genetic background, but its effect was magnified in umuC- cells. No influence on cell survival was observed after 4NQO treatment. Our data suggest that 8-hydroxyguanine, a non-lethal, non-bulky and directly miscoding lesion, might be responsible for the detected influence of Fpg protein expression on mutation induction by 4NQO. This is in agreement with the reported in vivo formation of 8-hydroxyguanine in cellular DNA after 4NQO exposure. The increased 4NQO-induction of GC to TA transversions on fpg- bacteria further support such a possibility. This work reinforces the role of Fpg protein in the bacterial defense against the mutagenicity by genotoxic agents.

Repressor mutations in the marRAB operon that activate oxidative stress genes and multiple antibiotic resistance in Escherichia coli.

Resistance to multiple antibiotics and certain oxidative stress compounds was conferred by three independently selected mutations (marR1, soxQ1, and cfxB1) that mapped to 34 min on the Escherichia coli chromosome. Mutations at this locus can activate the marRAB operon, in which marR encodes a putative repressor of mar transcription and marA encodes a putative transcriptional activator of defense genes against antibiotics and oxidants. Overexpression of the wild-type MarR protein reversed the phenotypes (antibiotic resistance and increased antioxidant enzyme synthesis) of all three mutants. DNA sequence analysis showed that, like marR1, the other two mutations were alterations of marR: a 285-bp deletion in cfxB1 and a GC-->AT transition at codon 70 (Ala-->Thr) in soxQ1. All three mutations cause increased amounts of mar-specific RNA, which supports the hypothesis that MarR has a repressor function in the expression of the marRAB operon. The level of mar RNA was further induced by tetracycline in both the marR1 and soxQ1 strains but not in the cfxB1 deletion mutant. In the cfxB1 strain, the level of expression of a truncated RNA, with or without tetracycline exposure, was the same as the fully induced level in the other two mutants. Overproduction of MarR in the cfxB1 strain repressed the transcription of the truncated RNA and restored transcriptional inducibility by tetracycline. Thus, induction of the marRAB operon results from the relief of the repression exerted by MarR. The marRAB operon evidently activates both antibiotic resistance and oxidative stress genes.

Reversible protein phosphorylation modulates nucleotide excision repair of damaged DNA by human cell extracts.

Nucleotide excision repair of DNA in mammalian cells uses more than 20 polypeptides to remove DNA lesions caused by UV light and other mutagens. To investigate whether reversible protein phosphorylation can significantly modulate this repair mechanism we studied the effect of specific inhibitors of Ser/Thr protein phosphatases. The ability of HeLa cell extracts to carry out nucleotide excision repair in vitro was highly sensitive to three toxins (okadaic acid, microcystin-LR and tautomycin), which block PP1- and PP2A-type phosphatases. Repair was more sensitive to okadaic acid than to tautomycin, suggesting the involvement of a PP2A-type enzyme, and was insensitive to inhibitor-2, which exclusively inhibits PP1-type enzymes. In a repair synthesis assay the toxins gave 70% inhibition of activity. Full activity could be restored to toxin-inhibited extracts by addition of purified PP2A, but not PP1. The p34 subunit of replication protein A was hyperphosphorylated in cell extracts in the presence of phosphatase inhibitors, but we found no evidence that this affected repair. In a coupled incision/synthesis repair assay okadaic acid decreased the production of incision intermediates in the repair reaction. The formation of 25-30mer oligonucleotides by dual incision during repair was also inhibited by okadaic acid and inhibition could be reversed with PP2A. Thus Ser/Thr- specific protein phosphorylation plays an important role in the modulation of nucleotide excision repair in vitro.

An OGG1 orthologue encoding a functional 8-oxoguanine DNA glycosylase/lyase in Arabidopsis thaliana.

Repair of the ubiquitous mutagenic lesion 7,8-dihydro-8-oxoguanine (8-oxoG) is initiated in eukaryotes by DNA glycosylases/lyases, such as yeast Ogg1, that do not share significant sequence identity with their prokaryotic counterparts, typified by Escherichia coli MutM (Fpg) protein. The unexpected presence of a functional mutM orthologue in the model plant Arabidopsis thaliana has brought into question the existence of functional OGG1 orthologues in plants. We report here the cDNA cloning, expression and functional characterization of AtOGG1, an Arabidopsis thaliana gene widely expressed in different plant tissues which encodes a 40.3 kDa protein with significant sequence identity to yeast and human Ogg1 proteins. Purified AtOgg1 enzyme specifically cleaves duplex DNA containing an 8-OxoG:C mispair, and the repair reaction proceeds through an imine intermediate

cDNA cloning, expression and functional characterization of an Arabidopsis thaliana homologue of the Escherichia coli DNA repair enzyme endonuclease III.

Reactive oxygen species (ROS) are ubiquitous DNA-damaging agents, and the repair of oxidative DNA lesions is essential to prevent mutations and cell death. Escherichia coli endonuclease III is the prototype repair enzyme for removal of oxidized pyrimidines from DNA. A database homology search identified a genomic sequence in Arabidopsis thaliana encoding a predicted protein with sequence similarity to E. coli endonuclease III. We cloned, sequenced and expressed the corresponding cDNA, which encodes a 39.1 kDa protein containing several sequence motifs conserved in endonuclease III homologues, including an iron-sulfur cluster domain and critical residues at the active site. The protein, designated AtNTH1, was over-expressed in E. coli and purified to apparent homogeneity. AtNTH1 exhibits DNA-glycosylase activity on different types of DNA substrates with pyrimidine damage, being able to release both urea and thymine glycol from double-stranded polydeoxyribonucleotides. The enzyme also possesses an apurinic/apyrimidinic lyase activity on UV- and gamma-irradiated DNA substrates. The AtNTH1 gene contains 10 introns and 11 exons and is widely expressed in different plant tissues. Our results suggest that AtNTH1 is a structural and functional homologue of endonuclease III and probably plays a major role in plant defence against oxidative DNA damage.

Repair of an interstrand DNA cross-link initiated by ERCC1-XPF repair/recombination nuclease.

Interstrand DNA cross-link damage is a severe challenge to genomic integrity. Nucleotide excision repair plays some role in the repair of DNA cross-links caused by psoralens and other agents. However, in mammalian cells there is evidence that the ERCC1-XPF nuclease has a specialized additional function during interstrand DNA cross-link repair, beyond its role in nucleotide excision repair. We placed a psoralen monoadduct or interstrand cross-link in a duplex, 4-6 bases from a junction with unpaired DNA. ERCC1-XPF endonucleolytically cleaved within the duplex on either side of the adduct, on the strand having an unpaired 3' tail. Cross-links that were cleaved only on the 5' side were purified and reincubated with ERCC1-XPF. A second cleavage was then observed on the 3' side. Relevant partially unwound structures near a cross-link may be expected to arise frequently, for example at stalled DNA replication forks. The results show that the single enzyme ERCC1-XPF can release one arm of a cross-link and suggest a novel mechanism for interstrand cross-link repair.

Xeroderma pigmentosum group F caused by a defect in a structure-specific DNA repair endonuclease.

Nucleotide excision repair, which is defective in xeroderma pigmentosum (XP), involves incision of a DNA strand on each side of a lesion. We isolated a human gene homologous to yeast Rad1 and found that it corrects the repair defects of XP group F as well as rodent groups 4 and 11. Causative mutations and strongly reduced levels of encoded protein were identified in XP-F patients. The XPF protein was purified from mammalian cells in a tight complex with ERCC1. This complex is a structure-specific endonuclease responsible for the 5' incision during repair. These results demonstrate that the XPF, ERCC4, and ERCC11 genes are equivalent, complete the isolation of the XP genes that form the core nucleotide excision repair system, and solve the catalytic function of the XPF-containing complex.