Evolution of biological effects of Aznalcóllar mining spill in the Algerian mouse (Mus spretus) using biochemical biomarkers.

The status of Guadiamar stream, polluted in 1998 by metals spilled from a pyrite tailings dam, was monitored from 1999 to 2001 to assess possible biological effects in terrestrial ecosystems of Doñana National Park (DNP) (Andalusia, SW Spain). The Algerian mouse (Mus spretus) was used as bioindicator at different Guadiamar and Doñana sites. Eleven biochemical parameters, including the activities of antioxidative and biotransforming enzymes and oxidative damages to biomolecules, were assayed in liver as biomarkers responsive to metals and organic pollutants. In 2001, metals were also determined in kidney and their possible correlation with biomarker responses was studied. Contents of Pb, Cd and As significantly correlated with several antioxidative enzymes. Biomarkers responsive to oxidative stress indicate the presence of transition metals in the high and medium Guadiamar course, and their response diminished with the distance to the collapsed dam. The high ethoxyresorufin-O-deethylase (EROD) activity of mice from the medium and low Guadiamar course point to organic pollutants, such as the pesticides used in intensive crops grown in areas nearby Doñana. The increasing responses of several biomarkers at reference sites may suggest a progressive pollution of key Doñana ecosystems.

Oxidative mutagenesis in Escherichia coli strains lacking ROS-scavenging enzymes and/or 8-oxoguanine defenses.

Escherichia coli strains with different combinations of null mutations in the katG, katE, sodA, sodB, fpg, and mutY genes were constructed to compare their spontaneous mutation frequencies and sensitivities to various oxidants with those of bacteria solely deficient in catalase (katG katE) or cytosolic superoxide dismutase (sodA sodB) and the parental strain possessing a full complement of these enzymes. The MutY DNA glycosylase represented the major protection against the mutagenic consequences of processes associated with normal aerobic metabolism. Spontaneous mutagenesis in MutY-lacking bacteria was not influenced by the absence of (A)BC excinuclease or the presence of MucAB proteins, a result consistent with 8-oxoguanine being a principal premutational lesion. In contrast, catalase and SOD represented the major protection against the genotoxic consequences of bursts of oxidative stress caused by reactive-oxygen-generating compounds. Therefore, only bacteria simultaneously defective in both katG and katE or sodA and sodB genes were hypersensitive with respect to mutability by peroxide and superoxide, respectively. These data suggest that oxidative lesions other than 8-oxoguanine contribute to mutagenesis by hydrogen peroxide and redox-cycling chemicals.

Hydrogen peroxide and coffee induce G:C-->T:A transversions in the lacI gene of catalase-defective Escherichia coli.

The mutagenicity of hydrogen peroxide (H2O2) was compared with that of coffee, a complex mixture which generates H2O2. An Escherichia coli strain defective in catalase activity (katG katE double mutant) and carrying a single copy mucAB (pRW144) plasmid was constructed to enhance the mutagenic response to oxidants. The ability of the mucAB genes to influence the type, frequency and distribution of H2O2-induced mutations was also investigated in isogenic bacteria lacking pRW144. Induced mutational spectra were characterized and compared with that of spontaneous mutagenesis. A total of 444 independent forward mutations affecting the first 210 bp of the lacI gene were identified by DNA sequence analysis. The spontaneous mutation spectrum showed no bias (P = 0.52) for substitutions at G:C base pairs. In contrast, in the H2O2-induced spectrum substitutions occurred preferentially at G:C base pairs (P < 0.0001) with a preponderance of G:C-->T:A transversions (43.4% of H2O2-induced mutants versus 17.3% of spontaneous mutants). These data support the view that 7,8-dihydro-8-oxoguanine is the main premutagenic lesion induced by H2O2 and that catalase-defective bacteria have elevated levels of 8-oxoguanine in chromosome DNA after H2O2 exposure. Coffee produced a similar distribution of mutational events as H2O2 (P > 0.05), suggesting that this compound may be the main cause of the coffee-induced mutagenesis. The presence of plasmid pRW144 did not affect the frequency of H2O2-induced G:C-->T:A transversions, but caused an increase in A:T-->T:A transversions and a decrease in -1 base frameshifts. Although the frequencies of G:C-->T:A transversions were similar in all three induced spectra (H2O2 and coffee +/- pRW144), differences were observed in location of mutations throughout the target gene.

Formation of 8-oxoguanine in cellular DNA of Escherichia coli strains defective in different antioxidant defences.

This paper examines the relationship in Escherichia coli between the in vivo content of 8-oxoguanine (8-oxoG) in chromosomal DNA and deficiencies of various key antioxidant defences. The structural genes for catalases (katG and katE), cytosolic superoxide dismutases (sodA and sodB) or formamidopyrimidine-DNA glycosylase (fpg) were inactivated to obtain bacterial strains lacking the scavenger enzymes for H2O2 or O2.- or the DNA repair protein for 8-oxoG. Wild-type bacteria showed 5-fold increased sensitivity to both lethality and mutagenesis by H2O2 in K medium (1% casamino acids and 1% glucose), as compared with nutrient broth. This higher sensitivity was associated with increased chromosomal oxidative damage, estimated as the 8-oxodG content, and with a marked decrease in both catalase and SOD activities. Bacteria lacking both cytosolic SODs (sodA sodB mutant) displayed increased 8-oxodG content in chromosomal DNA (2.8-fold that of the wild-type) when grown under standard aerated conditions. Comparatively, no significant difference in 8-oxodG content was observed in cells grown without aeration. Bacteria totally devoid of catalase activity (katG katE mutant) showed wild-type contents of 8-oxodG in chromosomal DNA when grown under aerated conditions. Nevertheless, the protective role of catalase in preventing formation of 8-oxodG in chromosomal DNA became evident under oxidative stress conditions: growth under hyperoxygenation and, particularly, following H2O2 exposure. Catalase deficiency resulted in a dramatic decrease in viability after H2O2 exposure. A deficiency of Fpg protein also sensitized E.coli to H2O2 lethality, though to lesser extent than a deficiency of catalase activity. However, the scavenger enzyme and the DNA repair protein protected equally against 8-oxoG formed in vivo upon H2O2 treatment.

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.