Genotoxicity of 2-nitro-7-methoxy-naphtho[2,1-b]furan (R7000): a case study with some considerations on nitrofurantoin and nifuroxazide.

Two nitrofurans present broad-spectrum antimicrobial properties and some of them are used in human and veterinary medicine. Most of these molecules are mutagens and some of them were reported as carcinogens. Due to its extreme mutagenic potency in bacteria, the nitronaphtho derivative 2-nitro-7-methoxy-naphtho[2,1-b]furan (R7000) was used as a tool to analyze the mechanism of the genotoxic action of this family of chemicals. In the present paper, we review essential data on the genotoxicity of R7000 and briefly discuss the case of nitrofurantoin and nifuroxazide, two nitrofurans, still in use as urinary and gastrointestinal disinfectants.

Palindromic unit-independent transposition of IS1397 in Yersinia pestis.

Palindromic units (PUs) are intergenic repeated sequences scattered over the chromosomes of Escherichia coli and several other enterobacteria. In the latter, IS1397, an E. coli insertion sequence specific to PUs, transposes into PUs with sequences close to the E. coli consensus. Reasons for this insertion specificity can relate to either a direct recognition of the target (by its sequence or its structure) by the transposase or an interaction between a specific host protein and the PU target DNA sequence. In this study, we show that for Yersinia pestis, a species deprived of PUs, IS1397 can transpose onto its chromosome, with transpositional hot spots. Our results are in favor of a direct recognition of target DNA by IS1397 transposase.

Comparison of kinetics of induction of DNA adducts and gene mutations by a nitrofuran compound, 7-methoxy-2-nitronaphtho[2,1-b]furan (R7000), in the caecum and small intestine of Big Blue mice.

In previous experiments, i.p. injection of the 5 nitronaphthofuran derivative 7-methoxy-2-nitronaphtho[2,1-b]furan (R7000) to lacI transgenic Big Blue mice led to an increase in the mutant frequency (MF), especially in the caecum and the small intestine. In the present work, the in vivo genotoxicity of R7000 in these two target organs was further investigated. Big Blue mice were treated with a single daily i.p. injection of R7000 of 0.05-0.5 mg/day for five consecutive days and killed 28 days later. These treatments led to significant increases in MF of 1.8-, 3- and 5.4-fold at 0.1, 0.2 and 0.5 mg/day R7000, respectively, in the small intestine. In the caecum, a mutagenic effect, of 4.5-fold, was only observed at the highest dose. DNA adduct formation and MFs resulting from R7000 were also analysed in parallel at various times after the last injection. R7000 led to 14 and seven different nucleotide modifications in the caecum and small intestine, respectively. Three hours after the final injection the level of induced DNA adducts was 10 times higher in the caecum than in the small intestine. From 3 h to 5 days after the final injection, 93 and 58% of DNA adducts disappeared in the caecum and small intestine, respectively. The resulting MF values were similar when comparing the two organs. Analysis of the R7000-induced mutation spectrum in the caecum showed that single G:C and large, > or =3 bp deletions and GC-->CG transversions were the first induced mutations at the end of the treatment. Fifteen days later, the R7000 mutation specificity characteristics already reported in Escherichia coli and in the small intestine of Big Blue mice were evident in the caecum, with the two major events being GC-->TA transversions and deletions of one G:C base pair. In both organs, a relationship between the decrease in R7000-DNA adducts and induction of MF was evident. However, the efficiency of this compound in damaging DNA was not correlated with the capacity of DNA lesions to lead to mutations. Some discrepancies in the R7000 genotoxic effects between the two organs were observed, which may be attributable to differences in the metabolic activation pathway of the compound, as well as to DNA repair proficiency in each tissue.