D.R. McCalla

Cytotoxicity and DNA damage to mammalian cells by nitrofurans

Nitrofurazone, nitrofurantoin, furazolidone, furaltadone and N-[4-(5-nitro-2-furyl)-2-thiazolyl] formamide (FANFT) were toxic to cultured mouse L cells. The extent of toxocity and the rate of reduction of nitrofurazone increased markedly as the oxygen content of the incubation medium was lowered. The toxic effect of nitrofurans was decreased by addition of serum and was much greater in phosphate-buffered saline containing glucose (PSG) than in medium. Damage to L cell DNA by nitrofurans increased as the oxygen concentration decreased from 21% to 0%. The concentration of nitrofurazone and duration of exposure also determined the number of DNA single-strand breaks. It is suggested that toxicity and DNA damage may result from the actions of toxic intermediates in the metabolic reduction of nitrofurans.

The action of AF 2 on cultured hamster and human cells under aerobic and hypoxic conditions

AF 2 (2-(2-furyl)-3-(5-nitro-furyl)acrylamide) was toxic to Chinese hamster V 79 cells and normal human fibroblasts in aerobic media. However, the toxicity of the drug was increased many times by hypoxia. Similarly, the frequency of AF 2-induced azaguanine- and ouabain-resistant mutants of V 79 cells was much higher in hypoxia than under aerobic conditions. Both hamster V 79 cells and human fibroblasts metabolized AF 2 and other nitrofurans rapidly only under hypoxic conditions. Human fibroblasts were more sensitive to AF 2 both under aerobic conditions and in hypoxia than were V 79 cells under similar conditions. The Chinese hamster cells consistently gave survival curves with marked shoulders while human cells did not. Aerobic cultures of fibroblasts derived from xeroderma pigmentosum (XP) patients were markedly sensitive to AF 2 while fibroblasts from two ataxia telangeictasia patients had normal sensitivity. Under hypoxic conditions the sensitivity of both types of cells was increased but the XP line remained 5--10-fold more sensitive than normal or ataxia cells. These results suggest that the DNA lesions produced by AF 2 may be regarded as similar to those produced by ultraviolet light, at least in terms of their repairability in human cells.

Effect of nitrofurazone on bacterial RNA and ribosome synthesis and on the function of ribosomes

Exposure of E. coli B/r to nitrofurazone strongly inhibits the synthesis of all classes of RNA and both ribosomal sub-units. Polysome formation is likewise inhibited. However, in E. coli nfr-207 a mutant of B/r which lacks nitrofurazone-reductase I, the synthesis of RNA, ribosomal sub-units and formation of polysomes are not significantly affected. This result implies that a reduced metabolite of the drug rather than the drug itself is the active agent. The ability of ribosomes isolated from nitrofurazone-treated E. coli B/r to carry out poly-U directed polyphenylalanine synthesis was lower than that of ribosomes from untreated cells. 14C from labelled nitrofurazone was found to bind to ribosomal sub-units.

Amaranth suppresses the mutagenicity of 2-acetylaminofluorene by lowering the concentration of NADPH in top agar.

Addition of 1 mg amaranth (FD&C Red No. 2) to the top agar of Salmonella/S9 assay plates decreased the yield of revertants induced by 20 micrograms 2-acetylaminofluorene (AAF) by over 50% and additional amaranth completely eliminated the mutagenic response. Similar suppression of AAF mutagenicity was seen with sulfonazo III, another azo dye. The suppressive effect of amaranth was greatest at low S9 concentrations and decreased as the amount of S9 was increased. When N-hydroxyacetylaminofluorene (N-OH-AAF) was used as mutagen, amaranth had little or no effect on either the number of revertants obtained or the S9 optimum. Similarly, 1-naphthylamine-4-sulfonic acid (a reduction product of amaranth) did not significantly affect the mutagenicity of AAF. The rate of metabolism of [14C]AAF by the S9 preparations was shown to be markedly decreased by amaranth, as were the levels of both the phenolic metabolites and of N-OH-AAF. Thus, it appeared that amaranth acts by blocking the conversion of AAF to N-OH-AAF and that this effect is caused by the amaranth itself and not by its constituent amines. Further experiments indicated that amaranth greatly decreased the levels of NADPH formed in reaction mixtures comparable to S0 mix in top agar and that such reaction mixtures also metabolized amaranth to colourless compounds. It appears likely that in top agar, NADPH reacts with amaranth at a fast enough rate to limit severely the level of the reduced co-factor (which must be formed from NADPH+ by the action of endogenous glucose-6-phosphate dehydrogenase) and thus decreases the rate of activation of mutagens by other NADPH-dependent processes.