The interaction of acetoxy-dimethylnitrosamine, a proximate metabolite of the carcinogenic amine, and bacteriophages R17 and T7

A method for measuring the lifetime of chemically and metabolically generated electrophilic species

A method is presented for the characterization of the reaction order and rate constant for chemically and metabolically generated reactive electrophilic intermediates. The procedure employs flow kinetics and trapping of the electrophilic species. Reactive agents or metabolic intermediates are passed through a column containing a bound nucleophilic reagent. The electrophilic species reacts at a characteristic rate while moving through the column at a fixed pH, temperature and rate of flow. The alkylation products formed during this reaction are quantified in individual column segments which correspond to time intervals. This provides data for the calculation of the lifetime of the short-lived species. The method may be used for agents having half-lives of 1 s to 30 min. Metabolic intermediates need not be isolated. Data is presented for the reaction rates of 1-methyl-1-nitrosourea (MNU), 1-methyl-3-nitro-1-nitrosoguanidine (MNNG) and iodomethane. A metabolic activation system is described for the conversion of acetoxy-methylmethylnitrosamine (DMN-OAc) to hydroxymethylmethylnitrosamine (DMN-OH) and measurement of the stability of that intermediate. Hydroxymethylmethylnitrosamine was found to have a half-life of 28s at pH 7.4, 37 degrees C.

The mutagenicity of nitrosopyrrolidine is related to its metabolism

Various cell fractions from rat liver were tested for their ability to convert nitrosopyrrolidine (NO-PYR) to products which were mutagenic to E. coli in liquid-incubation assays. Microsomes alone produced only a small number of tyr+ revertants, approximately 40/10(8) survivors), while the S100 supernatant produced none at all. However, the S8 Fraction or combinations of microsomes and the S100 supernatant, yielded 300-400 tyr+ revertants/10(8) survivors. Neither products of the microsomal, nor microsome + supernatant reactions were mutagenic in the absence or presence of cellular fractions. These results suggest that bacterial mutagens are formed during the microsomal metabolism of NO-PYR to 2-hydroxytetrahydrofuran by alpha-hydroxylation, but not during the metabolism of 2-hydroxytetrahydrofuran by the S100 supernatant enzymes. Possible roles of the supernatant enzymes in the formation of mutagenic intermediates during the initial alpha-hydroxylation of NO-PYR are discussed.

High mutagenicity of N-(alpha-acyloxy)alkyl-N-alkylnitrosamines in S. typhimurium: model compounds for metabolically activated N,N-dialkylnitrosamines

A series of N,N-dialkylnitrosamines (alkyl means methyl, ethyl, n-propyl, n-butyl or tert-butyl group) mono-substituted at the alpha-carbon with an acetoxy group, were tested for their mutagenic action in Salmonella typhimurium TA1530 in the presence or absence of a rat-liver supernatant from 9000 X g. The presumed released of methyl, ethyl, n-butyl and n-propyl carbonium ions from the corresponding alpha-acetoxy derivatives, either by enzymic cleavage or by non-enzymic hydrolysis of the ester group, caused high mutagenicity in the bacteria. As has been demonstrated for certain alpha-acetoxy compounds, the mutagenicity of these compounds was inversely related to their half-lives in aqueous media. N-(Acetoxy)methyl-N-tert-butylnitrosamine and a beta-acetoxy derivative of N,N-diethylnitrosamine were not mutagenic either in the presence or in the absence of hydrolysing rat-liver enzymes. These results support the hypothesis that alpha-carbon hydroxylation is one mechanism involved in the metabolic activation of N,N-dialkylnitrosamines.