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ABSTRACT
Mutagenesis by simple alkylating agents is thought to occur by either a lexA+-dependent process called error-prone repair or a lex-independent process often attributed to mispairing during replication. We show here that error-prone repair is responsible for the majority of mutants formed after a large dose of alkylating agent, but it is unlikely that it contributes significantly to mutagenesis during exposure to low concentrations of these chemicals. The mutagenicity of these low doses of alkylating agent is reduced by a repair system constitutively present in lexA+ cells but absent in lexA mutants. This system reduces mutagenesis until a second error-free system, called the adaptive responses, can be induced [P. Jeggo, M. Defais, L. Samson, and P. Schendel, Mol. Gen. Genet, 157:1-9, 1977; L. Samson and J. Cairns, Nature (London) 267:281-283, 1977]. The adaptive response is capable of dealing with a much larger amount of alkylation damage than the constitutive system and, when induced, appears to be able to reduce mutagenesis by both decreasing the number of sites available for mutagenesis and delaying the induction of error-prone repair enzymes. Finally, we discuss a model of chemically induced mutagenesis based on these findings which maintains that the observed mutation frequency is dependent on a "race" between these two error-free systems and the two mutagenic pathways.
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