Abstract
Transfection of M13 single-stranded viral DNA bearing a 3,N4-ethenocytosine lesion into Escherichia coli cells pretreated with UV results in a significant elevation of mutagenesis at the lesion site compared to that observed in untreated cells. This response, termed UVM, for UV modulation of mutagenesis, is induced by a variety of DNA-damaging agents and is distinct from known cellular responses to DNA damage, including the SOS response. This report describes our observation, as a part of our investigation of the UVM phenomenon, that E. coli cells bearing a mutA or mutC allele display a UVM-constitutive phenotype. These mutator alleles were recently mapped (M. M. Slupska, C. Baikalov, R. Lloyd, and J. H. Miller, Proc. Natl. Acad. Sci. USA 93:4380-4385, 1996) to the glyV (mutA) and glyW (mutC) tRNA genes. Each mutant allele was shown to arise by an identical mutation in the anticodon sequence such that the mutant tRNAs could, in principle, mistranslate aspartate codons in mRNA as glycine at a low level. Because a UVM-constitutive phenotype resulting from a mutation in a tRNA gene was unexpected, we undertook a series of experiments designed to test whether the phenotype was indeed mediated by the expression of mutant glycine tRNAs. We placed either a wild-type or a mutant glyV gene under the control of a heterologous inducible promoter on a plasmid vector. E. coli cells expressing the mutant glyV gene displayed all three of the following phenotypes: (i) missense suppression of a test allele, (ii) a mutator phenotype measured by mutation to rifampin resistance, and (iii) a UVM-constitutive phenotype. These phenotypes were not associated with cells expressing the wild-type glyV gene or with cells in which the mutant allele was present but was not transcriptionally induced. These observations provide strong support for the idea that expression of mutant tRNA can confer a mutator phenotype, including the UVM-constitutive phenotype observed in mutA and mutC cells. However, our data imply that low-level mistranslation of the epsilon subunit of polymerase III probably does not account for the observed UVM-constitutive phenotype. Our results also indicate that mutA deltarecA double mutants display a normal UVM phenotype, suggesting that the mutA effect is recA dependent. The observations reported here raise a number of intriguing questions and raise the possibility that the UVM response is mediated through transient alteration of the replication environment.