Inducible error-prone repair in yeast suppression by heat shock

Abstract

The production of reversion mutations in wild-type, diploid Saccharomyces cerevisiae by the alkylating agents N-methyl- N′-nitro- N-nitrosoguanidine (MNNG) and methylnitrosourea (MNU) was suppressed in cells previously treated with a heat shock, or the protein synthesis inhibitor, cycloheximide. The same treatment after mutagen exposure did not lower the induced mutation frequency. In split-dose experiments, a first MNNG exposure prevented subsequent heat (or cycloheximide) treatment from blocking mutation by a second, later mutagen exposure. These data suggest that, in yeast, MNNG or MNU induces an error-prone DNA-repair system, and that this induction is blocked by protein-synthesis inhibitors. The specificity of this system for different types of DNA damage was investigated using a variety of other mutagenic agents. A prior heat shock did not suppres mutation produced by exposure to ethyl methanesulfonate, ethylnitrosourea, 8-methoxypsoralen + UVA, or γ-radiation. Partial suppression was observed in cells exposed to methyl methanesulfonate or to 254-nm ultraviolet light. These results indicate that, unlike the SOS system of E. coli, this inducible error-prone process of yeast is reponsive to only certain mutagens. Heat shock suppression of mutation produced by MNNG exposure was also demonstrated in wild-type haploid cells, as well as haploid strains mutant in representative genes of the RAD52 epistasis group ( rad52, rad53, rad54), the RAD3 epistasis group ( rad1, rad2, rad3) and the RAD6 epistasis group ( rad9, rad18). The rad6 mutant itself was immutable with MNNG and therefore untestable by these techniques. These data indicate that this error-prone repair system is not absolutely dependent on the integrity of the RAD52 (recombination) or the RAD3 (excision) systems, or on at least some parts of the RAD6 system.