The cancer chemotherapy drug bleomycin (BLM) is a potent inducer of genetic damage in a wide variety of assays. The radioprotectors cysteamine (CSM) and WR-1065 have been shown in previous studies to potentiate the induction of micronuclei and chromosome aberrations by BLM in Go human lymphocytes. By contrast, WR-1065 is reported to reduce the induction of hprt mutations by BLM in Chinese hamster cells. To elucidate the basis for these interactions, we examined the effects of CSM and WR-1065 on the induction of mitotic gene conversion by BLM in the yeast Saccharomyces cerevisiae. Treatment with BLM causes a dose-dependent increase in the frequency of mitotic gene conversion and gene mutations. Unlike its potentiation of BLM in Go lymphocytes, WR-1065 protected against the recombinagenicity of BLM in yeast. CSM was also strongly-antirecombinagenic under, some conditions, but the nature of the interaction depended strongly on the treatment conditions. Under hypoxic conditions, cysteamine protected against BLM, but under oxygen-rich conditions CSM potentiated the genetic activity of BLM. The protective effect of aminothiols against BLM may be ascribed to the depletion of oxygen required for the activation of BLM and the processing of BLM-induced damage. Aminothiols may potentiate the effect of BLM by acting as an electron source for the activation of BLM and/or by causing conformational alterations that make DNA more accessible to BLM. The results indicate that aminothiols have a strong modulating influence on the genotoxicity of BLM in yeast as they do in other genetic assays. Moreover, the modulation differs markedly depending on physiological conditions. Thus, yeast assays help to explain why aminothiols have been observed to potentiate BLM in some genetic systems and to protect against it in others.