Effects of growth temperature and caffeine on genetic responses of Candida albicans to ethyl methanesulfonate, nitrous acid and ultraviolet radiation.

Ultraviolet radiation is more effective than either ethyl methanesulfonate or nitrous acid in inducing reverse mutation from auxotrophy to prototrophy in C. albicans. The killing effect of each of the mutagens is greater for cells grown at 37 C than at 25 C after treatment; mutation frequencies are unaffected by post-treatment growth temperatures. Though caffeine depresses survival of mutagen treated cells at both 25 C or 37 C, its effect is more pronounced at 37 C. Caffeine has no effect on mutagenesis by nitrous acid or ethyl methanesulfonate; it depresses UV mutagenesis, but only at 37 C and at high UV dosages. These findings indicate that UV mutagenesis in C. albicans is mediated by a caffeine-sensitive, recombinational system for DNA repair analogous to those known to occur in other species of yeasts. The repair system of C. albicans is unique in being susceptible to caffeine only at high temperature and when the number of DNA lesions to be repaired is large. The caffeine-sensitive steps in repair critical to UV mutagenesis are not involved in fixing mutations induced by the chemical mutagens tested.

Some phylogenetic implications of action spectra for photoreactivation of ultraviolet-inactivated yeasts.

Action spectra for photoreactivation of ultraviolet-inactivated cells of representative species of five genera of yeasts indicate that the spectral requirements for photoreactivation are characteristic for individual genera and may be useful data in analyses of the systematics of yeasts.