The response to heat stress in six yeast species isolated from Antarctica was examined. The yeast were classified into two groups: one psychrophilic, with a maximum growth temperature of 20 degrees C, and the other psychrotrophic, capable of growth at temperatures above 20 degrees C. In addition to species--specific heat shock prote in (hsp) profiles, a heat shock (15 degrees C-25 degrees C for 3 h) induced the synthesis of a 110-kDa protein common to the psychrophiles, Mrakia stokesii, M. frigida, and M. gelida, but not evident in Leucosporidium antarcticum. Immunoblot analyses revealed heat shock inducible proteins (hsps) corresponding to hsps 70 and 90. Interestingly, no proteins corresponding to hsps 60 and 104 were observed in any of the psychrophilic species examined. In the psychrotrophic yeast, Leucosporidium fellii and L. scottii, in addition to the presence of hsps 70 and 90, a protein corresponding to hsp 104 was observed. In psychrotrophic yeast, as observed in psychrophilic yeast, the absence of a protein corresponding to hsp 60 was noted. Relatively high endogenous levels of trehalose which were elevated upon a heat shock were exhibited by all species. A 10 Celsius degree increase in temperature above the growth temperature (15 degrees C) of psychrophiles and psychrotrophs was optimal for heat shock induced thermotolerance. On the other hand, in psychrotrophic yeast grown at 25 degrees C, only a 5 Celsius degree increase in temperature was necessary for heat shock induced thermotolerance. Induced thermotolerance in all yeast species was coincident with hsp synthesis and trehalose accumulation. It was concluded that psychrophilic and psychrotrophic yeast, although exhibiting a stress response similar to mesophilic Saccharomyces cerevisiae, nevertheless had distinctive stress protein profiles.
Conditions are described for the heat shock acquisition of thermotolerance, peroxide tolerance and synthesis of heat shock proteins (hsps) in the Antarctic, psychrophilic yeast Candida psychrophila. Cells grown at 15 degrees C and heat shocked at 25 degrees C (3 h) acquired tolerance to heat (35 degrees C) and hydrogen peroxide (100 mM). Novel heat shock inducible proteins at 80 and 110 kDa were observed as well as the presence of hsp 90, 70 and 60. The latter hsps were not significantly heat shock inducible. The absence of hsp 104 was intriguing and it was speculated that the 110 kDa protein may play a role in stress tolerance in psychrophilic yeasts, similar to that of hsp 104 in mesophilic species.
Heat stress tolerance was examined in the thermophilic enteric yeast Arxiozyma telluris. Heat shock acquisition of thermotolerance and synthesis of heat shock proteins hsp 104, hsp 90, hsp 70, and hsp 60 were induced by a mild heat shock at temperatures from 35 to 40°C for 30 min. The results demonstrate that a yeast which occupies a specialized ecological niche exhibits a typical heat shock response.
The Saccharomyces cerevisiae Sin3 transcriptional repressor is part of a large multiprotein complex that includes the Rpd3 histone deacetylase. A LexA-Sin3 fusion protein represses transcription of promoters with LexA binding sites. To identify genes involved in repression by Sin3, we conducted a screen for mutations that reduce repression by LexA-Sin3. One of the mutations identified that reduces LexA-Sin3 repression is in the RPD3 gene, consistent with the known roles of Rpd3 in transcriptional repression. Mutations in CBK1 and HYM1 reduce repression by LexA-Sin3 and also cause defects in cell separation and altered colony morphology. cbk1 and hym1 mutations affect some but not all genes regulated by SIN3 and RPD3, but the effect on transcription is much weaker. Genetic analysis suggests that CBK1 and HYM1 function in the same pathway, but this genetic pathway is separable from that of SIN3 and RPD3. The remaining gene from this screen described in this report is SDS3, previously identified in a screen for mutations that increase silencing at HML, HMR, and telomere-linked genes, a phenotype also seen in sin3 and rpd3 mutants. Genetic analysis demonstrates that SDS3 functions in the same genetic pathway as SIN3 and RPD3, and coimmunoprecipitation experiments show that Sds3 is physically present in the Sin3 complex.
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