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. 1994 Aug;137(4):967–976. doi: 10.1093/genetics/137.4.967

Site-Directed Mutations Altering the Caax Box of Ste18, the Yeast Pheromone-Response Pathway Gγ Subunit

M S Whiteway 1, D Y Thomas 1
PMCID: PMC1206073  PMID: 7982577

Abstract

The STE18 gene encodes the γ subunit of the G protein which functions in the Saccharomyces cerevisiae pheromone-response pathway. The STE18 gene product undergoes a post-translational processing at the carboxyl terminus directed by the CCAAX box motif CCTLM(110). A variety of site-directed mutations of this sequence have been constructed to test the role of this motif on Ste18 function. Mutations which change or eliminate the cysteine at position 107 abolish Ste18-dependent mating, and thus the cysteine (C107) is essential for Ste18 function. However, inactivation of the prenyltransferase by disruption of DPR1 has only a minor effect on Ste18-dependent mating. Mutation of cysteine 106 to serine significantly reduces but does not eliminate Ste18 function. Deletion of the C-terminal TLM sequence or modification of the ultimate methionine to lysine, arginine or leucine, all changes which do not affect the CAAX box cysteines, have only minor effects on Ste18-dependent mating. Intriguingly, these latter mutations dramatically compromise Ste18 function in cells which are deleted for Gpa1, the α subunit of the G protein. In addition, overexpression of these mutant versions of STE18 causes a dominant negative phenotype and inhibits the constitutive mating response generated by GPA1 deletion in cells which contain a functional STE18 gene. These results suggest that the C terminus of Ste18 and the Gpa1 protein have overlapping roles in some aspect of yeast G protein function such as membrane targeting.

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Selected References

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