Regulated proteolysis of Candida albicans Ras1 is involved in morphogenesis and quorum sensing regulation

In Candida albicans, a fungal pathogen, the small G‐protein Ras1 regulates many important behaviors including white‐opaque switching, biofilm formation, and the induction and maintenance of hyphal growth. Like other Ras proteins, Ras1 is activated upon guanine triphosphate binding, and its activity is further modulated by post‐translational lipid modifications. Here, we report that the levels of membrane‐associated, full‐length Ras1 were higher in hyphae than in yeast, and that yeast contained a shorter, soluble Ras1 species that resulted from cleavage. Deletion of the putative cleavage site led to more rapid induction of hyphal growth and delayed hypha‐to‐yeast transitions. The cleaved Ras1 species was less able to activate its effector, adenylate cyclase (Cyr1), unless tethered to the membrane by a heterologous membrane‐targeting domain. Ras1 cleavage was repressed by cAMP‐signalling, indicating the presence of a positive feedback loop in which Cyr1 and cAMP influence Ras1. The C. albicans quorum sensing molecule farnesol, which inhibits Cyr1 and represses filamentation, caused an increase in the fraction of Ras1 in the cleaved form, particularly in nascent yeast formed from hyphae. This newly recognized mode of Ras regulation may control C. albicans Ras1 activity in important ways.     

Cooperation between the chloroplast psbA 5′‐untranslated region and coding region is important for translational initiation: the chloroplast translation machinery cannot read a human viral gene coding region

Chloroplast mRNA translation is regulated by the 5′‐untranslated region (5′‐UTR). Chloroplast 5′‐UTRs also support translation of the coding regions of heterologous genes. Using an in vitro translation system from tobacco chloroplasts, we detected no translation from a human immunodeficiency virus tat coding region fused directly to the tobacco chloroplast psbA 5′‐UTR. This lack of apparent translation could have been due to rapid degradation of mRNA templates or synthesized protein products. Replacing the psbA 5′‐UTR with the E. coli phage T7 gene 10 5′‐UTR, a highly active 5′‐UTR, and substituting synonymous codons led to some translation of the tat coding region. The Tat protein thus synthesized was stable during translation reactions. No significant degradation of the added tat mRNAs was observed after translation reactions. These results excluded the above two possibilities and confirmed that the tat coding region prevented its own translation. The tat coding region was then fused to the psbA 5′‐UTR with a cognate 5′‐coding segment. Significant translation was detected from the tat coding region when fused after 10 or more codons. That is, translation could be initiated from the tat coding region once translation had started, indicating that the tat coding region inhibits translational initiation but not elongation. Hence, cooperation/compatibility between the 5′‐UTR and its coding region is important for translational initiation.     

The white-phase-specific gene<Emphasis Type="Italic"> WH11</Emphasis> is not required for white-opaque switching in<Emphasis Type="Italic"> Candida albicans</Emphasis>

Phenotypic switching between white and opaque cells is important for adaptation to different host environments and for mating in the opportunistic fungal pathogen Candida albicans. Genes that are specifically activated in one of the two cell types are likely to be important for their phenotypic characteristics. The WH11 gene is a white-phase-specific gene that has been suggested to be involved in the maintenance of the white-phase phenotype. To elucidate the role of WH11 in white-opaque switching, we constructed mutants of the C. albicans strain WO-1 in which the WH11 gene was deleted. The wh11 mutants were still able to form both white and opaque cells whose cellular and colony phenotypes were indistinguishable from those of the wild type. Deletion of WH11 also did not affect the activation and deactivation of the white-phase-specific WH11 promoter and the opaque-phase-specific OP4 and SAP1 promoters in the appropriate cell type. Finally, switching from the white to the opaque phase and vice versa occurred with the same frequency in wild-type and wh11 mutants. Therefore, the WH11 gene is not required for phenotypic switching, and its protein product seems to have other roles in white cells, which are dispensable after the switch to the opaque phase.Communicated by E. Cerdá-Olmedo