Ras Protein Kinase Research Articles

Tight Control of Trehalose Content Is Required for Efficient Heat-induced Cell Elongation in Candida albicans

The ability to form hyphae in the human pathogenic fungus Candida albicans is a prerequisite for virulence. It contributes to tissue infection, biofilm formation, as well as escape from phagocytes. Cell elongation triggered by human body temperature involves the essential heat shock protein Hsp90, which negatively governs a filamentation program dependent upon the Ras-protein kinase A (PKA) pathway. Tight regulation of Hsp90 function is required to ensure fast appropriate response and maintenance of a wide range of regulatory and signaling proteins. Client protein activation by Hsp90 relies on a conformational change of the chaperone, whose ATPase activity is competitively inhibited by geldanamycin. We demonstrate a novel regulatory mechanism of heat- and Hsp90-dependent induced morphogenesis, whereby the nonreducing disaccharide trehalose acts as a negative regulator of Hsp90 release. By means of a mutant strain deleted for Gpr1, the G protein-coupled receptor upstream of PKA, we demonstrate that elevated trehalose content in that strain, resulting from misregulation of enzymatic activities involved in trehalose metabolism, disrupts the filamentation program in response to heat. Addition of geldanamycin does not result in hyphal extensions at 30 °C in the gpr1Δ/gpr1Δ mutant as it does in wild type cells. In addition, validamycin, a specific inhibitor of trehalase, the trehalose-degrading enzyme, inhibits cell elongation in response to heat and geldanamycin. These results place Gpr1 as a regulator of trehalose metabolism in C. albicans and illustrate that trehalose modulates Hsp90-dependent activation of client proteins and signaling pathways leading to filamentation in the human fungal pathogen.

Mitophagy in yeast is independent of mitochondrial fission and requires the stress response gene WHI2

Dysfunctional mitochondria show a reduced capacity for fusion and, as mitochondrial fission is maintained, become spatially separated from the intact network. By that mechanism, dysfunctional mitochondria have been proposed to be targeted for selective degradation by mitophagy, thereby providing a quality control system for mitochondria. In yeast, conflicting results concerning the role of mitochondrial dynamics in mitophagy have been reported. Here, we investigate the effects on mitophagy of altering mitochondrial fission and fusion, using biochemical, as well as fluorescence-based, assays. Rapamycin-induced mitophagy was shown to depend upon the autophagy-related proteins Atg11, Atg20 and Atg24, confirming that a selective type of autophagy occurred. Both fragmentation of mitochondria and inhibition of oxidative phosphorylation were not sufficient to trigger mitophagy, and neither deletion of the fission factors Dnm1, Fis1, Mdv1 or Caf4 nor expression of dominant-negative variants of Dnm1 impaired mitophagy. The diminished mitophagy initially observed in a Δfis1 mutant was not due to the absence of Fis1 but rather due to a secondary mutation in WHI2, which encodes a factor reported to function in the general stress response and the Ras-protein kinase A (PKA) signaling pathway. We propose that, in yeast, mitochondrial fission is not a prerequisite for the selective degradation of mitochondria, and that mitophagy is linked to the general stress response and the Ras-PKA signaling pathway.

Role of the fungal Ras-protein kinase A pathway in governing epithelial cell interactions during oropharyngeal candidiasis

Tpk1p, Tpk2p and Efg1p are members of the Ras-protein kinase A pathway that governs the yeast-to-hyphal transition in Candida albicans. We used tpk1Delta/tpk1Delta, tpk2Delta/tpk2Delta and efg1Delta/efg1Delta mutants to investigate the role of these proteins in regulating the interactions of C. albicans with oral epithelial cell lines in vitro and virulence in murine models of oropharyngeal candidiasis (OPC) and haematogenously disseminated candidiasis (HDC). The tpk1Delta/tpk1Delta strain adhered to, invaded and damaged oral epithelial cells in vitro similarly to the wild-type strain. In contrast, both the tpk2Delta/tpk2Delta and efg1Delta/efg1Delta strains had reduced capacity to invade and damage oral epithelial cells, and the efg1Delta/efg1Delta strain also exhibited decreased adherence to these cells. Consistent with these in vitro findings, the tpk2Delta/tpk2Delta and efg1Delta/efg1Delta strains also had significantly attenuated virulence during OPC. Therefore, Tpk2p and Efg1p both govern factors that enable C. albicans to invade and damage oral epithelial cells in vitro and cause OPC. These results also suggest that hyphal formation mediated by the Ras-protein kinase A pathway is a key virulence mechanism during OPC. Interestingly, the efg1Delta/efg1Delta strain, but not the tpk2Delta/tpk2Delta had reduced virulence during HDC. Thus, Tpk2p may be more important for governing virulence during OPC than HDC.

Direct Pathway to RNA Polymerase II

Cellular responses to the extracellular environment can involve changes in gene expression, often the end point of signaling cascades that originate at the cell surface. Some signaling pathways regulate RNA polymerase II enzyme activity to control transcription. Many pathways impinge on transactivator proteins poised at gene promoters. These transactivators recruit the RNA polymerase II by interacting with regulator proteins of the Srb and Mediator complexes that also make up the polymerase holoenzyme. Chang et al. report that the Ras-protein kinase A (PKA) signaling pathway of the yeast Saccharomyces cerevisiae , which controls cell proliferation, targets the Srb9p protein in the Srb complex. Srb proteins and the Ras-PKA pathway are known to repress the expression of genes during the stationary phase of cell growth. Srb9p was phosphorylated by PKA in vitro and in vivo. Expression of a constitutively activated form of Ras also increased phosphorylation of Srb9p and the modification modulated the effect of the Srb complex on cell growth. The authors propose that by directly targeting proteins of the polymerase complex, cells could rapidly induce broad changes in gene expression. Y.-W. Chang, S. C. Howard, P. K. Herman, The Ras/PKA signaling pathway directly targets the Srb9 protein, a component of the general RNA polymerase II transcription apparatus. Mol. Cell 15 , 107-116 (2004). [Online Journal]

Msn2p/Msn4p Act as a Key Transcriptional Activator of Yeast Cytoplasmic Thiol Peroxidase II

We observed that the transcription of Saccharomyces cerevisiae cytoplasmic thiol peroxidase type II (cTPx II) (YDR453C) is regulated in response to various stresses (e.g. oxidative stress, carbon starvation, and heat-shock). It has been suggested that both transcription-activating proteins, Yap1p and Skn7p, regulate the transcription of cTPx II upon exposure to oxidative stress. However, a dramatic loss of transcriptional response to various stresses in yeast mutant strains lacking both Msn2p and Msn4p suggests that the transcription factors act as a principal transcriptional activator. In addition to two Yap1p response elements (YREs), TTACTAA and TTAGTAA, the presence of two stress response elements (STREs) (CCCCT) in the upstream sequence of cTPx II also suggests that Msn2p/Msn4p could control stress-induced expression of cTPx II. Analysis of the transcriptional activity of site-directed mutagenesis of the putative STREs (STRE1 and STRE2) and YREs (TRE1 and YRE2) in terms of the activity of a lacZ reporter gene under control of the cTPx II promoter indicates that STRE2 acts as a principal binding element essential for transactivation of the cTPx II promoter. The transcriptional activity of the cTPx II promoter was exponentially increased after postdiauxic growth. The transcriptional activity of the cTPx II promoter is greatly increased by rapamycin. Deletion of Tor1, Tor2, Ras1, and Ras2 resulted in a considerable induction when compared with their parent strains, suggesting that the transcription of cTPx II is under negative control of the Ras/cAMP and target of rapamycin signaling pathways. Taken together, these results suggest that cTPx II is a target of Msn2p/Msn4p transcription factors under negative control of the Ras-protein kinase A and target of rapamycin signaling pathways. Furthermore, the accumulation of cTPx II upon exposure to oxidative stress and during the postdiauxic shift suggests an important antioxidant role in stationary phase yeast cells.

Differential regulation of glutaredoxin gene expression in response to stress conditions in the yeast Saccharomyces cerevisiae

Glutaredoxins are small heat-stable proteins that are active as glutathione-dependent oxidoreductases and are encoded by two genes, designated GRX1 and GRX2, in the yeast Saccharomyces cerevisiae. We report here that the expression of both genes is induced in response to various stress conditions including oxidative, osmotic, and heat stress and in response to stationary phase growth and growth on non-fermentable carbon sources. Furthermore, both genes are activated by the high-osmolarity glycerol pathway and negatively regulated by the Ras-protein kinase A pathway via stress-responsive STRE elements. GRX1 contains a single STRE element and is induced to significantly higher levels compared to GRX2 following heat and osmotic shock. GRX2 contains two STRE elements, and is rapidly induced in response to reactive oxygen species and upon entry into stationary phase growth. Thus, these data support the idea that the two glutaredoxin isoforms in yeast play distinct roles during normal cellular growth and in response to stress conditions.