Large-Scale Analysis of Kinase Signaling in Yeast Pseudohyphal Development Identifies Regulation of Ribonucleoprotein Granules

Yeast pseudohyphal filamentation is a stress-responsive growth transition relevant to processes required for virulence in pathogenic fungi. Pseudohyphal growth is controlled through a regulatory network encompassing conserved MAPK (Ste20p, Ste11p, Ste7p, Kss1p, and Fus3p), protein kinase A (Tpk2p), Elm1p, and Snf1p kinase pathways; however, the scope of these pathways is not fully understood. Here, we implemented quantitative phosphoproteomics to identify each of these signaling networks, generating a kinase-dead mutant in filamentous S. cerevisiae and surveying for differential phosphorylation. By this approach, we identified 439 phosphoproteins dependent upon pseudohyphal growth kinases. We report novel phosphorylation sites in 543 peptides, including phosphorylated residues in Ras2p and Flo8p required for wild-type filamentous growth. Phosphoproteins in these kinase signaling networks were enriched for ribonucleoprotein (RNP) granule components, and we observe co-localization of Kss1p, Fus3p, Ste20p, and Tpk2p with the RNP component Igo1p. These kinases localize in puncta with GFP-visualized mRNA, and KSS1 is required for wild-type levels of mRNA localization in RNPs. Kss1p pathway activity is reduced in lsm1Δ/Δ and pat1Δ/Δ strains, and these genes encoding P-body proteins are epistatic to STE7. The P-body protein Dhh1p is also required for hyphal development in Candida albicans. Collectively, this study presents a wealth of data identifying the yeast phosphoproteome in pseudohyphal growth and regulatory interrelationships between pseudohyphal growth kinases and RNPs.     

Cyclic AMP-protein kinase A and Snf1 signaling mechanisms underlie the superior potency of sucrose for induction of filamentation in Saccharomyces cerevisiae

Under specific environmental conditions, the yeast Saccharomyces cerevisiae can undergo a morphological switch to a pseudohyphal growth pattern. Pseudohyphal differentiation is generally studied upon induction by nitrogen limitation in the presence of glucose. It is known to be controlled by several signaling pathways, including mitogen-activated protein kinase, cyclic AMP-protein kinase A (cAMP-PKA), and Snf1 kinase pathways. We show that the alpha-glucoside sugars maltose and maltotriose, and especially sucrose, are more potent inducers of filamentation than glucose. Sucrose even induces filamentation in nitrogen-rich media and in the mep2Δ/mep2Δ ammonium permease mutant on ammonium-limiting medium. We demonstrate that glucose also inhibits filamentation by means of a pathway parallel to the cAMP-PKA pathway. Deletion of HXK2 shifted the pseudohyphal growth pattern on glucose to that of sucrose, while deletion of SNF4 abrogated filamentation on both sugars, indicating a negative role of glucose repression and a positive role for Snf1 activity in the control of filamentation. In all strains and in all media, sucrose induction of filamentation is greatly diminished by deletion of the sucrose/glucose-sensing G-protein-coupled receptor Gpr1, whereas it has no effect on induction by maltose and maltotriose. The competence of alpha-glucoside sugars to induce filamentation is reflected in the increased expression of the cell surface flocculin gene FLO11. In addition, sucrose is the only alpha-glucoside sugar capable of rapidly inducing FLO11 expression in a Gpr1-dependent manner, reflecting the sensitivity of Gpr1 for this sugar and its involvement in rapid sucrose signaling. Our study identifies sucrose as the most potent nutrient inducer of pseudohyphal growth and shows that glucose inactivation of Snf1 kinase signaling is responsible for the lower potency of glucose.     

Stable Pseudohyphal Growth in Budding Yeast Induced by Synergism between Septin Defects and Altered MAP-kinase Signaling

Upon nutrient limitation, budding yeasts like Saccharomyces cerevisiae can be induced to adopt alternate filament-like growth patterns called diploid pseudohyphal or invasive haploid growth. Here, we report a novel constitutive pseudohyphal growth state, sharing some characteristics with classic forms of filamentous growth, but differing in crucial aspects of morphology, growth conditions and genetic regulation. The constitutive pseudohyphal state is observed in fus3 mutants containing various septin assembly defects, which we refer to as sadF growth (septin assembly defect induced filamentation) to distinguish it from classic filamentation pathways. Similar to other filamentous states, sadF cultures comprise aggregated chains of highly elongated cells. Unlike the classic pathways, sadF growth occurs in liquid rich media, requiring neither starvation nor the key pseudohyphal proteins, Flo8p and Flo11p. Moreover sadF growth occurs in haploid strains of S288C genetic background, which normally cannot undergo pseudohyphal growth. The sadF cells undergo highly polarized bud growth during prolonged G2 delays dependent on Swe1p. They contain septin structures distinct from classical pseudo-hyphae and FM4-64 labeling at actively growing tips similar to the Spitzenkörper observed in true hyphal growth. The sadF growth state is induced by synergism between Kss1p-dependent signaling and septin assembly defects; mild disruption of mitotic septins activates Kss1p-dependent gene expression, which exacerbates the septin defects, leading to hyper-activation of Kss1p. Unlike classical pseudo-hyphal growth, sadF signaling requires Ste5, Ste4 and Ste18, the scaffold protein and G-protein β and γ subunits from the pheromone response pathway, respectively. A swe1 mutation largely abolished signaling, breaking the positive feedback that leads to amplification of sadF signaling. Taken together, our findings show that budding yeast can access a stable constitutive pseudohyphal growth state with very few genetic and regulatory changes.     

Pooled Segregant Sequencing Reveals Genetic Determinants of Yeast Pseudohyphal Growth

The pseudohyphal growth response is a dramatic morphological transition and presumed foraging mechanism wherein yeast cells form invasive and surface-spread multicellular filaments. Pseudohyphal growth has been studied extensively as a model of conserved signaling pathways controlling stress responses, cell morphogenesis, and fungal virulence in pathogenic fungi. The genetic contribution to pseudohyphal growth is extensive, with at least 500 genes required for filamentation; as such, pseudohyphal growth is a complex trait, and linkage analysis is a classical means to dissect the genetic basis of a complex phenotype. Here, we implemented linkage analysis by crossing each of two filamentous strains of Saccharomyces cerevisiae (Σ1278b and SK1) with an S288C-derived non-filamentous strain. We then assayed meiotic progeny for filamentation and mapped allelic linkage in pooled segregants by whole-genome sequencing. This analysis identified linkage in a cohort of genes, including the negative regulator SFL1, which we find contains a premature stop codon in the invasive SK1 background. The S288C allele of the polarity gene PEA2, encoding Leu409 rather than Met, is linked with non-invasion. In Σ1278b, the pea2-M409L mutation results in decreased invasive filamentation and elongation, diminished activity of a Kss1p MAPK pathway reporter, decreased unipolar budding, and diminished binding of the polarisome protein Spa2p. Variation between SK1 and S288C in the mitochondrial inner membrane protein Mdm32p at residues 182 and 262 impacts invasive growth and mitochondrial network structure. Collectively, this work identifies new determinants of pseudohyphal growth, while highlighting the coevolution of protein complexes and organelle structures within a given genome in specifying complex phenotypes.     

Calmodulin Binding to Dfi1p Promotes Invasiveness of Candida albicans

Candida albicans, a dimorphic fungus, undergoes hyphal development in response to many different environmental cues, including growth in contact with a semi-solid matrix. C. albicans forms hyphae that invade agar when cells are embedded in or grown on the surface of agar, and the integral membrane protein Dfi1p is required for this activity. In addition, Dfi1p is required for full activation of mitogen activated protein kinase Cek1p during growth on agar. In this study, we identified a putative calmodulin binding motif in the C-terminal tail of Dfi1p. This region of Dfi1p bound to calmodulin in vitro, and mutations that affected this region affected both calmodulin binding in vitro and invasive filamentation when incorporated into the full length Dfi1p protein. Moreover, increasing intracellular calcium levels led to calcium-dependent, Dfi1p-dependent Cek1p activation. We propose that conformational changes in Dfi1p in response to environmental conditions encountered during growth allow the protein to bind calmodulin and initiate a signaling cascade that activates Cek1p.     

Multiple TORC1-associated proteins regulate nitrogen starvation-dependent cellular differentiation in Saccharomyces cerevisiae

Background

The budding yeast Saccharomyces cerevisiae undergoes differentiation into filamentous-like forms and invades the growth medium as a foraging response to nutrient and environmental stresses. These developmental responses are under the downstream control of effectors regulated by the cAMP/PKA and MAPK pathways. However, the upstream sensors and signals that induce filamentous growth through these signaling pathways are not fully understood. Herein, through a biochemical purification of the yeast TORC1 (Target of Rapamycin Complex 1), we identify several proteins implicated in yeast filamentous growth that directly associate with the TORC1 and investigate their roles in nitrogen starvation-dependent or independent differentiation in yeast.

Methodology

We isolated the endogenous TORC1 by purifying tagged, endogenous Kog1p, and identified associated proteins by mass spectrometry. We established invasive and pseudohyphal growth conditions in two S. cerevisiae genetic backgrounds (Σ1278b and CEN.PK). Using wild type and mutant strains from these genetic backgrounds, we investigated the roles of TORC1 and associated proteins in nitrogen starvation-dependent diploid pseudohyphal growth as well as nitrogen starvation-independent haploid invasive growth.

Conclusions

We show that several proteins identified as associated with the TORC1 are important for nitrogen starvation-dependent diploid pseudohyphal growth. In contrast, invasive growth due to other nutritional stresses was generally not affected in mutant strains of these TORC1-associated proteins. Our studies suggest a role for TORC1 in yeast differentiation upon nitrogen starvation. Our studies also suggest the CEN.PK strain background of S. cerevisiae may be particularly useful for investigations of nitrogen starvation-induced diploid pseudohyphal growth.     

Isolation and Characterization of EPD1, an Essential Gene for Pseudohyphal Growth of a Dimorphic Yeast, Candida maltosa

Additional copies of the centromeric DNA (CEN) region induce pseudohyphal growth in a dimorphic yeast, Candida maltosa (T. Nakazawa, T. Motoyama, H. Horiuchi, A. Ohta, and M. Takagi, J. Bacteriol. 179:5030–5036, 1997). To understand the mechanism of this transition, we screened the gene library of C. maltosa for sequences which could suppress this morphological change. As a result, we isolated the 5′ end of a new gene, EPD1 (for essential for pseudohyphal development), and then cloned the entire gene. The predicted amino acid sequence of Epd1p was highly homologous to those of Ggp1/Gas1/Cwh52p, a glycosylphosphatidylinositol-anchored protein of Saccharomyces cerevisiae, and Phr1p and Phr2p of Candida albicans. The expression of EPD1 was moderately regulated by environmental pH. A homozygous EPD1 null mutant showed some morphological defects and reduction in growth rate and reduced levels of both alkali-soluble and alkali-insoluble β-glucans. Moreover, the mutant could not undergo the transition from yeast form to pseudohyphal form induced by additional copies of the CEN sequence at pH 4 or by n-hexadecane at pH 4 or pH 7, suggesting that EPD1 is not essential for yeast form growth but is essential for transition to the pseudohyphal form. Overexpression of the amino-terminal part of Epd1p under the control of the GAL promoter suppressed the pseudohyphal development induced by additional copies of the CEN sequence, whereas overexpression of the full-length EPD1 did not. This result and the initial isolation of the 5′ end of EPD1 as a suppressor of the pseudohyphal growth induced by the CEN sequence suggest that the amino-terminal part of Epd1p may have a dominant-negative effect on the functions of Epd1p in the pseudohyphal growth induced by the CEN sequence.     

A small G protein Rhb1 and a GTPase-activating protein Tsc2 involved in nitrogen starvation-induced morphogenesis and cell wall integrity of Candida albicans

Rheb is a new member of the small G proteins of the Ras superfamily in eukaryotic organisms and controls various physiological processes. Activity of Rheb is regulated by Tsc2, a GTPase-activating protein (GAP). In this study, we have identified Candida albicans homologs of Rheb (named as Rhb1) and Tsc2. Deletion of the RHB1 gene showed enhanced sensitivity to rapamycin (an inhibitor of TOR kinase), suggesting that Rhb1 is associated with the TOR signaling pathway in C. albicans. Further analysis indicated RHB1 and TSC2 are involved in nitrogen starvation-induced filamentation, likely by controlling the expression of MEP2 whose gene product is an ammonium permease and a sensor for the nitrogen signal. Moreover, we have demonstrated that Rhb1 is also involved in cell wall integrity pathway, by transferring signals through the TOR kinase and the Mkc1 MAP kinase pathway. Together, this study brings new insights into the complex interplay of signaling and regulatory pathways in C. albicans.     

Accumulation of P-bodies in Candida albicans under different stress and filamentous growth conditions

Candida albicans is an opportunistic fungal pathogen that grows as budding yeast, pseudohyphal, and hyphal forms. In response to external signals, C. albicans switches rapidly among these forms. mRNA-containing cytoplasmic granules, termed processing bodies (P-bodies), have been reported to accumulate under various environmental stress conditions in diverse species from yeast to mammals. Here, we provide the first microscopic and genetic characterization of P-bodies in C. albicans. The core components of P-bodies, including the decapping machinery (Dcp2 and Dhh1), 5′–3′ exoribonuclease (Kem1/Xrn1), and the P-body scaffolding protein (Edc3), were identified and their localizations with respect to P-bodies were demonstrated. Various growth conditions, including glucose deprivation, hyperosmotic stress, and heat stress, stimulated the accumulation of P-bodies. In addition, we observed P-body aggregation during hyphal development. The deletion mutant strain edc3/edc3 had a defect in filamentation and exhibited a dramatic reduction in the number of P-bodies. These results suggest that Edc3 plays an essential role in the assembly and maintenance of P-bodies in C. albicans, and that the switch to filamentous growth appears to accompany P-body accumulation.     

An analysis of the Impact of <Emphasis Type="Italic">NRG1</Emphasis> Overexpression on the <Emphasis Type="Italic">Candida albicans</Emphasis> Response to Specific Environmental Stimuli

The ability of the opportunistic fungal pathogen Candida albicans to form filaments has been strongly linked to its capacity to cause disease in humans. We previously described the construction of a strain in which filamentation can be modulated both in vitro and in vivo by placing one copy of the NRG1 gene under the control of a tetracycline-regulatable promoter. To further characterize the role of NRG1 in controlling filamentous growth, and in an attempt to determine whether NRG1 downregulation is a requirement for filamentation per se, or is only necessary under certain environmental conditions, we have conducted an analysis of the growth of the tet-NRG1 strain under a variety of in vitro conditions. Through overexpression of NRG1, we were able to block filamentation of C. albicans in both liquid media and on solid media. Filamentation in response to the low-oxygen environment of embedded growth was also inhibited. In all of these conditions, normal filamentation could be restored by down regulating expression from the tet-NRG1 allele. Interestingly, although elevated NRG1 levels were able to inhibit the formation of true hyphae in response to a wide range of environmental stimuli, elevated NRG1 expression did not affect the formation of pseudohyphae on nitrogen-limiting synthetic low ammonia dextrose (SLAD) medium. This work further illustrates the key role played by NRG1 in the control of filamentation and suggests that, although NRG1 repression plays a key role in regulating true hyphal growth, it apparently does not regulate pseudohyphal growth in the same fashion.     

Roles of the Snf1-Activating Kinases during Nitrogen Limitation and Pseudohyphal Differentiation in Saccharomyces cerevisiae

In Saccharomyces cerevisiae, Snf1 protein kinase is important for growth on carbon sources that are less preferred than glucose. When glucose becomes limiting, Snf1 undergoes catalytic activation, which requires phosphorylation of its T-loop threonine (Thr210). Thr210 phosphorylation can be performed by any of three Snf1-activating kinases: Sak1, Tos3, and Elm1. These kinases are redundant in that all three must be eliminated to confer snf1Δ-like growth defects on nonpreferred carbon sources. We previously showed that in addition to glucose signaling, Snf1 also participates in nitrogen signaling and is required for diploid pseudohyphal differentiation, a filamentous-growth response to nitrogen limitation. Here, we addressed the roles of the Snf1-activating kinases in this process. Loss of Sak1 caused a defect in pseudohyphal differentiation, whereas Tos3 and Elm1 were dispensable. Sak1 was also required for increased Thr210 phosphorylation of Snf1 under nitrogen-limiting conditions. Expression of a catalytically hyperactive version of Snf1 restored pseudohyphal differentiation in the sak1Δ/sak1Δ mutant. Thus, while the Snf1-activating kinases exhibit redundancy for growth on nonpreferred carbon sources, the loss of Sak1 alone produced a significant defect in a nitrogen-regulated phenotype, and this defect resulted from deficient Snf1 activation rather than from disruption of another pathway. Our results suggest that Sak1 is involved in nitrogen signaling upstream of Snf1.Snf1 protein kinase of the yeast Saccharomyces cerevisiae belongs to the conserved Snf1/AMP-activated protein kinase (AMPK) family; members of this family play central roles in responses to metabolic stress in eukaryotes (reviewed in references 17 and 18). Interest in Snf1/AMPK pathways is high due to their important functions. Deregulation of AMPK signaling in humans has been linked to type 2 diabetes, heart disease, and cancer (for a review, see reference 16). Snf1 homologs of pathogenic fungi have been implicated in virulence and drug resistance (23, 63, 64).Yeast Snf1 (Cat1, Ccr1) was first identified by its requirement for growth on carbon sources that are less preferred than glucose (5, 7, 65). Subsequent evidence indicated that Snf1 protein kinase (6) is directly involved in glucose signaling, since its activity is stimulated in response to glucose limitation (62). Catalytic activation of Snf1 occurs through phosphorylation of its conserved T-loop threonine (Thr210) (12) by upstream kinases (40, 62). Three protein kinases—Sak1, Tos3, and Elm1—have been identified that can phosphorylate Thr210 of Snf1 (22, 41, 55). These kinases are related to the mammalian kinases that activate AMPK by phosphorylating the equivalent T-loop threonine (Thr172) (reviewed in references 17 and 18). We recently presented evidence that Snf1 homologs of two pathogenic Candida species, Candida albicans and C. glabrata, also undergo T-loop phosphorylation (42).It is not entirely clear why S. cerevisiae has three different kinases that can activate Snf1. Judging by assays of Snf1 kinase activity, Sak1 makes the largest individual contribution to Snf1 activation in the cell (19, 22). However, deletion of SAK1 alone does not result in growth defects on alternative carbon sources, and all three Snf1-activating kinases must be eliminated to produce a phenotypic defect comparable to that of the snf1Δ mutant (22, 39, 55). Deletion of TOS3 was reported to moderately affect growth on nonfermentable carbon sources; this correlated with a reduction in Snf1 activity, although effects on another pathway(s) cannot be excluded (25). Mutation of ELM1 affects cell cycle progression and cell morphology, but this effect is unrelated to Elm1''s role as a Snf1-activating kinase and pertains to its role in the activation of Nim1-related protein kinases involved in morphogenesis checkpoint control (1, 56).While showing significant redundancy for growth on nonpreferred carbon sources, the Snf1-activating kinases could exhibit specialization in Snf1 signaling in response to stresses other than carbon stress. Evidence indicates that Snf1 is important for adaptation to a number of stress conditions (reviewed in reference 18). In some cases, such as genotoxic stress or exposure to hygromycin B, weak activity of unphosphorylated Snf1 appears to be sufficient for resistance (10, 48). In others, such as sodium ion stress and alkaline stress, Thr210 phosphorylation of Snf1 is required for adaptation, and Snf1 becomes activated upon stress exposure (21, 40). As with glucose limitation, however, in these latter cases Sak1 makes the largest contribution to Snf1 activation judging by biochemical assays, and yet it remains dispensable for wild-type levels of stress-resistant growth in phenotypic tests; loss of all three Snf1-activating kinases results in growth defects comparable to those of cells lacking Snf1 (21). Thus, investigation of these stresses provided no evidence for phenotypically relevant specialization of Sak1, Tos3, or Elm1 in Snf1 signaling.Diploid pseudohyphal differentiation is a developmental response to nitrogen limitation (15). When nitrogen becomes limiting, diploid cells adopt elongated morphology, alter their budding pattern, and generate filaments (pseudohyphae) consisting of chains of cells attached to one another. One of the key events in this process is activation of the FLO11 (MUC1) gene, which encodes a cell surface glycoprotein involved in cell-cell adhesion (29, 33, 34). Following up on an observation that Snf1 is important for FLO11 expression on low glucose, we previously found that diploids lacking Snf1 fail to undergo pseudohyphal differentiation on low nitrogen (27, 28). The requirement of Snf1 for a nitrogen-regulated process raised the possibility that Snf1 is directly involved in nitrogen signaling. In support of this notion, we subsequently showed that weak activity of nonphosphorylatable Snf1-T210A is not sufficient for pseudohyphal differentiation and that Thr210 phosphorylation of Snf1 increases in response to nitrogen limitation (43).Here, we have examined the roles of Sak1, Tos3, and Elm1 in pseudohyphal differentiation and Snf1 activation on low nitrogen. We show that elimination of Sak1 leads to a significant defect in nitrogen-regulated pseudohyphal differentiation, whereas Tos3 and Elm1 are dispensable. Sak1 is also required for normal Thr210 phosphorylation of Snf1 under nitrogen-limiting conditions. Our data strongly suggest that the loss of Sak1 affects pseudohyphal differentiation by affecting Snf1 activation and not by disruption of another pathway. Collectively, our findings implicate Sak1 in nitrogen signaling upstream of Snf1.     

The Contribution of Candida albicans Vacuolar ATPase Subunit V1B,Encoded by VMA2, to Stress Response,Autophagy, and Virulence Is Independent of Environmental pH

Candida albicans vacuoles are central to many critical biological processes, including filamentation and in vivo virulence. The V-ATPase proton pump is a multisubunit complex responsible for organellar acidification and is essential for vacuolar biogenesis and function. To study the function of the V₁B subunit of C. albicans V-ATPase, we constructed a tetracycline-regulatable VMA2 mutant, tetR-VMA2. Inhibition of VMA2 expression resulted in the inability to grow at alkaline pH and altered resistance to calcium, cold temperature, antifungal drugs, and growth on nonfermentable carbon sources. Furthermore, V-ATPase was unable to fully assemble at the vacuolar membrane and was impaired in proton transport and ATPase-specific activity. VMA2 repression led to vacuolar alkalinization in addition to abnormal vacuolar morphology and biogenesis. Key virulence-related traits, including filamentation and secretion of degradative enzymes, were markedly inhibited. These results are consistent with previous studies of C. albicans V-ATPase; however, differential contributions of the V-ATPase V_o and V₁ subunits to filamentation and secretion are observed. We also make the novel observation that inhibition of C. albicans V-ATPase results in increased susceptibility to osmotic stress. Notably, V-ATPase inhibition under conditions of nitrogen starvation results in defects in autophagy. Lastly, we show the first evidence that V-ATPase contributes to virulence in an acidic in vivo system by demonstrating that the tetR-VMA2 mutant is avirulent in a Caenorhabditis elegans infection model. This study illustrates the fundamental requirement of V-ATPase for numerous key virulence-related traits in C. albicans and demonstrates that the contribution of V-ATPase to virulence is independent of host pH.