Activation of the HOG pathway upon cold stress in Saccharomyces cerevisiae

When Saccharomyces cerevisiae cells are exposed to hyper-osmotic stress, the high-osmolarity glycerol response (HOG) pathway is activated to induce osmotic responses. The HOG pathway consists of two upstream osmosensing branches, the SLN1 and SHO1 branches, and a downstream MAP kinase cascade. Although the mechanisms by which these upstream branches transmit signals to the MAP kinase cascade are well understood, the mechanisms by which they sense and respond to osmotic changes are elusive. Here we show that the HOG pathway is activated in an SLN1 branch-dependent manner when cells are exposed to cold stress (0 degrees C treatment). Dimethyl sulfoxide (DMSO) treatment, which rigidifies the cell membrane, also activates the HOG pathway in both SLN1 branch- and SHO1 branch-dependent manners. Moreover, cold stress, as well as hyper-osmotic stress, exhibits a synergistic effect with DMSO treatment on HOG pathway activation. On the other hand, ethanol treatment, which fluidizes the cell membrane, partially represses the cold stress-induced HOG pathway activation. Our results suggest that both osmosensing branches respond to the rigidification of the cell membrane to activate the HOG pathway.     

Aspergillus nidulans HOG pathway is activated only by two-component signalling pathway in response to osmotic stress

Genome sequencing analyses revealed that Aspergillus nidulans has orthologous genes to all those of the high-osmolarity glycerol (HOG) response mitogen-activated protein kinase (MAPK) pathway of Saccharomyces cerevisiae. A. nidulans mutant strains lacking sskA, sskB, pbsB, or hogA, encoding proteins orthologous to the yeast Ssk1p response regulator, Ssk2p/Ssk22p MAPKKKs, Pbs2p MAPKK and Hog1p MAPK, respectively, showed growth inhibition under high osmolarity, and HogA MAPK in these mutants was not phosphorylated under osmotic or oxidative stress. Thus, activation of the A. nidulans HOG (AnHOG) pathway depends solely on the two-component signalling system, and MAPKK activation mechanisms in the AnHOG pathway differ from those in the yeast HOG pathway, where Pbs2p is activated by two branches, Sln1p and Sho1p. Expression of pbsB complemented the high-osmolarity sensitivity of yeast pbs2Delta, and the complementation depended on Ssk2p/Ssk22p, but not on Sho1p. Pbs2p requires its Pro-rich motif for binding to the Src-homology3 (SH3) domain of Sho1p, but PbsB lacks a typical Pro-rich motif. However, a PbsB mutant (PbsB(Pro)) with the yeast Pro-rich motif was activated by the Sho1p branch in yeast. In contrast, HogA in sskADelta expressing PbsB(Pro) was not phosphorylated under osmotic stress, suggesting that A. nidulans ShoA, orthologous to yeast Sho1p, is not involved in osmoresponsive activation of the AnHOG pathway. We also found that besides HogA, PbsB can activate another Hog1p MAPK orthologue, MpkC, in A. nidulans, although mpkC is dispensable in osmoadaptation. In this study, we discuss the differences between the AnHOG and the yeast HOG pathways.     

The Sho1 adaptor protein links oxidative stress to morphogenesis and cell wall biosynthesis in the fungal pathogen Candida albicans

The Sho1 adaptor protein is an important element of one of the two upstream branches of the high-osmolarity glycerol (HOG) mitogen-activated protein (MAP) kinase pathway in Saccharomyces cerevisiae, a signal transduction cascade involved in adaptation to stress. In the present work, we describe its role in the pathogenic yeast Candida albicans by the construction of mutants altered in this gene. We report here that sho1 mutants are sensitive to oxidative stress but that Sho1 has a minor role in the transmission of the phosphorylation signal to the Hog1 MAP kinase in response to oxidative stress, which mainly occurs through a putative Sln1-Ssk1 branch of the HOG pathway. Genetic analysis revealed that double ssk1 sho1 mutants were still able to grow on high-osmolarity media and activate Hog1 in response to this stress, indicating the existence of alternative inputs of the pathway. We also demonstrate that the Cek1 MAP kinase is constitutively active in hog1 and ssk1 mutants, a phenotypic trait that correlates with their resistance to the cell wall inhibitor Congo red, and that Sho1 is essential for the activation of the Cek1 MAP kinase under different conditions that require active cell growth and/or cell wall remodeling, such as the resumption of growth upon exit from the stationary phase. sho1 mutants are also sensitive to certain cell wall interfering compounds (Congo red, calcofluor white), presenting an altered cell wall structure (as shown by the ability to aggregate), and are defective in morphogenesis on different media, such as SLAD and Spider, that stimulate hyphal growth. These results reveal a role for the Sho1 protein in linking oxidative stress, cell wall biogenesis, and morphogenesis in this important human fungal pathogen.     

Osmoregulation and fungicide resistance: the Neurospora crassa os-2 gene encodes a HOG1 mitogen-activated protein kinase homologue

Neurospora crassa osmosensitive (os) mutants are sensitive to high osmolarity and therefore are unable to grow on medium containing 4% NaCl. We found that os-2 and os-5 mutants were resistant to the phenylpyrrole fungicides fludioxonil and fenpiclonil. To understand the relationship between osmoregulation and fungicide resistance, we cloned the os-2 gene by using sib selection. os-2 encodes a putative mitogen-activated protein (MAP) kinase homologous to HOG1 and can complement the osmosensitive phenotype of a Saccharomyces cerevisiae hog1 mutant. We sequenced three os-2 alleles and found that all of them were null with either frameshift or nonsense point mutations. An os-2 gene replacement mutant also was generated and was sensitive to high osmolarity and resistant to phenylpyrrole fungicides. Conversely, os-2 mutants transformed with the wild-type os-2 gene could grow on media containing 4% NaCl and were sensitive to phenylpyrrole fungicides. Fludioxonil stimulated intracellular glycerol accumulation in wild-type strains but not in os-2 mutants. Fludioxonil also caused wild-type conidia and hyphal cells to swell and burst. These results suggest that the hyperosmotic stress response pathway of N. crassa is the target of phenylpyrrole fungicides and that fungicidal effects may result from a hyperactive os-2 MAP kinase pathway.     

Unique and redundant roles for HOG MAPK pathway components as revealed by whole-genome expression analysis

The Saccharomyces cerevisiae high osmolarity glycerol (HOG) mitogen-activated protein kinase pathway is required for osmoadaptation and contains two branches that activate a mitogen-activated protein kinase (Hog1) via a mitogen-activated protein kinase kinase (Pbs2). We have characterized the roles of common pathway components (Hog1 and Pbs2) and components in the two upstream branches (Ste11, Sho1, and Ssk1) in response to elevated osmolarity by using whole-genome expression profiling. Several new features of the HOG pathway were revealed. First, Hog1 functions during gene induction and repression, cross talk inhibition, and in governing the regulatory period. Second, the phenotypes of pbs2 and hog1 mutants are identical, indicating that the sole role of Pbs2 is to activate Hog1. Third, the existence of genes whose induction is dependent on Hog1 and Pbs2 but not on Ste11 and Ssk1 suggests that there are additional inputs into Pbs2 under our inducing conditions. Fourth, the two upstream pathway branches are not redundant: the Sln1-Ssk1 branch has a much more prominent role than the Sho1-Ste11 branch for activation of Pbs2 by modest osmolarity. Finally, the general stress response pathway and both branches of the HOG pathway all function at high osmolarity. These studies demonstrate that cells respond to increased osmolarity by using different signal transduction machinery under different conditions.     

The osmoregulatory pathway represses mating pathway activity in Saccharomyces cerevisiae: isolation of a FUS3 mutant that is insensitive to the repression mechanism.

Mitogen-activated protein (MAP) kinase cascades are conserved signal transduction pathways that are required for eukaryotic cells to respond to a variety of stimuli. Multiple MAP kinase pathways can function within a single cell type; therefore, mechanisms that insulate one MAP kinase pathway from adventitious activations by parallel pathways may exist. We have studied interactions between the mating pheromone response and the osmoregulatory (high-osmolarity glycerol response [HOG]) pathways in Saccharomyces cerevisiae which utilize the MAP kinases Fus3p and Hog1p, respectively. Inactivating mutations in HOG pathway kinases cause an increase in the phosphotyrosine content of Fus3p, greater expression of pheromone-responsive genes, and increased sensitivity to growth arrest by pheromone. Therefore, the HOG pathway represses mating pathway activity. In a HOG1+ strain, Fus3p phosphotyrosine increases modestly and transiently following an increase in the extracellular osmolarity; however, it increases to a greater extent and for a sustained duration in a hog1-delta strain. Thus, the HOG-mediated repression of mating pathway activity may insulate the mating pathway from activation by osmotic stress. A FUS3 allele whose gene product is resistant to the HOG-mediated repression of its phosphotyrosine content has been isolated. This mutant encodes an amino acid substitution in the highly conserved DPXDEP motif in subdomain XI. Other investigators have shown that the corresponding amino acid is also mutated in a gain-of-function allele of the MAP kinase encoded by the rolled locus in Drosophila melanogaster. These data suggest that the DPXDEP motif plays a role in the negative regulation of MAP kinases.     

Analysis of mitogen-activated protein kinase signaling specificity in response to hyperosmotic stress: use of an analog-sensitive HOG1 allele

When confronted with a marked increase in external osmolarity, budding yeast (Saccharomyces cerevisiae) cells utilize a conserved mitogen-activated protein kinase (MAPK) signaling cascade (the high-osmolarity glycerol or HOG pathway) to elicit cellular responses necessary to permit continued growth. One input that stimulates the HOG pathway requires the integral membrane protein and putative osmosensor Sho1, which recruits and enables activation of the MAPK kinase kinase Ste11. In mutants that lack the downstream MAPK kinase (pbs2Delta) or the MAPK (hog1Delta) of the HOG pathway, Ste11 activated by hyperosmotic stress is able to inappropriately stimulate the pheromone response pathway. This loss of signaling specificity is known as cross talk. To determine whether it is the Hog1 polypeptide per se or its kinase activity that is necessary to prevent cross talk, we constructed a fully functional analog-sensitive allele of HOG1 to permit acute inhibition of this enzyme without other detectable perturbations of the cell. We found that the catalytic activity of Hog1 is required continuously to prevent cross talk between the HOG pathway and both the pheromone response and invasive growth pathways. Moreover, contrary to previous reports, we found that the kinase activity of Hog1 is necessary for its stress-induced nuclear import. Finally, our results demonstrate a role for active Hog1 in maintaining signaling specificity under conditions of persistently high external osmolarity.     

Cell wall composition and structure of Yarrowia lipolytica transposon mutants affected in calcofluor sensitivity

A collection of transposon-mutagenized strains of Yarrowia lipolytica was screened for wall defects by determination of their sensitivity to calcofluor white. A number of strains were hypersensitive, whereas others were resistant. Different non-allelic mutants displayed increased sensitivity to autolysis and lytic enzymes, independently of whether they were sensitive or resistant to calcofluor white. A thorough analysis of their cell walls revealed minor quantitative alterations, and no significant changes in chitin content. Electrophoretic analysis of wall-bound and excreted proteins proved to be a sensitive method that revealed defects in the cell wall structure of the mutants. Important alterations in the patterns of the wall proteins extracted by SDS or by enzymatic treatments were noticed for the mutants, as compared to the parental strain. Mutants released to the growth medium a larger number of protein species than the parental strain, suggesting impairment in wall assembly of certain polypeptides. Patterns of wall-bound and excreted proteins, as well as alterations in wall chemical composition were not diagnostic of calcofluor white sensitivity or resistance, but were specific for each mutant. Our data show that an increase in either sensitivity or resistance of Y. lipolytica to certain levels of calcofluor is equally indicative of alterations in cell wall structure, independent of chitin levels. This revised version was published online in August 2006 with corrections to the Cover Date.     

The high-osmolarity glycerol response pathway in the human fungal pathogen Candida glabrata strain ATCC 2001 lacks a signaling branch that operates in baker's yeast

The high-osmolarity glycerol (HOG) mitogen-activated protein (MAP) kinase pathway mediates adaptation to high-osmolarity stress in the yeast Saccharomyces cerevisiae. Here we investigate the function of HOG in the human opportunistic fungal pathogen Candida glabrata. C. glabrata sho1Delta (Cgsho1Delta) deletion strains from the sequenced ATCC 2001 strain display severe growth defects under hyperosmotic conditions, a phenotype not observed for yeast sho1Delta mutants. However, deletion of CgSHO1 in other genetic backgrounds fails to cause osmostress hypersensitivity, whereas cells lacking the downstream MAP kinase Pbs2 remain osmosensitive. Notably, ATCC 2001 Cgsho1Delta cells also display methylglyoxal hypersensitivity, implying the inactivity of the Sln1 branch in ATCC 2001. Genomic sequencing of CgSSK2 in different C. glabrata backgrounds demonstrates that ATCC 2001 harbors a truncated and mutated Cgssk2-1 allele, the only orthologue of yeast SSK2/SSK22 genes. Thus, the osmophenotype of ATCC 2001 is caused by a point mutation in Cgssk2-1, which debilitates the second HOG pathway branch. Functional complementation experiments unequivocally demonstrate that HOG signaling in yeast and C. glabrata share similar functions in osmostress adaptation. In contrast to yeast, however, Cgsho1Delta mutants display hypersensitivity to weak organic acids such as sorbate and benzoate. Hence, CgSho1 is also implicated in modulating weak acid tolerance, suggesting that HOG signaling in C. glabrata mediates the response to multiple stress conditions.     

The stress-activated mitogen-activated protein kinase signaling cascade promotes exit from mitosis

In budding yeast, a signaling network known as the mitotic exit network (MEN) triggers exit from mitosis. We find that hypertonic stress allows MEN mutants to exit from mitosis in a manner dependent on the high osmolarity glycerol (HOG) mitogen-activated protein (MAP) kinase cascade. The HOG pathway drives exit from mitosis in MEN mutants by promoting the activation of the MEN effector, the protein phosphatase Cdc14. Activation of Cdc14 depends on the Cdc14 early anaphase release network, a group of proteins that functions in parallel to the MEN to promote Cdc14 function. Notably, exit from mitosis is promoted by the signaling branch defined by the Sho1 osmosensing system, but not by the Sln1 osmosensor of the HOG pathway. Our results suggest that the stress MAP kinase pathway mobilizes programs to promote completion of the cell cycle and entry into G1 under unfavorable conditions.     

Yeast Cdc42 GTPase and Ste20 PAK-like kinase regulate Sho1-dependent activation of the Hog1 MAPK pathway

The adaptive response to hyperosmotic stress in yeast, termed the high osmolarity glycerol (HOG) response, is mediated by two independent upstream pathways that converge on the Pbs2 MAP kinase kinase (MAPKK), leading to the activation of the Hog1 MAP kinase. One branch is dependent on the Sho1 transmembrane protein, whose primary role was found to be the binding and translocation of the Pbs2 MAPKK to the plasma membrane, and specifically to sites of polarized growth. The yeast PAK homolog Ste20 is essential for the Sho1-dependent activation of the Hog1 MAP kinase in response to severe osmotic stress. This function of Ste20 in the HOG pathway requires binding of the small GTPase Cdc42. Overexpression of Cdc42 partially complements the osmosensitivity of ste20Delta mutants, perhaps by activating another PAK-like kinase, while a dominant-negative Cdc42 mutant inhibited signaling through the SHO1 branch of the HOG pathway. Since activated Cdc42 translocates Ste20 to sites of polarized growth, the upstream and downstream elements of the HOG pathway are brought together through the membrane targeting function of Sho1 and Cdc42.     

Sphingolipids regulate the yeast high-osmolarity glycerol response pathway

The yeast high-osmolarity glycerol response (HOG) mitogen-activated protein (MAP) kinase pathway is activated in response to hyperosmotic stress via two independent osmosensing branches, the Sln1 branch and the Sho1 branch. While the mechanism by which the osmosensing machinery activates the downstream MAP kinase cascade has been well studied, the mechanism by which the machinery senses and responds to hyperosmotic stress remains to be clarified. Here we report that inhibition of the de novo sphingolipid synthesis pathway results in activation of the HOG pathway via both branches. Inhibition of ergosterol biosynthesis also induces activation of the HOG pathway. Sphingolipids and sterols are known to be tightly packed together in cell membranes to form partitioned domains called rafts. Raft-enriched detergent-resistant membranes (DRMs) contain both Sln1 and Sho1, and sphingolipid depletion and hyperosmotic stress have similar effects on the osmosensing machinery of the HOG pathway: dissociation of an Sln1-containing protein complex and elevated association of Sho1 with DRMs. These observations reveal the sphingolipid-mediated regulation of the osmosensing machinery of the HOG pathway.     

Dissection of the HOG pathway activated by hydrogen peroxide in Saccharomyces cerevisiae

Cells usually cope with oxidative stress by activating signal transduction pathways. In the budding yeast Sacchromyces cerevisiae, the high osmolarity glycerol (HOG) pathway has long been implicated in transducing the oxidative stress‐induced signal, but the underlying mechanisms are not well defined. Based on phosphorylation of the mitogen‐activated protein kinase (MAPK) Hog1, we reveal that the signal from hydrogen peroxide (H₂O₂) flows through Ssk1, the response regulator of the two‐component system of the HOG pathway. Downstream signal transduction into the HOG MAPK cascade requires the MAP kinase kinase kinase (MAP3K) Ssk2 but not its paralog Ssk22 or another MAP3K Ste11 of the pathway, culminating in Hog1 phosphorylation via the MAP2K Pbs2. When overexpressed, Ssk2 is also activated in an Ssk1‐independent manner. Unlike in mammals, H₂O₂ does not cause endoplasmic reticulum stress, which can activate Hog1 through the conventional unfolded protein response. Hog1 activated by H₂O₂ is retained in the cytoplasm, but is still able to activate the cAMP‐ or stress‐responsive elements by unknown mechanisms.     

Stimulation of the yeast high osmolarity glycerol (HOG) pathway: evidence for a signal generated by a change in turgor rather than by water stress

The Saccharomyces cerevisiae HOG pathway controls responses to osmotic shock such as production of the osmolyte glycerol. Here we show that the HOG pathway can be stimulated by addition of glycerol. This stimulation was strongly diminished in cells expressing an unregulated Fps1p glycerol channel, presumably because glycerol rapidly equilibrated across the plasma membrane. Ethanol, which passes the plasma membrane readily and causes water stress by disturbing the hydration of biomolecules, did not activate the HOG pathway. These observations suggest that stimulation of the HOG pathway is mediated by a turgor change and not by water stress per se.