HOG MAP Kinase Pathway Research Articles

The MAPK Hog1 mediates the response to amphotericin B in Candida albicans

The HOG MAP kinase pathway plays a crucial role in the response to different stresses in the opportunistic pathogen Candida albicans. The polyene amphotericin B (AMB) has been reported to trigger oxidative stress in several pathogenic fungi, including C. albicans. In the present work, we have analyzed the role of the MAPK Hog1 in sensing and survival to AMB treatment. Mutants lacking Hog1 are more susceptible to AMB than their parental strains and Hog1 became phosphorylated in the presence of this polyene. A set of mutated versions of Hog1 revealed that both the kinase activity and phosphorylation of Hog1 are required to cope with AMB treatment. Flow cytometry analysis showed that AMB induced intracellular ROS accumulation in both parental and hog1 null mutant strains. In addition, AMB triggered a Hog1-independent synthesis of trehalose. The addition of rotenone to AMB-treated cells improved cell viability, decreased intracellular ROS and prevented intracellular trehalose accumulation, suggesting that AMB-induced ROS is associated to a functional electron transport chain but the presence of rotenone did not impair Hog1 phosphorylation in AMB-treated cells. Our results indicate that Hog1 is necessary during AMB treatment to increase its survival.

Two hybrid histidine kinases, TcsB and the phytochrome FphA, are involved in temperature sensing in Aspergillus nidulans.

The adaptation of microorganisms to different temperatures is an advantage in habitats with steadily changing conditions and raises the question about temperature sensing. Here we show that in the filamentous fungus Aspergillus nidulans, the hybrid histidine kinase TcsB and phytochrome are involved in temperature-induced gene transcription. Temperature-activated phytochrome fed the signal into the HOG MAP kinase pathway. There is evidence that the photoreceptor phytochrome fulfills a temperature sensory role in plants and bacteria. The effects in plants are based on dark reversion from the active form of phytochrome, Pfr, to the inactive form, Pr. Elevated temperature leads to higher dark reversion rates, and hence, temperature sensing depends on light. In A. nidulans and in Alternaria alternata, the temperature response was light-independent. In order to understand the primary temperature response of phytochrome, we performed spectral analyses of recombinant FphA from both fungi. Spectral properties after heat stress resembled the spectrum of free biliverdin, suggesting conformational changes and a softening of the binding pocket of phytochrome, possibly mimicking photoactivation. We propose a novel function for fungal phytochrome as temperature sensor.

The HOG MAPK pathway in Candida albicans: more than an osmosensing pathway.

In 1993, Brewster and Gustin described the existence of a kinase whose activity was essential for Saccharomyces cerevisiae to grow in environments with high osmolarity. This led to the discovery of the HOG pathway, a MAP kinase (MAPK) pathway that has been revealed to be crucial to respond to a wide range of stress conditions frequently encountered by fungi in their common habitats. MAPK signaling is initiated at the plasma membrane, where triggering stimuli lead to a phosphorylation cascade that ultimately activates transcription factors to ensure an appropriate adaptive response. In pathogenic fungi, the HOG pathway gains special significance as it is involved in traits related to pathogenicity; these include biofilm formation, adhesion to surfaces, and morphogenetic and epigenetic transitions. It also plays a role in controlling both the pathogen and the commensal state program. Understanding the signals leading to its activation, the elements of the pathways and the targets of the pathway are therefore of primary importance in the design of novel antifungals.

Saccharomyces cerevisiae Hog1 MAP kinase pathway is activated in response to honokiol exposure.

The goal of the study was to investigate the cellular tolerance mechanism in response to honokiol exposure. The broth microdilution method was employed to test the sensitivity of different Saccharomyces cerevisiae strains to honokiol. Intracellular levels of reactive oxygen species (ROSs) were determined by DCFH-DA staining. The phosphorylation of Hog1 was evaluated by Western blot analysis. The mRNA expressions of genes involved in the Ras-cyclic AMP (cAMP) pathway were analysed by real-time reverse transcription polymerase chain reaction. We found that the sod1▵ mutant was hypersensitive to honokiol and produced more ROS compared with wild-type and sod2▵ cells. Hog1 was phosphorylated in response to honokiol exposure and deletion of HOG1 increased the sensitivity to honokiol. The expressions of genes involved in the Ras-cAMP pathway were down-regulated after honokiol exposure; exogenous cAMP significantly reduced the phosphorylation of Hog1, although the level was higher than the control level. In addition to SOD1, the Ras-cAMP cascade and Hog1 MAP kinase pathway is essential for protecting against honokiol-induced oxidative stress. Our results provide insight into the understanding of the action mechanism of honokiol.

Expression control of the AMPK regulatory subunit and its functional significance in yeast ER stress response

AMP-activated protein kinase (AMPK) is an evolutionarily conserved heterotrimeric kinase complex consisting of a catalytic subunit, α, and two regulatory subunits, β and γ. Previously, we demonstrated that Snf1, the Saccharomyces cerevisiae ortholog of AMPK, negatively regulates the unfolded protein response (UPR) pathway and the Hog1 MAP kinase pathway in ER stress response. However, it remains unclear how the alternate three β subunits, Sip1, Sip2, and Gal83, of the Snf1 complex participate in ER stress response. Here, we show that Gal83 plays a major role in Snf1-mediated downregulation of the UPR and Hog1 pathways. Gal83 is the most abundant β subunit in the normal state and further induced by ER stress. This induction is mediated via activation of the GAL83 promoter by the UPR. When expressed under the control of the GAL83 promoter, Sip2 exhibits potent functional activity equivalent to Gal83. Our results suggest that the functional significance of the β subunit of Snf1 AMPK in ER stress response is defined by modulation of the expression level through regulation of the promoter activity.

Delayed Turnover of Unphosphorylated Ssk1 during Carbon Stress Activates the Yeast Hog1 Map Kinase Pathway.

In Saccharomyces cerevisiae, the Hog1 mitogen-activated protein kinase (MAPK) pathway coordinates the adaptation to osmotic stress and was recently reported to respond to acute changes in glucose levels. Similarly as in osmotic stress, glucose starvation leads to a transient accumulation of Hog1 in the nucleus. However, the kinetics and the mechanism of Hog1 activation are different for these stress conditions. During osmotic shock the activation of Hog1 can be transduced by either the Sho1 or the Sln1/Ypd1/Ssk1 branch. During glucose starvation the phosphorylation of Hog1 is slower and is completely dependent on Ssk1, but independent of Sho1. To characterize the mechanism of activation of Hog1 during carbon stress, we examined the turnover of Ssk1 protein levels upon glucose starvation in the presence of cycloheximide and monitored protein levels by western blotting. Our data demonstrate that unphosphorylated Ssk1 was quickly degraded during exponential growth and after osmotic stress but remained remarkably stable during glucose limitation. We conclude that glucose starvation induces a delay in the turnover of unphosphorylated Ssk1, which is sufficient to activate the Hog1 MAPK pathway. Although unphosphorylated Ssk1 is known to be degraded by the proteasome, its stabilization is apparently not due to changes in cellular localization or decrease in ubiquitination levels during glucose limitation.

Strain-dependent tolerance to acetic acid in Dekkera bruxellensis

Dekkera bruxellensis—a yeast species associated with wine and beer production—has recently received attention because of its ability to compete with Saccharomyces cerevisiae in distilleries producing fuel ethanol, and due to its resistance to high ethanol and acid levels. The tolerance to acetic acid in 29 strains of D. bruxellensis was investigated by screening growth at different concentrations up to 120 mM at pH 4.5. Different metabolic responses were exhibited in three strains (CBS 98, CBS 2499 and CBS 4482) that were analysed by their FTIR-metabolomic fingerprint. Physiological studies showed that the presence of acetic acid significantly affected their growth, causing a different reduction in growth rate, glucose consumption and ethanol production rates, as well as biomass and ethanol yields. The examined strains were unable to metabolise acetic acid in the presence of glucose, probably due to a glucose repression mechanism on the acetyl-CoA syntethase activity. Interestingly, the cells continued to produce acetic acid as byproduct of their fermentative metabolism. We also showed that the HOG MAP kinase pathway was not activated by phosphorylation upon exposure of the cells to acetic acid.

The yeast Hot1 transcription factor is critical for activating a single target gene, STL1.

Transcription factors are commonly activated by signal transduction cascades and induce expression of many genes. They therefore play critical roles in determining the cell's fate. The yeast Hog1 MAP kinase pathway is believed to control the transcription of hundreds of genes via several transcription factors. To identify the bona fide target genes of Hog1, we inducibly expressed the spontaneously active variant Hog1(D170A+F318L) in cells lacking the Hog1 activator Pbs2. This system allowed monitoring the effects of Hog1 by itself. Expression of Hog1(D170A+F318L) in pbs2∆ cells imposed induction of just 105 and suppression of only 26 transcripts by at least twofold. We looked for the Hog1-responsive element within the promoter of the most highly induced gene, STL1 (88-fold). A novel Hog1 responsive element (HoRE) was identified and shown to be the direct target of the transcription factor Hot1. Unexpectedly, we could not find this HoRE in any other yeast promoter. In addition, the only gene whose expression was abolished in hot1∆ cells was STL1. Thus Hot1 is essential for transcription of just one gene, STL1. Hot1 may represent a class of transcription factors that are essential for transcription of a very few genes or even just one.

Dynamic Control of Yeast MAP Kinase Network by Induced Association and Dissociation between the Ste50 Scaffold and the Opy2 Membrane Anchor

Membrane localization of the Ste11 MAPKKK is essential for activation of both the filamentous growth/invasive growth (FG/IG) MAP kinase (MAPK) pathway and the SHO1 branch of the osmoregulatory HOG MAPK pathway, and is mediated by binding of the Ste50 scaffold protein to the Opy2 membrane anchor. We found that Opy2 has two major (CR-A and CR-B), and one minor (CR-D), binding sites for Ste50. CR-A binds Ste50 constitutively and can transmit signals to both the Hog1 and Fus3/Kss1 MAPKs. CR-B, in contrast, binds Ste50 only when Opy2 is phosphorylated by Yck1/Yck2 under glucose-rich conditions and transmits the signal preferentially to the Hog1 MAPK. Ste50 phosphorylation by activated Hog1/Fus3/Kss1 MAPKs downregulates the HOG MAPK pathway by dissociating Ste50 from Opy2. Furthermore, Ste50 phosphorylation, together with MAPK-specific protein phosphatases, reduces the basal activity of the HOG and the mating MAPK pathways. Thus, dynamic regulation of Ste50-Opy2 interaction fine-tunes the MAPK signaling network.

Signal processing by the HOG MAP kinase pathway

Signaling pathways relay information about changes in the external environment so that cells can respond appropriately. How much information a pathway can carry depends on its bandwidth. We designed a microfluidic device to reliably change the environment of single cells over a range of frequencies. Using this device, we measured the bandwidth of the Saccharomyces cerevisiae signaling pathway that responds to high osmolarity. This prototypical pathway, the HOG pathway, is shown to act as a low-pass filter, integrating the signal when it changes rapidly and following it faithfully when it changes more slowly. We study the dependence of the pathway's bandwidth on its architecture. We measure previously unknown bounds on all of the in vivo reaction rates acting in this pathway. We find that the two-component Ssk1 branch of this pathway is capable of fast signal integration, whereas the kinase Ste11 branch is not. Our experimental techniques can be applied to other signaling pathways, allowing the measurement of their in vivo kinetics and the quantification of their information capacity.

Dissecting yeast Hog1 MAP kinase pathway using a chemical genetic approach

Using a chemical genetic approach, we identified four novel physiological substrates of Hog1 kinase (Krs1, Tdh3, Hsp26, and Shm2). These substrates suggest plausible mechanisms for actin reorganization, cell cycle arrest and regulation of protein synthesis observed upon osmotic stress. We further show that the human homolog of Shm2 (SHMT1) is a novel physiological substrate of p38 MAP kinase in vitro and in vivo. Down-regulation of its enzymatic activity was observed following p38-mediated phosphorylation revealing a potential cancer-modulating property of p38 MAP kinase. This screen has uncovered several novel Hog1 substrates that provide new avenues for investigation into the mechanism of osmoadaptation by this kinase.

Role of protein phosphatases 2C on tolerance to lithium toxicity in the yeast Saccharomyces cerevisiae

Protein phosphatases 2C are a family of conserved enzymes involved in many aspects of the cell biology. We reported that, in the yeast Saccharomyces cerevisiae, overexpression of the Ptc3p isoform resulted in increased lithium tolerance in the hypersensitive hal3 background. We have found that the tolerance induced by PTC3 overexpression is also observed in wild-type cells and that this is most probably the result of increased expression of the ENA1 Na(+)-ATPase mediated by the Hog1 MAP kinase pathway. This effect does not require a catalytically active protein. Surprisingly, deletion of PTC3 (similarly to that of PTC2, PTC4 or PTC5) does not confer a lithium-sensitive phenotype, but mutation of PTC1 does. Lack of PTC1 in an ena1-4 background did not result in additive lithium sensitivity and the ptc1 mutant showed a decreased expression of the ENA1 gene in cells stressed with LiCl. In agreement, under these conditions, the ptc1 mutant was less effective in extruding Li(+) and accumulated higher concentrations of this cation. Deletion of PTC1 in a hal3 background did not exacerbate the halosensitive phenotype of the hal3 strain. In addition, induction from the ENA1 promoter under LiCl stress decreased similarly (50%) in hal3, ptc1 and ptc1 hal3 mutants. Finally, mutation of PTC1 virtually abolishes the increased tolerance to toxic cations provided by overexpression of Hal3p. These results indicate that Ptc1p modulates the function of Ena1p by regulating the Hal3/Ppz1,2 pathway. In conclusion, overexpression of PTC3 and lack of PTC1 affect lithium tolerance in yeast, although through different mechanisms.

Two-component signal transduction in human fungal pathogens

Signal transduction pathways provide mechanisms for adaptation to stress conditions. One of the most studied of these pathways is the HOG1 MAP kinase pathway that in Saccharomyces cerevisiae is used to adapt cells to osmostress. The HOG1 MAPK has also been studied in Candida albicans, and more recently observations on the Hog1p functions have been described in two other human pathogens, Aspergillus fumigatus and Cryptococcus neoformans. The important, but not surprising, concept is that this pathway is used for different yet similar functions in each of these fungi, given their need to adapt to different environmental signals. Current studies of C. albicans focus upon the identification of two-component signal proteins that, in both C. albicans and S. cerevisiae, regulate the HOG1 MAPK. In C. albicans, these proteins regulate cell wall biosynthesis (and, therefore, adherence to host cells), osmotic and oxidant adaptation, white-opaque switching, morphogenesis, and virulence of the organism.

The role of thesakA(Hog1) andtcsB(sln1) genes in the oxidant adaptation ofAspergillus fumigatus

The Hog1 MAP kinase pathway regulates stress adaptation in several fungi. To assess its role in stress adaptation in Aspergillus fumigatus, we constructed mutants in genes encoding the sensor histidine kinase (HK) tcsB as well as sakA, which are homologues of the Saccharomyces cerevisiae sln1 and Hog1, respectively. Compared to the wild type strain (Wt), growth of sakA (sakAtriangle up) mutant was reduced, and growth inhibition was increased when H(2)O(2), menadione, or SDS was added to the media. On the other hand, the tcsB mutant (tcsBtriangle up) was similar to the Wt strain in regard to growth and morphology, although a partial sensitivity to SDS was observed. Western blot analysis of Wt and the tcsBtriangle up strains indicated that when stressed with H(2)O(2), phosphorylation of Hog1p still occurs in the mutant. Since in Candida albicans, Hog1 regulates transcription of at least one histidine kinase, we performed RT-PCR of 6 histidine kinase genes as well as the ssk1 and skn7 response regulator genes of A. fumigatus. No significant differences in transcription were observed with the sakAtriangle up when compared to the Wt, indicating that the sakA does not regulate transcription of these genes. Our studies indicate that the A. fumigatus sakA is required for optimal growth of the organism with or without oxidant stress, while tcsB gene is dispensable.

Studies on the regulation of the two-component histidine kinase gene CHK1 in Candida albicans using the heterologous lacZ reporter gene.

The two-component histidine kinase Chk1p of Candida albicans has been implicated in the regulation of cell wall biosynthesis. Deletion of CHK1 results in avirulence that in part may be due to the increased sensitivity of mutant strains to polymorphonuclear leukocytes. The mutant also does not adhere to human oesophageal tissue in vitro, probably as a consequence of its altered cell wall. In the current study, a CHK1 promoter-lacZ reporter (CHK1prlacZ) construct was expressed in wild-type C. albicans strain CAI4 and in two-component signal transduction mutants to determine the effect of environmental stress conditions on the regulation of CHK1 and the co-regulatory activities among these proteins. It is shown that lacZ expression varied according to the type of growth conditions and incubation time; expression was also influenced by the strain background. lacZ expression in CAI4 was greater at 37 degrees C and at a pH of 3.5 and in the presence of 4 mM H2O2, 0.1 mM menadione, 10 % serum or 1.5 M NaCl compared to cells grown at 30 or 42 degrees C. The increases in expression were time-dependent and not observed until cells were incubated for 120 min in these conditions (P < 0.05). As a correlate of the increase in transcription of CHK1-lacZ in the presence of H2O2, the chk1 mutant was more sensitive than wild-type and revertant cells to H2O2 in vitro. In addition to strain CAI4, we also measured CHK1p-lacZ reporter activity of mutants deleted in genes encoding other two-component proteins such as the response regulator gene SSK1, the histidine kinases, SLN1 and NIK1, and the HOG1 MAP kinase. Of these proteins, Ssk1p and Sln1p are presumed to mediate phosphotransfer to the HOG1 [hyperosmotic glycerol] MAP kinase pathway during oxidative and perhaps osmotic stress in C. albicans. Compared to strain CAI4, lacZ reporter activity increased significantly in the ssk1 mutant under all growth conditions after a 10 and 120 min incubation (P < 0.0001). lacZ expression in the ssk1 mutant was less at 42 degrees C compared to all other growth conditions (P < 0.05). Furthermore, lacZ reporter activity also increased in the hog1 mutant of C. albicans. These data suggest that SSK1 and HOG1 indirectly or directly negatively regulate CHK1 under most growth conditions tested. In the sln1 mutant, downregulation of CHK1 was observed in all growth conditions compared to strain CAI4 (P < 0.05), while regulation of lacZ in the nik1 mutant was similar to strain CAI4 except when cells were incubated in the presence of 4 mM H2O2 for 120 min (P < 0.05). Western blot analysis was used to determine the role of Chk1p in phosphorylation of Hog1p under oxidative or osmotic stress. It was found that Hog1p was phosphorylated in the chk1 mutant similar to wild-type CAF2-1 cells, although the temporal events of phosphorylation differed slightly in mutant cells. These results show that transcription of CHK1, as measured by the lacZ reporter assay, is statistically increased when cells are exposed to several types of stress or when incubated in 10 % serum in a mutant-specific background and at a specific time point. Of importance, our data also suggest that lacZ expression is indirectly or directly regulated by the HOG1 MAP kinase pathway, although a determination of its position in this pathway or in a cross-talking pathway awaits additional studies.

The Hog1 MAP kinase pathway and the Mec1 DNA damage checkpoint pathway independently control the cellular responses to hydrogen peroxide

The DNA damage checkpoint pathway and the MAP kinase pathway respond to various forms of environmental as well as endogenous stresses through signal transduction mechanisms involving protein kinases. Both pathways are intertwined in mammalian cells, but potential crosstalk between these two pathways in budding yeast has not been examined yet. We show that the Rad53 checkpoint kinase and the Hog1 MAP kinase of Saccharomyces cerevisiae become phosphorylated upon exposure to hydrogen peroxide, indicative of activation of the DNA damage checkpoint and MAP kinase pathways in response to oxidative stress. Rad53 kinase is equally activated in wild type and in hog1-Δ cells. Likewise, the activation of Hog1 MAP kinase is not dependent on Mec1 kinase, the central checkpoint kinase in budding yeast. Mutants in either pathway are sensitive to hydrogen peroxide and the double mutants exhibit a near perfectly additive phenotype. These data demonstrate that the DNA damage checkpoint pathway and the MAP kinase pathway respond to oxidative stress independently of each other and suggest that these two stress signaling pathways are activated by different types of insults induced by hydrogen peroxide.

The Hog1 MAP kinase pathway and the Mec1 DNA damage checkpoint pathway independently control the cellular responses to hydrogen peroxide

The DNA damage checkpoint pathway and the MAP kinase pathway respond to various forms of environmental as well as endogenous stresses through signal transduction mechanisms involving protein kinases. Both pathways are intertwined in mammalian cells, but potential crosstalk between these two pathways in budding yeast has not been examined yet. We show that the Rad53 checkpoint kinase and the Hog1 MAP kinase of Saccharomyces cerevisiae become phosphorylated upon exposure to hydrogen peroxide, indicative of activation of the DNA damage checkpoint and MAP kinase pathways in response to oxidative stress. Rad53 kinase is equally activated in wild type and in hog1-Δ cells. Likewise, the activation of Hog1 MAP kinase is not dependent on Mec1 kinase, the central checkpoint kinase in budding yeast. Mutants in either pathway are sensitive to hydrogen peroxide and the double mutants exhibit a near perfectly additive phenotype. These data demonstrate that the DNA damage checkpoint pathway and the MAP kinase pathway respond to oxidative stress independently of each other and suggest that these two stress signaling pathways are activated by different types of insults induced by hydrogen peroxide.

Transient Inhibition of Translation Initiation by Osmotic Stress

Cells respond and adapt to changes in the environment. In this study, we examined the effect of environmental stresses on protein synthesis in the yeast Saccharomyces cerevisiae. We found that osmotic stress causes irreversible inhibition of methionine uptake, transient inhibition of uracil uptake, transient stimulation of glucose uptake, transient repression of ribosomal protein (RP) genes such as CYH2 and RPS27, and the transient inhibition of translation initiation. Rapid inhibition of translation initiation by osmotic stress requires a novel pathway, different from the amino acid-sensing pathway, the glucose-sensing pathway, and the TOR pathway. The Hog1 MAP kinase pathway is not involved in the inhibition of either methionine uptake or translation initiation but is required for the adaptation of translation initiation after inhibition and the repression of RP genes by osmotic stress. These results suggest that the transient inhibition of translation initiation occurs as a result of a combination of both acute inhibition of translation and the long-term activation of translation by the Hog1 pathway.

Expression of the yeast glycogen phosphorylase gene is regulated by stress‐response elements and by the HOG MAP kinase pathway

Yeast glycogen metabolism responds to environmental stressors such as nutrient limitation and heat shock. This response is mediated, in part, by the regulation of the glycogen metabolic genes. Environmental stressors induce a number of glycogen metabolic genes, including GPH1, which encodes glycogen phosphorylase. Primer extension analysis detected two start sites for GPH1, one of which predominated. Sequences upstream of these sites included a possible TATA element. Mutation of this sequence reduced GPH1 expression by a factor of 10 but did not affect start site selection. This mutation also did not affect the relative induction of GPH1 upon entry into stationary phase. Three candidates for stress response elements (STREs) were found upstream of the TATA sequence. Mutation of the STREs showed that they were required for regulation of GPH1 expression in early stationary phase, and in response to osmotic shock and heat shock. These elements appeared to act synergistically, since the intact promoter exhibited 30-fold more expression in stationary phase than the sum of that observed for each element acting independently. HOG1, which encodes a MAP kinase, has been implicated in control mediated by STREs. For GPH1, induction by osmotic shock depended on a functional HOG1 allele. In contrast, induction upon entry into stationary phase was only partially dependent on HOG1. Furthermore, the heat shock response, which can also be mediated by STREs, was independent of HOG1. These observations suggest that the GPH1 STREs respond to more than one pathway, only one of which requires HOG1.

Defects in glycosylphosphatidylinositol (GPI) anchor synthesis activate Hog1 kinase and confer copper-resistance in Saccharomyces cerevisisae.

Las21/Gpi7 contains a heavy-metal-associated motif at its N-terminus. When this motif was disrupted by amino acid substitution, the cells acquired weak copper-resistance. We found that the previously isolated las21 mutants were strongly resistant to copper. Metallothionein is necessary for the expression of the copper-resistance of the las21 mutants. However, hyper-production of metallothionein is unlikely to be the cause of copper-resistance of the las21 mutants. Copper-sensitive mutants (collectively called Cus mutants) were isolated from the las21delta and characterized. One of the Cus genes was found to be PBS2, which encodes Hog1 MAP kinase kinase, indicating that the Hog1 MAP kinase pathway is needed for the expression of copper-resistance of the las21 mutants. As expected, the las21delta hog1delta strain was no longer copper-resistant. We found that Hog1 was constitutively activated in las21delta cells and in ssk1delta las21delta cells but not in sho1delta las21delta cells. Inactivation of either FSR2/MCD4 or MPC1/GPI13, both of which are involved in GPI anchor synthesis, like LAS21, caused a similar level of constitutive activation of Hog1 kinase and copper-resistance as found in the las21delta strain. The constitutive activation was canceled by introducing the sskl mutation, but not the sho1 mutation, in each GPI anchor mutant tested, suggesting that the defect in GPI anchor synthesis specifically affects the Slnl branch of the MAP kinase pathway. Since the wild-type cells grown in YPD containing 0.5 M NaCl do not show copper-resistance, mere activation of Hog1 is not sufficient for expression of copper-resistance. We propose that a defect in GPI anchor synthesis has multiple consequences, including activation of the Hog1 MAP kinase cascade and conferring copper-resistance.