Ash1, a Daughter Cell-Specific Protein, Is Required for Pseudohyphal Growth of Saccharomyces cerevisiae

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Mol Cell Biol, May 1998, p. 2884-2891, Vol. 18, No. 5
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.

Ash1, a Daughter Cell-Specific Protein, Is Required for Pseudohyphal Growth of Saccharomyces cerevisiae

Sarat Chandarlapaty and Beverly Errede^*

Department of Biochemistry and Biophysics, University of North Carolina, Chapel Hill, North Carolina 27599-7260

Received 17 November 1997/Returned for modification 9 January 1998/Accepted 3 February 1998

	ABSTRACT

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Ash1 (for asymmetric synthesis of HO) was first uncovered in genetic screens that revealed its role in mating-type switching.Ash1 prevents HO expression in daughter cells. Because Ash1 hasa zinc finger-like domain related to that of the GATA family oftranscription factors, it presumably acts by repressing HO transcription.Nonswitching diploid cells also express Ash1, suggesting it couldhave functions in addition to regulation of HO expression. Weshow here that Ash1 has an essential function for pseudohyphalgrowth. Our epistasis analyses are consistent with the deductionthat Ash1 acts separately from the mitogen-activated protein kinasecascade and Ste12. Similarly to the case in yeast form cells,Ash1 is asymmetrically localized to the nuclei of daughter cellsduring pseudohyphal growth. This asymmetric localization revealsthat there is a previously unsuspected daughter cell-specificfunction necessary for pseudohyphal growth.

	INTRODUCTION

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The developmental process requires that parent cells assign distinctive fates to progeny. This capacity to differentiate oftenhinges on the action of a few specific molecules. Mating-typeswitching of haploid Saccharomyces cerevisiae is an example ofsuch a phenomenon. While mother cells switch mating type, daughtercells are unable to switch because transcription of the HO endonucleaseis repressed (23). Unlike a mother cell, a daughter cell expressesAsh1 (for asymmetric synthesis of HO), which, by an unknown mechanism,blocks HO expression (4, 33). This asymmetric distributionof Ash1, therefore, is critical to the different fates of motherand daughter cells. Interestingly, Ash1 asymmetry is preservedin nonswitching a/ $alpha$ diploids, leading to speculation thatthere may be other developmental processes under Ash1 control(33).

One developmental process that exists in both the haploid and diploid cell types of S. cerevisiae is filamentous growth. Haploidyeast cells respond to long incubations on rich medium by growinginto the agar substrate in a process termed invasive growth (27).Such growth is characterized by a slight elongation of cells,along with a switch from an axial to a bipolar budding pattern.In the diploid pseudohyphal response, nitrogen starvation cuesa more dramatic transition resulting in changes in cell shape,cell separation, agar invasion, and cell cycle (14). Perhapsthe most striking change is in morphogenesis, as cells becomehighly elongated (12, 15). Unlike yeast form cells, theseelongated cells remain attached after the cell cycle is complete,showing incomplete cell separation (12). The chains of elongatedcells are competent to grow invasively into the agar surface,like their haploid counterparts (12). Finally, pseudohyphalcells exhibit a unique cell cycle in which the G₁ delay beforeStart is largely eliminated and the G₂ phase is significantlylengthened (15). The macroscopic result of these changes isa colony of cells with multiple projections radiating away fromthe bulk of cells (12).

Identification of the molecular components of filamentous growth is currently under way. Indeed, several components have beenimplicated in mediating the pseudohyphal response to nutritionaldeprivation. These include Ste20 (a PAK family member), the enzymesof the mitogen-activated protein kinase (MAPK) activation cascade(Ste11 and Ste7), and the Ste12 transcription factor and its negativeregulators, Rst1/Dig1 and Rst2/Dig2 (6, 18, 27, 34).While deletion mutants lacking Ste12, Ste11, or Ste7 still formpseudohyphal filaments if they express activated variants of Ras2(Ras2-V¹⁹) or Cdc42 (Cdc42-V¹²), a sterile 20 deletion mutant expressing Ras2-V¹⁹ or Cdc42-V¹² does not (21, 22, 28). These results have led to the postulationof a branch in the pathway emerging at the level of Ste20 or possiblya parallel pathway to which Ste20 contributes (28).

This report demonstrates an essential function for Ash1 in the pseudohyphal-growth response. Epistasis experiments suggestthat Ash1 does not operate directly upon the MAPK activation cascadeor the transcriptional regulators that are downstream of the cascade.Interestingly, deletion of both Ste12 and Ash1 is required toblock pseudohyphal-filament formation stimulated by a constitutivelyactivated Ras2 variant. Therefore, it appears that both Ash1 andSte12 function after Ras2 but on separate arms of a branched pathway.Further, we show that Ash1 maintains its asymmetric localizationto daughters as cells undergo pseudohyphal growth. A mechanisticimplication of this behavior is that the pseudohyphal-growth processrequires a key daughter cell-specific function.

	MATERIALS AND METHODS

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Plasmids. Several deletion alleles were used to construct various strains for the studies described here. pNC409 carries an allele thatis a deletion of the entire coding region of ASH1. The ash1- $Delta$ 1allele was constructed by using pNC543, a clone that we isolatedfrom the pYES-R genomic overexpression library. This plasmid containsthe complete ASH1 coding region under control of the GAL promoterin the pYES-R (CEN4 URA3) vector (9). A 100-bp fragment fromthe ASH1 5' untranslated region was amplified by PCR with pNC543as the template and synthetic oligonucleotides 196 (5'-GCGCACATGCATGCCAAAATTCTATCTT)and 197 (5'-GCTCTAGATTTTCCTTTTCCCGT) as primers. A 500-bp fragmentof the ASH1 3' untranslated region was similarly amplified byusing oligonucleotides 204 (5'-CGCGCGGATCCAATTGTACATT) and 205(5'-CGCCGGAATTCGTAGAATTAGA) as primers. The two PCR-amplifiedfragments were inserted at the respective XbaI-SphI and EcoRI-BamHIcloning sites in pNC343 (5). These two cloning sites in pNC343flank the hisG-URA3-hisG cassette. This cassette allows for Uraselection of the deletion allele in gene replacement manipulationsand subsequent deletion of the URA3 marker by selecting for recombinationevents that occur between the repeated hisG sequences (1).pNC527 contains the leu2- $Delta$ 1 fragment from p307 inserted as a SalIfragment into the SalI site of the integrating vector pRS306 (URA3selectable marker) (32). The ste12 $Delta$ ::LEU2 allele from pSUL16has been described previously (8).

A fusion of Ash1 to green fluorescence protein (GFP) was constructed to monitor localization of Ash1. pKS+GFP contains a 700-bpcassette encoding GFP in the vector pBluescript KS+ (7). ThisGFP sequence was fused to ASH1 via the annealed oligonucleotides271 (5'-GATCCTGGGGACTTCCCAGGAGATTTACCGCGGCCGCCG) and 272 (5'-GATCCGGCGGCCGCGGTATAATCTCCTGGGAAGTCCCCAG),which encode the polypeptide linker GGRGKSPGKSP. The oligonucleotidelinker first was inserted into the BamHI site that is immediatelyafter the ATG of ASH1 in pAS163. pAS163 is the 2µm URA3 vector,pRS426, with an epitope-tagged allele of ASH1 (32, 33). Thisallele has three tandem copies of the Myc epitope-coding sequenceinserted immediately after the ATG initiation codon of ASH1. Thelinker insertion that we made at the BamHI site of pAS163 replacesthe Myc epitope sequences. The NotI fragment of pKS+GFP was theninserted between the ATG codon and the segment encoding the polypeptidelinker. The resulting plasmid, pNC513, expresses an in-frame GFP-linker-ASH1fusion from the 2µm URA3 vector, pRS426 (32). The integratingplasmid pNC514 was constructed by cloning an XhoI-SacII fragmentcontaining the GFP-linker-ASH1 fusion from pNC513 into the XhoI-SacIIsites of pRS306 (32). Standard molecular biological techniqueswere employed in plasmid constructions (30).

pNC248 is a 2µm URA3 vector (YEp52) carrying the STE12M-668 allele from pNC247 (2). pCG37 is the 2µm URA3 vector, pRS202,containing a 2.6-kb PHD1 allele fused to a FLU1 epitope tag (11).pIL30-URA3 is a URA3 CEN plasmid with the FG[Ty]-lacZ reportergene (17). pMW2 is a URA3 CEN plasmid for expressing Ras2-V¹⁹ (35). We isolated pNC544 from the genomic overexpression pYES-Rlibrary (9). This isolate expresses the Ste11^296-717 variant from the GAL promoter.

Yeast genetic procedures, media, and strain constructions. Standard yeast genetic procedures and various media were as described previously (12, 31). Yeast transformations weredone by the lithium acetate method or electroporation (3, 10).Gene replacements were done according to the method of Rothstein(29).

The strains used in this study and their genotypes are listed in Table 1. Diploid strain SC110, which is heterozygous forthe ash1- $Delta$ 1::hisG-URA3-hisG allele, was made by gene replacementin strain L5783 with the EcoRI-SphI fragment of pNC409. Haploidstrains SC112, SC113, and SC114 are ash1- $Delta$ 1::hisG-URA3-hisG orASH1 meiotic segregants from strain SC110. Strains SC121 and SC122are ash1- $Delta$ 1::hisG derivatives of SC112 and SC113, respectively,that were isolated by the 5-fluoro-orotic acid method (1).Diploid strain SC125 was constructed by mating haploid strainsSC121 and SC122. Diploid strain SC126 was constructed by transformingstrain SC125 with the GFP-linker-ASH1 allele contained on theNheI fragment of pNC514. The transformation resulted in the integrationof GFP-ASH1 5' to the ash1- $Delta$ 1::hisG sequence on one chromosome.Strains SC127 and SC128, which have the leu2- $Delta$ 1 allele, were constructedby targeting HpaI-linearized pNC527 to LEU2 and then identifyingLEU2 "popouts" among 5-fluoro-orotic acid-resistant isolates thatlost the adjacent URA3 sequence. Strains SC135 and SC136 are ste12 $Delta$ ::LEU2derivatives of SC127 and SC128, respectively. They were constructedby gene replacement with the SacI-SphI fragment of pSUL16. Diploidstrain SC137, which is homozygous for ste12 $Delta$ ::LEU2, was constructedby first transforming SC135 and SC136 with the STE12 replicatingplasmid pNC247, mating the resulting transformants, and then curingthe diploid strain of pNC247.

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TABLE 1. S. cerevisiae strains^a

Assays for the yeast pseudohyphal form. The qualitative growth assay for filament formation in colonies of diploid cells was performed as described previously (11,12). Essentially, cells were streaked onto solid synthetic low-ammoniadextrose medium (SLAD) and incubated at 30°C for the specifiedperiods of time, and representative colonies were photographed.A filament is defined as a chain of attached cells that projectsaway from the colony.

Invasive-growth assays were done as described by Roberts and Fink (27). Essentially, cells were streaked onto plates ofcomplete medium (yeast extract-peptone-dextrose [YPD]), with caretaken to avoid scratching the agar surface. After incubation ofplates at 30°C for 4 days and at room temperature for 1 day, theculture plates were washed with a gentle stream of deionized water.This treatment washes noninvasive cells off of the plate but leavesthe invasive cells behind as a visible residue in the agar surface.

Diploid pseudohyphal-form cells were distinguished from yeast form cells based on cell shape and budding pattern. After 3days of growth on SLAD at 30°C, colonies were scraped from platesand suspended in water. Analysis of cell elongation was performedby microscopic examination and visual estimation of the length-to-widthratios (l/w) of at least 100 cells. This inspection easily distinguishedthree categories of cells: round yeast form cells (l/w, ~1), ovalcells (l/w, 1 to 2), and elongated pseudohyphal-form cells (l/w,>2). Bud scar staining of the suspended cells was done with calcofluorwhite (Fluorescent Brightener no. 28 F6259; Sigma) as describedby Mosch and Fink (21). A unipolar budding pattern was assignedto cells with two or more bud scars at the same pole. A bipolarbudding pattern was assigned to cells with one or more scars atopposite poles.

The filamentous growth reporter gene, FG[Ty]-lacZ (pIL30-URA3), was used to monitor transcriptional activation during pseudohyphalgrowth that is mediated by the MAPK activation cascade and Ste12.For these experiments, activities of the lacZ reporter gene product, $beta$ -galactosidase, were compared by using whole-cell protein extractsprepared from yeast form and pseudohyphal-form cultures. Culturesof yeast form cells were grown in YPD to a density of 1 × 10⁷ to 2 × 10⁷ cells/ml at 30°C. Cells were harvested by centrifugation, washed,and suspended to a density of 4 × 10⁸ to 5 × 10⁸ cells/ml for cell lysis. Pseudohyphal-form cells were grown onsolid SLAD for 3 days at 30°C. Cells were scraped from the surfaceof the plates, washed, and suspended to a density of 4 × 10⁸ to 5 × 10⁸ cells/ml for cell lysis. Cell lysis by the glass bead methodand quantitative $beta$ -galactosidase assays were done as describedpreviously except that the optical density (OD) at 420 nm wasdetermined by using a fixed end point after addition of Na₂CO₃(26).

Microscopy. Imaging of colonies was routinely done with a Zeiss Axiophot microscope with a 10× objective (Plan-NEOFLUAR 10/0.30). Imageswere recorded either by video with a Sony DXC-760MD camera orby photography on TMAX 400 film. Fluorescence imaging of GFP-Ash1was done on a Microphot FXA with a 60× objective (Plan-APO 60/1.4)and collected with a cooled charge-coupled device camera (C4880-Hamamatsu)as described previously (36, 37). To obtain suitable colonies,thin slabs of SLAD medium were made directly on microscope slides.One hundred to 200 cells were dispersed on these slides, coveredwith a coverslip, and visualized after 12 h at 30°C.

	RESULTS

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Phenotypes of strains lacking or overexpressing Ash1. Ash1 was first uncovered in genetic screens that revealed its role in mating-type switching. Because nonswitching diploidcells also express Ash1, we anticipated that it would have additionalfunctions (13, 33). To test whether Ash1 might be needed fordiploid functions such as sporulation or pseudohyphal differentiation,we constructed a strain that is homozygous for a complete deletionof the gene. Diploid cells completely lacking Ash1 grow normally.Therefore, Ash1 is nonessential for the viability of either diploidor haploid cell types (13, 33). Because strains lacking orexpressing Ash1 showed the same sporulation efficiency and sporeviability, Ash1 does not appear to have an essential role in sporulation(data not shown). However, Ash1 is essential for pseudohyphalgrowth. Hypha-like projections, or filaments, radiating from colonieson solid SLAD are the consequence of the life cycle transitionof diploid cells to a pseudohyphal form. Colonies of wild-typecells made such filaments after 2 days of growth on SLAD (Fig.1B, ASH1/ASH1). Colonies lacking Ash1 did not form pseudohyphalfilaments, while the strain overexpressing Ash1 made more filamentsthan did the wild-type reference strain (Fig. 1B, ash1 $Delta$ /ash1 $Delta$ and 2µm ASH1).

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FIG. 1. Role of Ash1 in filamentous growth. (A) Invasive growth. Haploid ASH1 [SC114(pRS426)], ash1 $Delta$ [SC112(pRS426)], and 2µm ASH1 [SC112(pAS163)] strains were grown on a YPD plate for 5 days. Photographs show patches before and after the plate was washed with water. (B) Pseudohyphal-colony formation. Diploid ASH1/ASH1 [L5783(pRS426)], ash1 $Delta$ /ash1 $Delta$ [SC125(pRS426)], and 2µm ASH1 [SC125(pAS163)] strains were streaked out on nitrogen starvation medium (SLAD) and grown for 2.5 days at 30°C. Photographs show representative colonies of each strain.

Cells comprising the filaments of diploid pseudohyphal colonies differ in morphology and budding pattern from yeast form cells.Whereas yeast form cells are round or ellipsoidal and have a bipolarbudding pattern, pseudohyphal-form cells are elongated and havea unipolar budding pattern. Therefore, to characterize Ash1 effectsat the cellular level, we compared the cell morphologies and buddingpatterns of ASH1, 2µm ASH1, and ash1 $Delta$ diploid strains (Table 2).To score these parameters on individual cells, colonies were washedoff SLAD plates after 2 days growth at 30°C and suspended in waterfor microscopic examination. The ratio of elongated to round andoval cells found in the ASH1 colonies is 0.31 and presumably reflectsthe mixture of yeast and pseudohyphal-form cells comprising thecolonies. The unipolar-to-bipolar budding pattern ratio (0.3)also reflects a mixture of yeast and pseudohyphal-form cells.Notably, the fractions of elongated cells (0.57) and cells witha unipolar budding pattern (0.70) are greater in colonies overexpressingAsh1 than in colonies of wild-type cells. This outcome is anticipated,because the 2µm ASH1 strain has a larger number of filaments emanatingfrom the core of yeast form cells (Fig. 1B). By contrast, coloniesof cells lacking Ash1 have an insignificant fraction of elongatedcells (0.05) and also a lower fraction of cells with a unipolarbudding pattern (0.2). These defects of the ash1 $Delta$ /ash1 $Delta$ mutantare consistent with the absence of colony filaments that are characteristicof pseudohyphal-form cells (Fig. 1B).

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TABLE 2. Shapes and budding patterns of ASH1, 2µm ASH1, and ash1 $Delta$ strains^a

Haploid cells undergo a related invasive-growth response which causes cells to grow into the agar surface. When patches ofwild-type cells on plates are washed off with a stream of water,a residue of embedded cells typical of invasive growth is leftbehind (Fig. 1A, ASH1). By contrast, patches of the strain lackingAsh1 left little or no residue (Fig. 1A, ash1 $Delta$ ). Furthermore,overexpression of Ash1 apparently enhanced invasive growth, becausethere was more of a residue than for the reference wild-type strain(Fig. 1A, 2µm ASH1). These findings establish that Ash1 also hasan essential role in invasive growth.

Relationship of Ash1 to other components of the pseudohyphal-response pathway. Single deletions that eliminate the sequentially acting protein kinases Ste20, Ste11, and Ste7 or the transcription factorSte12 block the transition to a pseudohyphal form (Fig. 2A, 2µmvector) (18, 27). It is well established that Ste12 acts downstreamof the kinase cascade and that its overproduction suppresses thepseudohyphal defect in different ste $Delta$ mutant strains (Fig. 2A,2µm STE12) (18, 27). To test whether Ash1 has a similar relationshipto the MAPK cascade, we tested whether Ash1 overexpression wouldallow filament formation in the same ste $Delta$ mutant strains. Overexpressionof Ash1 (2µm ASH1) restored pseudohyphal growth to the strainsthat lack Ste7 or Ste12 (Fig. 2A, ste7 $Delta$ or ste12 $Delta$ ). Colonies ofcells lacking Ste11 but overexpressing Ash1 also made hypha-likeprojections after 1 day of growth on SLAD (Fig. 2A, 2µm ASH, ste11 $Delta$ ).However, the response was transient, because after 2 days of growth,the colony was overtaken by yeast form cells (data not shown).

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FIG. 2. Effects of Ash1 overexpression on pseudohyphal-colony formation in strains with deletions of MAPK activation pathway components. (A) ste20 $Delta$ /ste20 $Delta$ (HLY492), ste11 $Delta$ /ste11 $Delta$ (HLY506), ste7 $Delta$ /ste7 $Delta$ (HLY351), and ste12 $Delta$ /ste12 $Delta$ (HLY352) diploid strains containing either vector (pRS426), 2µm ASH1 (pAS163), or 2µm STE12 (pNC248) were grown on SLAD. (B) The ste20 $Delta$ /ste20 $Delta$ strain (HLY492) containing either vector (pRS426) or GAL-ASH1 (pNC543) was streaked out on nitrogen starvation medium containing galactose. Photographs show representative colonies of each strain after 2 (A) or 3 (B) days of growth at 30°C.

By contrast, overexpression of Ash1 from a high-copy-number plasmid was insufficient to promote pseudohyphal growth at anytime after incubation on SLAD in the strain lacking Ste20 (Fig.2A, 2µm ASH1, ste20 $Delta$ ). In this regard, Ash1 acts differently fromSte12, because overexpression of Ste12 from a high-copy-numberplasmid does allow pseudohyphal growth in the strain lacking Ste20(Fig. 2A, 2µm STE12, ste20 $Delta$ ). Interestingly, ectopic expressionof Ash1 from the GAL1 promoter bypassed the need for Ste20 (Fig.2B). This condition may be permissive simply because there isa larger amount of Ash1 produced from the GAL1 promoter. Alternatively,the heterologous promoter may allow a broader spatial and temporalpattern of Ash1 expression than can be achieved from its own promoter.(See "Localization and expression of Ash1" below). Nevertheless,these analyses show that Ash1 function can bypass the need forthe kinase cascade and Ste12. This outcome suggests that Ash1acts downstream or independently of the MAPK cascade.

Constitutive activation of the MAPK cascade by expression of a gain-of-function STE11 allele (STE11-4) or bypassing the cascadewith GAL-STE12 has been reported to enhance pseudohyphal growth(18). Therefore, such alleles can be used for epistasis teststhat are the reciprocal of those done with the deletion strains.We made use of the constitutive Ste11 variant Ste11^296-717 and 2µm Ste12 overexpression to artificially induce pseudohyphalgrowth and then test whether the response would be blocked ina strain devoid of Ash1 (ash1 $Delta$ /ash1 $Delta$ ). Colonies of diploid strainsoverexpressing Ste12 (2µm STE12) and either lacking or expressingAsh1 made similar filaments on SLAD (Fig. 3A). Ste11^296-717-promoted pseudohyphal growth was also the same for strains lackingor expressing Ash1 (Fig. 3B). These results support the deductionthat Ash1 functions separately from Ste12 and the MAPK activationcascade.

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FIG. 3. Comparison of ASH1 and ash1 $Delta$ mutant strains for pseudohyphal-colony formation promoted by hyperactivation of the pathway. (A) ASH1/ASH1 (L5783) and ash1 $Delta$ /ash1 $Delta$ (SC125) diploid strains containing 2µm STE12 (pNC248) were grown on SLAD for 2 days at 30°C. (B) ASH1/ASH1 (L5783) and ash1 $Delta$ /ash1 $Delta$ (SC125) diploid strains containing GAL-STE11^296-717 (pNC544) were grown on nitrogen starvation medium containing galactose for 1 day at 30°C. Photographs are of representative colonies.

The Ste12 transcription factor is thought to regulate the expression of genes that are critical for pseudohyphal growth. Althoughno pseudohyphal gene that is under Ste12 control has been identified,the Ste12-dependent response element from the yeast transposonTy1 is responsive to conditions that promote pseudohyphal growth(22). If Ash1 functions separately from Ste12, transcriptionalactivation of the Ty1 UAS by nitrogen starvation should be unaffectedin cells lacking Ash1. To test this prediction, we measured expressionof a pseudohyphal reporter gene (FG[Ty]-lacZ) in homozygous ASH1and ash1 $Delta$ strains (22). Log-phase cultures (YPD) of the strainsexpressing or lacking Ash1 produced the same background amountof reporter gene product ( $beta$ -galactosidase activity, 12 ± 6 and15 ± 3 units of $beta$ -galactosidase activity [milli-OD/min/mg], respectively).Nitrogen-deprived cultures (SLAD) of cells expressing Ash1 produced~15-fold-larger amounts of reporter gene product (175 ± 18 milli-OD/min/mg).Under these conditions (SLAD), cells lacking Ash1 similarly inducedreporter gene expression (140 ± 3 milli-OD/min/mg). These resultsshow that Ash1 is not required for Ste12 function.

Because Ash1 and Ste12 appear to function separately in the pseudohyphal response, we expected that the phenotype of the doublemutant would be more severe than that of either single mutant.Some pseudohyphae emanate from patches of homozygous ste12 $Delta$ orash1 $Delta$ strains after 4 days of growth on SLAD, showing that neithersingle mutation completely blocks filament formation (Fig. 4Band C). By contrast, the double homozygous mutant (ste12 $Delta$ ash1 $Delta$ )is devoid of any filaments after the same incubation period (Fig.4D). No filaments were apparent in the double-mutant strain evenafter 10 days on SLAD, which is longest incubation time that wehave monitored (data not shown). The additive effect of Ash1 andSte12 supports a model that assigns Ash1 a role in the pseudohyphalresponse separate from that of Ste12 and the MAPK activation cascade.

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FIG. 4. Synthetic pseudohyphal-colony phenotype of ash1 $Delta$ and ste12 $Delta$ mutants. ASH1/ASH1 STE12/STE12 [L5783(pRS426)], ash1 $Delta$ /ash1 $Delta$ STE12/STE12 [SC125(pRS426)], ASH1/ASH1 ste12 $Delta$ /ste12 $Delta$ [HLY352(pRS426)], and ash1 $Delta$ /ash1 $Delta$ ste12 $Delta$ /ste12 $Delta$ [SC137(pRS426)] diploid strains were patched onto SLAD and grown at 30°C for 4 days. Photographs show a representative region of an edge from each patch.

Relationship of Ste12 and Ash1 to other regulators of pseudohyphal growth. Expression of an activated variant of Ras2, Ras2-V¹⁹, has been reported to induce pseudohyphal growth (12). Additionally,strains that express Ras2-V¹⁹ show an eightfold increase in FG[Ty]-lacZ reporter gene expressioncompared with a reference Ras2 strain. Because this effect onFG[Ty]-lacZ expression is blocked in mutants that lack Ste20,Ste11, Ste7, or Ste12, it has been proposed that Ras2 functionsupstream of the MAPK activation cascade and Ste12 (22). If Ras2function is mediated solely by Ste12, this model predicts thatan absence of Ste12 should also block pseudohyphal-filament formationpromoted by Ras2-V¹⁹. However, we find that cells expressing Ras2-V¹⁹ but lacking Ste12 still form pseudohyphal filaments (Fig. 5A,ASH1 ste12 $Delta$ ). This result opens the possibility that componentsseparate from the MAPK cascade might also mediate Ras2-V¹⁹ effects on pseudohyphal growth. The results of our epistasisanalyses suggested that Ash1 functions separately from Ste12 andhypothetically could fulfill such a role. To test this possibility,we compared pseudohyphal-filament formation promoted by Ras2-V¹⁹ in homozygous ash1 $Delta$ single-mutant and ash1 $Delta$ ste12 $Delta$ double-mutantdiploid strains. While the absence of Ash1 alone was insufficientto block Ras2-V¹⁹-promoted pseudohypha formation, the absence of both Ash1 andSte12 did block the effect (Fig. 5A, ash1 $Delta$ STE12 and ste12 $Delta$ ash1 $Delta$ ).These results are consistent with a model in which Ste12 an Ash1have a compensatory role in mediating the Ras2-dependent signal(s)for pseudohyphal growth.

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FIG. 5. Comparison of ash1 $Delta$ and ste12 $Delta$ single- or double-mutant strains for pseudohyphal-colony formation promoted by hyperactivation of the pathway. ASH1/ASH1 STE12/STE12 (L5783), ash1 $Delta$ /ash1 $Delta$ STE12/STE12 (SC125), ASH1/ASH1 ste12 $Delta$ /ste12 $Delta$ (HLY352), and ash1 $Delta$ /ash1 $Delta$ ste12 $Delta$ /ste12 $Delta$ (SC137) diploid strains containing either RAS2-V¹⁹ (pMW2) (A) or 2µm PHD1 (pCG37) (B) were grown on SLAD for 2 days at 30°C. Photographs are of representative colonies.

Phd1 is a presumed transcription factor that is also implicated in the regulation of pseudohyphal growth. While the absenceof Phd1 is insufficient to prevent pseudohyphal growth, its overexpressionenhances pseudohyphal growth (11). Additionally, overexpressionof Phd1 can suppress the pseudohyphal-growth defect in a strainthat lacks Ste12 (Fig. 5B, ASH1 ste12 $Delta$ ) (21). We were curiousto learn how Phd1 overexpression would affect pseudohyphal growthof homozygous ash1 $Delta$ single- and ash1 $Delta$ ste12 $Delta$ double-mutant strains.Phd1 overexpression promoted vigorous pseudohyphal growth in thestrain lacking Ash1 and allowed some pseudohyphal growth evenin the strain lacking both Ash1 and Ste12 (Fig. 5B, ash1 $Delta$ STE12and ash1 $Delta$ ste12 $Delta$ ). Unlike Ras2-V¹⁹, overproduction of Phd1 can act independently of both Ste12 andAsh1 to promote pseudohyphal growth.

Localization and expression of Ash1. Ash1 localizes to the nuclei of daughter cells in both haploid and diploid yeast form cells (13, 33). To learn if Ash1also localizes to the nuclei of pseudohyphal-form daughter cells,we constructed a GFP-tagged version of Ash1. The allele encodingthe fusion protein was integrated at the ASH1 locus of the homozygousash1 $Delta$ diploid strain. The GFP-Ash1 fusion fully complemented thepseudohyphal-growth defect of the ash1 $Delta$ /ash1 $Delta$ strain. Fluorescentand differential interference contrast photographs of over 20pseudohyphal mother-daughter pairs were analyzed. Similarly tothe case in yeast form cells, GFP-Ash1 localized exclusively tothe nuclei of pseudohyphal daughter cells (Fig. 6A).

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FIG. 6. Localization of GFP-Ash1 during pseudohyphal growth. Fluorescent (A and C) and differential interference contrast (B and D) views of cells are shown. (A and B) Diploid strain SC126, which is heterozygous for GFP-ASH1, grown on SLAD for 12 h. Insets show a mother-daughter pair of yeast form cells of the same diploid strain grown on SD-Ura. (C and D) Diploid ash1 $Delta$ /ash1 $Delta$ strain SC125 with pNC513, which expresses GFP-ASH1 from the 2µm vector pRS426, grown on SLAD for 12 h. m, mother cell; d, daughter cell.

The intensity of the signal in pseudohyphal cells on SLAD differed little from that observed with yeast form cells grown onnitrogen-rich medium (Fig. 6A, inset). This result is consistentwith our finding that steady-state amounts of Ash1 mRNA were notgreater in cultures grown on SLAD than in those grown on liquidnitrogen-rich medium (data not shown). Based on the size and positionof nuclei in the cells expressing Ash1, it appears that Ash1 becomesexpressed late in M phase, similar to what has been observed foryeast form haploid cells (13, 33).

Also similar to what has been reported for yeast form cells, overexpression of Ash1 in pseudohyphal cells leads to a moresymmetric localization pattern (Fig. 6C). Because overexpressionof Ash1 is not inhibitory to pseudohyphal growth, the presenceof Ash1 in mother cells is not disruptive (Fig. 1B and 6D). Thisresult provides additional support for the idea that Ash1 is formallya positive regulator of pseudohyphal growth. Because of its positiveregulatory role and the finding that under normal conditions Ash1is detectable only in daughter cells, we conclude that there mustbe a daughter cell-specific function needed for the transitionfrom yeast to pseudohyphal-form cells.

	DISCUSSION

Top Abstract Introduction Materials & Methods Results Discussion References

Pseudohyphal differentiation of S. cerevisiae requires Ash1. Ash1 deletion mutants are defective for pseudohyphal and invasive growth. These defects establish that Ash1 is formally apositive regulator of filamentous growth. In this regard, therole of Ash1 in pseudohyphal-form growth is different from itsnegative regulatory role in mating-type switching (13, 33).Ash1 has a zinc finger-like domain related to that of the GATAfamily of transcription factors (24, 33). This relationshipand the nuclear location of Ash1 suggested that it is most likelya transcriptional regulator. This view encouraged speculationthat Ash1 might negatively regulate mating-type switching by bindingdirectly to sequences in the HO promoter and repressing its transcriptionor by binding to and interfering with the Swi5 transcriptionalactivator of HO (13, 33). The contrasting role for Ash1 inpseudohyphal differentiation suggests that similar to other membersof GATA family, Ash1 might function as both an activator and arepressor of transcription (24). On the other hand, if Ash1functions only as a transcriptional repressor, its role in pseudohyphaldifferentiation would involve repression of a negative regulatorof the process.

Relationship of Ash1 to other known regulators of the pseudohyphal process. Nitrogen starvation stimulates the transition of S. cerevisiae to a pseudohyphal form. This signal is mediated, at least inpart, by a MAPK activation cascade and its downstream transcriptionfactor, Ste12 (18) (Fig. 7). Signaling through this branch ofthe pathway involves the monomeric G protein Cdc42, as well asthe 14-3-3 homologs Bmh1 and Bmh2, which associate with Ste20(22, 28). More recently, Gpa2-G $alpha$ has been shown to be essentialfor pseudohyphal growth. Gpa2 and also Ras2 appear to regulatea separate branch of the nitrogen-sensing pathway that leads toincreases in cyclic AMP levels (16, 20). Ras2 has also beenimplicated as an upstream regulator of the MAPK cascade and Ste12.This suggestion is based on the finding that an activated Ras2variant (Ras2-V¹⁹) stimulates expression of a pseudohyphal reporter gene (FG[Ty]-lacZ)and that this effect depends on components of the MAPK cascade(22). As such, Ras2 could coordinate activities of the MAPKand cyclic AMP branches of the pseudohyphal signaling network.

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FIG. 7. Model for the pseudohyphal-response pathway. The diagram shows the postulated relationship of signal transmission components that function after the starvation signal(s) for induction of pseudohyphal growth. Arrows indicate activation or stimulation. Lines with bars indicate repression or inhibition. See the text for discussion of the evidence suggesting these relationships.

The results of our epistasis analyses are consistent with the deduction that Ash1 acts separately from the MAPK activationcascade and Ste12 but is still downstream from Ras2 (Fig. 7).Furthermore, Ste12 and Ash1 have additive effects in the response,because a deletion of both is needed to completely block normalor Ras2-V¹⁹-promoted filamentation. Additional support for the view thatAsh1 acts separately from Ste12 comes from the finding that thepresence or absence of Ash1 has no effect on expression of a Ste12-dependentpseudohyphal reporter gene (FG[Ty]-lacZ).

Our epistasis analyses also suggest that Ste20 may have roles in the pseudohyphal response in addition to activation of theMAPK cascade. This deduction stems from the observation that moderateoverexpression of Ash1 can bypass deletion mutants of the MAPKactivation cascade but not of Ste20. One possibility is that Ste20regulates both the Ash1 and Ste12 branches of the pathway (22,28) (Fig. 7). Alternatively, Ste20 could control morphogeneticalterations that while not essential, nevertheless facilitatepseudohyphal growth. This postulated dual role would be analogousto the dual role that has recently been uncovered for Ste20 inmating differentiation (25).

Although Ste12 and Ash1 appear to have separate and additive functions, we nevertheless found that hyperactivation of Ste12or Ash1, either by their overproduction or by Ras2-V¹⁹, can bypass the need of one for the other. This interesting compensatoryrelationship is not unique to Ash1 and Ste12. Phd1, another presumedtranscription factor, also appears to have functions that areadditive with Ste12. Similar to our results with Ash1, filamentformation was blocked completely only in strains that lacked bothSte12 and Phd1 (19). Also similar to our findings, overexpressionof Phd1 compensates for the absence of Ste12 (19). Because overexpressionof Phd1 also promotes filamentation in strains lacking both Ash1and Ste12, Phd1 may be on yet another arm of the pseudohyphalsignaling network.

The genes required for pseudohyphal growth that are regulated by these presumed or actual transcription factors have yet tobe identified. Nevertheless, the ability of Ash1, Ste12, and Phd1to compensate for one another suggests some interesting possibilitiesfor regulation of pseudohyphal-gene expression. One possibilityis that the three transcription factors regulate the same subsetof genes that are essential for filamentous growth. Accordingto this model, the critical genes are expressed optimally onlywhen the three transcription factors and the stimuli to whichthey respond are present. Residual expression of these genes whenany two of the transcription factors are present is sufficientto support the amount of filamentation seen with the single-mutantstrains. Conversely, hyperactivation of any one transcriptionfactor could increase expression of the critical genes to levelssufficient for filamentation. It is equally feasible that Ste12,Ash1, and Phd1 control separate sets of genes whose products havepartially overlapping functions. In this case, hyperactivationof any of the transcription factors could lead to overexpressionof one or the other set and again allow adequate activity to supportfilamentous growth.

Daughter cell-specific functions in pseudohyphal growth. Similarly to the case in yeast form cells, Ash1 localizes to daughter cells of pseudohyphal-form yeast, revealing a differencebetween daughter and mother cells. Because Ash1 mutants do notform pseudohyphae, the implicit daughter-specific functions areessential for filamentous growth. In yeast form cells Ash1 expressionis restricted to daughter cells in late anaphase and G₁ (13,33). Based on the size and position of the nuclei in cells expressingAsh1, it appears that Ash1 has a similar cell cycle restrictionin its expression during pseudohyphal growth. Because of thesespatial and temporal restrictions on Ash1 expression, the geneproducts subject to its regulatory control must be critical forpseudohyphal development only in the apical cells of the colonyduring this window of the cell cycle. An important implicationof these restrictions is that the pseudohyphal fate is establishedsolely by daughter cells. Once the transition from yeast to pseudohyphalform is made, cells appear to maintain the pseudohyphal form independentlyof Ash1 and perhaps other regulators of this growth mode. Fullcomprehension of what role Ash1 might have in establishing thepseudohyphal fate awaits identification of its targets.

	ACKNOWLEDGMENTS

This research was supported by Public Health grant GM-39852 from the National Institutes of Health.

We thank H. Liu and G. Fink for providing yeast strains and pIL30 and pCG37 plasmids, A. Sil and I. Herskowitz for providingpAS163, J. Pringle for providing pKS+GFP, M. Ward and S. Garrettfor providing pMW2, and S. Ramer and S. Elledge for providingthe pYES-R yeast genomic DNA expression library. We are also gratefulto E. D. Salmon and E. Yeh for use of the microscope facilityand for sharing their expertise with us and to R. Duronio, J.Heitman, and S. Kron for critical reading of the manuscript andhelpful discussions.

	FOOTNOTES

^* Corresponding author. Mailing address: Department of Biochemistry and Biophysics CB#7260, University of North Carolina, ChapelHill, NC 27599-7260. Phone: (919) 966-3628. Fax: (919) 966-4812.E-mail: errede{at}nun.oit.unc.edu.

REFERENCES

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

1. Alani, E., L. Cao, and N. Kleckner. 1987. A method for gene disruption that allows repeated use of URA3 selection in the construction of multiply disrupted yeast strains. Genetics 116:541-545[Abstract/Free Full Text].

2. Baur, M., R. K. Esch, and B. Errede. 1997. Cooperative binding interactions required for function of the Ty1 sterile responsive element. Mol. Cell. Biol. 17:4330-4337[Abstract].

3. Becker, D. M., and L. Guarente. 1990. High efficiency transformation of yeast by electroporation. Methods Enzymol. 194:182-187.

4. Bobola, N., R.-P. Jansen, T. H. Shin, and K. Nasmyth. 1996. Asymmetric accumulation of Ash1p in postanaphase nuclei depends on a myosin and restricts yeast mating-type switching to mother cells. Cell 84:699-709[Medline].

5. Cade, R., and B. Errede. 1994. MOT2 encodes a negative regulator of gene expression that affects basal expression of pheromone-responsive genes in Saccharomyces cerevisiae. Mol. Cell. Biol. 14:3139-3149[Abstract/Free Full Text].

6. Cook, J. G., L. Bardwell, S. J. Kron, and J. Thorner. 1996. Two novel targets of the MAP kinase Kss1 are negative regulators of invasive growth in Saccharomyces cerevisiae. Genes Dev. 10:2831-2848[Abstract/Free Full Text].

7. DeVirgilio, C., D. J. DeMarini, and J. R. Pringle. 1996. SPR28, a sixth member of the septin gene family in Saccharomyces cerevisiae that is expressed specifically in sporulating cells. Microbiology 142:2897-2905[Abstract].

8. Dolan, J. W., C. Kirkman, and S. Fields. 1989. The yeast Ste12 protein binds to the DNA sequence mediating pheromone induction. Proc. Natl. Acad. Sci. USA 86:5703-5707[Abstract/Free Full Text].

9. Elledge, S. J., J. T. Mulligan, S. W. Ramer, M. Spottswood, and R. Davis. 1991. $lambda$ YES: a multifunctional cDNA expression vector for the isolation of genes by complementation of yeast and Escherichia coli mutations. Proc. Natl. Acad. Sci. USA 88:1731-1735[Abstract/Free Full Text].

10. Gietz, D., J. A. St. Jean, R. A. Woods, and R. H. Schiestl. 1992. Improved method for high efficiency transformation of intact yeast cells. Nucleic Acids Res. 20:1425[Free Full Text].

11. Gimeno, C. J., and G. R. Fink. 1994. Induction of pseudohyphal growth by overexpression of PHD1, a Saccharomyces cerevisiae gene related to transcriptional regulators of fungal development. Mol. Cell. Biol. 14:2100-2112[Abstract/Free Full Text].

12. Gimeno, C. J., P. O. Ljungdahl, C. A. Styles, and G. R. Fink. 1992. Unipolar cell divisions in the yeast S. cerevisiae lead to filamentous growth: regulation by starvation and RAS. Cell 68:1077-1090[Medline].

13. Jansen, R.-P., C. Dowzer, C. Michaelis, M. Galova, and K. Nasmyth. 1996. Mother cell-specific HO expression in budding yeast depends on the unconventional myosin Myo4p and other cytoplasmic proteins. Cell 84:687-697[Medline].

14. Kron, S. J., and N. A. Gow. 1995. Budding yeast morphogenesis: signalling, cytoskeleton, and cell cycle. Curr. Opin. Cell Biol. 7:845-855[Medline].

15. Kron, S. J., C. A. Styles, and G. R. Fink. 1994. Symmetric cell division in pseudohyphae of the yeast Saccharomyces cerevisiae. Mol. Biol. Cell 5:1003-1022[Abstract].

16. Kubler, E., H.-U. Mosch, S. Rupp, and M. P. Lisanti. 1997. Gpa2p, a G-protein alpha-subunit, regulates growth and development in Saccharomyces cerevisiae via a cAMP-dependent mechanism. J. Biol. Chem. 272:20321-20323[Abstract/Free Full Text].

17. Laloux, I., E. Jacobs, and E. Dubois. 1994. Involvement of SRE element of Ty1 transposon in TEC1-dependent transcriptional activation. Nucleic Acids Res. 22:999-1005[Abstract/Free Full Text].

18. Liu, H., C. A. Styles, and G. R. Fink. 1993. Elements of the yeast pheromone response pathway required for filamentous growth of diploids. Science 262:1741-1744[Abstract/Free Full Text].

19. Lo, H.-J., J. R. Kohler, B. DiDomenico, D. Loebenberg, A. Cacciapuoti, and G. R. Fink. 1997. Nonfilamentous C. albicans mutants are avirulent. Cell 90:939-949[Medline].

20. Lorenz, M. C., and J. Heitman. 1997. Yeast pseudohyphal growth is regulated by GPA2, a G protein alpha homolog. EMBO J. 16:7008-7018[Medline].

21. Mosch, H.-U., and G. R. Fink. 1997. Dissection of filamentous growth by transposon mutagenesis in Saccharomyces cerevisiae. Genetics 145:671-684[Abstract].

22. Mosch, H.-U., R. L. Roberts, and G. R. Fink. 1996. Ras2 signals via the Cdc42/Ste20/mitogen-activated protein kinase module to induce filamentous growth in Saccharomyces cerevisiae. Proc. Natl. Acad. Sci. USA 93:5352-5356[Abstract/Free Full Text].

23. Nasmyth, K. 1993. Regulating the HO endonuclease in yeast. Curr. Opin. Gen. Dev. 3:286-294[Medline].

24. Orkin, S. H. 1992. GATA-binding transcription factors in hematopoietic cells. Blood 80:575-581[Free Full Text].

25. Peter, M., A. M. Neiman, H.-O. Park, M. van Lohuizen, and I. Herskowitz. 1996. Functional analysis of the interaction between the small GTP binding protein Cdc42 and the Ste20 protein kinase in yeast. EMBO J. 15:7046-7059[Medline].

26. Rhodes, N., L. Connell, and B. Errede. 1990. STE11 is a protein kinase required for cell type specific transcription and signal transduction in yeast. Genes Dev. 4:1862-1874[Abstract/Free Full Text].

27. Roberts, R. L., and G. R. Fink. 1994. Elements of a single MAP kinase cascade in Saccharomyces cerevisiae mediate two developmental programs in the same cell type: mating and invasive growth. Genes Dev. 8:2974-2985[Abstract/Free Full Text].

28. Roberts, R. L., H.-U. Mosch, and G. R. Fink. 1997. 14-3-3 proteins are essential for RAS/MAPK cascade signaling during pseudohyphal development in S. cerevisiae. Cell 89:1055-1065[Medline].

29. Rothstein, R. J. 1991. Targeting, disruption, replacement, and allele rescue: integrative DNA transformation in yeast. Methods Enzymol. 101:202.

30. Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. In Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

31. Sherman, F., G. R. Fink, and J. Hicks. 1986. In Methods in yeast genetics. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.

32. Sikorski, R. S., and P. Hieter. 1989. A system of shuttle vectors and yeast host strains designed for efficient manipulation of DNA in Saccharomyces cerevisiae. Genetics 122:19-27[Abstract/Free Full Text].

33. Sil, A., and I. Herskowitz. 1996. Identification of an asymmetrically localized determinant, Ash1p, required for lineage-specific transcription of the yeast HO gene. Cell 84:711-722[Medline].

34. Tedford, K., S. Kim, D. Sa, K. Stevens, and M. Tyers. 1997. Regulation of the mating pheromone and invasive growth responses in yeast by two MAP kinase substrates. Curr. Biol. 7:228-238[Medline].

35. Ward, M. P., C. J. Gimeno, G. R. Fink, and S. Garrett. 1995. SOK2 may regulate cyclic AMP-dependent protein kinase-stimulated growth and pseudohyphal development by repressing transcription. Mol. Cell. Biol. 15:6854-6863[Abstract].

36. Yang, S. S., E. Yeh, E. D. Salmon, and K. Bloom. 1997. Identification of a mid-anaphase checkpoint in budding yeast. J. Cell Biol. 136:345-354[Abstract/Free Full Text].

37. Yeh, E., R. V. Skibbens, J. W. Cheng, E. D. Salmon, and K. Bloom. 1995. Spindle dynamics and cell cycle regulation of Dyenin in the budding yeast, Saccharomyces cerevisiae. J. Cell Biol. 130:687-700[Abstract/Free Full Text].

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1.	Alani, E., L. Cao, and N. Kleckner. 1987. A method for gene disruption that allows repeated use of URA3 selection in the construction of multiply disrupted yeast strains. Genetics 116:541-545[Abstract/Free Full Text].
2.	Baur, M., R. K. Esch, and B. Errede. 1997. Cooperative binding interactions required for function of the Ty1 sterile responsive element. Mol. Cell. Biol. 17:4330-4337[Abstract].
3.	Becker, D. M., and L. Guarente. 1990. High efficiency transformation of yeast by electroporation. Methods Enzymol. 194:182-187.
4.	Bobola, N., R.-P. Jansen, T. H. Shin, and K. Nasmyth. 1996. Asymmetric accumulation of Ash1p in postanaphase nuclei depends on a myosin and restricts yeast mating-type switching to mother cells. Cell 84:699-709[Medline].
5.	Cade, R., and B. Errede. 1994. MOT2 encodes a negative regulator of gene expression that affects basal expression of pheromone-responsive genes in Saccharomyces cerevisiae. Mol. Cell. Biol. 14:3139-3149[Abstract/Free Full Text].
6.	Cook, J. G., L. Bardwell, S. J. Kron, and J. Thorner. 1996. Two novel targets of the MAP kinase Kss1 are negative regulators of invasive growth in Saccharomyces cerevisiae. Genes Dev. 10:2831-2848[Abstract/Free Full Text].
7.	DeVirgilio, C., D. J. DeMarini, and J. R. Pringle. 1996. SPR28, a sixth member of the septin gene family in Saccharomyces cerevisiae that is expressed specifically in sporulating cells. Microbiology 142:2897-2905[Abstract].
8.	Dolan, J. W., C. Kirkman, and S. Fields. 1989. The yeast Ste12 protein binds to the DNA sequence mediating pheromone induction. Proc. Natl. Acad. Sci. USA 86:5703-5707[Abstract/Free Full Text].
9.	Elledge, S. J., J. T. Mulligan, S. W. Ramer, M. Spottswood, and R. Davis. 1991. $lambda$ YES: a multifunctional cDNA expression vector for the isolation of genes by complementation of yeast and Escherichia coli mutations. Proc. Natl. Acad. Sci. USA 88:1731-1735[Abstract/Free Full Text].
10.	Gietz, D., J. A. St. Jean, R. A. Woods, and R. H. Schiestl. 1992. Improved method for high efficiency transformation of intact yeast cells. Nucleic Acids Res. 20:1425[Free Full Text].
11.	Gimeno, C. J., and G. R. Fink. 1994. Induction of pseudohyphal growth by overexpression of PHD1, a Saccharomyces cerevisiae gene related to transcriptional regulators of fungal development. Mol. Cell. Biol. 14:2100-2112[Abstract/Free Full Text].
12.	Gimeno, C. J., P. O. Ljungdahl, C. A. Styles, and G. R. Fink. 1992. Unipolar cell divisions in the yeast S. cerevisiae lead to filamentous growth: regulation by starvation and RAS. Cell 68:1077-1090[Medline].
13.	Jansen, R.-P., C. Dowzer, C. Michaelis, M. Galova, and K. Nasmyth. 1996. Mother cell-specific HO expression in budding yeast depends on the unconventional myosin Myo4p and other cytoplasmic proteins. Cell 84:687-697[Medline].
14.	Kron, S. J., and N. A. Gow. 1995. Budding yeast morphogenesis: signalling, cytoskeleton, and cell cycle. Curr. Opin. Cell Biol. 7:845-855[Medline].
15.	Kron, S. J., C. A. Styles, and G. R. Fink. 1994. Symmetric cell division in pseudohyphae of the yeast Saccharomyces cerevisiae. Mol. Biol. Cell 5:1003-1022[Abstract].
16.	Kubler, E., H.-U. Mosch, S. Rupp, and M. P. Lisanti. 1997. Gpa2p, a G-protein alpha-subunit, regulates growth and development in Saccharomyces cerevisiae via a cAMP-dependent mechanism. J. Biol. Chem. 272:20321-20323[Abstract/Free Full Text].
17.	Laloux, I., E. Jacobs, and E. Dubois. 1994. Involvement of SRE element of Ty1 transposon in TEC1-dependent transcriptional activation. Nucleic Acids Res. 22:999-1005[Abstract/Free Full Text].
18.	Liu, H., C. A. Styles, and G. R. Fink. 1993. Elements of the yeast pheromone response pathway required for filamentous growth of diploids. Science 262:1741-1744[Abstract/Free Full Text].
19.	Lo, H.-J., J. R. Kohler, B. DiDomenico, D. Loebenberg, A. Cacciapuoti, and G. R. Fink. 1997. Nonfilamentous C. albicans mutants are avirulent. Cell 90:939-949[Medline].
20.	Lorenz, M. C., and J. Heitman. 1997. Yeast pseudohyphal growth is regulated by GPA2, a G protein alpha homolog. EMBO J. 16:7008-7018[Medline].
21.	Mosch, H.-U., and G. R. Fink. 1997. Dissection of filamentous growth by transposon mutagenesis in Saccharomyces cerevisiae. Genetics 145:671-684[Abstract].
22.	Mosch, H.-U., R. L. Roberts, and G. R. Fink. 1996. Ras2 signals via the Cdc42/Ste20/mitogen-activated protein kinase module to induce filamentous growth in Saccharomyces cerevisiae. Proc. Natl. Acad. Sci. USA 93:5352-5356[Abstract/Free Full Text].
23.	Nasmyth, K. 1993. Regulating the HO endonuclease in yeast. Curr. Opin. Gen. Dev. 3:286-294[Medline].
24.	Orkin, S. H. 1992. GATA-binding transcription factors in hematopoietic cells. Blood 80:575-581[Free Full Text].
25.	Peter, M., A. M. Neiman, H.-O. Park, M. van Lohuizen, and I. Herskowitz. 1996. Functional analysis of the interaction between the small GTP binding protein Cdc42 and the Ste20 protein kinase in yeast. EMBO J. 15:7046-7059[Medline].
26.	Rhodes, N., L. Connell, and B. Errede. 1990. STE11 is a protein kinase required for cell type specific transcription and signal transduction in yeast. Genes Dev. 4:1862-1874[Abstract/Free Full Text].
27.	Roberts, R. L., and G. R. Fink. 1994. Elements of a single MAP kinase cascade in Saccharomyces cerevisiae mediate two developmental programs in the same cell type: mating and invasive growth. Genes Dev. 8:2974-2985[Abstract/Free Full Text].
28.	Roberts, R. L., H.-U. Mosch, and G. R. Fink. 1997. 14-3-3 proteins are essential for RAS/MAPK cascade signaling during pseudohyphal development in S. cerevisiae. Cell 89:1055-1065[Medline].
29.	Rothstein, R. J. 1991. Targeting, disruption, replacement, and allele rescue: integrative DNA transformation in yeast. Methods Enzymol. 101:202.
30.	Sambrook, J., E. F. Fritsch, and T. Maniatis. 1989. In Molecular cloning: a laboratory manual, 2nd ed. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
31.	Sherman, F., G. R. Fink, and J. Hicks. 1986. In Methods in yeast genetics. Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y.
32.	Sikorski, R. S., and P. Hieter. 1989. A system of shuttle vectors and yeast host strains designed for efficient manipulation of DNA in Saccharomyces cerevisiae. Genetics 122:19-27[Abstract/Free Full Text].
33.	Sil, A., and I. Herskowitz. 1996. Identification of an asymmetrically localized determinant, Ash1p, required for lineage-specific transcription of the yeast HO gene. Cell 84:711-722[Medline].
34.	Tedford, K., S. Kim, D. Sa, K. Stevens, and M. Tyers. 1997. Regulation of the mating pheromone and invasive growth responses in yeast by two MAP kinase substrates. Curr. Biol. 7:228-238[Medline].
35.	Ward, M. P., C. J. Gimeno, G. R. Fink, and S. Garrett. 1995. SOK2 may regulate cyclic AMP-dependent protein kinase-stimulated growth and pseudohyphal development by repressing transcription. Mol. Cell. Biol. 15:6854-6863[Abstract].
36.	Yang, S. S., E. Yeh, E. D. Salmon, and K. Bloom. 1997. Identification of a mid-anaphase checkpoint in budding yeast. J. Cell Biol. 136:345-354[Abstract/Free Full Text].
37.	Yeh, E., R. V. Skibbens, J. W. Cheng, E. D. Salmon, and K. Bloom. 1995. Spindle dynamics and cell cycle regulation of Dyenin in the budding yeast, Saccharomyces cerevisiae. J. Cell Biol. 130:687-700[Abstract/Free Full Text].