Large-Scale Analysis of Yeast Filamentous Growth by Systematic Gene Disruption and Overexpression

Rui Jin, Craig J. Dobry, Phillip J. McCown, and Anuj Kumar

Department of Molecular, Cellular, and Developmental Biology and Life Sciences Institute, University of Michigan, Ann Arbor, MI 48109-2216

Submitted June 1, 2007; Revised September 10, 2007; Accepted October 29, 2007
Monitoring Editor: Charles Boone

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Under certain conditions of nutrient stress, the budding yeastSaccharomyces cerevisiae initiates a striking developmentaltransition to a filamentous form of growth, resembling developmentaltransitions required for virulence in closely related pathogenicfungi. In yeast, filamentous growth involves known mitogen-activatedprotein kinase and protein kinase A signaling modules, but thefull scope of this extensive filamentous response has not beendelineated. Accordingly, we have undertaken the first systematicgene disruption and overexpression analysis of yeast filamentousgrowth. Standard laboratory strains of yeast are nonfilamentous;thus, we constructed a unique set of reagents in the filamentous ${Sigma}$ 1278b strain, encompassing 3627 integrated transposon insertionalleles and 2043 overexpression constructs. Collectively, weanalyzed 4528 yeast genes with these reagents and identified487 genes conferring mutant filamentous phenotypes upon transposoninsertion and/or gene overexpression. Using a fluorescent proteinreporter integrated at the MUC1 locus, we further assayed eachfilamentous growth mutant for aberrant protein levels of thekey flocculence factor Muc1p. Our results indicate a varietyof genes and pathways affecting filamentous growth. In total,this filamentous growth gene set represents a wealth of yeastbiology, highlighting 84 genes of uncharacterized function andan underappreciated role for the mitochondrial retrograde signalingpathway as an inhibitor of filamentous growth.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In its most familiar growth form, the baker's yeast Saccharomycescerevisiae divides mitotically by budding, forming two independentand separate daughter cells from a single mother cell. In responseto specific environmental cues, however, some strains of S.cerevisiae are capable of forming multicellular filaments—chainsof cells that remain physically connected after cytokinesis(Gimeno et al., 1992; Kron, 1997; Madhani and Fink, 1998). Inyeast, this form of filamentous growth is thought to constitutea foraging mechanism initiated under conditions of limited nutrientavailability (Gimeno et al., 1992; Liu et al., 1993; Cullenand Sprague, 2000). Similar filamentous growth transitions areevident in many fungal species; in particular, many fungal pathogenstransition between unicellular and filamentous growth forms,and, in fact, this transition is required for virulence in mostof these organisms (Alspaugh et al., 1997; Lo et al., 1997b).For example, in the opportunistic human pathogen Candida albicans,environmental cues of temperature, pH, and serum source havebeen found to trigger a distinct morphogenetic program resultingin the transition from a cellular yeast form to a filamentousgrowth form (Liu et al., 1994; Singh et al., 1997). Furthermore,a mutant strain of C. albicans impaired in its ability to undergofilamentous growth is avirulent in a mouse model of disseminatedcandidiasis (Lo et al., 1997a). Thus, filamentous growth isrelevant to our understanding of fungal pathogenesis, and thebudding yeast has emerged as an informative model for studiesof filamentous growth.

In S. cerevisiae, filamentous growth is induced under conditionsof nitrogen stress or by growth in media containing short-chainalcohols (Gimeno et al., 1992; Lorenz et al., 2000; Miled etal., 2001). In each case, this environmental stress elicitssubstantive changes in yeast cell morphology and growth: theyeast cells delay in G2/M, exhibit an elongated morphology,display an altered budding pattern, remain physically attached,and invade their growth substrate (Kron et al., 1994). Collectively,this results in the formation of filamentous chains of elongatedcells, called pseudohyphae. Specifically, a diploid strain ofyeast extends pseudohyphal filaments over the surface of itsgrowth substrate and downward into the agar medium; classically,this form of growth is referred to as diploid pseudohyphal growth.A haploid strain of yeast under conditions of nutrient sufficiencyextends invasive filaments downward, but it does not extendsurface-spread filaments; classically, this is referred to ashaploid invasive growth (Gancedo, 2001). Alternative growthconditions, however, can induce surface filamentation in haploidyeast as well (Lorenz et al., 2000). Thus, to avoid confusion,we use the term filamentous growth and simply refer to the growthas occurring in a haploid or diploid strain of yeast.

Yeast filamentous growth is regulated by at least two knownsignaling pathways: 1) the nutrient-sensing cyclic AMP–proteinkinase A (PKA) pathway and 2) a mitogen-activated protein kinase(MAPK) pathway (Buehrer and Errede, 1997; Madhani and Fink,1997; Lengeler et al., 2000; Cullen et al., 2004). During filamentousgrowth, the GTP-binding protein Ras2p is activated through asensor system that is poorly understood at present; Ras2p, inturn, stimulates the synthesis of cAMP, resulting in the activationof PKA (Robertson and Fink, 1998). PKA promotes filamentousgrowth, in part, by activating the key filamentous growth transcriptionfactor Flo8p, a pseudogene in nonfilamentous lab strains ofyeast (Pan and Heitman, 1999). The filamentous growth MAPK pathwayencompasses the p21-activated kinase (PAK) Ste20p (Peter etal., 1996) and the MAPK cascade itself of Ste11p, Ste7p, andKss1p (Cook et al., 1997). Kss1p activates a presumably largeset of targets, including the transcription factor Ste12p, whichheterodimerizes with the transcription factor Tec1p to regulateexpression of genes contributing to filamentous growth (Liuet al., 1993; Madhani et al., 1997; Borneman et al., 2006).

At present, the cell-surface glycoprotein Muc1p (formerly Flo11p)is the most well-characterized downstream effector of yeastfilamentous growth (Gagiano et al., 1999; Guo et al., 2000).Muc1p is required for cell–cell adhesion, or flocculation,and filamentous growth in budding yeast, and it is the onlyknown target of both the PKA and MAPK pathways described above(Lo and Dranginis, 1996, 1998). MUC1 contains an unusually large2.8-kb promoter with experimentally verified recognition sequencesfor the MAPK pathway-regulated transcription factor complexSte12/Tec1p and for the PKA pathway-regulated transcriptionfactor Flo8p (Rupp et al., 1999; Borneman et al., 2006). Accordingly,MUC1 is expressed at very low levels under normal conditionsof vegetative growth, and it is induced during filamentous growth(Caro et al., 1997; Strittmatter et al., 2006).

The MAPK and PKA pathways described above are incompletely defined,and they likely represent only a fraction of the signaling andmetabolic pathways mediating yeast filamentous growth. Througha number of independent observations, reviewed in Rua et al.(2001), the filamentous growth PKA and MAPK modules have beenlinked with genes functioning in the establishment of cell polarity,bud site selection, and cell cycle progression. The extensivegenetic and morphological changes underlying the transitionto yeast filamentous growth suggest a very broad network ofassociated signaling pathways—a network that may be bestinvestigated through systematic and large-scale approaches.To this end, we present the first systematic gene disruptionand overexpression analysis of yeast filamentous growth. Usingtransposon-based directed allele replacement (Kumar et al.,2000, 2002c), we have generated 3627 transposon insertion mutantsfor subsequent phenotypic analysis; we also have individuallyintroduced 2043 gene overexpression constructs into the samefilamentous strain background to assess overexpression-inducedfilamentous growth phenotypes. Collectively, this study encompasses4528 yeast genes ( $~$ 78% of the total gene complement in S. cerevisiae),identifying 487 genes contributing to filamentous growth. Amongother interesting points, this gene set highlights the importanceof mitochondrial function during filamentous growth, and throughfollow-up studies using targeted gene deletions, we identifythe mitochondrial retrograde signaling pathway as a key negativeregulator of yeast filamentous growth.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Yeast Strains and Growth Conditions
All mutants in this study were constructed in strain Y825 derivedfrom the filamentous ${Sigma}$ 1278b genetic background. The genotypeof Y825 is as follows: MATa ura3-52 leu2 ${Delta}$ 0. Transposon insertionand gene overexpression mutants were generated as describedbelow. Precise start codon-stop codon gene deletions were generatedusing the one-step gene replacement strategy of Baudin et al.(1993) with the KanMX6 disruption cassette from plasmid pFA6a-KanMX6(Longtine et al., 1998) unless otherwise noted. Strains lackingmitochondrial DNA (rho⁰ strains) were generated by treatmentwith ethidium bromide (Sherman et al., 1994); the loss of mitochondrialDNA was confirmed by staining with 4,6-diamidino-2-phenylindole.

Filamentous growth was induced on solid medium according tostandard protocols using low-nitrogen growth medium (2% glucose,50 µm ammonium sulfate, 0.17% yeast nitrogen base withoutamino acid and ammonium sulfate, with essential amino acidsfor nutritional auxotrophies) supplemented with 1% (vol/vol)butanol (Lorenz et al., 2000). Filamentous growth was inducedin liquid culture by using YPD rich medium (1% bacto yeast extract,2% bacto peptone, and 2% glucose) supplemented with 1% butanolas described in Lorenz et al. (2000). Low-autofluorescence mediumwas prepared according to standard protocols for appropriatesynthetic complete (SC) medium, substituting yeast nitrogenbase (YNB) without ammonium sulfate, folic acid, and riboflavinfor YNB without ammonium sulfate (Guthrie and Fink, 1991).

Construction of the Yeast Transposon Insertion and Gene Overexpression Collections in a Filamentous Strain of Yeast
Transposon insertion alleles were generated in a previous study(Ross-Macdonald et al., 1999; Kumar et al., 2002b, 2004). Insertionalleles likely to represent null alleles were determined manuallyby inspection of the insertion site relative to the open readingframe coding sequence. A representative and nonredundant collectionof transposon insertion alleles was generated by cherry-pickingindividual bacterial cultures into 96-well plates; we preparedplasmid DNA from these cultures by using standard alkaline lysisprotocols adapted for application in 96-well format. PlasmidDNA was digested with NotI to release inserts of yeast genomicDNA, each carrying a single transposon insertion; this DNA wasintroduced individually in 96-well format into strain Y825 bystandard methods of lithium acetate-mediated transformationadapted for high throughput as described previously (Kumar etal., 2000, 2004). Transformants were selected on SC –Ura,and three independent transformants were saved per transformation.

Gene overexpression plasmids were constructed as reported inKumar et al. (2002a), and they represent the set of genes successfullycloned into pYES2/GS by topoisomerase I-mediated ligation. Inthis study, overexpression plasmids were introduced individuallyinto Y825 by the high-throughput lithium acetate-mediated transformationprotocol referenced above, and transformants were selected onSC –Ura.

Phenotypic Profiling of Filamentous Growth Mutants
In yeast, filamentous growth phenotypes may be identified througha number of assays. Surface-spread filaments are readily apparentfrom visual inspection of colony morphology (Gimeno et al.,1992). Invasive filaments can be identified through a plate-washingassay, in which a gentle stream of water is run over a Petriplate streaked with yeast, such that surface-spread cells arewashed away and invasive cells left behind (Gimeno et al., 1992).Filamentous growth also may be assessed in liquid culture, becausefilamentous cells exhibit an elongated morphology and clusterto a greater degree than nonfilamentous cells (Lorenz et al.,2000; Zeitlinger et al., 2003). Filamentation in haploid yeastis stimulated by growth in fusel alcohols; the short-chain alcoholsare thought to mimic the end products of amino acid catabolismin nitrogen-poor conditions (Lorenz et al., 2000). The resultingfilamentous growth form exhibits both surface-spread and invasivefilaments. Thus, all of the assays described above may be usedto determine alcohol-induced filamentous growth in haploid strainsof yeast, and our screening approach used each of these methods.Here, phenotypes were assessed qualitatively and were binnedin the indicated categories.

For this analysis, haploid yeast strains (Y825 background) carryingintegrated transposon insertion alleles were arrayed in 96-wellformat for inoculation in liquid YPD supplemented with 1% (vol/vol)butanol. Mutants were grown in 96-well format with shaking at30°C for $~$ 2–3 d, and they were subsequently screenedfor cell morphology and cell clustering by standard microscopy.Liquid cultures were spotted onto multiwell microscope slides,and they were imaged individually at 10x magnification. Eachmutant strain was assayed for increased or decreased filamentousgrowth, as indicated by the observed degree of cell clusteringand cell elongation; in our hands, this assay yielded the mostobvious and easily distinguished filamentous growth phenotypes.Only insertion alleles for which at least two of three independenttransformants scored positive were considered further. Thesemutants exhibiting altered filamentous growth phenotypes wereexamined on solid medium to define colony morphology and cellinvasiveness. For this analysis, mutants were grown in liquidSc –Ura medium overnight, and cultures were spotted in96-well format on solid SC –Ura low nitrogen medium (50µM ammonium sulfate) supplemented with 1% (vol/vol) butanol.Spotted cultures were grown at 30°C 3–5 d before analysisof surface-spread filamentation by standard microscopy. Onlyinsertional mutants exhibiting filamentous growth phenotypesin both liquid and solid media were scored as filamentous growthmutants in this screen. Filamentous growth mutants also wereassayed on solid medium for invasive phenotypes by the plate-washingassay described in Gimeno et al. (1992).

Gene overexpression mutants were analyzed similarly, exceptthat transformants were sequentially grown in standard liquidSC –Ura medium for 1 d, in liquid SC –Ura mediumwith raffinose as the carbon source overnight, and in liquidSC –Ura medium with 1% (vol/vol) butanol and galactoseas the carbon source for 2 d. Mutants were subsequently analyzedas described above. Overexpression strains exhibiting filamentousgrowth mutants in liquid culture were analyzed on solid growthmedium for colony morphology and invasiveness. Mutants wereinitially grown in liquid SC –Ura medium overnight, andthen they were spotted onto solid low-nitrogen medium (50 µMammonium sulfate) with galactose as the carbon source and 1%(vol/vol) butanol. Cultures were grown 2–3 d at 30°Cbefore examination by microscopy and by the plate-washing assayreferenced above.

Determining Muc1p and Yef3p Abundance
To determine the abundance of Muc1p (as an indicator of filamentousgrowth) and Yef3p (as a general indicator of protein levels),we established a dual reporter system in which Muc1p is fusedto green fluorescent protein (GFP) at its carboxy terminus,and Yef3p is fused to Discosoma sp. fluorescent protein (DsRed)at its carboxy terminus. Muc1p-GFP was constructed by integratingthe GFP-KanMX6 cassette from pFA6a-KanMX6 (Longtine et al.,1998) at the 3' end of MUC1 in Y825. To generate the Yef3p–DsRedfusion, we constructed a DsRed-URA3 cassette and integratedthis cassette at the 3' end of YEF3.

Transposon insertion mutants containing the dual reporters wereincubated in liquid SC –Ura medium supplemented with 1%(vol/vol) butanol overnight, and they were then incubated infresh medium at an optical density (650 nm) of 0.3 ( $~$ 3.9 x 10⁶haploid cells) for an additional 3 h of growth. Insertion mutantswere analyzed for GFP and DsRed fluorescence in black 96-wellassay plates by using the Victor² multilabel counter (PerkinElmer-Cetus,Waltham, MA); cell density was determined using the ThermoMaxmicroplate reader (Molecular Devices, Vienna, VA). Gene overexpressionmutants were cultured in liquid as described above (phenotypicprofiling), with 3 h of galactose induction before analysis.Insertion mutants and overexpression mutants of interest werealso imaged by fluorescence microscopy to consider cell–cellvariability in Muc1p and Yef3p abundance. To minimize autofluorescence,the media described above were made with YNB lacking folic acidand riboflavin (Guthrie and Fink, 1991).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Generating Transposon Insertion Alleles and Overexpression Constructs in a Filamentous Strain of Budding Yeast
Many large-scale phenotypic studies have been performed in S.cerevisiae by using the genome-wide deletion collection (Winzeleret al., 1999); however, this collection has been constructedin a nonfilamentous strain of yeast and is, therefore, inappropriatefor studies of filamentous growth. Ideally, filamentous growthstudies should be performed in the yeast strain ${Sigma}$ 1278b, becausethis strain is known to undergo an extensive and easily controlledtransition to filamentous growth (Grenson, 1966; Gimeno et al.,1992).

To construct a genome-wide set of gene disruption mutants inthe ${Sigma}$ 1278b genetic background, we used a plasmid-based collectionof gene disruption alleles generated previously by large-scalemutagenesis of the yeast genome (Figure 1A) (Ross-Macdonaldet al., 1999; Kumar et al., 2002c). The specifics of these insertionalleles are presented in Kumar et al. (2004). The assembledcollection encompasses 3627 plasmid-based transposon insertionalleles (representing 63% of all annotated protein coding genesin yeast), in 38 96-well plates. Transposon insertion alleleswere introduced individually into a haploid strain of the ${Sigma}$ 1278bgenetic background by using protocols described previously (Kumaret al., 2000). Yeast strains for overexpression analysis weregenerated using a collection of high-copy plasmids carryinggenes cloned under transcriptional control of a galactose-induciblepromoter (Figure 1B) (Kumar et al., 2002). In total, this plasmid-basedcollection encompasses 2043 yeast genes (35% of the yeast genome),and the identity of each gene has been verified by DNA sequencing.Overexpression constructs from this collection also were introducedinto the filamentous ${Sigma}$ 1278b strain for phenotypic analysis asoutlined in Figure 1B.

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Figure 1. Construction of yeast gene disruption and overexpression arrays for phenotypic analysis of filamentous growth. (A) Diagrammatic representation of the plasmid-based mini-transposon (mTn) insertion alleles and the approach by which these insertion alleles were introduced into a filamentous strain of yeast. The transposon-mutagenized yeast DNA was introduced into the filamentous ${Sigma}$ 1278b strain in 96-well format; thus, the final yeast gene disruption array reflects the same order as the arrayed transposon insertion plasmids. As indicated, the mTn carries the URA3 marker. (B) Overview of the gene overexpression plasmids and the construction of a corresponding yeast gene overexpression array in the ${Sigma}$ 1278b strain. The overexpression plasmid carries the galactose-inducible GAL1 promoter; each yeast gene is maintained on this plasmid in the filamentous yeast strain.

Collectively, the yeast gene disruption and overexpression collectionsencompass 4528 genes (Table 1), representing 78% of the predictedgene complement in S. cerevisiae. These collections include816 essential genes, 632 of which are represented in the transposoninsertion collection. On introduction into haploid yeast, themajority (90%) of transposon insertions in essential genes failedto yield colonies, indicating that these insertion representednull alleles. Overexpression constructs of essential genes (184)yielded viable colonies upon introduction into yeast. Thus,247 essential genes were analyzed in this study, largely bygene overexpression.

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Table 1. Summary of gene disruptions and overexpression analysis

A Systematic Screen for Filamentous Growth Mutants
Haploid gene disruption and overexpression mutants were screenedfor filamentous growth phenotypes in the presence of short-chainalcohols to enable analysis of surface-spread filamentation,cell elongation/clustering, and cell invasiveness (see Materialsand Methods). By this approach, we identified 487 genes ( $~$ 11%of all genes examined in this study) conferring filamentousgrowth phenotypes upon gene disruption and/or overexpression(Table 1). This gene set encompasses 309 genes, yielding mutantfilamentous growth phenotypes by transposon-based gene disruptionand 199 genes exhibiting filamentous growth phenotypes by overexpression.By plate-washing assays, 243 transposon insertion mutants and38 gene overexpression mutants are noninvasive. Thus, surface-spreadfilamentation phenotypes do not always correlate with invasivegrowth phenotypes. Disruption mutants with filamentous growthphenotypes typically exhibited decreased filamentous growth(240 of 309 disruption mutants), and the mutants were generallynoninvasive. Conversely, the majority of gene overexpressionmutants with filamentous growth phenotypes exhibited exaggeratedfilamentation (156 of 199 overexpression mutants) and were invasive(Table 1). Few genes, however, exhibited both gene disruptionand overexpression phenotypes, consistent with previous observationsfrom large-scale deletion and overexpression studies in yeast(Sopko et al., 2006

). Specifically, 1142 genes are redundantbetween the transposon insertion and overexpression mutant collections.Of these genes, 217 yielded a mutant phenotype in either screen,and 20 exhibited filamentous growth phenotypes as both disruptionand overexpression alleles (e.g., the transcription factor PHD1indicated in Figure 2, A and B). Six of these 20 genes are involvedin the regulation of nitrogen metabolism, including the knownfilamentous growth genes PHD1, TEC1, and RAS2. It is also noteworthythat four of 20 genes (MGM101, MGR1, MSK1, and MSW1) are involvedin mitochondrial functions; the importance of mitochondrialfunction during filamentous growth is addressed later in thistext. Aside from PHD1, TEC1, and RAS2, these genes do not, however,exhibit any enrichment for genetic or physical interactionswith each other or with known filamentous growth signaling modulesor pathway components. The results from this analysis are summarizedfurther in Table 1, and they are available in full as SupplementalTables S1 and S2).

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Figure 2. A visual library of yeast filamentous growth mutants. (A) Colony morphologies of transposon-based gene disruption mutants. This sampling of images highlights a subset of previously uncharacterized genes exhibiting disruption phenotypes related to filamentous growth; for comparison, we have also included the wild-type background and mutants with transposon insertions in known filamentous growth genes (FLO8, FLO9, PHD1, and RIM9). All gene disruption mutants were spotted in 96-well format on solid SC – Ura low nitrogen medium (50 µM ammonium sulfate) supplemented with 1% (vol/vol) butanol, and mutants of interest were streaked for single colonies (shown here). The severity of the phenotype is indicated below each image (+, exaggerated filamentous growth; ++, strongly exaggerated filamentous growth; –, decreased filamentous growth; ––, strongly decreased filamentous growth). (B) Colony morphologies of gene overexpression mutants. To drive gene overexpression under conditions inducing filamentous growth, the mutants were grown in low-nitrogen SC –Ura with galactose and 1% butanol. Again, the images depict single colonies, and the severity of the phenotype is indicated below each image.

A Visual Library of Filamentous Growth Phenotypes
The filamentous growth mutants identified in this study presenta striking array of colony morphologies; in particular, we highlighthere a complement of previously uncharacterized genes presentingfilamentous growth phenotypes upon transposon insertion or geneoverexpression (Figure 2). By convention, these uncharacterizedgenes are listed by their systematic names—a standardizednomenclature applied to all yeast genes derived from the physicallocation of each open reading frame in the yeast genome (e.g.,YBR116c). In total, 59 previously uncharacterized genes (withno common name or functional description available in the SaccharomycesGenome Database at www.yeastgenome.org as of April 2007) wereidentified in the disruption screen, and 27 uncharacterizedgenes were identified by gene overexpression; two genes (YKR074wand YNL260c) were identified in both screens. For comparison,we also include here several examples of functionally characterizedgenes previously known to affect filamentous growth upon genedisruption (FLO8, FLO9, PHD1, and RIM9) or gene overexpression(GCN4, HMS1, MEP2, MSN2, PHD1, and RAS2). The filamentous growthphenotypes resulting from disruption or overexpression of theseknown filamentous growth genes are comparable in severity tothe observed phenotypes of the uncharacterized genes; thus,we expect these previously uncharacterized genes play significantroles in enabling wild-type filamentous growth.

Collectively, the images gathered in this study constitute aunique visual library of yeast filamentous growth phenotypes.To maximize the widespread utility of these data, we have capturedan image of each filamentous growth mutant, and we have assembledthese images into an archived file that can be freely downloaded.Information for downloading this file is presented as SupplementalMaterial. With this resource, users can inspect any specificmutants of interest in great detail. We have also assigned abroad score to each mutant, indicating the extent of its filamentousgrowth relative to wild type; in this way, mutants can be easilygrouped by the severity of the phenotype. This data set is availablein Supplemental Table S1.

A Genome-Wide Set of Genes Affecting Filamentous Growth
To characterize this filamentous growth gene set, we have annotatedeach gene identified in our screen with information from theGene Ontology (GO) project, and we have searched the gene setfor any enriched GO terms (Consortium, 2006). GO descriptorsare available for three information categories: the cellularcompartment to which the protein localizes, the molecular functionfor the gene product, and the biological process to which thegene contributes. In our gene set, we find no enrichment forproteins localized to a particular subcellular compartment andrelatively little enrichment for proteins of a particular molecularfunction. In contrast, however, we see significant enrichmentfor gene products associated with a number of biological processes.Figure 3B presents a tree diagram highlighting GO biologicalprocess terms statistically enriched among the 487 nonredundantgenes identified in this study. Specific biological processesare indicated in Figure 3C; genes from this screen associatedwith the indicated processes are listed here, along with p valuesdescribing the statistical significance of each enriched genesubset. Complete gene lists are presented in Supplemental TableS3.

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Figure 3. Statistically significant enrichment for gene functions in the filamentous growth mutants. (A) Overview of the gene disruption and overexpression screen results. (B) Tree diagram indicating related GO functional categories enriched in the filamentous growth gene set. GO biological process terms are indicated in boxes; biological processes enriched in the filamentous growth mutant data set are shaded in light red. The GO numerical identifier for each of these biological processes is indicated in parentheses. (C) The statistical significance of each enriched GO biological process term is indicated along with the actual number of identified genes belonging to this GO process category. As the GO categories can overlap significantly, we have indicated four general groupings (boxes), representing closely related processes. Sample gene subsets for at least one enriched GO biological process in each grouping are presented; the corresponding gene number for each of these listed gene sets is highlighted in red. Complete gene lists are available in Supplemental Table S3.

Not surprisingly, this data set is significantly enriched forgenes known to affect filamentous growth (a subcategory of cellgrowth and morphology). By prior GO annotation, 65 genes havebeen associated with yeast pseudohyphal growth (Consortium,2006

). We identified 16 of these genes here (p value 1.3 x 10^–4)(Figure 3C); 14 genes were not represented in either the transposoninsertion or overexpression collection; thus, they were unavailablefor analysis. To ensure that our scoring criteria are effectivein identifying genes affecting filamentous growth, we generatedgene disruption or overexpression constructs for 17 previouslyknown filamentous growth genes absent from our plasmid-basedallele collections: BEM1, BUD1, BUD5, BUD9, CDK1, CLB1, CLB2,CLN2, CLN3, ELM1, GRR1, MIH1, MSB3, MSS11, MUC1, and NDD1. Analysisof each mutant yielded observable filamentous growth phenotypes,suggesting that our scoring strategy is appropriate, althoughour screen is not saturated.

In addition to known filamentous growth genes, we also identifieda statistically significant set of genes contributing to cellgrowth and morphogenesis, nitrogen metabolism, nucleic acidmetabolism (including transcription-related processes), andmitochondrial function. In particular, these latter two processesare not conceptually intuitive contributors to the filamentousgrowth response. From previous studies, however, we know thatfilamentous differentiation does require an extensive transcriptionalprogram regulated by a sizable cohort of transcription factors(Rupp et al., 1999; Prinz et al., 2004; Borneman et al., 2006).It is further interesting to note that the gene overexpressionscreen, but not the gene disruption screen, yielded an enrichedset of transcription-associated genes, including the transcriptionfactors FLO8, GCN4, MSN2, and PHD1. Compared with other proteinclasses, overexpression of a transcription factor may be morelikely to yield exaggerated filamentous growth. The requirementfor mitochondrial function during filamentous growth is alsoconsistent with the prior observation that a rho⁰ strain ofyeast impaired in mitochondrial function is unable to undergofilamentous growth (Kang and Jiang, 2005).

Although GO annotations can be limited in consistency and detail,this analysis, nonetheless, raises two points. First, we identifieda set of genes extending well beyond the scope of previouslyknown filamentous growth genes. Second, our data set is enrichedfor genes functioning in cell processes associated with filamentousgrowth, encompassing known filamentous growth genes, and genesinvolved in the regulation of nitrogen metabolism, cell morphogenesis,and growth.

Muc1p Abundance in Filamentous Growth Mutants
Muc1p is considered a principal downstream effector of yeastfilamentous growth, and it is the only known gene whose expressionintegrates signals from both the filamentous growth MAPK andPKA pathways (Gagiano et al., 1999; Rupp et al., 1999; Guo etal., 2000); accordingly, we examined each identified filamentousgrowth mutant to determine whether the observed phenotype correspondedwith altered levels of Muc1p. For this analysis, we constructeda Muc1p-fluorescent protein reporter. In each mutant, we integrateda cassette containing GFP and a selectable marker at the 3'end of MUC1 as a readout of MUC1 promoter activity. This reporterstrain is competent for filamentous growth, and, upon translation,the GFP fusion results in fluorescence at the cell periphery,consistent with results from previous studies (Lo and Dranginis,1996). Fluorescence was assessed in 96-well format by usinga plate reader, and individual mutants of interest were examinedat the single cell level by microscopy to account for cell–cellheterogeneity in MUC1 expression. To confirm the accuracy ofthe fluorescence measurements, we assessed Muc1p-GFP levelsby Western blotting in five selected mutants, and we observedcorroborating results in each case (Supplemental Figure SF1).

To consider whether these effects are specific to MUC1 and filamentousgrowth pathways, we constructed a second reporter consistingof red fluorescent protein (DsRed) fused to the carboxy terminusof the translation elongation factor Yef3p. YEF3 is an essentialgene encoding translation factor (EF)-3; Yef3p stimulates EF-1 ${alpha}$ in binding aminoacyl-tRNA to the ribosome; therefore, it functionsoutside of pathways specific to filamentous growth. A cassettecarrying DsRed and an appropriate selectable marker were fusedat the 3' end of YEF3 in each identified filamentous growthmutant exhibiting significantly modified levels of Muc1p. Aswith Muc1-GFP, we assessed Yef3p–DsRed levels in eachmutant by using a fluorescence plate reader and normalized theresulting values by cell density.

Figure 4A indicates Muc1-GFP and Yef3p-DsRed levels in genedisruption and overexpression mutants relative to levels observedin a wild-type strain; we highlight here all mutants exhibitingsignificant differences in Muc1p abundance without correspondingdifferences in Yef3p expression. In total, we report 27 genesconferring filamentous growth phenotypes upon disruption and/oroverexpression through a molecular mechanism controlling Muc1pabundance distinct from any general effect on protein expressionover the proteome. These mutants identify candidate filamentousgrowth genes in which the filamentous growth response may bemediated, in part, through direct or indirect regulation ofMuc1p abundance. For example, Tec1p is a transcription factorthat heterodimerizes with Ste12p; the Ste12/Tec1p complex isrequired for filamentous growth, and it is known to activateexpression of MUC1. We found that disruption of TEC1 resultedin decreased levels of Muc1p but approximately wild-type levelsof Yef3p. Conversely, overexpression of TEC1 resulted in increasedMuc1p abundance but slightly decreased levels of Yef3p. Thisassay correctly identified numerous bona fide filamentous growthgenes (including TEC1, TPK2, SOK2, PHD1, RAS2, and FUS1). Interestingly,we found that disruption or overexpression of the previouslyuncharacterized genes YGR050c, YJR008w, and YDR415c resultedin mutant filamentous growth phenotypes exhibiting modifiedlevels of Muc1p relative to Yef3p; these genes, therefore, verylikely represent new filamentous growth genes.

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Figure 4. Analysis of Muc1p abundance in filamentous growth mutants. (A) Dual reporter system describing the change in Muc1p-GFP abundance from wild type and the corresponding change in Yef3p-DsRed abundance. Data are presented here for those genes exhibiting changes in Muc1-GFP levels consistent with the observed filamentous growth phenotype without comparable changes in Yef3p-DsRed abundance. For comparison, the mdm30::mTn mutant and GCN4 overexpression mutant are included; Yef3p-DsRed levels differ significantly from wild-type in these mutants, suggesting that, in these cases, the observed changes in Muc1p-GFP levels likely represent general effects on protein production. For this analysis, error bars are generated from three biological replicates. (B) Studies of epistasis using MUC1 deletion and overexpression alleles in mutants disrupted for GLN3, WHI2, YGR050c, TEC1, and MDM30, and in mutants overexpressing ASP3-4, UGA3, YDR415c, and YJR008w. Filamentous growth phenotypes at the colony and cell levels are indicated, along with growth conditions for each analysis.

To define further whether these genes function in MUC1-dependentpathways, we performed a series of epistasis studies in whichMUC1 was either ectopically expressed or deleted in selectedgene disruption and overexpression mutants from Figure 4A. Specifically,MUC1 was expressed from a galactose-inducible promoter in mutantsdisrupted for GLN3, WHI2, YGR050c, TEC1, and MDM30, and in amutant overexpressing YJR008w. Conversely, MUC1 was deletedin hyperfilamentous mutants overexpressing ASP3-4, UGA3, andYDR415c. Filamentous growth phenotypes of the mutants are indicatedin Figure 4B. The analysis of tec1::mTn serves as a positivecontrol, and, as expected, overexpression of MUC1 rescues filamentousgrowth in this mutant. Analysis of mdm30::mTn serves as a negativecontrol: disruption of MDM30 does not produce an effect specificto MUC1, and overexpression of MUC1 in this background doesnot restore filamentous growth. MUC1 overexpression restoredfilamentation in mutants deleted for GLN3, a transcriptionalactivator of genes subject to nitrogen catabolite repression(Mitchell and Magasanik, 1984

), and in mutants deleted for WHI2,a phosphatase activator involved in the general stress responsein yeast (Kaida et al., 2002

). Overexpression of MUC1 also restoredfilamentous growth in a mutant deleted for YGR050c; however,MUC1 overexpression did not complement the loss of filamentationobserved upon overexpression of YJR008w. Deletion of MUC1 decreasedfilamentous growth in a mutant overexpressing the cell wallasparaginase ASP3-4 (Kim et al., 1988

), and even more stronglyin mutants overexpressing the transcriptional activator UGA3and the uncharacterized gene YDR415c. Thus, GLN3, WHI2, ASP3-4,UGA3, YGR050c, and YDR415c function in pathways regulating MUC1.

Mitochondrial Function during Filamentous Growth and the Retrograde Signaling Pathway
By gene disruption and overexpression analysis, we identifya data set statistically enriched (p value 3.9 x 10^–3)in genes contributing to mitochondrial function (Figure 3C).Independent studies by Kang and Jiang (2005) identified twogenes, IML1 and UGO1, required for both mitochondrial functionand filamentous growth in haploid yeast; here, we report eightgenes from our screens (Figure 3C) contributing to mitochondrialgenome maintenance as annotated by GO. Furthermore, a rho⁰ straincontaining a deleted version of the mitochondrial genome isunable to undergo filamentous growth even in the filamentous ${Sigma}$ 1278b genetic background (Figure 5B) (Kang and Jiang, 2005).Interestingly, mitochondrial function is not required for normalvegetative growth on a fermentable carbon source, because rho⁰cells are viable under standard growth conditions. Thus, mitochondrialfunction is required for filamentous growth, but the mechanismby which mitochondrial function is transduced into a signalaffecting filamentous growth is unknown.

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Figure 5. The mitochondrial retrograde signaling pathway and filamentous growth. (A) Overview of the pathway and relevant proteins. (B) Phenotypic analysis of RTG pathway mutants. Gene deletion and rho⁰ mutants were analyzed for filamentous growth phenotypes as indicated. Colony morphology was assessed on low-nitrogen solid growth medium supplemented with 1% butanol; cell morphology was assessed in rich liquid medium supplemented with 1% butanol. (C) The RTG pathway inhibits filamentous growth. Retrograde signaling acts as part of the mechanism by which mitochondrial dysfunction is transduced into a signal affecting filamentous growth.

To consider the extent to which mitochondrial dysfunction isresponsible for filamentous growth defects, we screened eachgene disruption mutant exhibiting decreased filamentous growthfor impaired respiratory function. Each loss-of-function filamentousgrowth mutant was grown on medium with glycerol substitutedfor glucose. Glycerol is a nonfermentable carbon source; yeaststrains grown on glycerol must meet their energy needs throughaerobic respiration, and mitochondrial mutants are, therefore,unable to grow (Guthrie and Fink, 1991

; Ross-Macdonald et al.,1999

). Of 309 mutants screened for growth on glycerol, 23 mutantswere inviable (Table 2). Muc1p abundance is typically decreasedin these mutants, but the effect is also frequently evidentin Yef3p levels (e.g., as in mdm30::mTn indicated in Figure 4A);therefore, mitochondrial function likely affects many pathways,acting upstream of the filamentous growth MAPK and PKA signalingmodules.

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Table 2. Disrupted genes conferring filamentous growth and glycerol growth phenotypes

With this in mind, the retrograde signaling (RTG) pathway representsa possible avenue by which mitochondrial signals may affectfilamentous growth. The yeast retrograde signaling pathway,illustrated in Figure 5A, is a mitochondria-to-nucleus pathwaytransducing changes in mitochondrial function to specific adaptivechanges in nuclear gene expression (Butow and Avadhani, 2004

;Liu and Butow, 2006

). The pathway encompasses one positive regulator,Rtg2p, four negative regulators, Lst8p, Mks1p, Bmh1p, and Bmh2p,and two terminal transcription factors, Rtg1p and Rtg3p (Liaoand Butow, 1993

; Jia et al., 1997

; Liu et al., 2001

). The mitochondrialretrograde response pathway is also known to engage in crosstalk with the target of rapamycin (TOR) pathway (Komeili etal., 2000

), likely through Mks1p, a negative regulator of theRas2p signaling pathway (Edskes et al., 1999

Because the majority of these genes were not represented inour transposon insertion collection, we generated a series ofgene deletions targeting RTG pathway regulatory components inthe filamentous ${Sigma}$ 1278b genetic background. The results of thisanalysis are indicated in Figure 5B. Deletion of the positiveRTG pathway regulator RTG2 results in exaggerated alcohol-inducedfilamentous growth, whereas deletion of the RTG pathway negativeregulator MKS1 results in a loss of filamentous growth. Deletionof MKS1 has been shown to diminish filamentous growth inducedunder conditions of nitrogen starvation (Edskes et al., 1999);we see a similar phenotype in mks1 ${Delta}$ upon conditions of alcoholinduction. Loss-of-filamentation phenotypes have also been observedin BMH1 and BMH2 mutants (Gelperin et al., 1995; Roberts etal., 1997). Consistent with these observations, deletion ofTOR1 and transposon-mediated disruption of RAS2 yields loss-of-filamentationphenotypes. From these results, the retrograde signaling pathwaynegatively regulates filamentous growth. It is interesting tonote, however, that deletion of RTG2 in a rho⁰ background restoresfilamentous growth slightly: in liquid medium, cell clusteringis comparable with wild type, but cell morphology seems lesselongated, whereas, on solid medium, limited filamentation canbe observed. Deletion of RTG2 in a tor1 ${Delta}$ mutant also restoresfilamentous growth to an intermediate level; again, cell morphologyis less elongated in liquid medium, and only limited filamentationis evident on solid medium. The TORC1 complex is known to regulatemany pathways, and this intermediate phenotype reflects thefact that the RTG pathway is not its sole downstream effector.Thus, retrograde signaling is a significant pathway by whichmitochondrial dysfunction inhibits filamentous growth, but itis likely not the only avenue by which that signal is transduced.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We present here a systematic and large-scale study of yeastfilamentous growth, introducing 3627 sequenced transposon insertionalleles and 2043 gene overexpression constructs into the filamentous ${Sigma}$ 1278b strain of yeast for subsequent phenotypic analysis. Bythis approach, we identify 487 genes affecting filamentous growth.This gene set encompasses components of the previously knownfilamentous growth MAPK and PKA pathways, as well as genes contributingto cellular morphogenesis, nitrogen metabolism, mitochondrialfunction, and transcription-related processes. This analysisoffers the first phenotypic characterization of 84 yeast genes,illustrating the need to investigate gene function in nonstandardgenetic backgrounds as a means of ascribing functions to previouslyuncharacterized genes. In total, we report 27 genes that directlyor indirectly affect Muc1p abundance as part of the filamentousgrowth response, and, in particular, we identify GLN3, WHI2,ASP3-4, UGA3, YGR050c, and YDR415c as components of pathwaysthat regulate MUC1. This study also highlights the importanceof mitochondrial function during filamentous growth and identifiesthe mitochondrial retrograde signaling pathway as a negativeregulator of yeast filamentous growth.

To support the broad dissemination of our results, we make alldata from this study publicly available at https://lsinwfs03.lsi.umich.edu/NetStorage/(instructionsfor access are available as supplementary information to thistext). In addition, any transposon insertion mutant or geneoverexpression strain generated in this study can be requestedfree of charge from the authors.

Regulation of Muc1p Abundance as a Downstream Control Point During Filamentous Growth
Muc1p has garnered significant attention as a key downstreameffector of yeast filamentous growth. As indicated by approachescoupling chromatin immunoprecipitation with DNA microarray analysis,the unusually large MUC1 promoter is directly targeted by atleast six filamentous growth transcriptional regulators (Ste12p,Tec1p, Sok2p, Phd1p, Mga1p, and Flo8p) (Borneman et al., 2006).Previous studies have revealed that transcription of MUC1 isinduced during filamentous growth (Caro et al., 1997; Strittmatteret al., 2006), and we observe this induction at the proteinlevel as well. We, therefore, hypothesized that the genes identifiedin this study may affect filamentous growth through a mechanisminvolving the regulation of Muc1p abundance. To consider thispossibility, we constructed a Muc1-GFP/Yef3p-DsRed dual reportersystem, enabling us to identify changes in Muc1p abundance relativeto general changes in protein expression over the proteome asa whole. By this method, we find 27 transposon insertion orgene overexpression mutants exhibiting 1) altered Muc1p abundancerelative to Yef3p and 2) a corresponding filamentous growthphenotype. The gene products identified by this approach donot necessarily affect Muc1p abundance directly; in most cases,the encoded gene products are not obvious regulatory elements,and the effect is presumably indirect. Tec1p and Sok2p are notableexceptions, likely affecting MUC1 expression directly, consideringthe chromatin immunoprecipitation data referenced above.

Many of these genes had not been implicated previously in pathwaysregulating MUC1. To investigate a possible role for some ofthese genes in MUC1-dependent pathways, we performed a seriesof epistasis experiments with MUC1 deletion and overexpressionalleles. We specifically selected the genes GLN3, WHI2, ASP3-4,UGA3, YDR415c, YGR050c, and YJR008w as putative MUC1 regulators,and we confirmed all but YJR008w as components of pathways regulatingMUC1. Again, the effects may not be direct, and additional studieswill be necessary to define the specific pathways in which thesegenes function.

On a related point, it is interesting that the change in Muc1pabundance did not correlate strongly with the filamentous growthphenotype in many mutants. Several factors may explain thisobservation. First, MUC1 expression and filamentous growth areheterogeneous even within a clonal population of cells (Halmeet al., 2004). Although fluorescence readings for mutants ofinterest were confirmed at the single cell level by microscopy,Muc1p–GFP levels were initially surveyed using a platereader, which would only provide a composite reading for thepopulation as a whole. Plate reader data may, in fact, maskchanges in Muc1p abundance if the observed difference is onlyevident in a relatively small subpopulation of cells. That stated,in our hands, we found plate reader results to be very comparablewith results obtained by microscopy of single cells, and wedo not consider this to wholly explain discrepancies betweenMuc1p abundance and filamentous growth phenotypes. Second, Muc1pactivity may indeed differ from wild type in these mutants,but this modified activity may not result from altered Muc1pabundance. MUC1 possesses a long region of internal tandem repeats,and variability in the length of this region is known to correlatewith MUC1 function (Voynov et al., 2006); thus, Muc1p activitymay reflect variability in the length of this repeat region.Alternatively, Muc1p may be controlled by regulatory mechanismsaffecting the subcellular localization of this protein, althoughregulated localization of Muc1p was not readily apparent inour microscopy analysis. Finally, and perhaps most importantly,Muc1p may not be the sole downstream effector of filamentousgrowth. Our data indicate that a subset of genes affect filamentousgrowth through a mechanism involving MUC1, but these mechanismsmay not target MUC1 exclusively. In support of this possibility,filamentous growth can be induced in the absence of MUC1 onlow-nitrogen medium supplemented with a fusel alcohol (Lorenzet al., 2000). Thus, despite the significant attention paidto MUC1, other genes may play equally important roles in enablingfilamentous growth.

Previously Uncharacterized Genes in Filamentous Growth
The functionally uncharacterized genes identified in this studyprovide a particularly interesting starting point for furtherexploration of the yeast filamentous growth response. In particular,YDR415c and YGR050c function in pathways impinging upon MUC1.YGR050c is a dubious open reading frame, as designated by theSaccharomyces Genome Database, flanked by the uncharacterizedopen reading frame YGR051c and the putative CDC4 regulator SCM4.Transposon insertion mutants of these flanking genes failedto yield mutant filamentous growth phenotypes; so, the aberrantMUC1 regulation is derived from disruption of YGR050c. Collectively,however, it is difficult to draw obvious conclusions regardingthe molecular functions of the 84 uncharacterized genes presentedhere. Two hybrid data sets (Uetz et al., 2000; Ito et al., 2001)and synthetic lethal interaction studies (Tong et al., 2004)do not reveal a statistically significant enrichment for knownfilamentous growth genes among putative partners of these genes.Additional individual studies may be necessary to place thisgene set among regulatory and metabolic pathways affecting filamentousgrowth.

The Mitochondrial Retrograde Signaling Pathway Inhibits Filamentous Growth
Our transposon mutagenesis and overexpression analysis highlightsthe importance of mitochondrial function during filamentousgrowth, and, through additional follow-up studies, we identifythe RTG pathway as one route by which mitochondrial signalsmay affect filamentous growth. The RTG pathway is known to activateexpression of genes involved in glutamate biosynthesis (e.g.,CIT1, CIT2, ACO1, IDH1, and IDH2) (Liao and Butow, 1993; Liuand Butow, 2006), and glutamate, together with its downstreammetabolite glutamine, represents the principal nitrogen sourceused in biosynthetic reactions (Chen and Kaiser, 2002). TheRTG pathway, therefore, ensures a sufficient level of glutamateto meet cellular demands for nitrogen, especially in respiration-deficientcells. This function of the RTG pathway is conceptually consistentwith its observed role as an inhibitor of filamentous growth.Activation of the RTG pathway results in an increased concentrationof total cellular amino acids (Chen and Kaiser, 2002), and wespeculate this ameliorates nitrogen stress, thereby inhibitingfilamentous growth. We do not, as of yet, understand the exactmolecular mechanism by which nitrogen stress is sensed/transducedinto signals affecting filamentous growth; nor do we understandthe molecular link between filamentous growth and the RTG pathway.The TORC1 complex is the most obvious candidate, and the filamentousgrowth phenotypes we observe in relevant mutants are consistentwith previous studies suggesting that TORC1 activates filamentousgrowth and inhibits the RTG pathway (Komeili et al., 2000; Gancedo,2001). Interestingly, deletion of RTG2 in a rho⁰ mutant backgroundresults in intermediate filamentation; it does not restore wild-typelevels of filamentous growth, suggesting that mitochobndrialdysfunction may activate additional pathways affecting the filamentousgrowth response. Identification of these pathways will requireextensive investigation, and the gene set identified in thisstudy provides a first step toward that end.

A Broad Spectrum of Genes and Pathways Contribute to Yeast Filamentous Growth
In budding yeast, the morphological and genetic changes associatedwith the transition to filamentous growth are extensive, and,perhaps not surprisingly, the genes and pathways underlyingthese changes seem to be equally extensive. The MAPK and PKAsignaling modules initially identified as key components ofthe filamentous growth response are undeniably important inenabling filamentation, but the intense emphasis on these signalingmodules does not adequately characterize the broad molecularscope of filamentous differentiation. From the results presentedhere, literally hundreds of other genes confer filamentous growthphenotypes of equal severity to those observed upon disruptionof the MAPK and/or PKA pathway components. Although effortsto place these genes within specific pathways or networks willrequire sizable investments in labor and resources, our resultingknowledge base regarding yeast filamentous growth will expandtremendously as a result of such research, with concomitanthope of improved clinical antifungal therapeutics to follow.

ACKNOWLEDGMENTS

We thank Damian Krysan, Robert Fuller, Anthony Borneman, andMichael Snyder for providing filamentous yeast strains. Thiswork was supported by grant RSG-06-179-01-MBC from the AmericanCancer Society (to A.K.), grant DBI 0543017 from the NationalScience Foundation (to A.K.), and Basil O'Connor Award 5-FY05-1224from the March of Dimes (to A.K.).

Footnotes

This was published online ahead of print in MBC in Press(http://www.molbiolcell.org/cgi/doi/10.1091/mbc.E07-05-0519)on November 7, 2007.

Address correspondence to: Anuj Kumar (anujk{at}umich.edu)

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