Candida albicans VAC8 Is Required for Vacuolar Inheritance and Normal Hyphal Branching

Hyphal growth is prevalent during most Candida albicans infections.Current cell division models, which are based on cytologicalanalyses of C. albicans, predict that hyphal branching is intimatelylinked with vacuolar inheritance in this fungus. Here we reportthe molecular validation of this model, showing that a specificmutation that disrupts vacuolar inheritance also affects hyphaldivision. The armadillo repeat-containing protein Vac8p playsan important role in vacuolar inheritance in Saccharomyces cerevisiae.The VAC8 gene was identified in the C. albicans genome sequenceand was resequenced. Homozygous C. albicans vac8 ${Delta}$ deletion mutantswere generated, and their phenotypes were examined. Mutant vac8 ${Delta}$ cells contained fragmented vacuoles, and minimal vacuolar materialwas inherited by daughter cells in hyphal or budding forms.Normal rates of growth and hyphal extension were observed forthe mutant hyphae on solid serum-containing medium. However,branching frequencies were significantly increased in the mutanthyphae. These observations are consistent with a causal relationshipbetween vacuolar inheritance and the cell division cycle inthe subapical compartments of C. albicans hyphae. The data supportthe hypothesis that cytoplasmic volume, rather than cell size,is critical for progression through G₁.

INTRODUCTION

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Introduction

Vacuolar inheritance is thought to play an important role incell cycle control and cellular division in the pathogenic fungusCandida albicans (1). C. albicans is polymorphic and diploidand has no exploitable sexual cycle (9, 21, 25). In nutrient-richconditions this fungus exhibits bipolar budding, but under starvationconditions it undergoes morphological transitions to divideas pseudohyphae or hyphae (27). The degree of nutrient limitationregulates cell division in the growing hypha: branching frequenciesdecrease as the severity of the nutrient limitation increases(1). This is thought to represent a foraging response that allowsthe fungus to move efficiently to areas of nutrient sufficiency(18), and it has been suggested that this ability promotes fungalinvasion of host tissue (19).

During hyphal development in C. albicans, the germ tube growslinearly throughout the first cell cycle, at which point a septumis laid down, thereby dividing the hypha into two distinct compartments.The two compartments are equal in length, and each containsa single nucleus, but the two compartments differ in total cytosolicvolume. The apical compartment inherits the majority of thecytoplasm, leaving the subapical compartment highly vacuolatedand with little cytoplasmic volume (17). This asymmetrical celldivision has a profound impact on subsequent cell divisions.The apical compartment continues to grow at a constant rateand to divide as before. However, the subapical compartmentexhibits a growth delay and does not enter a second cell cycleto form a branch until the vacuole volume decreases and thecytosolic volume increases. We have shown previously that thesesubapical compartments are held in G₁ until critical cytosolicvolume is achieved and they can progress through Start (1).However, a causal relationship between vacuolar inheritanceand hyphal branching has not been confirmed.

Vacuolar inheritance in Saccharomyces cerevisiae is a spatiallyand temporally ordered event (48, 49, 52). In late G₁ the vacuoleorients itself toward the bud site. The onset of S phase resultsin the formation of a so called "segregation structure" thatconsists of a stream of small vesicles flowing from the nowfragmented maternal vacuole into the bud (50). Reversible dynamicflow of vacuolar material occurs between mother and daughter.Translocation of vacuolar vesicles is dependent upon the actincytoskeleton and myosin (Myo2p), which acts as the motor forthis dynamic process (20, 22). The process of vacuolar divisionlasts for approximately 20 min, culminating in M phase, andit results in the accumulation of small vesicles in the daughtercell (13). These subsequently fuse to form a mature vacuole.This phenomenon of vacuole fusion has been studied extensivelyin vitro and can be divided into three stages: priming, docking,and fusion (53, 54).

S. cerevisiae mutants defective in vacuole inheritance or segregationhave been isolated and characterized (14, 15, 38, 45, 51). Mutantsdefective in vacuole partitioning, known as vac mutants, havebeen categorized into three groups according to their vacuolemorphology (3, 7, 52) and further subdivided into vacuole protein-sorting(vps) mutants (14, 32, 33, 38, 45). Class I mutants have normalvacuole morphology but do not exhibit polarization toward thebud site. Hence, the resultant daughter cells contain littleor no maternal vacuolar material. Class II mutants have fewervacuolar lobes and contain a node on the vacuolar membrane.Large single vacuoles that sometimes display a single contiguousopen "figure eight" structure between mother and daughter cellsare found in class III mutants (52).

The close relationship between vacuole segregation and proteintransport pathways has inevitably resulted in mutants defectivein both processes. The class D vps mutants, which missort vacuolarproteins from the Golgi to the cell surface and also displayaberrant vacuole segregation, are examples of this. Theseare categorized as class II mutants according to theirvacuole morphology. This overlap makes it difficult to separatevacuole segregation from protein transport and to distinguishbetween cause and effect. Mutant screens, however, have ledto the isolation of a series of non-vps mutants. One of thesemutants is vac8 (10, 29, 42, 46).

In S. cerevisiae, vac8 mutants exhibit a multilobed or fragmentedvacuole phenotype and are defective in vacuolar inheritanceand in cytoplasm-to-vacuole protein targeting (Cvt pathway)(37). However, proteins are transported normally from the Golgito the vacuole (Vps pathway). As such, they are defined as classI, non-vps mutants. The Vac8p protein contains 11 armadillo(Arm) repeats and is most closely related to the Drosophilaarmadillo protein (34), ß-catenin (24), and plakoglobin(12). Tandem arrays of Arm repeats, each about 42 amino acidsin length, are proposed to form scaffold-like structures thatact to support multiprotein complexes. Vac8p is localized tothe vacuolar membrane and is required for multiple vacuole-relatedprocesses. Both myristoylation and palmitoylation of Vac8p arerequired for complete localization. Palmitoylation plays a rolein vacuolar inheritance (10, 29, 46) and is critical for subsequentvacuole fusion in the daughter cell (42, 46). Vacuolar inheritanceis dependent upon the formation of a complex between the molecularmotor Myo2p, the Myo2p-specific binding protein Vac17p, andVac8p (41). Vac17p provides the specific link between the motorprotein and the vacuole. Its expression correlates with thecell cycle, and hence Vac17p plays a critical role in the temporalregulation of vacuole inheritance.

In this study, we tested whether a causal relationship existsbetween vacuolar inheritance and hyphal branching in C. albicans.Our approach was to disturb vacuolar inheritance by disruptingthe VAC8 locus and then to examine vacuolar inheritance andhyphal growth in these mutants. Our data confirm the importanceof vacuolar segregation in the growth and division of the hyphalform of this human pathogen.

MATERIALS AND METHODS

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Materials and Methods

Strains and media. Standard yeast media and microbiological techniques were used(39). For liquid growth assays, cells were pregrown in yeastextract-peptone-dextrose (YPD) (39) overnight at 30°C andthen diluted to an optical density at 600 nm (OD₆₀₀) of 0.1in YPD, YPD containing 1.5 M NaCl, or YPD containing 2.5 M glycerol.Equivalent medium containing 2% (wt/vol) agar was used for theplate assays, and cell cultures were diluted as described byPalmer et al. (28). C. albicans strains are listed in Table1.

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TABLE 1. C. albicans strains used in this study

DNA manipulation. Based on partial genome sequence data available at the time,the primers 5'-GGATCCTCAAATTGACTTCATTACTTG and 5'-ATAGAGTTCAAAGAAATGCTACTGGGGwere used to PCR amplify 1.1 kb of the VAC8 open reading frame(ORF) from the C. albicans genome. This product was cloned intopGEMT to create pGEMT-VAC8 and sequenced using ABI Prism DyeTerminator cycle sequencing kits (Perkin-Elmer) and an ABI 377automated DNA sequencer. Subsequently, this sequence was usedto identify the VAC8 locus in contig4-2360 from the StanfordC. albicans genomic database. The complete C. albicans VAC8ORF, including 1 kb of 5' sequence, was then PCR amplified usingthe primers 5'-CAAGAAGCTTTCAAAATGGG (HindIII site underlined)and 5'-CCCAGCTAGCACTGTTGGTCC (NheI site underlined), clonedinto pGEMT, and resequenced. The HindIII-NheI VAC8 fragmentwas then cloned into a version of CIp10 (26) that contains theS. cerevisiae CYC1 terminator sequence (2) to create CIp-URA3-VAC8(CAVAC8-5).

Strain construction. To generate the vac8 ${Delta}$ ::hisG-URA3-hisG disruption cassette, ashort linker region (28 bp) containing unique HindIII and BglIIsites was cloned between the Pf1mI and EconI sites of pGEMT-VAC8.Then the hisG-URA3-hisG cassette was released from pMB-7 (11)by digestion with HindIII and BglII and cloned between the HindIIIand BglII sites in pGEMT-VAC8. This vac8 ${Delta}$ ::hisG-URA3-hisG cassettewas released from pGEMT with ApaI and SacI and transformed intoC. albicans strain CAI-4 with selection for Ura⁺ colonies (11),thereby deleting codons 339 to 459 of the 585-codon VAC8 ORF.This generated the VAC8/vac8::hisG-URA3-hisG heterozygote CAVAC8-1(Table 1). Ura3^– VAC8/vac8::hisG segregants were thenselected on YPD containing 5-fluoroorotic acid (11), therebygenerating strain CAVAC8-2. The second VAC8 allele was disruptedwith the vac8::hisG-URA3-hisG cassette to generate the vac8::hisG/vac8::hisG-URA3-hisGhomozygote CAVAC8-3. Ura3^– segregants were then selectedas described before, generating the null mutant CAVAC8-4. TheVAC8 gene was reintroduced into CAVAC8-4 on the plasmid CIp-VAC8.This plasmid was linearized with StuI and transformed into CAVAC8-4to create CAVAC8-5. At each stage of the process, the genotypeof strains was confirmed by diagnostic PCR and Southern blotting(36). Diagnostic PCR was carried out with a three-primer mix—VAC8ATG (5' ATGGGTGCCTGCTGTAGTTGTTTAGG 3'), VAC8 DEL (5' AAGCGGAAATTTCCAGTTGAACTG3'), and HisG (5' ACGCGCAGGATATCAATCGGCATGTTTTC 3')—todifferentiate between wild-type and disrupted alleles.

Western blotting. Protein extracts were prepared from cell cultures growing exponentially(OD₆₀₀ = 0.5 to 0.7) in YPD at 30°C. Cells were washed twicein ice-cold sterile water, and protein extracts were preparedas described previously (46). Equal protein loadings from eachsample were run on NuPAGE 4 to 12% Tris-N,N-methylenebisacrylamidegels in MOPS (morpholinepropanesulfonic acid) buffer and transferredonto polyvinylidene difluoride membranes according to the manufacturer'sinstructions (Invitrogen, Carlsbad, CA). Membranes were incubatedwith antibodies against S. cerevisiae Vac8p (46) and then withsheep anti-rabbit antibody conjugated to HRPO (Sigma) and developedusing enhanced chemiluminescence (Amersham Pharmacia BiotechUK Ltd., Buckinghamshire, England).

Vacuole staining. C. albicans yeast cells were stained with FM4-64 (MolecularProbes Europe BV), as described previously (44). Briefly, yeastcultures were grown in YPD to an OD₆₀₀ of about 0.1, harvested,and resuspended in 0.1 ml of medium containing 40 µM FM4-64.Samples were incubated at 30°C for 40 min and then washedin YPD. Cells to be grown in the yeast form were then resuspendedin 1 ml of fresh YPD and incubated for 2.5 h at 30°C beforeanalysis of the inheritance of vacuoles. To visualize newlysynthesized as well as inherited vacuoles, the chase periodwas reduced to 90 min. To visualize hyphal cells, samples wereincubated with FM4-64 as described and then resuspended in 1%serum at 37°C for 2.5 h (or 1.5 h, where specified). Vacuoleswere stained with CDCFDA [5- (and 6-) carboxy-2',7'-dichlorofluoresceindiacetate] (Molecular Probes Europe BV), as described previously(30). Cells were grown to early log phase, harvested, and resuspendedin 1 ml of YCM (1% yeast extract, 1% bactopeptone, 2% dextrose)(35) containing 50 µM CDCFDA. Cells were incubated at30°C for 30 min, collected by centrifugation, and viewed.

Growth analyses. To analyze the growth of budding cells, C. albicans strainswere grown overnight at 30°C in YPD, and these cells wereused to inoculate YPD, YPD containing 2.5 M glycerol, and YPDcontaining 1.5 M NaCl at a starting OD of 0.1. Growth was monitoredat 30°C and 37°C using the A₆₀₀. For each condition,triplicate cultures were analyzed and the whole experiment wasrepeated three times. Only reproducible differences in doublingtime are reported. To examine hyphal growth and branching, approximately10⁴ yeast cells from an overnight C. albicans culture were inoculatedonto a poly-L-lysine (Sigma) slide. The slides were incubatedovernight in 1% serum at 37°C, washed in H₂O, and stainedwith calcofluor white, as described previously (16). Hyphalgrowth and branching were measured (1).

Microscopy. Phase-contrast and fluorescence microscopy were performed usingan Axioplan 2 microscope (Carl Zeiss Ltd., United Kingdom) withfilter sets XF 66, XF 67, and XF 77 (Omega Optical Inc., Brattleboro,VT). Images were generated using a Hamamatsu charge-coupled-devicecamera.

RESULTS

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Results

Isolation and analysis of C. albicans VAC8. The overall aim of this study was to test whether there is acausal relationship between vacuolar inheritance and hyphalbranching in C. albicans. To achieve this we needed to generatea C. albicans mutant in which vacuole inheritance was disrupted.We targeted the VAC8 locus, because of its key role in vacuolarinheritance in S. cerevisiae (10, 29, 46).

Initially we identified the homologue of S. cerevisiae VAC8on the basis of partial C. albicans genome sequence information.Subsequently, the complete VAC8 sequence became available withinthe Stanford C. albicans genome sequence database. The VAC8locus was PCR amplified and resequenced, revealing a 100% matchwith the genome sequence (orf19.745; IPF9747.1). The predictedamino acid sequence of C. albicans Vac8p is 69% identical and81% similar to that of S. cerevisiae Vac8p (Fig. 1). The mostconserved regions are the Arm repeats, which are believed tobe important for Vac8p function.

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FIG. 1. Comparison of the predicted C. albicans and S. cerevisiae Vac8 proteins. Arm repeats are indicated between vertical lines. The conserved amino-proximal cysteine residues important for palmitoylation (42, 47) and the conserved amino-terminal glycine residue involved in myristoylation (46) are indicated by boldface type.

C. albicans VAC8 gene disruption. Both alleles of the C. albicans VAC8 locus were disrupted sequentiallyusing a vac8::hisG-URA3-hisG cassette that deleted amino acids339 to 459 and blocked the expression of the 585-amino-acidprotein. The disruption of the locus was confirmed by Southernblotting (not shown) and diagnostic PCR (Fig. 2A). Furthermore,Western blotting with antibodies raised against S. cerevisiaeVac8p (46) indicated that no Vac8p was detectable in the deletionmutant (Fig. 2B). C. albicans vac8 ${Delta}$ cells were viable, suggestingthat VAC8, like its homologue in S. cerevisiae, is not an essentialgene (46).

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FIG. 2. Confirmation of VAC8 gene deletion. (A) Transformants from each round of disruption were screened by PCR using a mix of three primers: VAC8 ATG, VAC8 DEL, and HisG. VAC8 ATG and VAC8 DEL produce a band of 1.2 kb in the wild-type locus, and the product of VAC8 ATG and HisG is 1.3 kb in a disrupted locus. (B) Western blot of protein extracts from CAF-2, CAVAC8-1, CAVAC8-3, and CAVAC8-5. Equal protein extracts from each strain were loaded into a gel and transferred to a polyvinylidene difluoride membrane, as described in Materials and Methods. The blot was probed with ScVac8p antiserum.

Effect of disruption of VAC8 upon vacuolar inheritance of C. albicans. Our rationale for targeting Vac8p was that, based on the functionof its homologue in S. cerevisiae (10, 29, 46), it was likelyto play an important role in the inheritance, rather than thesynthesis, of vacuoles in C. albicans. To test this we comparedthe vacuoles in wild-type and vac8 ${Delta}$ cells.

Vacuoles were visualized in budding cells by using a stablederivative of fluorescein diacetate (CDCFDA). The number ofvacuoles per cell was determined for all cells within a fieldof view (Table 2). Wild-type (CAF2-1) and vac8 ${Delta}$ cells (CAVAC8-3)were compared. All wild-type buds contained visible vacuoles,but only 50% of the buds on vac8 ${Delta}$ cells contained visible vacuoles.Furthermore, more than four vacuoles were visible in most vac8 ${Delta}$ mother cells, and these were more fragmented than the vacuolesof wild-type mother cells. To gain greater insight into themorphology of the vacuoles in vac8 ${Delta}$ cells, we stained them withthe lipophilic styryl dye FM4-64. The detectable vacuolar materialwas greatly reduced if not absent in vac8 ${Delta}$ daughter cells, comparedwith mother cells (Fig. 3). Furthermore, these vacuoles appearedto be more fragmented or multilobed than wild-type vacuoles.Hence, the inactivation of VAC8 caused defects in the vacuolarinheritance of budding C. albicans cells similar to those seenin S. cerevisiae vac8 ${Delta}$ mutants.

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TABLE 2. Effect of vac8 ${Delta}$ on vacuolar inheritance in budding cells

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FIG. 3. Effect of vac8 ${Delta}$ upon vacuolar inheritance in budding cells. Cells were stained with FM4-64 and then visualized after a 2.5-h chase period. Microscopy of budding cells is as follows: phase-contrast image of CAF2-1 cells (a), FM4-64-stained CAF2-1 cells (b), phase-contrast image of CAVAC8-3 cells (c), and FM4-64-stained CAVAC8-3 cells (d). Arrows indicate vacuolar material inherited by daughter cells. Bar, 10 µm.

Vacuolar inheritance was also examined in hyphal cells (Fig.4). VAC8 and vac8 ${Delta}$ cells were stained with FM4-64 and then inducedto form hyphae in 1% serum at 37°C for 2.5 h. Vacuolar stainingwas evident throughout the length of the wild-type hyphae. Thevacuolar staining in vac8 ${Delta}$ hyphae was significantly reduced incomparison with the wild-type hyphae. Furthermore, for vac8 ${Delta}$ cells, most staining was observed in the mother cell, and minimalstaining was observed in subapical compartments. Normal vacuolestaining was visualized in both yeast and hyphal forms in thereintegrant strain CAVAC8-5 (Fig. 4L). We conclude that, aspredicted, the inactivation of VAC8 caused defects in vacuolarinheritance in both the yeast and hyphal growth forms of C.albicans.

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FIG. 4. Effect of vac8 deletion upon vacuolar inheritance in hyphal cells. Hyphal cells were stained with FM4-64 and then visualized after a chase period. (A to H) To visualize inherited vacuoles, a chase period of 2.5 h was used. Shown are a phase-contrast image (A) and FM4-64-stained (B) CAF2-1 hyphal cells. (C, E, and G) Phase-contrast image of CAVAC8-3 cells. (D, F, and H) FM4-64-stained CAVAC8-3 cells. Vacuolar inheritance was restored in CAVAC8-5 cells (not shown). (I to L) A shorter chase period (90 min) was used to visualize newly synthesized as well as inherited vacuoles. Shown are a phase-contrast image (I) and FM4-64-stained (J) CAVAC8-3 cells and a phase-contrast image (K) and FM4-64-stained (L) CAVAC8-5 cells. Bar, 10 µm.

Effects of disruption of VAC8 upon growth of C. albicans in the yeast form. Our next objective was to determine whether C. albicans celldivision was affected by the vac8 deletion. This was analyzedin both yeast and hyphal cells using Ura3⁺ cells, because ura3mutants are known to display subtle hyphal growth defects (4,8, 40).

No significant differences in the growth rates of wild-typeand vac8 ${Delta}$ cells were detecttheed on YPD plates at 30°C (notshown). However, vacuolar dysfunction is known to cause sensitivityto osmotic stress and/or increased temperature (5, 28, 46).Therefore, we tested the sensitivity of vac8 ${Delta}$ cells to osmoticstress and elevated temperatures during growth in the yeastform. There were no detectable differences in the growth ofwild-type (CAF2-1) and vac8 ${Delta}$ (CAVAC8-3) cells on YPD plates containing1.5 M NaCl or 2.5 M glycerol at 30°C or 37°C (not shown).However, subtle differences were reproducibly observed in liquidcultures. The doubling time of vac8 ${Delta}$ cells was 1.25-fold longerthan that of wild-type cells in YPD containing 1.5 M NaCl at30°C. A twofold difference in growth rate was observed inthis medium at 37°C. Similar differences in growth ratewere observed when osmostress was applied with 2.5 M glycerol.At 30°C the doubling time of vac8 ${Delta}$ cells was 1.25-times longerthan that of wild-type cells, and at 37°C this differencewas increased to 1.5-fold. Therefore, the aberrant vacuolarinheritance of budding vac8 ${Delta}$ cells correlated with a slight increasein sensitivity to osmotic stress and temperature.

Effects of the VAC8 deletion upon hyphal growth. To quantify the effects of the VAC8 deletion upon hyphal development,wild-type (CAF2-1), heterozygous VAC8/vac8 ${Delta}$ (CAVAC8-1), homozygousvac8 ${Delta}$ /vac8 ${Delta}$ (CAVAC8-3), and reintegrant vac8 ${Delta}$ /vac8 ${Delta}$ /VAC8 (CAVAC8-5)cells were immobilized on poly-L-lysine slides and incubatedin 1% serum at 37°C for 14 h. Hyphal development was stimulatedwith 1% serum because we had observed the strongest correlationbetween vacuolation and hyphal division under these conditions(1). The cells were stained with calcofluor white, which interchelateswith chitin, to visualize cell walls and septa (Fig. 5). Allhyphal cells within the field of view were counted. There wasno significant difference in the number of compartments in VAC8and vac8 ${Delta}$ hyphae over the duration of the experiment (Fig. 6A).However, there was a significant increase in the proportionof branched hyphae for vac8 ${Delta}$ cells compared with wild-type, heterozygous,and reintegrant cells (Fig. 6B). Furthermore, there was a significantincrease in the number of branches emanating from the primaryhyphae of the vac8 ${Delta}$ strain compared with the control strains(Fig. 6C). Significantly more branches were evident in CAVAC-3hyphae than in CAF-2, CAVAC8-1, or CAVAC8-5 hyphae (Fig. 5 and6). Similar data were generated in three independent experiments.Therefore, the inactivation of VAC8 caused a significant increasein hyphal branching. This was consistent with a role for vacuolarinheritance in the regulation of hyphal cell division.

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FIG. 5. Branching phenotype of hyphal VAC8 and vac8 ${Delta}$ cells. Individual cells were examined microscopically following calcofluor white staining. Phase-contrast images are shown on the left; calcofluor white-stained cells are shown on the right. (A and B) CAF2-1 hyphal cells. (C and D) CAVAC8-3 cells. (E and F) CAVAC8-3 cells. (G and H) CAVAC8-5 cells. Bar, 20 µm.

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FIG. 6. Quantification of hyphal growth and division of VAC8 and vac8 cells. The phenotypes of wild-type (CAF-2), VAC8/vac8 (CAVAC8-1), vac8/vac8 (CAVAC8-5), and vac8/vac8/VAC8 (CAVAC8-5) cells were quantified using the image types illustrated in Fig. 5. (A) Total length of hyphae determined by total number of compartments. Data are for length of the primary hypha only (n = 100). (B) Percent branched and unbranched hyphae. Only true branches were counted (n = 100). Bud-shaped or pseudohyphally shaped filaments were discounted. (C) Degree of branching was determined by counting the number of true branches emanating from the primary hypha (n = 300). Branching from secondary hyphae was not included in this analysis.

DISCUSSION

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Discussion

In true, unconstricted C. albicans hyphae, there is a correlationbetween cell cycle progression and vacuolar status (1). Themore vacuolated the subapical cell, the greater the delay incell division before a new branch is formed. We have shown previouslythat, under nutrient-limiting conditions that induce long, sparselybranched hyphae (for example, in media containing a low serumconcentration), the apical compartment inherits most of thecytoplasmic material while subapical compartments inherit mostlyvacuolar material. Hence, subapical cells are highly vacuolated,and they are also arrested in G₁, prior to the point in thecell cycle at which a new branch would emerge from these subapicalcompartments (1). The addition of nutrients leads to a decreasein vacuole volume and an increase in cytoplasmic content, whichcorrelates with increased hyphal branching. Hence, we proposedpreviously that there is a causal relationship between vacuolarstatus and cell cycle progression in subapical compartments(1). In this study, we set out to test this hypothesis. Ourapproach was to disturb vacuolar inheritance by inactivatingVAC8 and then to examine the effects upon hyphal growth.

The vacuolar phenotype of C. albicans vac8 ${Delta}$ cells was similarto that visualized in S. cerevisiae (10, 29, 46). In S. cerevisiae,the vacuoles of vac8 null mutants display a fragmented or multilobedappearance and a reduced degree of vacuolar inheritance. TheC-terminal truncation of S. cerevisiae Vac8p inhibits vacuolarinheritance, and the severity of this phenotype correlates withthe extent of truncation (46). A deletion in S. cerevisiae VAC8that is analogous to the deletion we created in C. albicansVAC8 causes a dramatic inhibition of vacuolar inheritance inS. cerevisiae (Fig. 3; Table 2). The Arm repeats within theVac8p protein (Fig. 1) are believed to be important for theinteraction of the vacuole with actin (20). Movement along actinfilaments directs the segregation structure toward the daughtercell. The localization of Vac8p on the surface of the vacuolemembrane is essential to its interaction with the Myo2p-specificreceptor Vac17p. This specific three-way interaction providesspatial and temporal control over vacuolar inheritance. Althoughvacuole inheritance is not completely abolished in the C. albicansvac8 ${Delta}$ cells, it is greatly reduced, implying that Vac8p playsa role in C. albicans similar to that of its S. cerevisiae homologue.

C. albicans vac8 ${Delta}$ mutants still undergo morphogenesis to formtrue hyphae (Fig. 4). The fact that vac8 ${Delta}$ hyphae grow with normalextension rates suggests that Vac8p inactivation does not inhibitintracellular protein trafficking and vesicular delivery ofcell wall synthetic material to the growing tip.

The vac8 ${Delta}$ hyphae were more branched under low-serum conditionsthan were wild-type cells (Fig. 5). An increased number of secondaryhyphae emerged from the subapical compartments of the vac8 ${Delta}$ primaryhypha (Fig. 5C). In addition, these cells exhibited tertiaryand quaternary branching, unlike the control VAC8 cells (datanot shown). We conclude that disturbing vacuolar inheritancecauses a defect in hyphal branching patterns in C. albicans(Fig. 6). Aberrant vacuolar inheritance releases subapical cellsfrom the delay in cell cycle progression that is normally observedin hyphae under nutrient-limiting conditions.

Bruckmann and coworkers isolated and characterized the C.albicansVPS34 gene, which encodes a phosphatidylinositol 3-kinase (5,6). C. albicans vps34 ${Delta}$ cells have an enlarged vacuole (5, 6),but any adverse affects of Vps34p disruption on the recyclingof cell surface receptors and signal transduction are currentlyunknown. On the basis of our model (Fig. 6), which relates cellvacuolation to cellular division, one would expect vps34 ${Delta}$ cellsto display a delay in hyphal branching. Interestingly, C. albicansvps34 ${Delta}$ cells do exhibit delayed hyphal formation in liquid serummedium and an inability to switch on solid Spider medium andsolid serum-containing medium (5). We note that a mechanisticlink between endocytosis and the Rim101 pathway exists throughSnf7 (23) and that Rim101 signaling regulates morphogenesisin response to ambient pH (31). However, other endocytosis mutantsdo not affect Rim101 signaling (23), and therefore it seemslikely that, in general, the hyphal defects of vacuole mutantsare not mediated by effects on the Rim101 pathway.

Another C. albicans vacuolar protein-sorting mutant (vps11)has been studied extensively by Palmer et al. (28). This mutantalso shows defective hyphal formation in addition to increasedsensitivity to temperature, salt, and osmotic stresses. Thevps11 null mutant exhibits diffuse vacuolar staining indicativeof a vacuolar biogenesis defect. C. albicans vps11 ${Delta}$ cells containsmall amounts of vacuolar material, and they are unable to formgerm tubes as efficiently as wild-type cells. It is not knownwhether this phenotype is due to the physical lack of a vacuole,to the loss of multiple transport steps in vacuolar proteindelivery, to the loss of Kex2p activity, or simply to a temperature-relatedgrowth defect. As this mutant exhibits multiple phenotypes,it is difficult to attribute the defect in hyphal formationto vacuolar biogenesis.

An essential gene that results in altered budding growth (ABG1)has recently been described by Veses and coworkers (43). Inhyphal cells, a null mutant displays small, fragmented vacuoles,which is concurrent with an increased branching frequency. Thisobservation is entirely consistent with our working model inwhich decreased vacuolar content causes an increase in hyphalcell division.

In this study, we examined the effects of mutations in a geneinvolved in vacuolar inheritance rather than in vacuolar biogenesis.Indeed, C. albicans vac8 ${Delta}$ cells displayed normal growth ratesin the absence of osmotic stress. Therefore, we were able todistinguish the effects of disrupting VAC8 on growth rate fromthose on cell division. Our data strongly support the hypothesisthat cytoplasmic volume, rather than total cell volume, is acritical determinant for entry into S phase (1). Highly vacuolatedsubapical cells do not enter S phase until the cytoplasmic volumeincreases sufficiently to traverse Start (Fig. 7). This modelmight be generally applicable to the eukaryotic cell divisioncycle.

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FIG. 7. Model of a growing hypha. The septa are depicted as thick black lines, and the vacuoles are black ellipsoid shapes. As the growing hypha extends and divides, the subapical compartment inherits the majority of the vacuole and the apical cell inherits little. As a direct result of this, the apical cell can continue growing without delay and enter the next stage in the cell cycle. The subapical cell, however, does not have sufficient cell density to pass through Start. Hence, there is a delay in branching that correlates with the degree of vacuolation.

ACKNOWLEDGMENTS

We thank Lois Weisman (Department of Biochemistry, Universityof Iowa, Iowa City, Iowa) for providing S. cerevisiae vac8 strainsand for communicating data prior to publication. We are alsograteful to Norbert Schnell (AstraZeneca) for providing earlyaccess to the C. albicans VAC8 sequence.

This work was supported by the U.K. Biotechnology and BiologicalSciences Research Council (PAC02657), the Wellcome Trust (055015),and the European Commission.

FOOTNOTES

* Corresponding author. Mailing address: School of Medical Sciences, University of Aberdeen, Institute of Medical Sciences, Foresterhill, Aberdeen AB25 2ZD, United Kingdom. Phone: 44-1224-555883. Fax: 44-1224-555844. E-mail: al.brown{at}abdn.ac.uk.

REFERENCES

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