Yeast-to-Hyphal Transition Triggers Formin-dependent Golgi Localization to the Growing Tip in Candida albicans

Padmashree C.G. Rida^*, Akiko Nishikawa^*, Gena Y. Won, and Neta Dean

Department of Biochemistry and Cell Biology, Stony Brook University, Stony Brook, NY 11794-5215

Submitted February 16, 2006; Revised July 11, 2006; Accepted July 12, 2006
Monitoring Editor: Daniel Lew

ABSTRACT

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Rapid and long-distance secretion of membrane components iscritical for hyphal formation in filamentous fungi, but themechanisms responsible for polarized trafficking are not wellunderstood. Here, we demonstrate that in Candida albicans, themajority of the Golgi complex is redistributed to the distalregion during hyphal formation. Randomly distributed Golgi punctain yeast cells cluster toward the growing tip during hyphalformation, remain associated with the distal portion of thefilament during its extension, and are almost absent from thecell body. This restricted Golgi localization pattern is distinctfrom other organelles, including the endoplasmic reticulum,vacuole and mitochondria, which remain distributed throughoutthe cell body and hypha. Hyphal-induced positioning of the Golgiand the maintenance of its structural integrity requires actincytoskeleton, but not microtubules. Absence of the formin Bni1causes a hyphal-specific dispersal of the Golgi into a hazeof finely dispersed vesicles with a sedimentation density nodifferent from that of normal Golgi. These results demonstratethe existence of a hyphal-specific, Bni1-dependent cue for Golgiintegrity and positioning at the distal portion of the hyphaltip, and suggest that filamentous fungi have evolved a novelstrategy for polarized secretion, involving a redistributionof the Golgi to the growing tip.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The establishment of axes of polarization is crucial for thegrowth and division of both unicellular and multicellular organisms.A striking example of polarized morphogenesis is the processof hyphal formation in Candida albicans. In response to a numberof inductive signals, C. albicans switches from an ovoid yeastform to a highly elongated hyphal form, and its capacity toswitch between these forms is postulated to be related to itsvirulence as a fungal pathogen (Lo et al., 1997; Gow et al.,2002). Within minutes of encountering the inducing signal, growthis restricted to the germ tube, which rapidly extends into afilament that becomes >10 times the length of the cell bodywithin hours.

The mechanism that establishes and maintains rapid apical growthduring hyphal formation in C. albicans is not well understood.However, based on our knowledge of how polarized growth occursin other systems, it is generally accepted to involve the asymmetricdeposition of membrane and cell wall at the growing tip. Studiesfrom Saccharomyces cerevisiae have established that in responseto certain spatial or positional cues, Golgi-derived secretoryvesicles that fuse with the plasma membrane at random sitesduring isotropic growth of the mother cell are retargeted tofuse at a specified site, resulting in bud emergence and apicalgrowth (for review, see Lew and Reed, 1995; Finger and Novick,1998). The process of budding requires many proteins that regulatesite selection, reorganization of the actin cytoskeleton, andpolarization of the secretory apparatus (for review, see Pruyneet al., 2004b). Hyphal growth in C. albicans presents an additionalchallenge owing to the requirement to rapidly deliver materialsover a long distance. Rapid hyphal formation and elongationare crucial for the success of C. albicans as a pathogen, somechanisms that regulate efficient secretion are likely to bevital for its fitness and pathogenicity in the host environment.

Several conserved proteins that organize the actin cytoskeletonto orient polarized secretion in other organisms are known tobe required for hyphal formation in C. albicans. Among these,the formins play a key role as downstream effectors that linkRho-GTPase signaling to the remodeling of the actin cytoskeleton(Kohno et al., 1996; Tominaga et al., 2000; Evangelista et al.,2002; Sagot et al., 2002). Formins function in vivo and in vitroas actin cable nucleators (Evangelista et al., 2002; Pruyneet al., 2002) and this actin nucleating activity is triggeredby Rho-GTPases (see Evangelista et al., 2003). The S. cerevisiaeformin Bni1 binds activated forms of Rho1 and Cdc42 throughits N terminus (Kohno et al., 1996; Evangelista et al., 1997).Among other proteins, Bni1 also binds Spa2 (Fujiwara et al.,1998), which is the scaffolding component of a multiproteinstructure termed the polarisome that localizes to the growingtip in a cell cycle-dependent manner (Sheu et al., 1998). Theseregulated interactions that recruit Bni1 to the growing tipand coordinate its activity with the cell cycle ensure thatactin nucleation, and hence polarized secretion, occurs at theright time and place. As in S. cerevisiae, C. albicans encodestwo partially redundant formins, CaBni1 and CaBnr1. Simultaneousloss of both formins leads to lethality, and even though bothproteins can be found at the hyphal tip, Bni1, but not Bnr1,is required for normal hyphal progression (Li et al., 2005;Martin et al., 2005).

Although budding in S. cerevisiae has proved to be a usefulparadigm for studying polarized growth, several observationssuggest that there are some fundamental differences betweenthe regulation of budding in S. cerevisiae and hyphal formationin C. albicans (for review, see Sudbery et al., 2004). First,budding in S. cerevisiae is tightly coupled to the cell cycle(Lew and Reed, 1995), whereas in C. albicans the initiationand elongation of hyphae is regulated independently of the cellcycle (Hazan et al., 2002). Second, unlike budding yeast, theapex of C. albicans hyphal cells contains a high density ofsmall vesicles and other unidentified membranous structures,defined almost 80 years ago as the Spitzenkörper ("tipbody"), which is thought to act as the supply center of secretoryvesicles whose localization and directed deposition are essentialfor tip growth (Howard, 1981; Reynaga-Pena et al., 1997). Thesemembranous structures are thought to be Golgi-derived secretoryvesicles poised to fuse at the growing hyphal tip, but the compositionof the Spitzenkörper remains largely uncharacterized. Studiesof several filamentous fungi suggest that Bni1 in hyphal cellscolocalizes with the Spitzenkörper and not the polarisome,highlighting yet another difference between yeast and hyphalcells (Sharpless and Harris, 2002; Crampin et al., 2005; Martinet al., 2005). Finally, in S. cerevisiae, polarization and thetargeting of post-Golgi vesicles to the selected growth siteis an actin-based process and does not require microtubules.Although the actin cytoskeleton is essential for hyphal formationin C. albicans, there are conflicting reports of the role ofmicrotubules in this process (Yokoyama et al., 1990; Akashiet al., 1994). In other filamentous fungi, microtubules areimportant for rapid hyphal growth (Howard and Aist, 1977; Thatet al., 1988; Temperli et al., 1990; Raudaskoski et al., 1994;Steinberg et al., 2001), and it has been proposed that theyare responsible for the long-distance transport of post-Golgisecretory vesicles to the Spitzenkörper, whereas actinfilaments control short-range vesicle transport from the Spitzenkörperto the plasma membrane (Crampin et al., 2005; Harris et al.,2005).

To examine the role of the secretory pathway and the cytoskeletonduring hyphal formation in C. albicans, we analyzed severaldifferent epitope-tagged reporters of the Golgi, endoplasmicreticulum (ER), and vacuole, in live cells and by indirect immunofluorescence.We report that in contrast to other polarized cells that achievelong-distance transport of post-Golgi secretory vesicles oncytoskeletal tracks, C. albicans has evolved an alternativeand additional means of establishing polarity, whereby the majorityof the Golgi complex is redistributed to and maintained at thedistal portion of the hyphae near the growing apical tip. Ourstudies also demonstrate an additional, previously unrecognizedrole for the actin cable-nucleating formin Bni1, in localizingthe Golgi complex at the hyphal tip, and in maintaining thestructural integrity of the Golgi during the yeast-to-hyphaltransition.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Strains, Media, Growth Conditions, and Transformation Protocols
The C. albicans strains used in this study are listed in Table 1.For the characterization of Vrg4-GFP in S. cerevisiae, the chromosomallocus in W303a (MATa ade2-1 ura3-1 his3-11 trp1-1 leu2-3112can1-100) was tagged with green fluorescent protein (GFP) bypolymerase chain reaction (PCR)-mediated recombination by usingthe pFA6a-GFP-HIS3 plasmid as template (Longtine et al., 1998).Strains were routinely grown on YPAD (1% yeast extract, 2% BactoPeptone, 50 mg/l adenine sulfate, 2% glucose) or a minimal (SD)medium (0.67% yeast nitrogen base without amino acids supplementedwith 2% glucose) supplemented appropriately. Growth of cellsused for immunofluorescence was in YPAD, because we found thataddition of uridine to the growth medium resulted in an increasedlevel of autofluorescence.

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Table 1. C. albicans strains used in this study

To induce hyphal formation, cultures were grown overnight at30°C in YPAD to stationary phase, diluted the followingday to an OD₆₀₀ of 0.4 in YPAD containing 20% bovine calf serum,and incubated at 37°C for various times. For longer time-courseexperiments, cells were grown overnight in YPAD into stationaryphase and diluted to an OD₆₀₀ of 0.5–1.0 before seedingthem on coverslips. This protocol enabled the growth of individual,long hyphal cells that were otherwise too tangled to view individually.Seeded coverslips were placed in 24-well plates containing prewarmedYPD + 20% bovine calf serum and incubated at 37°C for thedurations indicated.

For induction of pseudohyphae, cultures were grown overnightat 30°C in YPAD to stationary phase. They were diluted thefollowing day to an OD₆₀₀ of 0.4 in YPAD buffered at pH 6.0with citric acid and incubated at 36°C (Sudbery et al.,2004). Transformation of C. albicans to integrate linearizedplasmids into chromosomal loci was carried out as describedpreviously (Walther and Wendland, 2003).

Plasmid Constructions
Plasmids and their relevant features used in this study arelisted in Table 2. The construction of all plasmids used toexpress either GFP-, myc-, or influenza hemagglutinin (HA)-taggedproteins was based on CIp10, a URA3 integration plasmid thatallows efficient integration of the target gene into the chromosomalRP10 locus (Murad et al., 2000). CIp10-HA₃ and CIp10-myc₃ allowC-terminal protein tagging with three tandem copies of the HAor myc epitope. These plasmids were made by ligating the SacI/NotI(blunted) fragment of either pSK-HA₃(P/X) or pSK-Myc₃(P/X) (Neimanet al., 1997) to the SacI/EcoRV fragment of CIp10.

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Table 2. Plasmids used in this study

Genes encoding the various reporter proteins (CaVRG4, CaKAR2,CaGDA1, CaALG1, and CaOCH1) used in this study were generatedby PCR by using CAI4 genomic DNA as template. Primers includedrestriction enzyme sites for in-frame ligation of each of thesegenes to the sequences encoding HA₃, myc₃, or yEGFP, in CIp10-HA₃,CIp10-myc₃ CIp10-GFP. Primers and their sequences are availableon request. The correct sequence of all of these fusion geneswas verified by DNA sequencing. Integration of these fusiongenes after linearization of the plasmid with Stu1 was confirmedby PCR, and protein expression was determined by Western blotting.The functionality of each reporter was also assessed by complementationof the corresponding S. cerevisiae or C. albicans mutant (Nishikawaet al., 2002

; our unpublished data).

pER-GFP encodes a yeast codon-optimized GFP tagged with theER retention signal HDEL at the COOH terminus and the CaKar2signal sequence at the NH₂ terminus. To construct this plasmid,the CaKAR2 open reading frame (ORF) (lacking a stop codon) wasamplified by PCR from genomic DNA purified from CAI4. This Xho1/Cla1fragment was cloned into the same sites of pSK P/X HA₃ (Neimanet al., 1997), which results in the in-frame fusion of the KAR2ORF and its promoter to sequences encoding three copies of theHA epitope. Sequences encoding HDEL sequences were appendedat the 3' terminus by incorporating these sequences into a reverseprimer used to amplify this fragment. This entire KAR2-HA-HDELfragment was amplified by PCR as an Xho1/Mlu1 fragment and clonedinto CIp10-ADH2p to generate CIp-CaKar2-HA-HDEL, which placesthis gene under the transcriptional control of the ADH2 promoter.After confirming the sequence, expression and ER localizationof this fusion protein, the KAR2 ORF in CIp-CaKar2-HA-HDEL wasreplaced with yEGFP amplified by PCR from pUC19 containing yEGFP(Cormack et al., 1997). This generates an HDEL-tagged GFP thatis targeted to the ER by the Kar2 signal sequence and whoseexpression is driven by the ADH2 promoter. The correct sequenceof this KAR2-GFP-HDEL fragment was verified by DNA sequenceanalysis. The KAR2-GFP-HDEL fusion gene ("pER-GFP") was integratedat the RP10 locus after linearization with Stu1.

Treatment of Cells with Brefeldin A (BFA), Nocodazole (NZ), and Cytochalasin A (CA)
Wild-type cells expressing CaVRG4-GFP were grown overnight inYPAD to stationary phase and induced to form hyphae for 1.5h to allow the redistribution of the Golgi to the distal regionof hyphae. BFA (Sigma-Aldrich, St. Louis, MO) was added to afinal concentration of 80 µg/ml (from a 5 mg/ml stocksolution in ethanol) along with 0.06% SDS, whose addition rendersthe cells more permeable to BFA (Pannunzio et al., 2004). Correspondingvolumes of ethanol and SDS were added to the control culture,and both were incubated for an additional 30 min at 37°Cwith shaking. Samples were harvested and CaVrg4-GFP localizationwas visualized by fluorescence microscopy.

Microtubules were depolymerized by NZ (Sigma-Aldrich) treatmentof yeast or hyphal cells. For examination of yeast cells, overnightcultures of a wild-type strain (BWP17) and TUB2-GFP were dilutedto an OD₆₀₀ of 0.2, and NZ was added (from a 10 mg/ml stockin dimethyl sulfoxide [DMSO]) at the indicated concentrations.Cells were incubated in the presence or absence of NZ for 2h and 15 min and directly viewed to quantitate visible microtubules.An aliquot of cells was also fixed in 3.7% formaldehyde andstained with 4', 6-diamidino-2-phenylindole (DAPI; Vector Laboratories,Burlingame, CA) to visualize nuclei by fluorescence microscopy.Titration of NZ in both yeast and hyphal cells demonstratedthat 5 µM NZ inhibited both nuclear division and microtubuleformation. At concentrations higher than 5 µM, cells showedevidence of lysis that increased with increasing NZ concentrationin the culture.

For the examination of NZ effects on microtubules in hyphalcells, cells expressing GFP-tagged CaVRG4, CaTUB1, or CaTUB2were grown overnight in YPAD to stationary phase, diluted, andinduced to form hypha in the presence of 5 µM NZ for 1.5h. Cells were harvested and immediately processed for imagingof CaVrg4-GFP, Tub1-GFP, and Tub2-GFP or fixed with 3.7% formaldehydeand stained with DAPI to visualize nuclei after NZ treatment.

To inhibit actin cable formation, C. albicans or S. cerevisiaecells were treated with CA (Fisher Scientific, Pittsburgh, PA).Overnight C. albicans cell cultures (OD₆₀₀ of 30–35) werediluted and induced to form hyphae in the presence or absenceof various concentrations of CA (stock solution of 5 mg/ml inDMSO) ranging from 1 to 100 µg/ml CA and 0.06% SDS tofacilitate the uptake of CA into the cells. For the treatmentof S. cerevisiae cells, overnight cultures (OD₆₀₀ of $~$ 10) werediluted to 0.5 OD₆₀₀ units/ml and grown for 2 h before the additionof 5 µg/ml CA. S. cerevisiae VRG4-GFP cells were incubatedfor 30 min before visualization of GFP. Corresponding volumesof SDS and DMSO were added to the untreated cells. C. albicansstrains were incubated for variable times as indicated. It shouldbe noted that our experiments demonstrated that CA is unstablein YPAD over hours. Thus, in all CA experiments, cells wereharvested and replenished with fresh CA-containing medium atthe appropriate concentration every 30 min, during which timeCA retains activity (our unpublished data).

Microscopy, Indirect Immunofluorescence, and Fluorescent Staining Techniques
We used a fluorescence microscope (Zeiss Axioskop model 2 plus;Carl Zeiss, Thornwood, NY) equipped with a 100x/1.3 oil objective(Plan-neofluor), a high-performance charge-coupled device camera(DAGE-MTI, Michigan City, IN), and Scion Image software version4.50 (Carl Zeiss) for image capture. Single focal plane imageswere processed using Adobe Photoshop CS, version 8 (Adobe Systems,Mountain View, CA) or Canvas, version 9 (ACD Systems of America,Miami, FL).

Indirect immunofluorescence microscopy was performed as describedpreviously (Dean et al., 1997) with the following modifications.After inducing hyphal growth for various periods as indicated,cells in medium were fixed using formaldehyde for 30 min at30°C, followed by an additional 3-h incubation in 100 mMpotassium phosphate buffer containing 3.7% formaldehyde. Fixedspheroplasts were incubated with rabbit polyclonal anti-HA antibody(Y-11; Clontech, Mountain View, CA), diluted 1:200, or withmouse 9E10 monoclonal anti-myc antibody, diluted 1:10. Afterincubation with the primary antibody cells were washed and incubatedwith Alexa 488-conjugated anti-rabbit or anti-mouse IgG antibody(Invitrogen, Carlsbad, CA) diluted 1:300. After washing extensivelywith phosphate-buffered saline (PBS) containing 0.2% bovineserum albumin, cells were resuspended in mounting media andapplied to slides before imaging with a fluorescein isothiocyanate(FITC) filter.

Cell membranes were stained with the lipophilic dicarbocyaninedye DiOC₆ (Eastman Kodak) at a final concentration of 10–100ng/ml, which results primarily in mitochondrial membrane staining(Koning et al., 1993 Pringle et al., 1989; Weisman et al., 1990,Walther and Wendland, 2004). A stock solution of 3,3-dihexyloxacarbocyanineiodide (DiOC₆) (10 mg/ml in ethanol) was added directly to cells(10⁷ cells/ml in YPAD) and imaged using an FITC filter set.The lipophilic fluorescent probe MDY-64 (Invitrogen) was usedas a fluorescent marker to visualize yeast vacuolar membrane(Cole et al., 1998; Fratti et al., 2004) and used at a finalconcentration of 10 µM, according to the manufacturer'sprotocol (Invitrogen).

For imaging of GFP-tagged proteins, cells were washed once withPBS, resuspended in PBS, and placed on ice for 10–30 minbefore visualization by fluorescence microscopy. GFP fluorescentpatterns were the same in the presence or absence of the PBSwash or incubation on ice, except for a higher level of backgroundfluorescence that is presumably due to the presence of YPAD.For longer time-course experiments CaVRG4-GFP–expressingcells were induced to form hyphae by seeding on coverslips,as described above. For each time point, cells were washed twicein PBS, stained with DAPI for 5 min in the dark, and washedagain in PBS before staining with 1 µg/ml calcofluor white(CW; fluorescent brightener 28, Sigma-Aldrich) solution for1 min in the dark. The coverslips were washed with PBS and mountedon slides for fluorescence microscopy. An image was capturedin a representative focal plane. In images where there was noapparent fluorescence in a particular portion of the cell, thecells were visually examined thoroughly in all focal planesto ensure the absence of any fluorescent signal in that regionof the cell. For time points where the hyphal length exceededthe dimensions of the field that could be captured on the microscope,two to three images were acquired to cover the entire lengthof the hypha and were overlaid using Adobe Photoshop, version7.0.

For phalloidin staining of actin, cells in medium were fixedby the addition of formaldehyde to a final concentration of3.7%. After a 30-min incubation cells were resuspended in 50mM potassium phosphate buffer, pH 6.8, and fixed for an additionalhour in this buffer containing 3.7% formaldehyde. Cells wereharvested, washed once in potassium phosphate buffer and resuspendedin this buffer containing 0.1% Triton X-100, and incubated foran additional 30 min. Fixed cells were washed twice with PBSand incubated with a 1:10 dilution of Alexa 546-phalloidin (Invitrogen)in PBS overnight at 4°C. Cells were washed twice with PBS,mounted on slides, and visualized with a Texas Red filter.

Subcellular Fractionation of HA-tagged Proteins
CaVrg4-HA-containing membrane organelles in wild-type or bni1 ${Delta}$ /bni1 ${Delta}$ mutant cells were analyzed by a combination of differentialcentrifugation, sucrose equilibrium density, and velocity sedimentation.Twenty-five milliliters of YPAD was inoculated with overnightcultures and induced to form hyphae for 1.5 h. Cells were collectedby centrifugation at 3000x g, washed once with JB buffer (HEPES-KOH,pH 6.8, 150 mM KCl, 0.1 M sorbitol, 1 mM EDTA, and 1 mM dithiothreitol[DTT]), resuspended in 500 µl of JB buffer containinga cocktail of protease inhibitors, and broken by glass beadlysis. Unlysed cells and debris were removed by centrifugationat 3000x g. Heavier membranes (ER, vacuole, and plasma membrane)were removed by centrifugation at 14,000x g for 20 min at 4°C,and the low-density membranes that remain in the supernatant(S14), including Golgi and vesicles, were isolated by centrifugationat 100,000x g (P100) for 30 min at 4°C. The resulting pellet(P100) that was greatly enriched for CaVrg4-HA was resuspendedin 200 µl of JB buffer lacking sorbitol and analyzed byeither sucrose equilibrium density or velocity gradients. Then,150 µl of the P100 fraction was layered onto 2 ml of 22–60%sucrose gradient (wt/vol in JB buffer lacking sorbitol) forequilibrium density centrifugation as described previously (Vidaet al., 1990) and centrifuged at 135,00x g for 18 h at 4°C.Then, 200-µl fractions were collected from the top. Aliquotsof each fraction (20 µl) were analyzed directly by SDS-PAGEand immunoblotted with 12CA5 anti-HA antibody.

Alternatively, for velocity sedimentation analysis, the P100fraction was layered onto 2-ml sucrose gradients of 0.2-ml stepsof 5–25% sucrose (wt/vol in JB buffer lacking sorbitol)with a 60% sucrose cushion. Sucrose gradients were centrifugedat 135,000x g in a TLS55 rotor for 30 min at 4°C. Then,200-µl fractions were collected from the top, and 20 µlfractions were analyzed by SDS-PAGE and immunoblotted with anti-HAantibody.

Whole cell protein extracts were prepared by the trichloroaceticacid/ $beta$ -mercaptoethanol procedure or by lysis with glass beads,exactly as described previously (Nishikawa et al., 2002), resolvedby SDS-PAGE, transferred to Immobilon-polyvinylidene difluoridemembranes (Millipore, Billerica, MA) and detected using anti-HAantibody. Primary antibody incubation was followed by incubationwith a secondary anti-mouse antibody conjugated to horseradishperoxidase (GE Healthcare, Little Chalfont, Buckinghamshire,United Kingdom) followed by chemiluminescence (ECL; GE Healthcare).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The Golgi Complex Relocates to the Distal Hyphal Tip during Hyphal Formation
The C. albicans GDP-mannose transporter encoded by the CaVRG4gene is a Golgi-localized protein (Nishikawa et al., 2002).Although its enrichment in a particular cisternae has not beenestablished, owing to its abundance and its essential role inproviding sugar substrates for cis-, medial-, and trans-localizedGolgi glycosyltransferases, Vrg4 is a useful reporter for visualizingthe yeast Golgi (Dean et al., 1997; Gao and Dean, 2000; Losevet al., 2006). Using epitope-tagged CaVrg4 as a Golgi reporter,we previously showed that in C. albicans yeast cells, the Golgiseems morphologically similar to that of S. cerevisiae, consistingof distinct, rod-like spots that are randomly distributed throughoutthe cell (Nishikawa et al., 2002). To examine the morphologyof the Golgi during filamentous growth, the localization ofCaVrg4-HA was analyzed by indirect immunofluorescence afterthe induction of hyphae. These cells expressed a single copyof the CaVRG4-HA gene, driven by its own promoter, and integratedat the RP10 locus. This allele complements C. albicans vrg4null mutants, demonstrating its functionality (Nishikawa etal., 2002). After hyphal induction, aliquots of cells were removedat various times and processed for indirect immunofluorescence.In yeast cells, an average of 10 randomly distributed spotswere observed in each cell (Nishikawa et al., 2002; our unpublisheddata). In stark contrast to this random distribution, much ofthe fluorescence seemed concentrated at the distal tip of thegerm tube after 90 min of hyphal induction (Figure 1A). A similarpattern of Golgi distribution was seen in hyphal cells expressingCaVRG4-myc (our unpublished data), and other resident Golgiproteins, including CaGda1-HA, the Golgi guanosine diphosphatase(Herrero et al., 2002), and CaOch1-myc, a Golgi mannosyltransferase(Bates et al., 2006) (Figure 1A). The fluorescence remainedassociated with the distal portion of the tip and was largelyabsent from the cell body (compare CaOch1-myc viewed by phasecontrast with that viewed by fluorescence; Figure 1A). Theseresults demonstrate that the polarized pattern of Golgi distributionat the distal portion of the germ tube is not an artifact ofindirect immunofluorescence arising from a particular antibodyor due to a peculiarity of a particular Golgi protein.

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Figure 1. Polarized localization of the Golgi to the apical tip of hyphal cells. (A) Indirect immunofluorescence of Golgi proteins in hyphal cells. Cells (BWP17) expressing Ca-VRG4-HA, CaGDA1-HA, or CaOCH1-myc were induced to form hyphae and processed for indirect immunofluorescence with anti-HA antibodies as described in Materials and Methods. The last panel shows the background signal in an untagged control strain. (B) Localization of CaVrg4-GFP in hyphal cells. Cells expressing CaVRG4-GFP were induced to form hyphae, removed at the indicated times, and viewed directly for CaVrg4-GFP localization or stained with DAPI to visualize nuclear division. (C) Branching is accompanied by accumulation of Vrg4-GFP. Cells expressing CaVRG4-GFP were induced to form hyphae on coverslips. At the indicated time points, cells were stained with DAPI for visualization of nuclei and with calcofluor white for visualization of cell walls and septa. CaVrg4-GFP was visualized by fluorescence microscopy. The last panel shows the background fluorescence in a strain where Ca-VRG4 is not GFP-tagged. (D) Brefeldin A treatment of hyphal cells expressing CaVrg4-GFP. Cells expressing CaVRG4-GFP were induced to form hypha for 1.5 h to allow the redistribution of the Golgi to the distal region of hyphae. An aliquot was removed (–BFA; 0 min), and cells were incubated in the presence or absence BFA for a further 30 min before harvesting to visualize CaVrg4-GFP by fluorescence microscopy. The inset shows some of the cisternae in a wild-type hyphal cell at higher magnification. (E) Random distribution of Golgi puncta in pseudohyphal cells. For induction of pseudohyphae, cells expressing CaVRG4-GFP were incubated at 36°C in YPD buffered at pH 6.0 with citric acid. For each time point, cells seeded on coverslips were stained with DAPI and then with calcofluor white. The coverslips were mounted on slides for fluorescence microscopy. Bars, 5 µm.

The localization of GFP-tagged Vrg4 protein was also analyzedin live cells. A strain was constructed that expressed a singlecopy of CaVRG4-GFP whose expression was driven by the VRG4 promoterand integrated at the RP10 locus. CaVRG4-GFP–expressingcells were removed at various times after hyphal induction andimaged by microscopy. Similar to the pattern of CaVrg4-HA seenusing indirect immunofluorescence, we observed characteristicGolgi "spots" that were randomly distributed in yeast cellsbut that clustered and remained largely associated with theextending tip during hyphal growth. In live cells, after 90–120min of hyphal induction, in 80% of the cells that had undergoneat least one nuclear division, the punctate fluorescence waslocalized within the top one-third of the extended germ tube(Figure 1B). As observed by indirect immunofluorescence, a notablefeature of the observed Vrg4-GFP fluorescence pattern in thesehyphal cells was the near absence of punctate staining in thecell body, although we occasionally observed some diffuse backgroundstaining in this region of the cell. To determine whether thisabsence of punctate staining in the cell body may be attributableto the quiescence of the proximal cells, we examined the Vrg4-GFPGolgi distribution in cells that were induced to form hyphaefor sufficiently long times (up to 210 min) to allow branchformation. After hyphal induction, aliquots of cells were removedat various times and stained with CW to examine cell wall andsepta, and with DAPI to examine nuclei (Figure 1C). The resultof this experiment demonstrated that the Vrg4-GFP signal wasrestricted to the distal portion of the hyphae, even in cellsthat had undergone two nuclear divisions. However, concomitantwith branch initiation, we always observed an abundance of Vrg4-GFPsignal in the cell that the new branch arose from (n > 80),suggesting a strong correlation between branch formation andGolgi presence in the branching cell.

To confirm that the CaVrg4-GFP staining pattern reflected thelabeling of Golgi cisternae, hyphal cells expressing VRG4-GFPwere treated with BFA. BFA causes a reversible disassembly ofthe Golgi complex and the redistribution of Golgi enzymes intothe ER. In cells treated with BFA, CaVrg4-GFP no longer seemedas distinct rod-like structures that concentrate in the distalregion of the hyphae (Figure 1D). Instead, CaVrg4-GFP redistributedto a reticular pattern of membranes throughout the hypha andmother cell, in a pattern resembling the ER in hyphal cells(Figure 2C). BFA treatment also caused a substantial fluorescentsignal that colocalized with vacuolar markers (our unpublisheddata) and interfered with the mesh-like distribution of theCaVrg4-GFP signal due to its ER distribution. Nevertheless,the BFA-dependent marked change in the distribution of the CaVrg4-GFPsignal provided evidence that the fluorescent signal in cellsexpressing VRG4-GFP indeed reflected the in vivo distributionof the Golgi.

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Figure 2. ER, mitochondria, and vacuoles are randomly distributed in hyphal cells. Cells (BWP17) were induced to form hyphae by growth at 37°C and the addition of serum. Aliquots of cells were removed every 30 min and processed for fluorescence microscopy. (A) Mitochondria (a) were visualized by staining cells with DiOC₆. Vacuoles (b) were visualized using MDY-64. (B) ER was visualized in a strain expressing an HDEL-tagged Kar2-GFP fusion protein (ER-GFP; see description in Materials and Methods). Cells expressing ER-GFP were induced to form hyphae, removed at the indicated times, and viewed directly for GFP localization, or stained with CW to visualize cell wall and septa as described in Materials and Methods. Bars, 5 µm.

The restricted localization of CaVrg4-GFP to distal sites ofpolarized growth is seen in hyphal but not budding C. albicanscells. To determine whether this Golgi localization patternis unique to hyphal cells, we also examined the distributionof Vrg4-GFP in cells that were induced to form pseudohyphaeby incubation at 36°C in media buffered at pH 6.0 (Sudberyet al., 2004

). Under these conditions the pattern of the Golgiremained punctate and seemed randomly distributed throughoutthe cell, with no evidence of polarity in pseudohyphal cells,even very long ones that superficially resemble hyphal cells(Figure 1E). These results demonstrate that the polarized localizationof the Golgi to the active growth site is a hyphal-specificevent.

The spatially restricted distribution of the Golgi in the distalportion of the filament in hyphal cells was unique to Golgimembranes and not observed for other organelles (Figure 2).For example, mitochondria (DiOC₆ staining; Figure 2A), vacuoles(MDY-64 staining; Figure 2A), and ER ("ER-GFP" fluorescence;Figure 2B) were distributed throughout the cell and germ tubein both yeast and in hyphal cells. Even in cells that had beeninduced to form hyphae for 150 min in which there was clearevidence of septation, the ER remained randomly distributed(Figure 2B). This ER pattern was in marked contrast to thatof the Golgi, which was largely absent from the cell body, exceptfor those cells that were undergoing branch formation. Theseresults also imply that the quiescence of these unbranched proximalcells seemed selective for the Golgi but not for the ER. Thissame, random distribution was also observed for another ER protein,Sec12-GFP (our unpublished data). Together, these results demonstratethat there is a marked redistribution of the Golgi during thetransition of yeast cells to hyphal cells, in which the Golgiis largely absent from the cell body and remains associatedwith the distal hypha as it extends.

Golgi Polarization to the Distal Portion of the Hyphae Is Not Dependent on Microtubules
To explore the mechanism by which the Golgi repolarizes itselfduring hyphal formation, we wanted to determine whether theorganelle's distal localization depended on cytoskeletal components.The requirement of microtubules for hyphal formation in C. albicanswas tested by treating cells with NZ, which causes microtubuledepolymerization. The efficacy of inhibition of microtubulesby NZ was assayed visually, by monitoring the absence of microtubuleformation in a TUB1-GFP (encoding ${alpha}$ -tubulin) and TUB2-GFP (encoding $beta$ -tubulin) strain (Figure 3), and by quantitatively monitoringinhibition of nuclear division due to the consequent activationof the spindle checkpoint (Table 3). Treatment with 5 µMNZ resulted in a 10-fold reduction in the number of cells withinthe population that successfully divided their nuclei. In addition,almost all of the cells in the treated samples arrested as largebudded cells (97 verses 51.7% in the untreated control). Theseresults demonstrate that this concentration of NZ efficientlyinhibited microtubule function and therefore arrested nucleardivision. Consistent with these results, under these conditionsof NZ treatment, microtubules in TUB1-GFP and TUB2-GFP hyphalcells could not be detected visually, although they were easilydetected in the untreated control cells (Table 3 and Figure 3).The only remaining fluorescent signal visible in these NZ-treatedcells were spots in the cell body, which likely represent themicrotubule organizing centers (Figure 3). Together, these resultsdemonstrate that NZ efficiently inhibited microtubule functionand formation in these cells. Importantly, this inhibition ofmicrotubule formation by NZ affected neither the ability ofcells to form hyphae nor their rate of formation (Figure 3).

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Figure 3. Redistribution of Golgi to the distal region of hyphae does not require microtubules. Cultures of wild-type cells expressing either CaVRG4-GFP, CaTUB1-GFP, or CaTUB2-GFP were induced to form hyphae in the presence (+NZ) or absence (–NZ) of 5 µM NZ. Samples were harvested after 1.5 h of hyphal induction and stained with DAPI for the visualization of CaVrg4-GFP, Tub1-GFP and Tub2-GFP or nuclei, as described in Materials and Methods. Bars, 5 µm.

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Table 3. NZ (5 µM) depolymerizes microtubules and inhibits nuclear division in C. albicans

Although microtubules seemed to be efficiently depolymerizedin the presence of 5 µM NZ, CaVrg4-GFP was still redistributedto the distal tip of hyphae in 85% (n > 300) of the NZ-treatedcells (Figure 3). As in the untreated control, almost no CaVrg4-GFPsignal could be observed in the body of cells treated with NZ.We also found that if cells were first allowed to form hyphaeand then treated with 5 µM NZ, the CaVrg4-GFP signal wasstill restricted to the distal region of the hypha. Furthermore,although the Tub1- and Tub2-GFP signals in untreated controlcells were sensitive to cold (i.e., the signal was lost overtime if samples were kept on ice for several hours), the CaVrg4-GFPsignal was not (our unpublished data). Together, these resultsdemonstrate that microtubules do not play a role in transportingor in maintaining the Golgi near the growing hyphal tip.

Golgi Positioning and Integrity in Cells Forming Hyphae Require Actin and the Formin CaBni1
To examine the requirement of actin for Golgi polarization,we first assayed the effect of treatment of cells with CA whoseeffect on cell polarity in C. albicans is well established (Akashiet al., 1994; Crampin et al., 2005). CA is a fungal metabolitethat binds to the barbed ends of actin filaments and to actinmonomers and thereby inhibits new filament formation (Cooper,1987). To identify a concentration of CA that was sufficientto disrupt the organization of the actin cytoskeleton in C.albicans cells, wild-type cells grown overnight into stationaryphase were diluted and induced to form hyphae in serum containingvarious concentrations of CA ranging from 1 to 100 µg/mlCA, and 0.06% SDS to facilitate the uptake of CA into the cells.Consistent with previous reports, addition of 20 µg/mlCA was sufficient to abolish both budding and hyphal formationin C. albicans cells and >98% of cells in this culture wereround and unbudded at the endpoint (our unpublished data; Akashiet al., 1994).

Because this concentration of CA abolished hyphal formation,we were unable to address the question of whether Golgi redistributionof the to the distal region of hyphae required the actin cytoskeleton.However, we could address whether an intact actin cytoskeletonis required to maintain the Golgi at the distal region oncehyphae have formed. To establish the efficacy of CA as an actininhibitor in hyphal cells, its effect on actin structure andfunction was assessed by 1) visualizing the actin cytoskeletondirectly in Alexa 546-phalloidin–stained hyphal cells;2) visualizing the localization pattern of yellow fluorescentprotein (YFP)-tagged myosin light chain protein 1 (Mlc1-YFP),a Spitzenkörper component whose hyphal tip localizationrelies on an intact actin cytoskeleton (Crampin et al., 2005);and 3) visualizing actin indirectly in hyphal cells expressingYFP-tagged actin binding protein 1 (Abp1-YFP), which localizespredominantly to cortical actin patches in C. albicans yeastand hyphal cells (Berman and Gerami-Nejad, unpublished data).As reported previously (Hazan et al., 2002), actin in hyphalcells (assayed by phalloidin-stained cells and by visualizationof fluorescence in the Abp1-YFP strain) was primarily detectedas bright cortical patches associated with the distal regionof the growing hyphae (Figure 4, A and B). Actin filaments inhyphal cells seemed much thinner than in yeast cells and althoughdetectable by microscopy, they were difficult to capture insingle focus plane images. Importantly, treatment of cells with20 µg/ml CA abolished hyphal extension and led to a lossof the bright tip localization pattern of phalloidin-stainedactin, Abp1-YFP, and Mlc1-YFP (Figure 4, A and B). Thus, althoughwe cannot rule out the remains of some undetectable actin cytoskeleton,these results suggested that this concentration of CA is effectivein inhibiting actin function in hyphal cells.

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Figure 4. Maintenance of Golgi organization near the hyphal tip requires an intact actin cytoskeleton. (A) Actin inhibition results in the disorganization of Golgi in hyphal cells. Stationary phase cultures of wild-type cells harboring CaVRG4-GFP, MLC1-YFP, or ABP1-YFP were induced to form hyphae for 1 h 45 min. Cells were treated with buffer alone (DMSO + SDS) (–CA) or buffer containing 20 µg/ml CA (+CA) for 45 min before visualization of cells by fluorescence microscopy. (B) CA inhibits actin organization in hyphal cells. Cells grown as described in A were incubated in the presence or absence of CA, fixed, and stained with Alexa 546-phalloidin as described in Materials and Methods. (C) Treatment of hyphal cells with CA has no effect on ER organization. BWP17 cells expressing ER-GFP were induced to form hyphae and then incubated in the presence or absence of 20 µg/ml CA for 45 min as described in A and visualized by fluorescence microscopy. Bars, 5 µm.

To determine whether actin is required to maintain the polarizedGolgi localization at the distal portion of the hyphae, cellswere induced to form hypha and then incubated in the presenceor absence of CA. Cells producing either CaVrg4-GFP as a Golgimarker, or ER-GFP as an ER marker were induced to form hyphaeby serum for 1.5 h. Then, 20 µg/ml CA was added, and thesamples were harvested after 45 min for the visualization ofthe Golgi and the ER by fluorescence microscopy. Although thetreatment with CA had no effect on the membrane-like distributionof the ER-GFP signal throughout the length of the hyphae andthe cell body (Figure 4C), we observed that CA treatment causeda marked disorganization of the Golgi (Figure 4A). Furthermore,63% of the CA-treated cells (n > 300) showed a region ofCaVrg4-GFP-dependent bright fluorescence in the cell body (Figure 4A),which seemed qualitatively different from the puncta in branchingcells and did not colocalize with the DAPI signal, vacuole orER membranes (our unpublished data). Longer treatment with CA(up to 2 h) resulted in the same fluorescent pattern. Together,these results demonstrated that the maintenance of the Golgiat the distal portion of hyphal cells requires an intact actincytoskeleton.

To understand better the involvement of the actin cytoskeletonin the apical redistribution of Golgi in hyphal cells, we chosea genetic approach and examined a mutant in which we expecteddefects in actin-dependent processes. Bni1 and its partiallyredundant homologue Bnr1 are required for actin nucleation andlinear cable assembly at sites of polarized growth (Evangelistaet al., 2002; Sagot et al., 2002). Unlike bnr1 mutants, in whichhyphal formation is normal, C. albicans bni1 mutants still undergothe yeast-to-hyphal switch, but they exhibit severe polaritydefects, forming short, swollen true hyphae that are kineticallydelayed (Li et al., 2005; Martin et al., 2005). Despite thesehyphal defects, bni1 null mutants are unaffected in buddingand germination.

To examine Golgi distribution in the absence of Bni1, a bni1 ${Delta}$ /bni1 ${Delta}$ strain was constructed that expressed a single copy of CaVRG4-GFP,driven by its endogenous promoter and integrated at the RP10locus. Overnight cultures of the isogenic wild-type parentalstrain (BWP17) and bni1 ${Delta}$ /bni1 ${Delta}$ VRG4-GFP cells were induced toform hyphae for 1.5 h, and the Golgi was examined in live cellsby examining CaVrg4-GFP fluorescence. Unexpectedly, rather thanthe typical punctate, tip localized pattern of Golgi observedin wild-type cells, the fluorescent signal of CaVrg4-GFP inthese bni1 ${Delta}$ /bni1 ${Delta}$ hyphal cells manifested as a haze that was evenlydistributed throughout the cells (Figure 5A). In addition toits role as a nucleator of actin cables, Bni1 physically interactswith a number of different proteins, including the polarisomescaffold Spa2. C. albicans spa2 ${Delta}$ /spa2 ${Delta}$ mutants display polarityphenotypes that are similar to those of bni1 ${Delta}$ (Zheng et al.,2003). The loss of CaVrg4-GFP fluorescence was not seen in spa2 ${Delta}$ /spa2 ${Delta}$ mutants, demonstrating that this phenotype was due to loss ofBNI1 rather than an indirect effect via the polarisome (Figure 5A).Although bni1 ${Delta}$ cells display polarity defects and are delayedin hyphal formation, true hyphae (i.e., parallel-sided tubesthat are clearly septated and whose mother/daughter neck lacksconstrictions) are eventually produced (Figure 5B). Even inbni1 ${Delta}$ /bni1 ${Delta}$ cells that had produced elongated hyphae, Vrg4-GFPfluorescence still occurred as nonresolvable haze, thus rulingout the possibility that the absence of Golgi-associated fluorescenceis a consequence of the inability of these bni1 ${Delta}$ /bni1 ${Delta}$ cells toform true hyphae.

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Figure 5. Bni1 has a hyphal-specific function in the maintenance of Golgi integrity and localization. (A) Golgi disassembly in the bni1 ${Delta}$ /bni1 ${Delta}$ strain. The Golgi was visualized in wild-type (BWP17), bni1 ${Delta}$ /bni1 ${Delta}$ , or spa2 ${Delta}$ /spa2 ${Delta}$ cells harboring CaVRG4-GFP. Overnight cultures of were induced to form hyphae with serum and viewed after 1.5 h of hyphal induction (WT) and 2.5 h for bni1 ${Delta}$ /bni1 ${Delta}$ , spa2 ${Delta}$ /spa2 ${Delta}$ (B) bni1 ${Delta}$ /bni1 ${Delta}$ form true hyphae but are delayed. bni1 ${Delta}$ /bni1 ${Delta}$ cells were induced to form hyphae as in A but harvested after 4.5 h and stained with DAPI and calcofluor white to visualize the nuclei, and cell walls and septa, respectively. (C) Loss of Bni1 has no effect on ER morphology. The ER was visualized in wild-type or bni1 ${Delta}$ /bni1 ${Delta}$ yeast or hyphal cells, harboring pER-GFP. (D) Loss of Golgi puncta in hyphal but not yeast bni1 ${Delta}$ mutant cells. An overnight culture of the bni1 ${Delta}$ /bni1 ${Delta}$ strain harboring VRG4-GFP was diluted and grown into logarithmic phase at 30°C and harvested for microscopy (time, 0 min). These cells were induced to form hyphae and samples were collected at the indicated time points for the visualization of CaVrg4-GFP distribution. Bars, 5 µm.

This pattern of CaVrg4-GFP fluorescence in bni1 ${Delta}$ /bni1 ${Delta}$ hyphalcells was specific to the Golgi, because the ER (observed usingthe ER-GFP reporter) looked normal and was indistinguishablefrom the ER pattern in wild-type cells (Figure 5C). Remarkably,this CaVrg4-GFP fluorescent haze was not seen when bni1 ${Delta}$ /bni1 ${Delta}$ cells were growing as yeast cells (Figure 5D, 0-min hyphal induction).Examination of the CaVrg4-GFP Golgi fluorescence in bni1 ${Delta}$ /bni1 ${Delta}$ cells over time after the induction of hyphae demonstrated thatthe punctate, randomly distributed Golgi spots looked normalin bni1 ${Delta}$ /bni1 ${Delta}$ yeast cells and at early times after inductionof hyphae (Figure 5D, times 0 and 20 min) and dispersed onlygradually, after the induction of hyphae (Figure 5C, e.g., 20–90min).

To determine whether this loss of CaVrg4-GFP fluorescence inbni1 ${Delta}$ /bni1 ${Delta}$ cells was due to Vrg4 degradation during hyphal formation,the steady-state level of Vrg4 was compared in bni1 ${Delta}$ /bni1 ${Delta}$ cellsduring hyphal formation. To facilitate detection of protein,extracts were prepared from bni1 ${Delta}$ /bni1 ${Delta}$ and isogenic wild-typeparental strains expressing a CaVRG4-HA-tagged allele. Afterinduction of hypha, aliquots of cells were removed, proteinwas extracted, and its concentration measured. Equal amountsof protein were analyzed by Western blotting with anti-HA antibody.It should be noted that C. albicans expresses an $~$ 50-kDa, 12CA5cross-reacting protein (denoted by the asterisk in Figure 6A,right), which serves as a convenient loading control. In bothwild-type cells (Figure 6A, left) and the bni1 ${Delta}$ /bni1 ${Delta}$ mutant strain,the relative amount of Vrg4, normalized to either total protein(Figure 6A) or to dry cell weight (our unpublished data) remainedconstant over 2 h of hyphal formation. These results ruled outthe possibility that the attenuated, dispersed fluorescent signalin the bni1 ${Delta}$ /bni1 ${Delta}$ strain was due to degradation of Vrg4. Instead,these results suggested that the dispersed haze observed inbni1 ${Delta}$ /bni1 ${Delta}$ may be due to the fragmentation or vesiculation ofthe Golgi.

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Figure 6. Golgi membranes from bni1 ${Delta}$ / ${Delta}$ cells have the same density as wild-type Golgi, but differ in size. (A) Western blot of CaVrg4-HA in hyphal cells. Wild-type or bni1 ${Delta}$ /bni1 ${Delta}$ mutant cells, expressing CaVRG4-HA, were induced to form hyphae, and protein extracts prepared from aliquots collected over time of induction. Equal amounts of protein extract were separated by SDS-PAGE and immunoblotted with anti-HA antibody. (B) Sedimentation equilibrium analysis of Golgi membranes. Protein extracts were prepared from wild-type or bni1 ${Delta}$ /bni1 ${Delta}$ mutant hyphal cells expressing VRG4- HA and subjected to differential centrifugation. The Golgi-enriched P100 fraction was layered on to a 22–60% sucrose gradient, centrifuged at 135,000x g for 18 h. Fractions were removed from the top, subjected to SDS-PAGE, and analyzed by immunoblotting with anti-HA antibodies. (C) Velocity sedimentation analysis of Golgi membranes. The Golgi enriched P100 fraction from wild-type or bni1 ${Delta}$ /bni1 ${Delta}$ cells was layered on to a 5–25% sucrose gradient and centrifuged at 135,000x g for 30 min. Fractions were removed from the top, subjected to SDS-PAGE, and analyzed by immunoblotting with anti-HA antibodies.

To test this idea, the relative density and size of Golgi membranesfrom bni1 ${Delta}$ /bni1 ${Delta}$ hyphal cells were compared with those from wild-typecells. Golgi membranes, assayed quantitatively by followingVrg4-HA, were isolated from hyphal whole cell lysates, separatedfrom ER, and enriched by differential centrifugation. Usingprotocols established for the enrichment of Golgi membranesin S. cerevisiae (see Materials and Methods), we found thatVrg4-containing Golgi membranes from wild-type and bni1 ${Delta}$ /bni1 ${Delta}$ hyphal cells remain soluble, could be separated from CaAlg1-containingER membranes during sedimentation at 14,000x g, and were quantitativelyrecovered by sedimentation at 100,000x g (Figure 6B; our unpublisheddata). The yield of CaVrg4- HA protein recovered in the Golgifraction from equal cell numbers of the wild-type and bni1 ${Delta}$ /bni1 ${Delta}$ mutant strain was similar, providing further evidence that thedispersed fluorescence in bni1 ${Delta}$ /bni1 ${Delta}$ strains is due to a dispersalof Golgi membranes, rather than degradation of CaVrg4-GFP (Figure 6B).The membranes that pelleted at 100,000x g (P100) were resuspendedand subjected to sedimentation equilibrium analysis to comparetheir relative density, and sedimentation velocity analysis,to compare their size.

After equilibrium density sedimentation was performed, fractionswere collected from the top, and the position of Golgi membraneswithin these gradients assayed by Western blotting each fractionfor the presence of CaVrg4-HA. As shown in Figure 6B, the relativeposition of Golgi-enriched membranes from wild-type and bni1 ${Delta}$ /bni1 ${Delta}$ cells was virtually identical, with the bulk of CaVrg4-HA peakingin fractions 3 and 4. These results suggest that CaVrg4-HA–containingGolgi membranes from bni1 ${Delta}$ /bni1 ${Delta}$ hyphal cells are of a similardensity, and hence composition, to those of wild type.

To compare the relative size of these membranes, velocity sedimentationwas performed. Fractions were collected from the top and assayedfor Vrg4-HA as described above. Under these conditions, Golgi-enrichedmembranes from bni1 ${Delta}$ /bni1 ${Delta}$ cells fractionated differently thanwild type. The peak of Golgi membranes from the wild-type strainsedimented in fractions 7 and 8 and displayed a leading edgetoward the bottom (heavier) portion of the sucrose gradient(Figure 6C). The peak of Golgi membranes from the bni1 ${Delta}$ /bni1 ${Delta}$ strain sedimented in fraction five and in the lighter portionof the gradient, and CaVrg4-HA was largely absent from the bottomof the gradient. Under these conditions, ER membranes (monitoredby the presence of CaAlg1-HA) from both wild-type and bni1 ${Delta}$ /bni1 ${Delta}$ cells, pelleted at the bottom of this gradient (our unpublisheddata). These results suggest that Vrg4-HA-containing Golgi membranesfrom the bni1 ${Delta}$ /bni1 ${Delta}$ strain are of a smaller size than those fromthe wild-type strain. Together, we conclude that the dispersedhaze observed in the bni1 ${Delta}$ /bni1 ${Delta}$ hyphal cells is due to a fragmentationor vesiculation of the Golgi cisternae and therefore that Bni1is required for maintaining the structural integrity of theGolgi in C. albicans hyphal cells.

To address the question of whether an intact actin cytoskeletonis important for maintaining the structural integrity of theGolgi in yeast cells, we asked whether treatment of wild-typeC. albicans cells with CA could mimic the bni1 ${Delta}$ /bni1 ${Delta}$ Golgi dispersalphenotype. Wild-type and the bni1 ${Delta}$ /bni1 ${Delta}$ yeast cells expressingVRG4-GFP were grown to logarithmic phase and treated with 5µg/ml CA, an intermediate concentration that we determinedprevents hyphal formation but not budding (our unpublished data).Aliquots of CA-treated cells were removed every 30 min and viewedfor CaVrg4-GFP localization. The results of this experimentdemonstrated that this intermediate CA treatment could indeedlead to a Golgi dispersal phenotype in wild-type cells, similarto that seen in bni1 ${Delta}$ mutants. As seen in Figure 7A, after exposureto CA for 30–60 min, wild-type cells displayed a gradualloss of the fluorescence associated with typical bright Golgipuncta and a concomitant increase in the fluorescent haze thatis characteristic of the Golgi in bni1 ${Delta}$ hyphal cells. In addition,treatment of bni1 ${Delta}$ /bni1 ${Delta}$ mutant yeast cells with 5 µg/mlCA had a similar effect, but it occurred more rapidly. In bni1 ${Delta}$ /bni1 ${Delta}$ cells, loss of CaVrg4-GFP fluorescence was evident by 30 minof CA treatment (Figure 7A).

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Figure 7. An intact actin cytoskeleton is essential for preserving the structural integrity of the Golgi in yeast cells. (A) Overnight cultures of wild-type and the bni1 ${Delta}$ /bni1 ${Delta}$ strain harboring VRG4-GFP were grown to logarithmic phase and treated with 5 µg/ml CA in DMSO, 0.06% SDS (+Int CA) or with 0.06% SDS and an equivalent volume of DMSO. Aliquots were removed every 30 min and processed for microscopy. Note that the images of bni1 ${Delta}$ /bni1 ${Delta}$ cells were captured at longer exposure times (1.5- to 2-fold) than the wild type due to their decreased signal intensity. Bars, 5 µm. (B) S. cerevisiae cells expressing VRG4-GFP were grown to logarithmic phase and treated with 5 µg/ml CA in DMSO, 0.06% SDS (+CA) or with 0.06% SDS and an equivalent volume of DMSO (–CA). Cells were visualized after 30 min.

To test whether the requirement of an actin cytoskeleton isgenerally important for Golgi integrity in yeast cells, we alsoexamined the morphology of the Golgi in S. cerevisiae. A strainexpressing Vrg4-GFP as the sole GDP-mannose transporter wasconstructed (see Materials and Methods). This strain exhibiteda normal phenotype, demonstrating that the addition of GFP onthe C terminus of ScVrg4 does not affect its normal function.As was seen in C. albicans VRG4-GFP strain, treatment of thisS. cerevisiae strain for 30 min with 5 µg/ml CA led toa similar dispersal of the Vrg4-GFP signal (Figure 7B). Together,these experiments demonstrate that the actin cytoskeleton hasa previously unrecognized role in maintaining the integrityof the Golgi in C. albicans and S. cerevisiae yeast cell, althoughthe role of BNI1 in S. cerevisiae has not yet been characterized.These data also demonstrate that in C. albicans, the absenceof Bni1 results in a Golgi that is more susceptible to undergofragmentation if the actin cytoskeleton is perturbed.

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In this study, we monitored the Golgi complex in C. albicanscells undergoing the yeast-to-hyphal transition, by using fluorescentreporters. We report that hyphal formation in C. albicans isaccompanied by a redistribution of most of the Golgi complextoward the growing tip, and this localization is dependent onthe formin Bni1. Shortly after inducing hypha, the randomlydistributed Golgi spots seen in vegetatively growing yeast cellsmigrate with the growing hyphal tip. Throughout hyphal extension,the Golgi remains associated with the distal portion of thehypha. Several pieces of evidence support our conclusion thatthis fluorescence is coincident with the Golgi. First, thispattern of localization was observed by both indirect immunofluorescenceby using several different antibodies and different reportersas well as by analysis of a GFP-tagged Golgi reporter in livecells. Second, this pattern of localization was lost after treatmentwith brefeldin A, a compound that causes a rapid but reversiblefusion of the Golgi with the ER (Figure 1). Third, this patternis distinct from that of the ER and vacuolar membranes, whichare found throughout the cell body and extended filament (Figure 2).Neither CaVrg4 nor any Golgi proteins have been precisely assignedto a particular cisternae in C. albicans, so it remains to bedetermined whether this phenomenon reflects the entire Golgior just a subset of cisternae. Nevertheless, the distributionof any of the Golgi cisternae to the distal portion of the hyphaimplies that post-Golgi secretory vesicles in hyphae do notrequire long-distance transport from the cell body to reachthe growing tip, but rather they are generated in proximityto the growth site.

We found that hyphal formation and the redistribution of theGolgi progressed normally in the absence of microtubules. Thisresult is in contrast to previous studies that reported therequirement of microtubules for hyphal formation in C. albicans(Akashi et al., 1994; Crampin et al., 2005). This apparent discrepancymay be due to the different drugs that were used to inhibitmicrotubule formation. Although we used NZ to inhibit microtubuleformation, the previous studies used benomyl, or its derivativemethyl benzimidazole carbamate. We also found that benomyl doesindeed inhibit hyphal growth but only when added at very highconcentrations, much higher than its solubility in the medium(our unpublished data). One explanation for the different effectsseen with NZ versus benomyl is that benomyl has secondary effectsat such high concentrations, including an effect on actin, aswas suggested by previous reports (Akashi et al., 1994). Therefore,we chose to assess microtubule requirements using NZ, whoseefficacy as a microtubule-depolymerizing agent in hyphal cellswas established in this work (Table 3 and Figure 3). Our NZdata also underscore the fact that hyphal formation and theredistribution of the Golgi, unlike in mammalian cells, arenot coupled to the partitioning of the genetic material, becausenuclear division was arrested in NZ-treated cells.

An important aspect of this present work is our observationthat loss of Bni1 affects Golgi organization and inhibits itslocalization to the hyphal tip. Remarkably, in the course ofthis study, we uncovered a previously unrecognized feature ofthe fungal Golgi; its capacity to disassemble in a manner reminiscentof the Golgi haze in mitotic animal cells. During the formationof hyphae in bni1 ${Delta}$ cells, the gradual disappearance of Golgispots was accompanied by the appearance of a haze that pervadedthe entire cell (Figure 5). Several lines of evidence supportthe idea that this haze represents Golgi vesicles that cannotbe resolved by fluorescence microscopy. First, the disappearanceof Vrg4 during bni1 ${Delta}$ hyphal induction is not due to Vrg4 degradation.Second, Vrg4-enriched Golgi membrane fractions from wild-typeand bni1 ${Delta}$ cells display similar differential centrifugation propertiesand density, but they differ in their velocity sedimentationproperties (Figure 6). Loss of Bni1 has no obvious affect onER (Figure 5) or on vacuole morphology (our unpublished data),suggesting this is a Golgi-specific affect. The simplest interpretationof these data are that the Golgi in bni1 ${Delta}$ cells is fragmented.

This interpretation raises the pivotal question of how the lossof Bni1 can affect the structural integrity of the Golgi. Wefavor a model in which normal Golgi morphology and localizationto the distal tip require actin filaments that are nucleatedby Bni1 during hyphal formation (Figure 8). A direct role foractin in mediating Golgi localization and integrity comes fromour observation that actin formation is required to maintainan organized Golgi localization at the distal portion of thehyphae, whereas inhibition of actin formation caused Golgi disassemblyin wild-type yeast cells as is seen in bni1 ${Delta}$ mutants (Figures 4and 7). In S. cerevisiae, the two partially redundant formins,Bnr1 and Bni1, localize to either the bud neck or the bud cortex,respectively. This difference in formin localization explains,in part, the orientation of actin cables in S. cerevisiae andthe different mutant phenotypes of the bni1 and bnr1 mutants(Pruyne et al., 2004a). Loss of ScBnr1 results in cell separationdefects, whereas loss of Bni1 results in budding defects (forreview, see Pruyne et al., 2004b). However, spatial differencescannot fully explain the different hyphal phenotypes of C. albicansbni1 ${Delta}$ and bnr1 ${Delta}$ null mutants. CaBni1 performs unique functionsduring hyphal formation, because bnr1 ${Delta}$ null mutants do not displaysevere hyphal phenotypes, but bni1 ${Delta}$ cells do (Li et al., 2005;Martin et al., 2005). Moreover, like Bni1, Bnr1 is also localizedat the hyphal tip in C. albicans and actin cables emanatingfrom the hyphal tip persist in the bni1 null mutant (Martinet al., 2005). The conclusion from this observation is thatthe effect on Golgi morphology and localization is not due toa complete loss of actin cables in bni1 null hyphal cells; instead,it suggests the existence of a signal-induced actin polymerizationin hyphal cells, critically dependent on Bni1, that is necessaryto maintain both proper polarized growth and Golgi architecture.Studies in budding yeast of actin cables that differ in theirlength, location, orientation, dynamics, and sensitivity tolatrunculin A (Yang and Pon, 2002) provide a precedent for theidea that hyphal cells may contain specialized actin cablesrequired for Golgi repositioning. One can envisage that uponactivation of the hyphal program, Golgi-localized proteins interactwith these specialized filaments to allow migration of the Golgito the tip hyphal cells, and they maintain its integrity whiledoing so. An alternative possibility is that hyphal cells demandmore actin cables than yeast cells to maintain polarized growthand Golgi integrity and that the defect in both these processesin the bni1 ${Delta}$ strain during the yeast-to-hyphal switch representsthe threshold point at which this high demand is unmet.

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Figure 8. Model of Golgi organization in C. albicans yeast and hyphal cells. The Golgi consists of puncta (denoted in green) that are randomly distributed throughout the cell during the cell division cycle. On induction of the hyphal program, Bni1-dependent nucleation of actin cables (denoted in red) mediates the redistribution of Golgi cisternae to the distal portion of the extending hyphae. During execution of the hyphal, but not the budding program, Bni1 is also required for the structural integrity of the Golgi (blue denotes Bni1). See text for further discussion.

Our data do not address why the effect of Bni1 on Golgi repositioningand structure is limited to the window encompassing the yeast-to-hyphaltransition. This undoubtedly involves a hyphal-specific interactionof Bni1 with other proteins that could, in principle, modulatethe rate of actin nucleation or elongation, or the structureof the filament. Most formins, including Bni1, are activatedby GTP-bound Rho-GTPases (for review, see Higgs, 2005

). Ourresults demonstrating the hyphal-specific effects of Bni1 areconsistent with the idea that a hyphal specific Rho-GTPase effectormay modulate Bni1 activity. Alternatively, hyphal specific actin-bindingproteins may modulate actin structure in a Bni1-dependent way.It is noteworthy that the expression of several C. albicansgenes predicted to encode small GTPase and cytoskeletal modulatorsis highly up-regulated in response to serum (Nantel et al.,2002

). These encode homologues of the S. cerevisiae Yke2 (anactin binding protein), Rdi1 (Rho-GTPase inhibitor that is implicatedin regulating Cdc42), Pfy1 (profilin), and Ybl060w (a Sec7 GEFdomain-containing protein). These proteins represent attractivecandidates for hyphal-specific Bni1 or actin cable modulators,and it will be of interest to investigate whether these proteinsaffect Golgi structure and repositioning during hyphal formation.The molecular mechanism linking Bni1 activation, Golgi repositioning,and actin remodeling is likely to involve a complex networkand will require further investigations.

The Golgi complex is a highly dynamic organelle that requiresa continuous influx and efflux of membrane trafficking to maintainits structure. It is notable that despite the dispersed Golgihaze observed in the bni1 ${Delta}$ mutant, secretion is not abolished.Cells lacking Bni1 still form hyphae (albeit slowly), displayonly a minor (25%) decrease in the secretion of acid phosphatase(Menzies and Dean, unpublished data), and do not seem to haveany defects in glycoprotein processing (our unpublished data).Therefore the Golgi seems to remain largely functional. Thisraises several questions. First, what is the benefit of polarizingthe Golgi to hyphal apex in C. albicans? Although purely speculative,redistribution of the Golgi to the growing tip, although notessential, may provide a selective advantage during infectionwhen rapid hyphal growth enables e