Candida albicans Septin Mutants Are Defective for Invasive Growth and Virulence

Hyphal growth of Candida albicans is implicated as an importantvirulence factor for this opportunistic human pathogen. Septinproteins, a family of cytoskeletal elements that regulate membraneevents and are important for proper morphogenesis of C. albicans,were examined for their role in tissue invasion and virulencein the mouse model of systemic infection. In vitro, septin mutantsare only mildly defective for hyphal growth in liquid culturebut display pronounced defects for invasive growth into agar.In vivo, the septin mutants were found to exhibit attenuatedvirulence. However, mice infected with the mutants displayedhigh fungal burdens in their kidneys without obvious symptomsof disease. Histological examination of infected kidneys revealeddefects in organ invasion for the cdc10 ${Delta}$ and cdc11 ${Delta}$ deletion mutants,which displayed both reduced tissue penetration and noninvasivefungal masses. Thus, the septin proteins are necessary for invasivegrowth, which appears to be more important to the successfulpathogenesis of C. albicans than hyphal growth alone.

INTRODUCTION

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Introduction

Candida albicans is an opportunistic human pathogen that accountsfor a large percentage of the nosocomial bloodstream infectionsacquired annually. It is a multimorphic yeast capable of growingin a variety of forms, ranging from small rounded buds to highlyelongated hyphae (44). The morphogenic switching ability ofC. albicans results from a complex interplay of signaling pathwaysthat link external environmental cues to polarized growth inorder to promote survival and facilitate dissemination withina host (for recent reviews on C. albicans, see references 8,11, 17, 37, and 58). The ability of C. albicans to switch betweenthe various morphologies has been strongly implicated as a virulencedeterminant, as mutants that are locked in either the hyphalor budding form have been shown to be either less virulent orcompletely avirulent in models of hematogenously disseminatedsystemic candidiasis (38, 45, 46).

The septin family of cytoskeletal filament-forming proteinshas recently been investigated for a role in hyphal growth (56)because these proteins function in cellular morphogenesis andcell surface events in other organisms (for reviews on septins,see references 12, 20, 25, 32, 39, and 54). The septins werefirst identified in the yeast Saccharomyces cerevisiae, wherethey localized to the bud neck and were named for their rolein the cell division cycle, specifically, cytokinesis and septumformation during budding (1, 10, 21, 22, 27, 28, 33, 39, 40).The septins are thought to function at the bud neck by forminga scaffold to recruit such effector proteins as cell cycle checkpointkinases (4, 36, 49) and chitin synthases (16). The septins mayalso act as a boundary domain to restrict proteins like actinto the daughter cells (3). In addition to their role in budding,the septins have also been implicated in other types of morphogenicevents in S. cerevisiae, including pheromone-induced morphogenesis(21, 24, 33) and spore formation (15, 18, 53). Homologues ofthe S. cerevisiae septins have been found in all eukaryotesexamined (with the exception of plants), where they functionin cytokinesis but also in other events, such as vesicle traffickingand polarized secretion (6, 29). Although the number of septinspresent and their particular function varies with cell type,the septins have been consistently linked to dynamic membraneand morphogenic events in all eukaryotes.

Deletion analysis of the seven septin genes identified in C.albicans showed that four (CDC3, 10, 11, and 12) were importantfor proper morphogenesis (56). CDC3 and CDC12 were determinedto be essential. Interestingly, C. albicans cells from whichCDC10 or CDC11 has been deleted were viable and grew at a normalrate but exhibited heterogeneous defects in morphogenesis. Thecdc10 ${Delta}$ mutant budded in a normal fashion at or below 30°C,but at elevated temperatures, it exhibited partial defects incytokinesis, giving rise to a nonuniform population with mostcells appearing multinucleate, enlarged, and/or elongated tovarious extents. Similar phenotypes were also observed in cdc11 ${Delta}$ mutants, which displayed budding defects at any growth temperature.In spite of these defects, the cultures were viable, and cellsgrew at a normal rate, even at elevated temperatures. Both mutantsalso formed germ tubes at a normal rate when stimulated withserum or other hyphal inducers. However, the cdc10 ${Delta}$ and cdc11 ${Delta}$ mutants exhibited partial defects in hyphal structure, includinga greater frequency of curved hyphae, and slight inconsistenciesin cell wall deposition compared to the wild type (56).

To better understand the role of septins in hyphal morphogenesis,the cdc10 ${Delta}$ and cdc11 ${Delta}$ septin mutants were examined in this studyfor defects in processes for which proper hyphal morphogenesisis critical, including invasive growth in agar, escape fromphagocytosis by macrophages, and pathogenesis in a mouse modelfor candidiasis. These studies showed that although the cdc10 ${Delta}$ and cdc11 ${Delta}$ septin mutants were capable of hyphal growth bothin vitro and in vivo, they were defective for invasive growthand displayed attenuated virulence in the mouse. These resultsdemonstrate that the ability of cells to form hyphae in responseto serum does not necessarily indicate that the cells will bevirulent in vivo. Proper morphogenesis, mediated in part byseptin proteins, is required for full pathogenic ability inC. albicans. Altogether, these studies suggest that to achievetherapeutic effects in vivo, it may be necessary only to alternormal morphogenesis, not block hyphal growth completely.

MATERIALS AND METHODS

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Materials and Methods

Strains and media. The C. albicans strains used in this study, indicated in Table1, are derivatives of the his1^- ura3^- arg4^- strain BWP17 (59).Septin deletion strains were previously constructed by deletionof the open reading frames of the septin genes CDC10, CDC11,and SEP7 (56) utilizing the methods of Wilson et al. (59). Briefly,deletions were performed through successive transformationswith PCR-generated constructs that contained either ARG4 orHIS1 flanked by short regions of homology to the gene of interest(59). The remaining ura3 auxotrophy was complemented by integrationof a functional URA3 gene by homologous integration of NotI-linearizedpRS-ARG-URA-BN at the arg4 locus as described previously (14).Septin-heterozygous strains were also corrected for the his1auxotrophy at the his1 locus through homologous integrationof NruI-linearized pGEM-HIS1 as previously described (14). Transformationof C. albicans with plasmid DNA was performed by a lithium acetateprotocol as previously described (56).

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TABLE 1. C. albicans strains used in this study

Yeast strains were routinely propagated on yeast extract-peptone-dextrosemedium (YPD) (47) supplemented with 50 mg of uridine/liter.Mutants were selected by growth on standard minimal definedmedium (47) lacking the appropriate amino acid, with the exceptionthat uridine was used in place of uracil. Agar-invasive hyphalgrowth was induced on 4% bovine calf serum containing variousconcentrations (0.5 to 3%) of bacteriological agar (U S Biological,Swampscott, Mass.) as indicated. Cells propagated overnightat 30°C were diluted to 5 x 10⁶ in YPD, and 2 µl (10⁴cells) were spotted on the surface of the serum agar and incubatedat 37°C for 5 days. Plates were monitored daily for invasivegrowth.

Macrophage phagocytosis. Macrophage lysis assays were performed utilizing both primarymouse bone marrow macrophages and the mouse macrophage-likecell line J774. Cell lines and media recipes were kindly providedby the laboratory of James Bliska (SUNY Stony Brook). J774 cellswere propagated in Dulbecco's modified Eagle medium (DMEM) with10% fetal bovine serum. Primary mouse bone marrow macrophagecells were propagated in a special medium containing 96 ml ofDMEM, 60 ml of L-Sup (supernatant from L929 fibrosarcoma cells),40 ml of fetal bovine serum, 2 ml of pyruvate, and 2 ml of L-glutamate.For both cell types, macrophages were grown to near confluence,harvested, and set in 24-well dishes on coverslips at 10⁵ cellsper well. Macrophages were allowed to set down overnight, washedwith phosphate-buffered saline (PBS), and then infected with3 x 10⁵ C. albicans cells per well (multiplicity of infectionof 3) from PBS-washed overnight cultures resuspended in serum-freemedia. Yeasts that were not taken up by the macrophages in 40min were washed off. Samples were fixed in 5% formaldehyde everyhour over the course of infection and observed for germ tubeformation and macrophage lysis.

Mouse infection studies. For virulence assays, the mouse model of hematogenously disseminatedcandidiasis infection was employed. Experiments were performedin outbred immunocompetent ICR male mice (Harlan Sprague Dawley,Indianapolis, Ind.) weighing approximately 22 to 25 g. Micewere housed five per cage, and food and water were suppliedad libitum. For infection, one colony from each C. albicansstrain was inoculated into 50 ml of YPD. Cultures were grownovernight, washed twice with 50 ml of sterile water, countedby hemocytometry, and resuspended at 10⁷ cells per ml in sterilewater. Mice were injected via the lateral tail vein with 0.1ml (10⁶ cells), and the course of infection was monitored forup to 18 days. Infected mice were considered moribund when theycould no longer reach food or water, and these, along with micesurviving to the end of the experiment, were euthanized by anesthetizationfollowed by cervical dislocation. A total of 25 mice were usedfor infection for each cdc10 ${Delta}$ and cdc11 ${Delta}$ strain, and 15 mice eachwere used for all other C. albicans strains. All experimentalprocedures were carried out according to the NIH guidelinesfor the ethical treatment of animals.

Infected mice were randomly chosen for necropsy in order toassay histology and CFU in the kidney. Kidneys were excised,halved longitudinally, and weighed. One half was homogenizedin sterile water, diluted, plated on YPD, and incubated at 30°Cfor 1 to 2 days to determine CFU per gram of kidney tissue.The other half was fixed in 10% phosphate-buffered formalin,embedded, sectioned with a Ridge microtome (Knoxville, Tenn.),and stained with HT-100A silver stain (Sigma, St. Louis, Mo.)or hematoxylin and eosin (H&E) by standard protocols.

RESULTS

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Results

Construction of yeast strains. C. albicans strains were constructed to facilitate the analysisof the role of the CDC10 and CDC11 septin genes in invasivegrowth (see Table 1). Previous studies showed that althoughcdc10 ${Delta}$ or cdc11 ${Delta}$ mutants grew at a normal rate and were not grosslydefective for hyphal induction in vitro, they displayed variousdegrees of defects in morphogenesis (56). In particular, minordefects in germ tube and hyphal growth were observed in somecells after serum stimulation, including abnormal chitin depositionand curvatures in the germ tube wall. To investigate whetherthese minor defects would impact the invasive growth necessaryfor tissue penetration in vivo, and thus the overall virulenceof these mutants, prototrophic versions of the cdc10 ${Delta}$ and cdc11 ${Delta}$ deletion mutant strains were constructed. A prototrophic versionof the sep7 ${Delta}$ deletion mutant was constructed, since this deletionmutant did not display readily observed defects and could serveas a control for the genetic background of the cdc10 ${Delta}$ and cdc11 ${Delta}$ deletion mutant strains. All strains were derived from the tripleauxotropically marked strain BWP17 (59). DAY185, a derivativeof BWP17 in which the auxotrophies were corrected by reintroductionof the corresponding wild-type genes, was used as the wild-typecontrol strain for these studies, as it most closely resemblesthe septin mutants in its genetic background. DAY185 was shownpreviously to display the same level of virulence in mouse infectionsas Sc5314, the naturally prototrophic parental strain for BWP17(14).

Septin mutants are defective in agar penetration. As an initial assessment of hyphal function, mutants were analyzedfor invasive growth into solid agar medium containing 4% bovinecalf serum. Cells from saturated overnight cultures of wild-typeand septin mutant strains were spotted onto the surface of platescontaining concentrations of agar ranging from 0.5 to 3% toprovide various levels of resistance to fungal penetration.Incubation at 37°C induced hyphal growth in all C. albicansstrains on all agar concentrations. By 24 h, obvious defectsin hyphal growth and agar penetration were observed for cdc10 ${Delta}$ and cdc11 ${Delta}$ strains. Both the wild type and the sep7 ${Delta}$ mutant, whichin previous studies did not exhibit budding or hyphal defects(data not shown and reference 56), showed long branching filamentsradiating into the agar from the cells on the surface. In contrast,cdc10 ${Delta}$ , and to a greater extent cdc11 ${Delta}$ , were partially defectivein invasive growth. These mutants displayed significantly shorterand often more tangled hyphal growth on the colony periphery(Fig. 1A). By 5 days, the invasion defect was easily observedby visual inspection. The invasion defect was greatest for cdc11 ${Delta}$ ,which displayed very little hyphal-type growth beyond the borderof the original spot colony. When the colonies were washed fromthe surface of the plate, extensive hyphal penetration deepinto the agar was apparent for both the wild-type and sep7 ${Delta}$ strains.In contrast, cdc10 ${Delta}$ and cdc11 ${Delta}$ produced filaments reaching onlyhalf as deep into the agar (Fig. 1B). The difference in capacityto undergo invasive growth was even more easily observed incross section (Fig. 1C).

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FIG. 1. cdc10 ${Delta}$ and cdc11 ${Delta}$ mutants are defective for invasive hyphal growth in agar. Wild-type (DAY185), sep7 ${Delta}$ (YAW22), cdc10 ${Delta}$ (YAW7), and cdc11 ${Delta}$ (YAW11) strains suspended in 1 µl of YPD containing 10⁴ cells were spotted to the surface of 4% serum plates containing 0.5 to 3% agar, and the plates were incubated at 37°C. (A) Microscopic images of spot colony edges at 24 h of incubation on 2% agar show reduced hyphal growth for septin mutants. Bar, 500 µm. (B) Top view of spot colonies at 7 days of incubation on 0.8% agar. (C) Cross section of spot colonies from a surface-washed 3% agar at 7 days of incubation. Dotted lines indicate the depth of invasive growth. (D) The degree of hyphal growth was measured microscopically from the colony edge at 48 h of incubation for four colonies each from three separate experiments on the indicated agar concentrations. Average invasion distance and standard error are displayed graphically.

To quantify the defects in agar invasion that were observed,the four strains were grown on different concentrations of agarand the length of invasive growth beyond the colony border wasmeasured microscopically at 48 h postplating (Fig. 1D). Allstrains exhibited a reduced invasion depth with increased agarconcentration. However, the cdc11 ${Delta}$ mutant showed the most reductionin agar penetration ability compared to the wild type at allagar concentrations tested. The reduced invasive growth of theseptin mutant strains was due to a specific defect in invasiveness,since all mutant strains grew on the agar surface at a rateequivalent to that of the wild type (data not shown).

Septin mutants form hyphae after macrophage engulfment. The septin mutants were analyzed for their ability to producehyphae in response to phagocytosis. C. albicans cells were addedto the macrophage cell line J774 at a three-to-one ratio inserum-free medium. By 30 min, the yeasts had been internalizedand were visible as rounded cells within the macrophages (datanot shown). By 3.5 h postinfection, the wild-type prototrophicstrain DAY185 had grown extensive hyphae which ruptured themacrophages that had contained them (Fig. 2C). In contrast,the auxotrophic parental strain BWP17 (his1^- ura3^- arg4^-), whichwould be predicted to be avirulent (34) and unable to grow withina phagosome due to nutrient deprivation (41), was unable toproduce hyphal growth. The original round yeast cells that wereengulfed by the macrophages were readily observed (Fig. 2B).The prototrophic versions of sep7 ${Delta}$ , cdc10 ${Delta}$ , and cdc11 ${Delta}$ septin mutantsall exhibited hyphal growth of lengths similar to that of thewild type, which resulted in lysis of the macrophages (Fig.2D, E, and F). Similar results were observed using primary mousebone marrow macrophages (data not shown). These results indicatethat the septin mutants do not exhibit any obvious defect inhyphal formation under these short-term in vitro conditions.Additionally, the mutants are not defective for responding toenvironmental cues to form hyphae in response to engulfmentby phagocytic cells.

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FIG. 2. Septin mutants are not defective for hyphal growth within phagocytic macrophages. J774 cells were plated at 10⁵ cells/well in 24-well dishes on coverslips. Overnight cultures of yeast grown at 30°C in YPD were washed in sterile PBS and diluted to 3 x 10⁵ cells/ml (multiplicity of infection of 3) into serum-free DMEM and added to PBS-washed J774 cells. Cells were fixed in 5% formaldehyde at various time points for 1 h and washed in PBS. Coverslips were removed and mounted for observation under differential interference contrast imaging. Images of J774 cells at 3.5 h postinfection are shown. (A) J774 cells incubated without yeast cells. (B) Avirulent strain BWP17 is unable to produce hyphal growth, but round yeast cells are readily observable. (C to F) Wild-type cells (DAY185) (C) and septin deletion mutants YAW22 (D), YAW7 (E), and YAW11(F) all show hyphal growth resulting in lysis of macrophages. Bar, 10 µm.

Septin mutants exhibit reduced virulence in mouse model of infection. Prototrophic versions of C. albicans strains carrying eitherheterozygous or homozygous deletions of septins CDC10, CDC11,and SEP7 (Table 1) were compared with the corresponding wild-typestrain DAY185 for pathogenicity following tail vein injectionin mice. The sep7 ${Delta}$ strain displayed a wild-type level of virulencein mice, consistent with the lack of obvious defects in buddingor short-term hyphal growth (56) (Fig. 2), and only a minorreduction in agar invasion ability (Fig. 1). As can be seenin Fig. 3, the mouse survival curves for both the sep7/SEP7heterozygote (YAW41) and sep7 ${Delta}$ deletion (YAW22) strains closelyparallel that of the wild-type strain (DAY185), with mediansurvival times of 6.6, 5.7, and 6 days, respectively. The cdc10(YAW6) and cdc11 (YAW10) heterozygote reconstituted strains,which were aphenotypic under all condition tested (reference56 and data not shown), also displayed a similar effectivenessin pathogenesis, with median survival times of 8.4 and 6.8 days,respectively. The cdc10 ${Delta}$ (YAW7) and cdc11 ${Delta}$ (YAW11) deletion strains,however, exhibit a marked attenuation in virulence, as the majorityof mice infected with either of these strains survived to theend point of the experiment without obvious signs of infection.The reduced virulence of the septin mutants was significantlydifferent (P < 0.01) from that of the wild type as determinedby the Mantel-Haenszel test (Prism version 3.00 for Windows,GraphPad Software, San Diego, Calif.).

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FIG. 3. Septins mutants exhibit attenuated virulence. Immunocompetent ICR male mice were injected via the lateral tail vein with 0.1 ml of solution containing 10⁶ C. albicans cells, and mice were monitored for 15 days. Moribund mice were sacrificed, and the percentage of total mice surviving for each strain on each day was plotted. Twenty-five mice each for strains YAW7 (cdc10 ${Delta}$ ) and YAW11 (cdc11 ${Delta}$ ) and 15 mice each for strains YAW6 (cdc10 heterozygote), YAW10 (cdc11 heterozygote), YAW22 (sep7 heterozygote), YAW41 (sep7 ${Delta}$ ), and DAY185 (wild type) were used.

To examine invasive growth in vivo, kidneys were harvested froma subset of mice that were randomly chosen during the courseof the infection for analysis. The kidneys tend to be the firstorgan colonized during systemic infection (42, 44) and are oneof the most invasively colonized organs, with the majority ofexperimental murine deaths resulting from pyelonephritis (2).Mice infected with the wild-type strain typically carried approximately10⁶ CFU/g of kidney when moribund. Upon termination of the infectionstudy, mice infected with the septin mutants that survived today 15 exhibited similar CFU/g, with means of 1.36 x 10⁶ (±0.78 x 10⁶) for cdc10 ${Delta}$ and 2.52 x 10⁶(± 4.39 x 10⁶) forcdc11 ${Delta}$ . In spite of these fungal loads, however, the mice didnot appear obviously ill or moribund. Interestingly, two outof nine mice infected with cdc11 ${Delta}$ showed less than 10³ CFU/g,indicating that the infection had likely been cleared.

Septin mutants colonize kidneys but are defective for invasion. In view of the defects in virulence, the septin mutants wereexamined for ability to grow invasively into kidneys in vivo.Silver staining of kidneys from mice infected with wild-typestrain DAY185 revealed extensive hyphal invasion of the renalpelvis at day 5 (Fig. 4A and D). The cdc10 ${Delta}$ strain also exhibitedsome invasion into the tissue of the papillus, but the hyphalgrowth appeared more restricted and was not found in deeperstructures of the kidney (Fig. 4B and E). Additionally, fungalmasses made up of hyphal cells were evident near the ureterspace, indicating a failure to invade yet persistence in growth(Fig. 4E, arrow). The cdc11 ${Delta}$ mutant exhibited an even strongerphenotype. Silver staining detected very pronounced fungal massesconsisting of hyphal cells in the ureter spaces, and no evidenceof invasion into any kidney structures was observed, even atday 15 (Fig. 4C and F).

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FIG. 4. Septin mutants are defective for kidney tissue invasion. Kidneys were harvested, sectioned, and silver stained to reveal yeast colonization. (A and D) Wild-type strain DAY185 on day 5 postinfection showed extensive invasive growth in the renal pelvis. (B and E) cdc10 ${Delta}$ strain (YAW7) on day 5 showed invasive growth of the papillus and a fungal mass with minimal invasive growth in the ureter space. (C and F) cdc11 ${Delta}$ (YAW11) on day 15 was found only as fungal masses in the ureter space with no invasive growth in the tissues. Circles on panels A to C indicate areas enlarged in panels D to F. Arrowheads indicate noninvasive fungal balls. Bar, 100 µm.

H&E staining of the tissue surrounding the fungal ballsindicated heavy infiltration of lymphocytes surrounding thefungal mass (Fig. 5B and C) as well as in the areas of tissueinvasion. This indicates that all strains are capable of elicitingan immune response. Thus, although the septin mutants are ableto colonize the kidneys and persist without rapid clearance,they are obviously defective in fully penetrating deeper intotissues to establish a more widely disseminated infection.

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FIG. 5. Inflammatory cells surround noninvasive fungal growth. (A) Silver stain of ureter space containing a fungal mass of cdc11 ${Delta}$ cells. Bar, 100 µm. (B and C) H&E staining of the fungal mass revealed heavy infiltration of leukocytes. The circle in panel B indicates the area of enlargement shown in panel C. Bar in panel C, 50 µm. Kidneys were harvested 15 days postinfection.

DISCUSSION

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Discussion

Hyphal growth is thought to be important in C. albicans pathogenesis,in part because hyphae facilitate invasive growth into tissues.Therefore, in this study, the ability of septin mutants to undergoinvasive growth in vitro and in vivo was examined. The cdc10 ${Delta}$ and cdc11 ${Delta}$ mutants were targeted for analysis of invasive growthbecause they displayed minor defects in hyphal morphogenesisin liquid culture assays. These septin mutants were not grosslydefective for hyphal growth in liquid when appropriately stimulated,and they showed typical induction of hyphal-specific genes suchas ALS1 and HWP1 (unpublished results). Similarly, the septinmutants were not defective for hyphal growth when phagocytosedby macrophages (Fig. 2). However, the cdc10 ${Delta}$ and cdc11 ${Delta}$ mutantsdisplayed defects for invasive growth into agar (Fig. 1). Thecdc11 ${Delta}$ mutant in particular showed very little invasive growthin agar, which correlated with this mutant displaying more defectsthan the cdc10 ${Delta}$ mutant in hyphal morphogenesis in liquid cultureassays (reference 56 and data not shown).

The ability of the cdc10 ${Delta}$ and cdc11 ${Delta}$ mutants to undergo invasivegrowth in vivo was examined in mouse infection studies. Interestingly,the septin mutants were significantly less virulent than thewild type, with the majority of the mice surviving to day 15,whereas at least 50% of mice infected with the control strainswere moribund by day 6 (Fig. 3). However, the septin mutantstrains were not completely avirulent, as the CFU level recoveredfrom the kidneys of mice injected with the septin mutants wassimilar to that of moribund mice infected with the wild type.This high number of organisms present in the mice infected withthe septin mutants was surprising considering the apparent healthof these animals, although not unprecedented (5, 31), and itmay relate to differences in invasiveness that will be describedbelow. In contrast, avirulent mutants are typically clearedby the immune system, rapidly resulting in very few or no CFUby day 15. For example, mutants that are strongly defectivefor normal hyphal growth, such as cdc35 ${Delta}$ (45) and cla4 ${Delta}$ (35),show reduced levels or complete clearance of C. albicans fromthe organs in a matter of days. Although two mice infected withcdc11 ${Delta}$ did show reduced levels of C. albicans in the kidneys,the majority exhibited high fungal burdens to day 15.

To directly examine the ability of septin mutants to undergoinvasive growth in vivo, kidneys were stained and examined.Wild-type cells at day 5 showed extensive invasion into thekidney, with mycelial growth extending throughout the tissue.In contrast, the cdc10 ${Delta}$ mutant was less invasive and in someareas appeared restricted to a fungal mass with little or noinvasion into the surrounding tissue, despite the presence ofhyphal cells. The cdc11 ${Delta}$ mutant appeared to be completely defectivefor invasion, exhibiting only large masses of hyphal cells withinthe ureter space. This accumulation of fungal cells in noninvasivemasses seems likely to account for the observation that themice infected with the septin mutants appear healthy in spiteof a fungal loads that are typically seen in moribund mice infectedwith wild-type C. albicans. This phenotype is also interestingin that it appears similar to a pattern of infection termedfungal balls that has been previously described for some humanpatients, particularly neonates (7, 9, 51).

The strong invasive defect for the cdc11 ${Delta}$ mutant in vivo is consistentwith the invasive growth defect observed in vitro in agar invasionassays. Interestingly, the septin mutants appeared to show evenstronger defects in invasive growth into kidneys than they didin agar invasion. Although this may relate to differences inthe difficulty of invading agar versus living tissue, anotherimportant difference is that C. albicans is subject to attackby the immune system in vivo. H&E staining revealed heavyinfiltration of lymphocytes surrounding the C. albicans fungalmasses. A similar observation was made for efg1 ${Delta}$ mutants whereininflammatory cells appeared to inhibit penetrative growth ofthe mutant more strongly than wild-type cells (19). Thus, theinvasive growth defect of the septin mutants may be exacerbatedin vivo by attack from leukocytes.

The results of this study indicate that although the septinmutants are not grossly defective in forming hyphae in liquidculture, they are defective for invasive growth in vitro andin vivo. Since septins are thought to act in the organizationof other effector proteins, it is interesting that Int1p, aseptin binding protein, was also shown to be important for hyphalgrowth on agar but not in liquid, and int1 ${Delta}$ mutants displayedreduced virulence in mice (23). One possibility is that thedefect in invasiveness for septin mutants is a direct consequenceof their abnormal cell wall construction, as evidenced by ahigher degree of curved hyphae and unusual chitin deposition.In agreement with this, hwp1 ${Delta}$ mutant cells lacking the hyphal-specificcell wall protein Hwp1 displayed hyphal defects on agar butnot in liquid culture (55). Similar to the septin mutants, miceinfected with hwp1 ${Delta}$ mutant cells exhibited high organ CFU withno mortality and clustered groupings of cells in the kidneyswith no extensive hyphal penetration (55). Interestingly, ash1 ${Delta}$ mutants of C. albicans, which lack a transcription factor presentin hyphal tip cells that is needed for filamentous growth undersome conditions, displayed reduced virulence and persistencein kidneys (30). However, ash1 ${Delta}$ mutants differed from the septinmutants in that their defect was attributed to a slower rateof invasive growth rather than a change in the overall patternof invasiveness. kex2 ${Delta}$ mutants also display defects in invasivegrowth and persist in kidneys during infection (43). In thiscase, it appears that kex2 ${Delta}$ mutants persist in kidneys by avoidingthe immune system because of a defect in processing secretedhydrolytic enzymes that are expected to cause tissue damageand thereby recruit lymphocytes. Thus, a variety of differentproteins function to influence the ability of C. albicans toundergo invasive growth during infection.

Proper hyphal growth has been proposed to be important for adhesionto host tissues (23, 52), rigidity to facilitate penetrationinto tissues (26), directional growth in response to thigmotropicor chemotropic cues (13, 48, 57), and for the release of hydrolyticenzymes, such as secreted aspartic proteinases (19, 50). Itis likely that during infection, multiple hyphal functions areacting in concert to allow pathogenesis to succeed. Altogether,these studies suggest that virulence many not rely solely onthe ability to switch between hyphal and budding morphologiesbut rather on the ability to coordinate a variety of responsesthat culminate in appropriate growth both qualitatively andquantitatively. In vitro assays that are designed only to testthe ability of hyphal formation in liquid cultures may be overlookingthe subtle defects that could be utilized for therapeutic drugdesign.

ACKNOWLEDGMENTS

We thank the laboratory of James Bliska (SUNY Stony Brook),especially Michelle Ryndak and Adam Smith, for their guidanceduring tissue culture experiments.

This work was supported by grant RO1 AI47837 from the NationalInstitutes of Health that was awarded to J.B.K. Digital cameraequipment was obtained through a Targeted Research OpportunityGrant from the Stony Brook School of Medicine.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Genetics and Microbiology, State University of New York, Stony Brook, NY 11794-5222. Phone: (631) 632-8715. Fax: (631) 632-9797. E-mail: james.konopka{at}sunysb.edu.

Editor: T. R. Kozel

REFERENCES

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