Eca1, a Sarcoplasmic/Endoplasmic Reticulum Ca2+-ATPase, Is Involved in Stress Tolerance and Virulence in Cryptococcus neoformans

The basidiomycetous fungal pathogen Cryptococcus neoformansis adapted to survive challenges in the soil and environmentand within the unique setting of the mammalian host. A C. neoformansmutant was isolated with enhanced virulence in a soil amoebamodel that nevertheless exhibits dramatically reduced growthat mammalian body temperature (37°C). This mutant phenotyperesults from an insertion in the ECA1 gene, which encodes asarcoplasmic/endoplasmic reticulum (ER) Ca²⁺-ATPase (SERCA)-typecalcium pump. Infection in murine macrophages, amoebae (Acanthamoebacastellanii), nematodes (Caenorhabditis elegans), and wax moth(Galleria mellonella) larvae revealed that the eca1 mutantsare virulent or hypervirulent at permissive growth temperaturesbut attenuated at 37°C. Deletion mutants lacking the entireECA1 gene were also hypersensitive to the calcineurin inhibitorscyclosporin and FK506 and to ER and osmotic stresses. An eca1 ${Delta}$ cna1 ${Delta}$ mutant lacking both Eca1 and the calcineurin catalyticsubunit was more sensitive to high temperature and ER stressesthan the single mutants and exhibited reduced survival in C.elegans and attenuated virulence towards wax moth larvae attemperatures that permit normal growth in vitro. Eca1 is likelyinvolved in maintaining ER function, thus contributing to stresstolerance and virulence acting in parallel with Ca²⁺-calcineurinsignaling.

INTRODUCTION

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INTRODUCTION

Nonobligate human pathogens confront and must survive diverseenvironmental conditions. The ability to survive and proliferatein various challenging environmental niches, including in environmentalmicrobial predators, is hypothesized to contribute to the abilityof Cryptococcus neoformans, a basidiomycete fungus of globaldistribution, to cause disease in humans (15, 37, 49). The successof this pathogen is also attributed to its ability to surviveat mammalian body temperature, which is an uncommon trait amongfungal species. Tolerance to thermal stress (caused by bodytemperature) and oxidative stresses (from mammalian host defenses)is critical for successful infection. C. neoformans mutantswith increased sensitivity to oxidative or nitrosative challenge,including those lacking superoxide dismutase Sod1 or Sod2 (18,35), alternative oxidase Aox1 (2), flavohemoglobin denitrosylaseFhb1 (23), thiol peroxidase Tsa1 (48), or thioredoxin Trx1 (47),exhibit attenuated virulence. Temperature-sensitive mutantshave been isolated in C. neoformans, including cna1 (calcineurincatalytic subunit), cnb1 (calcineurin regulatory subunit), cpa1(cyclophilin A), and ras1 strains, and all of these have reducedvirulence in mammalian host models (3, 29, 55, 73).

Calmodulin and calcineurin are central mediators of calciumsignaling and respond to a multiplicity of stresses. Calmodulinis a Ca²⁺ sensor that undergoes conformational changes uponCa²⁺ binding and transduces this Ca²⁺ signal to other proteins,such as calcineurin and Ca²⁺/calmodulin-dependent protein kinases(CaMK), via protein-protein interactions. Calcineurin is a highlyconserved Ca²⁺/calmodulin-activated serine/threonine proteinphosphatase that exists as a heterodimer of a catalytic A subunitand a regulatory B subunit. It is the target of the immunosuppressivedrugs cyclosporin (CsA), which binds to cyclophilin A, and FK506,which binds to FKBP12. Calcineurin transduces Ca²⁺ signalingby activating the transcription factors NFAT in mammalian Tcells and Crz1 in the yeasts Saccharomyces cerevisiae and Candidaalbicans (21, 36, 39). In C. neoformans, calcineurin is requiredfor mating, morphogenesis, growth at 37°C, and virulencein murine models (20, 29, 55). However, the downstream signalingevents regulated by calcineurin and the factors affecting calcineurinfunction are still largely unknown in C. neoformans and otherpathogenic fungi.

Cellular Ca²⁺ homeostasis is maintained through the coordinatedactions of Ca²⁺ pumps on the plasma, vacuolar, Golgi apparatus,and endoplasmic reticulum (ER) membranes. The sarcoplasmic/endoplasmicCa²⁺-ATPases (SERCAs) are a family of ER Ca²⁺ pumps that arehighly conserved in eukaryotic organisms. The ER is the cellularcompartment for protein posttranslational processing, such asfolding, glycosylation, assembly of protein complexes, and transportto the Golgi apparatus. ER function requires the maintenanceof high Ca²⁺ concentrations, an oxidative milieu in the lumen,and the activity of molecular chaperones (reviewed in reference12). The ER is also a major site of Ca²⁺ storage, with releaseof Ca²⁺ into the cytosol in response to certain stimuli. SERCAsare important in replenishing Ca²⁺ levels in the ER by transportingCa²⁺ from the cytosol to the ER and thereby play critical rolesin maintaining Ca²⁺ homeostasis in both the ER and the cytosol.In mammals, SERCAs are important for muscle relaxation and deficienciesin SERCAs are linked to multiple genetic diseases (46, 74).In the plant Arabidopsis thaliana, the ECA1 gene encodes a SERCAthat is required for growth under low Ca²⁺ or high Mn²⁺ concentrations(75). In the parasite Leishmania mexicana amazonesis, a SERCA-typeCa²⁺ pump (Lmaa1) is involved in virulence (59). In the basidiomyceteplant pathogen Ustilago maydis, ECA1 encodes a SERCA requiredfor growth at high temperature and hyphal development (1).

Forward genetic screens are a powerful approach to identifynew gene functions. Recently we identified a component in theCa²⁺ signaling pathway of C. neoformans (i.e., calmodulin) throughan insertional mutagenic screen of temperature-sensitive mutants(42). Here we report the identification of the C. neoformansgene ECA1, encoding a SERCA-type Ca²⁺ pump, by screening a collectionof insertion mutants in an amoeba model of virulence. Geneticanalysis indicated that ECA1 is involved in tolerance to multiplestresses and is required for growth at 37°C. Inhibitionor mutation of the Ca²⁺-activated protein phosphatase calcineurinaggravates eca1 ${Delta}$ mutant phenotypes. Infection in four host modelssuggests that Eca1 contributes to virulence in a temperature-dependentmanner: at 37°C, the eca1 mutants are hypovirulent, yetat temperatures permissive for in vitro growth the eca1 mutantshave wild-type or enhanced virulence. Our results further extendour understanding of the connections between Ca²⁺ signalingwith stress tolerance and virulence and suggest that the maintenanceof virulence of C. neoformans in the environment is a traitof greater complexity than simple positive selection in microbialpredators.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Strains and growth conditions. The C. neoformans strains used in this study are listed in Table1. The serotype A MAT ${alpha}$ strain H99 and congenic MAT ${alpha}$ KN99 ${alpha}$ and MATaKN99a strains were used as the wild type (53, 57). The calcineurinsubunit A cna1 ${Delta}$ deletion strains were as reported previously(40). The collection of $~$ 590 insertional mutants was generatedpreviously by biolistic transformation of strain H99 with plasmidpCH233 conferring resistance to nourseothricin (38). C. neoformanswas grown in YPD (1% yeast extract, 1% Bacto peptone, 2% dextrose)liquid or solid (supplemented with 2% agar) medium. For treatments,compounds were added after the medium was autoclaved. The macrophagecell line J774A.1 (ATCC TIB-67) is derived from a murine (BALB/c,haplotype H-2^d) reticulum sarcoma (58). Macrophage cells weremaintained at 37°C in 5% CO₂ in Dulbecco's modified Eagle'smedium (DMEM) (Invitrogen, Carlsbad, CA) supplemented with 10%heat-inactivated fetal bovine serum (Atlanta Biologicals, Atlanta,GA), 1% nonessential amino acids, 100 U/ml penicillin, 100 µg/mlstreptomycin, and 10% NCTC-109 medium (Invitrogen). The cellline was used between passages 4 and 15. The amoeba Acanthamoebacastellanii (ATCC 30234) was maintained at 22°C in PYG medium(ATCC medium 712) following ATCC instructions. Galleria mellonella(wax moth) larvae were obtained from Vanderhorst, Inc. (St.Marys, OH) and maintained in wood shavings at room temperature(22°C). The standard Caenorhabditis elegans strain N2 Bristolwas propagated on Escherichia coli strain OP50 lawns on nematodegrowth medium (NGM) at 25°C.

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TABLE 1. C. neoformans strains used in this study

Identification and disruption of ECA1. The hypervirulent mutant AI-5C9 was identified in a collectionof insertion mutants by screening for altered virulence in amoebae,using the virulence assay as described previously (65) and below.The genome insertion junction of AI-5C9 was cloned by inversePCR and sequenced. The ECA1 gene was identified in serotypeA and D strains by performing BLASTn searches of the Duke UniversityC. neoformans serotype A genome database (http://cneo.genetics.duke.edu)and The Institute for Genomic Research (TIGR) serotype D database(45) with the sequence of the insertion junction. Targeted replacementof the ECA1 open reading frame in strain H99 was achieved bybiolistic transformation with an overlap PCR product in whicha NAT cassette was flanked by a 1-kb fragment from upstreamof the ECA1 start codon and a 1-kb fragment from downstreamof the ECA1 stop codon. Transformants were selected on YPD agarmedium plates containing 100 mg/liter nourseothricin at 30°Cand then screened by PCR for an eca1 ${Delta}$ strain, and the deletionwas confirmed by Southern and Northern blot analyses. The eca1 ${Delta}$ mutation was complemented by reintroducing a wild-type versionof the gene. ECA1 was amplified from strain JEC21 and clonedinto plasmid pPZP-NEO1 (72). Agrobacterium tumefaciens strainEHA105 was transformed with this plasmid by electroporationand used to transform C. neoformans to neomycin resistance usingmethods reported previously (38).

Generation of an eca1 ${Delta}$ cna1 ${Delta}$ double mutant. The eca1 ${Delta}$ mutant (NAT^R) in the MAT ${alpha}$ background (parent strainH99) was crossed with a cna1 ${Delta}$ (Neo^R) mutant in the MATa background(parent strain KN99a) on V8 agar medium. Basidiospores weredissected 9 days after mating and were allowed to germinateon YPD medium at 30°C. The isolates were then tested forthe presence of both nourseothicin and neomycin resistance markers,and the presence of both eca1 and cna1 mutations in these strainswas confirmed by PCR analysis.

RNA extraction and Northern blot analysis. Total RNA was extracted from C. neoformans with the TRIzol reagent(Invitrogen), separated by electrophoresis in a 1.2% denaturingagarose gel, and transferred to nylon membrane (Hybond H+; AmershamBiosciences, United Kingdom). The blot was hybridized with ³²P-labeledprobes in the ULTRAhyb buffer (Ambion, Austin, TX) accordingto the manufacturer's instructions. Autoradiograph images wereanalyzed with NIH Image software.

Virulence assays. Virulence assays were conducted in four model systems as describedpreviously: amoeba A. castellanii (65), murine macrophage cellline J774A.1 (26, 27), the nematode C. elegans (50, 71), andG. mellonella (wax moth) larvae (52). For most assays, C. neoformanscells were cultured in YPD medium at 30°C to mid-to-latelog phase, and the cells were washed three times with phosphate-bufferedsaline (PBS) and resuspended in PBS to the desired concentrationsas the inocula. Cell numbers were determined by counting witha hemocytometer. For C. elegans assays, C. neoformans strainswere cultured overnight and spread onto brain heart infusion(BHI) agar to create lawns.

For the amoeba virulence assay, A. castellanii was culturedin PYG medium in 96-well microtiter plates to a density of 1x 10⁵ cells/well, and C. neoformans cells were added to theamoebae at a multiplicity of infection (MOI) of 2:1. The amoeba-yeastcoculture was incubated at either 30 or 37°C for 24 or 48h before being lysed with ice-cold H₂O containing 0.05% sodiumdodecyl sulfate. Serial dilutions of the lysate were platedon YPD, and the CFU served as an indicator of C. neoformansvirulence.

For the macrophage assay, J774A.1 cells were grown in 96-wellmicrotiter plates to a density of 1 x 10⁵ cells/well, and C.neoformans cells were added to the macrophages at an MOI of2:1, in the presence of 1 µg/ml monoclonal antibody 18B7(provided by Arturo Casadevall [14]), 50 U/ml of recombinantmouse gamma interferon (Roche Molecular Biochemicals, Mannheim,Germany), and 0.3 µg/ml lipopolysaccharide (Sigma-Aldrich,St. Louis, MO). After 1 h of incubation at 37°C in the presenceof 10% CO₂, unattached C. neoformans cells were washed off byaspiration with fresh medium and the macrophage-yeast coculturewas incubated for a further 24 h, at which time the macrophageswere lysed with ice-cold H₂O containing 0.05% sodium dodecylsulfate and serial dilutions of the lysate were plated on YPD.CFU served as the measure of C. neoformans virulence.

Three C. elegans system endpoints were used to examine the virulenceproperties of the C. neoformans strains: nematode survival,nematode progeny production, and fungal burden within nematodes.C. elegans worms were monitored for survival on C. neoformanslawns as described previously (50, 51). Fungal strains weregrown in 2 ml of YPD medium with kanamycin (45 µg/ml),ampicillin (100 µg/ml), and streptomycin (100 µg/ml)with shaking at 30°C for 24 to 48 h. Lawns were preparedby spreading 10 µl of each culture on 35-mm tissue cultureplates containing BHI agar with the same antibiotics. The plateswere incubated at 30°C for 24 h and then at 25°C for24 h. Approximately 60 nematodes at the L4 stage were transferredfrom NGM seeded with E. coli strain OP50 to each of four BHIplates per C. neoformans strain. The plates were incubated at25°C, and the worms were examined for survival at 24-h intervalswith a Nikon SMZ645 dissecting microscope. At each interval,inviable worms were counted and removed.

For C. elegans progeny quantification, C. neoformans lawns wereprepared as described above. One nematode at the L4 stage wasmoved from NGM plates seeded with E. coli OP50 to each of 24lawns per C. neoformans strain. At 24-h intervals, living wormswere transferred to new lawns for each strain, and at 72 h theliving worms were removed. Each BHI agar pad was inverted ontoa 100-mm tissue culture plate containing NGM agar with streptomycin(100 µg/ml) and seeded with E. coli. The plates were incubatedat 25°C for 48 h, and the progeny were counted. Only wormsthat survived all 3 days were included in calculating the totalprogeny laid over the course of 72 h.

The C. neoformans burdens within infected C. elegans were quantifiedas described previously (34), but with 10 animals at the L4stage in each group and only one 48-h time point of exposureto Cryptococcus lawns prepared on BHI plates as described above.After exposure, animals were washed twice in 8-µl dropsof M9 medium on a BHI agar plate containing antibiotics as describedabove, in order to remove surface cryptococcal cells. Each groupof 10 worms was then placed in 40 µl of M9 medium with1% Triton X-100 and ground with a pestle. The volume was adjustedto 600 µl with M9 medium containing 1% Triton X-100, andthe final suspension was serially diluted and plated on YPDagar containing the same antibiotics. The plates were incubatedfor 48 h at 30°C, and CFU were counted.

For virulence in the wax moth assay, each G. mellonella larvawas injected in the terminal pseudopod with C. neoformans cells(1 x 10⁵ in 5 µl PBS). Larvae were incubated at 30 or37°C, and virulence was measured by scoring the survivalof the larvae every 24 h.

RESULTS

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RESULTS

Isolation of a hypervirulent, temperature-sensitive insertion mutant. Nonmammalian models have been developed to test virulence propertiesof C. neoformans and other human pathogens, leading to theiruse in forward genetic screening to identify attenuated mutantsand thereby genes required for virulence. During a screen forC. neoformans strains with altered virulence in amoeba, onehypervirulent strain (AI-5C9) was identified out of 590 insertionalmutants examined (Fig. 1), and its in vitro phenotypes wereanalyzed for known virulence attributes. Capsule and melaninwere produced at wild-type levels. Strain AI-5C9 displayed normalgrowth at 30°C on YPD medium or the PYG medium used in amoebainteractions. However, when cultured at 37°C, growth ofmutant AI-5C9 was significantly reduced compared with that ofthe wild-type strain, H99 (Fig. 1 and 2A). Although strain AI-5C9exhibits reduced growth at 37°C, the cells display normalcellular morphology even after being cultured at 37°C for2 days (data not shown). Because of its paradoxical increasein virulence in amoeba yet reduced growth rate at mammalianbody temperature, the mutant strain was further characterized.

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FIG. 1. eca1 mutation enhances virulence in the amoeba A. castellanii. Cryptococcal yeast cells of the wild type (WT), eca1 insertion mutant AI-5C9, and two independent eca1 ${Delta}$ deletion mutants (eca1-11 and eca1-26) were inoculated into amoeba cell culture at an MOI of 2:1 (left panels) or into amoeba-free medium (PYG; right panels), and were cultured at either 30°C (top panels) or 37°C. A total of 1 x 10⁶ cryptococcal cells were inoculated into amoebae or medium (gray bars), and fungal cells were isolated 24 h (white bars) or 48 h (hatched bars) after incubation, with growth measured by plating on YPD medium and counting CFU after culture at 30°C for 2 days. *, P < 0.05.

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FIG. 2. Characterization of C. neoformans Eca1. (A). Temperature-sensitive growth of eca1 insertion mutant AI-5C9. Ten-fold dilutions of AI-5C9 and the wild-type (WT) H99 cells were plated on YPD agar and cultured at 25°C or 37°C for 2 days. (B) Phylogenetic analysis of Eca1 and its homologs. Amino acid sequences of C. neoformans Eca1 (Cn) and P-type Ca²⁺ pumps from other organisms were aligned using the MultAlin program (17). A phylogenetic tree was deduced to depict the evolutionary relationships of the homologs. All of the SERCA-type pumps cluster at the left node (labeled SERCA), and the fungal Pmr1 or mammalian AT2C1 pumps cluster at the right node (labeled Pmr1). (C). Schematic diagram of the targeted deletion of the ECA1 gene. The genomic DNA structure of ECA1 is illustrated as gray boxes for the exons, and the entire coding region was replaced with a nourseothricin resistance cassette (NAT). Shown are the results of Southern analysis of genomic DNA from two independent isolates, the eca1-11 (lanes 11) and eca1-26 (lanes 26) mutants, and parental strain H99 (WT). Genomic DNA was digested with EcoRV, HindIII, or XhoI. The probe used is indicated by the hatched bar. (D) Northern blot analysis of ECA1 expression. Total RNAs were isolated from wild-type, eca1, and cna1 cells cultured at 30°C in YPD medium (30°C) or YPD medium supplemented with 20 mM of CaCl₂ (Ca20) and cells cultured in YPD medium at 37°C (37°C), and the Northern blot was hybridized with ³²P-labeled probes for actin (ACT1) and ECA1. The autoradiography images were analyzed with NIH Image software to quantify the expression levels. Transcription of ECA1 in each sample was normalized by the ACT1 gene and compared with the 37°C-treated wild-type sample, the value of which was set to 100%. The relative levels of ECA1 expression are listed below the images (Rel. %). (E). Deletion of ECA1 resulted in temperature-sensitive phenotypes identical to that of AI-5C9. Ten-fold serial dilutions of eca1-11, eca1-26, and wild-type strains were plated on YPD agar and cultured at 30°C, 35°C, or 37°C for 2 days.

The ECA1 gene encodes a SERCA-type calcium pump. Segregation analysis of the progeny produced by mating the AI-5C9mutant with the congenic MATa strain KN99a confirmed that theNAT resistance marker is linked with the temperature-sensitivephenotype. Strain AI-5C9 mated normally with KN99a, producingwild-type amounts of viable basidiospores. Of those progenyanalyzed, 6/13 were nourseothricin resistant and temperaturesensitive and 7/13 were nourseothricin sensitive and temperatureresistant, indicating 100% genetic linkage. Likewise, in crossesbetween a eca1 and ${alpha}$ eca1 mutants, mating occurred to producefilaments and basidiospores (data not shown). The site of insertionof the plasmid into the C. neoformans genome was identifiedby inverse PCR and DNA sequencing. The AI-5C9 mutant carriesan insertion in a gene encoding a predicted protein of 1,006amino acids that belongs to the P-type calcium ATPase family.The corresponding gene in the serotype D strain JEC21 genome,which has been sequenced and annotated (45), is CNH02370. Althoughits closest homolog in Saccharomyces cerevisiae is Pmr1, whichis a Ca²⁺ pump localized to the Golgi apparatus, the C. neoformans-encodedprotein is more closely related to SERCA pumps in basidiomycetousfungi and other organisms, including plants, worms, fruit flies,mice, and humans. This is illustrated by the phylogenetic analysisof the deduced amino acid sequences of the C. neoformans geneand related P-type calcium pumps (Fig. 2B). The closest homologof CNH02370 in the GenBank database is the ECA1 gene from U.maydis (E = 0.0) (1), and the C. neoformans gene was thereforenamed ECA1. Alignment of the Eca1 amino acid sequence with thatof rabbit SERCA1, whose structure has been solved by X-ray crystallographyand well studied, showed that not only do they share a highdegree of similarity in protein primary structure (54% identity,68% similarity), but the overall domain structure and criticalamino acid residues, such as the nucleotide binding sites anda phosphorylation site (DKTGT), are all conserved.

The ECA1 gene was deleted by homologous recombination to generatetwo independent eca1 ${Delta}$ deletion mutants (Fig. 2C). Southern blotanalysis confirmed that the ECA1 coding region was deleted,resulting in a null mutant (Fig. 2C). ECA1 expression was undetectablein the eca1 ${Delta}$ mutants, as shown by Northern blotting (Fig. 2D),as expected for deletion mutants. The ECA1 transcript was inducedafter treatment of wild-type cells at 37°C for 1 h, andits expression was similar to that of the wild type in anothertemperature-sensitive C. neoformans strain background (calcineurincna1 mutant). When two independent eca1 ${Delta}$ strains (eca1-11 andeca1-26) were cultured at the permissive growth temperature(30°C) or elevated temperatures (35°C and 37°C),both eca1 ${Delta}$ isolates displayed the same enhanced virulence inamoebae and temperature sensitivity as the original AI-5C9 insertionmutant (Fig. 1 and 2E). The eca1 ${Delta}$ mutants grew at a rate similarto that of the wild type at 30°C. At 35°C, the mutantsgrew more slowly than the wild type, while at 37°C theirgrowth was dramatically inhibited (Fig. 2E). An eca1 ${Delta}$ deletionmutant was crossed to the congenic strain KN99a, and 24 progenywere analyzed. The 8 nourseothricin resistance mutants wereall temperature sensitive, while the 16 nourseothricin-sensitivestrains grew like the wild type at 37°C, indicative of geneticlinkage between the eca1 mutation and the temperature-sensitivegrowth phenotype. A wild-type copy of ECA1 was reintroducedinto the eca1 ${Delta}$ strain, and it complemented the temperature-sensitivephenotype (data not shown). Together, these results confirmthat Eca1 regulates virulence in amoebae and is important forC. neoformans growth at high temperatures.

The eca1 ${Delta}$ mutant is hypersensitive to calcineurin inhibitors. Previous research on C. neoformans has identified a set of temperature-sensitivemutants affected in the Ca²⁺-calmodulin-calcineuin A and B pathway;thus, it seemed probable that Eca1 might govern calcineurinsignaling. The temperature-sensitive phenotype of eca1 mutantsis shared with cna1 or cnb1 calcineurin mutants. The eca1 phenotypemay result from either increased cytosolic Ca²⁺ causing overactivationof calcineurin or even reduced Ca²⁺ availability in responseto stresses if Ca²⁺ derived from the ER is used in signaling.However, eca1 mutants are also hypersensitive to calcineurininhibitors, indicating that any interaction with Eca1 and calcineurinis not within a simple linear pathway (Fig. 3A). At the semipermissivetemperature of 35°C, both CsA and FK506 inhibited the growthof eca1 ${Delta}$ mutants similarly. At 37°C, the growth of wild-typeand eca1 ${Delta}$ cells was completely inhibited by CsA (Fig. 3B) orFK506 (not shown), displaying the temperature-sensitive phenotypeassociated with impaired calcineurin signaling caused by thesedrugs. However, when the cells were returned to 30°C andallowed to grow for 2 days, eca1 ${Delta}$ mutant cells were not ableto recover, while both H99 and cna1 ${Delta}$ cells recovered and resumedgrowth. Interestingly, when eca1 ${Delta}$ mutant cells were treated at37°C for 2 days in the absence of CsA, they were able torecover after being shifted back to 30°C (Fig. 3B). Therefore,at 37°C, while CsA is fungistatic to H99, it becomes fungicidalto eca1 ${Delta}$ mutant cells. This indicates that eca1 mutant cellsare viable but fail to proliferate at 37°C, calcineurinis required for eca1 mutant cell viability, and Eca1 and calcineurinfunction at least in parallel pathways in C. neoformans.

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FIG. 3. Growth and viability of the eca1 mutants are reduced by calcineurin inhibitors. (A). Ten-fold serial dilutions of eca1-11, eca1-26, the insertion mutant AI-5C9, and wild-type (WT) cells were plated on YPD agar or YPD medium supplemented with CsA or FK506 and cultured at 30°C or 35°C for 2 days. (B). Wild-type, eca1, or cna1 cells were plated on YPD medium or YPD medium supplemented with CsA and cultured at 37°C for 2 days before being transferred to 30°C and cultured for 2 more days.

eca1 ${Delta}$ is hypersensitive to ER and osmotic stresses. Because SERCA pumps such as Eca1 are responsible for transportingCa²⁺ into the ER and Ca²⁺ ions are required for correct foldingof newly synthesized proteins and for protein secretion, wetested whether the eca1 mutant is sensitive to ER stress. Firstwe examined whether the eca1 ${Delta}$ mutation might affect toleranceto calcium stress. Indeed, elevated levels of calcium (100 mMor 250 mM) in YPD medium inhibited the growth of the eca1 ${Delta}$ mutantstrains at either 30°C or 35°C (Fig. 4A). On the otherhand, depletion of Ca²⁺ with 10 mM of the calcium chelator EGTAalso inhibited growth of the eca1 ${Delta}$ strain. Although either highconcentrations of Ca²⁺ or Ca²⁺ depletion inhibited the growthof the wild-type strain H99, the inhibition of eca1 ${Delta}$ mutant cellswas much more severe. This indicates that Eca1 is involved inCa²⁺ homeostasis and protection against Ca²⁺ stresses.

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FIG. 4. Deletion of ECA1 results in hypersensitivity to multiple stresses. (A) Ten-fold dilutions of wild-type (WT), eca1, or cna1 cells were plated on YPD medium or YPD medium supplemented with 100 mM or 250 mM CaCl₂, 10 mM EGTA, 0.1 µg/ml tunicamycin (Tm), or 1.5 M NaCl and cultured at 30°C or 35°C for 2 days. (B) Wild-type, eca1, or cna1 cells were cultured in RPMI medium (pH 7.0) containing 10-fold serial dilutions of fludioxonil and cultured at 30°C for 2 days. Growth was determined by measuring the optical density at 595 nm. The graph shows the percentage of growth relative to cells cultured in medium containing no fludioxonil.

We also tested ER stress by adding tunicamycin to the growthmedium to disrupt protein N glycosylation. Treatment with 100nM tunicamycin moderately inhibited the eca1 ${Delta}$ mutant at 30°Cand severely inhibited its growth at 35°C (Fig. 4A). Thishypersensitivity indicates that Eca1 is involved in toleranceto ER stress.

To test whether the temperature sensitivity of the eca1 mutantswas due to overactive CaMKs, the eca1 strain was treated withthe CaMK-specific inhibitor KN-93 and the noninhibitory analogKN-92 (68). YPD solid medium was inoculated with a lawn of cells,a 6-mm filter paper disk soaked in either analog (10 µlat 5 mM) or the dimethyl sulfoxide solvent was placed on thelawn, and the strains were grown at 30°C and 37°C. Treatmentwith the drug was unable to rescue the temperature sensitivityof the eca1 ${Delta}$ mutant strain (data not shown), suggesting thatthe temperature sensitivity is more likely due to ER stressrather than enhanced Ca²⁺-calmodulin-dependent kinase activity.However, one caveat in this experiment is the assumption thatthese molecules are efficiently taken up by C. neoformans asin other fungi.

Ca²⁺ is an important second messenger regulating numerous cellularfunctions, including osmotic stress tolerance. We examined whetherthe eca1 ${Delta}$ mutant has any defect in osmostress tolerance by treatmentwith a high concentration of NaCl. We found that at 30°C,the eca1 ${Delta}$ mutant is as sensitive to 1.5 M NaCl as the wild-typestrain, H99 (Fig. 4A). However, at 35°C, while the growthof H99 was also further inhibited by NaCl, the eca1 ${Delta}$ mutant showedan even higher level of sensitivity. We also treated the eca1 ${Delta}$ mutant with fludioxonil, an antifungal drug that causes osmoticstress by activating the Hog1 mitogen-activated protein kinaseand inducing the intracellular accumulation of glycerol (32,40, 54, 76). While more than 10 mg/ml fludioxonil is requiredto inhibit growth by 80% in the wild type, less than 1 mg/mlwas required to achieve 80% growth inhibition of the eca1 ${Delta}$ mutantat 30°C (Fig. 4B).

Mutation of calcineurin (cna1 ${Delta}$ ) aggravates the phenotypes conferred by eca1 ${Delta}$ mutation. To examine further the relationship between Eca1 and calcineurin,we constructed an eca1 ${Delta}$ cna1 ${Delta}$ double mutant strain by crossingthe nourseothricin-resistant eca1::NAT mutant in the H99 (MAT ${alpha}$ )background with the neomycin-resistant cna1::NEO strain in theKN99a background (MATa). The eca1 ${Delta}$ cna1 ${Delta}$ strain was tested fortemperature sensitivity, as well as sensitivity to ER stressesand hyperosmolarity. When cultured on YPD medium or YPD mediumcontaining 100 mM CaCl₂, 5 mM EGTA, 0.1 mM tunicamycin, or 1.5M NaCl, the double mutant displayed a more severe sensitivitythan the eca1 ${Delta}$ mutant alone. The eca1 ${Delta}$ cna1 ${Delta}$ mutant was also moresensitive to high temperature than the eca1 ${Delta}$ mutant (Fig. 5B),which is consistent with the increased sensitivity of a singleeca1 ${Delta}$ strain when treated with calcineurin inhibitors (see Fig.3). These findings provide further evidence that Eca1 functionsin parallel with calcineurin, and Eca1 may also function upstreamor with other Ca²⁺-dependent proteins or processes to controlcalcium activation by calmodulin.

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FIG. 5. Calcineurin mutation exacerbates eca1 mutant phenotypes. (A) Ten-fold serial dilutions of the wild-type (WT), eca1, cna1, and eca1 cna1 mutant cells were plated on YPD medium or YPD medium supplemented with EGTA (5 mM), tunicamycin (Tm; 0.1 µg/ml), CaCl₂ (250 mM), or NaCl (1.5 M) and cultured at 30°C for 2 days. (B). Ten-fold serial dilutions of the wild-type or eca1, cna1, and eca1 ${Delta}$ cna1 ${Delta}$ mutant cells were plated on YPD medium and cultured at 37°C for 2 or 4 days.

Temperature-dependent roles of Eca1 in C. neoformans virulence. Using the amoeba A. castellanii as described previously (65),the ECA1 gene was identified in C. neoformans in a screen formutants with altered virulence (Fig. 1), and the data presentedthus far show that the Eca1 Ca²⁺ pump is involved in stresstolerance. We further investigated a role for Eca1 in virulenceand its interaction with calcineurin. First we examined thevirulence phenotype of eca1 mutants in the murine macrophageinfection model. Cells of two independent eca1 ${Delta}$ mutant strains,the insertion mutant AI-5C9, and the wild-type strain H99 wereinoculated into macrophage J774A.1 cultured cells and incubatedat 37°C in the presence of 5% CO₂. Virulence was measuredby the growth of C. neoformans cells as defined by CFU at the24-h time point. As shown in Fig. 6A, growth of the eca1 mutantswas significantly lower than that of the wild type. This demonstratesthat the eca1 mutants exhibit reduced virulence in the murinemacrophage model. However, the reduced virulence of eca1 mutantsmay simply reflect their reduced proliferation or viabilityat elevated temperature, as indicated by the growth of the eca1mutants in DMEM at 37°C (Fig. 6A) and as observed in previousexperiments.

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FIG. 6. The Eca1 SERCA pump is required for virulence in a murine macrophage model. Cryptococcal yeast cells of the wild type (WT), the eca1 insertion mutant (AI-5C9), and two eca1 ${Delta}$ deletion mutants (eca1-11 and eca1-26) were inoculated into macrophage J774A.1 cultured cells at an MOI of 2:1 (left panel) or into macrophage-free medium (DMEM; right panel). The cryptococcal strains were inoculated at 1 x 10⁶ cells (gray bars), and after 24 h (white bars) of incubation, growth was measured by plating on YPD and counting CFU after culture at 30°C for 2 days. *, P < 0.05.

Because experiments with murine models of cryptococcosis areperformed at 37°C, to analyze the contribution of Eca1 toC. neoformans virulence, we took advantage of wax moth (G. mellonella)larvae (52), an alternative host model that can grow at temperaturesranging from 22 to 37°C, and the nematode C. elegans (growthat 25°C). For the wax moth larva infection model, 1 x 10⁵C. neoformans cells were injected into the wax moth larvae andthe larvae were incubated at 30°C or 37°C. The virulenceof each strain was measured by the death/survival of the larvaeinjected with it. At 30°C, 80 to 90% of the larvae infectedwith wild-type or eca1 mutant cells died by day 13, whereas70 to 90% of the larvae infected with the cna1 or eca1 cna1mutant cells survived (Fig. 7; P < 0.05, Mann-Whitney test),showing that while calcineurin does contribute to virulencein this model at 30°C, Eca1 does not. However, when incubatedat 37°C, the wild-type strain killed all moth larvae within6 days, whereas the eca1 strain showed reduced virulence, andthe cna1 or eca1 cna1 mutants exhibited an even greater attenuationin virulence compared to the wild type (P < 0.05, Mann-Whitneytest), in accord with the temperature-sensitive phenotype ofthe eca1, cna1, and eca1 cna1 mutant strains.

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FIG. 7. Temperature influences the role of C. neoformans Eca1 SERCA pump and calcineurin in virulence in the wax moth G. mellonella. Ten wax moth larvae were injected with 1 x 10⁵ cells of the wild-type or eca1 ${Delta}$ , cna1 ${Delta}$ , or eca1 ${Delta}$ cna1 ${Delta}$ strains and incubated at 30 or 37°C, and survival was monitored daily.

Three virulence assay endpoints were used to assess the roleof Eca1 and calcineurin in virulence in the model nematode C.elegans, to assess the role of temperature sensitivity in virulence,and to study whether the hypervirulent phenotype of eca1 mutantswas amoeba specific. The C. elegans-C. neoformans interactionexperiments were performed at 25°C. For the strains tested,no major differences were observed in the assay that reliedon the fungus’ ability to kill the nematode (data notshown). However, in a second assay measuring the generationof nematode progeny after being infected with C. neoformans,differences were observed (Fig. 8). This assay relies on morevirulent strains having a detrimental effect of nematode fertility,such that more progeny are produced from nematodes infectedwith attenuated strains compared to those infected with wild-typestrains. Inoculation with the eca1 ${Delta}$ cna1 ${Delta}$ double mutant strainresulted in higher numbers of progeny compared to the wild typeor the single cna1 ${Delta}$ mutant (P < 0.005, Mann-Whitney test)and also higher numbers of progeny from worms infected withthe eca1 mutant strain compared to the wild type (P < 0.05).Microscopic examination of the nematodes revealed that the C.neoformans yeast cells were present in the intestines of nematodeswhen exposed to the wild type or eca1 ${Delta}$ or cna1 ${Delta}$ mutants, but rarelyfor the eca1 ${Delta}$ cna1 ${Delta}$ double mutant (Fig. 8), although there wasdistension of the proximal intestine in this case, suggestingthat the eca1 ${Delta}$ cna1 ${Delta}$ strain survived passage through the nematodegrinder and was subsequently lysed in the intestine. CFU fromthe nematodes infected with these strains confirmed the microscopicobservations, with fewer CFU being produced from the nematodesfed the eca1 ${Delta}$ cna1 ${Delta}$ mutant compared to other strains (P < 0.05).The intestines of the nematodes infected with the eca1 ${Delta}$ mutantalso appeared to contain fewer C. neoformans cells, and infectionwith the eca1 ${Delta}$ mutant allowed more progeny to be produced thanwith the wild type. However, there was no statistically significantdifference between CFU emanating from the wild type and eca1mutants. Thus, analysis of virulence in the nematode C. elegansreveals that only the eca1 ${Delta}$ cna1 ${Delta}$ double mutant shows a dramaticdecrease in fungal viability within nematodes and the fertilityof the infected nematodes, while the eca1 or cna1 single mutantshave little or no effect compared to the wild type.

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FIG. 8. Eca1 SERCA pump and calcineurin additively contribute to virulence in the nematode C. elegans. Micrographs of nematode intestines containing C. neoformans yeast cells. The grinder is to the right in each image. Bar = 20 µM. Shown is the generation of C. elegans progeny after exposure to C. neoformans strains (white bars). CFU are the average yeast colonies (± standard error) from individual C. elegans worms fed C. neoformans, with worms harvested from three plates (gray bars). The eca1 single and eca1 cna1 double mutants show statistically significant differences from the wild type. *, P < 0.05.

Taken together, the virulence phenotypes from multiple modelsat different temperatures suggest that both Eca1 and Cna1 contributeto virulence by supporting growth at mammalian body temperature;however, mutation of both genes has an additive effect and reducesvirulence at room temperature.

DISCUSSION

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DISCUSSION

Pathogenic fungi that normally exist outside the human hostface challenges in transitioning from one environmental nicheto another, particularly from the environment into the humanhost. Many rely on the ability to sense these changes via conservedsignaling cascades to adapt successfully to new conditions.One such signaling pathway is that mediated by Ca²⁺-calmodulin-calcineurin.Calcium signaling is important for C. neoformans and other human-pathogenicfungi to cope with stress and for their virulence (41).

In this study, we identified a new gene, ECA1, involved in Ca²⁺homeostasis in C. neoformans. The gene is part of a conservedfamily of SERCAs that regulate Ca²⁺ levels in the ER lumen inmany eukaryotes. In C. neoformans, this gene regulates resistanceto various stresses and growth at 37°C and functions inparallel with and upstream of the calcineurin pathway. The closesthomolog is the ECA1 gene of the related basidiomycete plant-pathogenicfungus U. maydis, in which the ECA1 gene was identified by analysisof a temperature-sensitive mutant (1). The growth phenotypesof the U. maydis and C. neoformans eca1 mutants are very similar.One exception is that in U. maydis the altered cell morphologyis clearly attributable to overactive CaMKs (1). However, inC. neoformans eca1 mutants there is no defect in cellular morphologyand a CaMK inhibitor did not rescue the temperature sensitivityof eca1. Rather, we hypothesize that many of the C. neoformanseca1 phenotypes are due to impaired ER function resulting inmisregulation of protein processing, suggesting a divergencein function between these two basidiomycetes. We performed apilot microarray study to elucidate the effects of eca1 deletionon gene transcription in C. neoformans (W. Fan, K. Kojima, andJ. Heitman, unpublished data). While we were able to confirmthe temperature regulation of transcription by subsequent Northernblot experiments for genes encoding proteins such as opsin,the cruciform DNA binding protein Hmp1, an oxidoreductase (GenBankaccession no. CNC03730), ribosomal protein L35, and an Ero1-likeprotein (data not shown), no Eca1-dependent transcriptionalresponse was identified, suggesting that other microarray experimentsor approaches will be required to elucidate Eca1 functions.

We initially hypothesized that the temperature-sensitive phenotypeof eca1 ${Delta}$ cells could be related to a role upstream in calmodulin-calcineurinsignaling. Mutation of ECA1 should impair Ca²⁺ import into theER, increasing cytosolic Ca²⁺ levels and overactivating calcineurin.However, the eca1 cna1 double mutant is more severely impairedthan either eca1 or cna1 single mutants for a number of phenotypes,including temperature sensitivity and virulence, suggestingthat Eca1 functions in parallel with calcineurin. We considerit likely that Eca1 also plays a role upstream of calcineurinby regulating cytosolic Ca²⁺ levels. Calcineurin is requiredfor virulence in all human-pathogenic fungi in which it hasbeen studied, but its roles in virulence differ between species.In C. albicans, calcineurin mutants grow like the wild typeat 37°C but are killed by calcium in serum (4, 8, 9, 61).In A. fumigatus, calcineurin mutants exhibit severe morphologicaldefects (22, 66). In C. neoformans, calcineurin mutants cannotgrow at 37°C (29, 55). Here we show that C. neoformans calcineurinmutants exhibit wild-type virulence at room temperature in C.elegans but reduced virulence in the wax moth at 30°C (atemperature at which there are no growth defects in vitro).Thus, based on the results in the wax moth, the virulence defectin mammalian models may not be attributed solely to temperaturesensitivity in C. neoformans. This study highlights the useof nonmammalian models in understanding the genetic mechanismsgoverning virulence, especially when one phenotype of mutatinga gene is temperature sensitivity. We note that because thecna1 mutant was fully virulent in C. elegans, but not in thewax moth, this indicates that virulence determinants can differbetween model heterologous hosts, providing unique vantage pointsfrom which to dissect branched signaling pathways controllingvirulence.

Many of the phenotypes of eca1 mutants are similar to thosecaused by calcineurin mutation, suggesting that conditions leadingto both loss and gain of calcineurin activity might similarlyperturb cellular physiology. Another component of calcium homeostasisthat has been recently identified is the Cch1 voltage-gatedCa²⁺ channel that is required for calcium uptake in C. neoformansand predicted to be in the plasma membrane (44). Strains withcch1 mutations show sensitivity to calcium chelation, like eca1mutants, but no temperature sensitivity. Thus, in the absenceof Cch1 other mechanisms must exist to provide sufficient Ca²⁺to activate calcineurin. Similarly, other components of calcium-calcineurinsignaling show variation in phenotype when mutated, such asmutants of the calcineurin binding protein (CBP1), which exhibitwild-type growth at high temperature but a mating defect likecalcineurin mutants (30), or a calmodulin mutant that has similartemperature sensitivity and mating defects to calcineurin mutationbut is also hypersensitive to the calcineurin inhibitor FK506(42). Taken together, these and other results suggest that variationexists between the phenotypes caused by perturbations to calciumhomeostasis in C. neoformans and other fungi.

While SERCAs are crucial for maintaining Ca²⁺ homeostasis inmany eukaryotes, including animals, plants, protists, and fungilike C. neoformans and U. maydis, organisms can function withoutthis class of Ca²⁺ pump. For example, the model eukaryote S.cerevisiae and related hemiascomycete yeasts do not containa SERCA protein, so intracellular calcium concentrations inthese fungi are regulated by other Ca²⁺ transporters. One isPmc1, which is localized to the vacuolar membrane, and the keyrole in S. cerevisiae of the vacuole, where most Ca²⁺ is stored,in maintaining Ca²⁺ levels has recently been demonstrated byscreening the yeast deletion collection for strains that accumulate(or do not accumulate) ions; the majority of strains affectedin Ca²⁺ levels were mutants that impair vacuole function (24).A second transporter, Pmr1, is localized to the Golgi apparatus,thereby controlling Ca²⁺ within these post-ER vesicles and alsoaffecting Ca²⁺ levels within the ER itself (10). S. cerevisiaedoes contain a P-type ATPase (Cod1/Spf1) localized to the ERto regulate calcium levels (19, 69), but, to the best of ourknowledge, there is no evidence that mutants of this gene exhibitinteractions with the calcineurin pathway. Mutation of any ofthese transporters affects calcium homeostasis and reduces viabilityof S. cerevisiae under stress conditions. Despite differentcalcium transporter compositions, in both C. neoformans andS. cerevisiae (and the related hemiascomycete pathogens C. albicansand Candida glabrata) impairment of both calcineurin and ERfunctions leads to additive deleterious effects in these fungi(10), showing a commonality in overall cellular functions.

One hypothesis as to how C. neoformans maintains its abilityto infect the human host is that it is under constant selectionin the environment by predators, such as amoebae, nematodes,and insects (63). Passage of the fungus through the slime moldDictyostelium discoideum enhanced virulence in a murine modelof disease (64). Several genes required for virulence in themammalian host are also required for virulence in heterologoushosts (31, 50). Furthermore, two recent screens for strainswith attenuated virulence in C. elegans identified the KIN1and ROM2 genes, which were subsequently shown to be requiredfor virulence in murine models of cryptococcosis (51, 71). Theoriginal AI-5C9 eca1 mutant strain was identified as hypervirulentin a screen for strains with altered virulence in an amoebamodel of the disease. Subsequent studies show that the magnitudeof virulence depends on the temperature of the experiment, asthe eca1 mutant has a growth and virulence defect at elevatedtemperatures but retains wild-type or enhanced virulence atroom temperature. While mutation of ECA1 would produce a C.neoformans strain that is better adapted to survive predationby certain environmental hosts like Acanthamoeba castellaniiand still be virulent in nematodes and wax moth, it would notsurvive in the mammalian host or under other stressful conditions.Thus, selection for virulence in this amoeba species by an eca1mutation would decrease mammalian virulence. A reverse situationexists for the carbonic anhydrase Can2, whose deletion yieldsa strain that proliferates better than the wild type in a rabbitintracranial model of infection yet is unable to grow outsidethe animal host in the low CO₂ concentrations present in theatmosphere (6). Thus, mutations towards enhanced virulence mustbe balanced with other selective pressures acting on C. neoformans.

The proposal of Steenbergen et al. (65) for a role for environmentalpredators as enhancing C. neoformans virulence has stimulatedconsiderable debate (see e.g., reference 43). While the differencesin virulence for eca1 and cna1 mutants in diverse host systemscould be interpreted as a consequence of these being nonnaturalhosts, we argue in favor of alternative systems as virulencemodels for this fungus. As noted previously, the C. neoformansinteraction with amoeba has been observed in nature (13, 16)and the fungus lives in soil, guano, and other debris coinhabitedby other microbial predators, such as nematodes and insects.The Cryptococcus genus clusters with other basidiomycetes thatare insect pathogens or insect associated (62). C. neoformanshas been isolated from the intestines of beetles (7, 67). Thewax moth is a common problem for beekeepers, and C. neoformanshas been isolated from beehives in Turkey (25). Thus, C. neoformanscould associate with these species in nature. Further supportfor studies with alternative hosts derives from analysis ofLegionnaires’ disease, in which it is well establishedthat infectious Legionella pneumophila bacteria are maintainedwithin amoebae in water sources (28, 60). Importantly, laboratory-isolatedmutants of L. pneumophila exhibit reduced virulence in bothamoebae and macrophages, in macrophages but not amoebae, orin amoebae but not macrophages (e.g., references 11 and 33 andreviewed in reference 70), representing a similar situationto that observed with C. neoformans eca1 mutants. The differencesin virulence of the eca1 and cna1 mutants in each model systemmay reflect underlying differences in host conditions (e.g.,Ca²⁺ concentrations) in each model. This is analogous to recentdiscoveries showing differing virulence properties of C. albicanscalcineurin mutants depending on host tissue, in that calcineurinis required for systemic but not vaginal infection (5, 56).These studies demonstrate the potential complexity in the host-pathogen-environmentinteractions that represent challenges for future research tounderstand and control infectious disease.

ACKNOWLEDGMENTS

We thank Charles Hall for help with phylogenetic analysis, ArturoCasadevall for the 18B7 antibody, and Alejandro Aballay forsuggesting improvements to the manuscript.

The research was supported by NIAID T32 grant AI52080 to A.I.,NIAID K08 grant AI63084 and an Ellison Medical Foundation NewScholar Award to E.M., and NIAID R01 grants AI042159 and AI063443to J.H.

FOOTNOTES

* Corresponding author. Mailing address: Room 322 CARL Building, Box 3546, Department of Molecular Genetics and Microbiology, Duke University Medical Center, Durham, NC 27710. Phone: (919) 684-2824. Fax: (919) 684-5458. E-mail: heitm001{at}duke.edu

Published ahead of print on 14 May 2007.

Editor: A. Casadevall

W.F. and A.I. contributed equally to this study.

Present address: BASF Plant Science, 26 Davis Drive, ResearchTriangle Park, NC 27709.

REFERENCES

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