Sexual Development in Cryptococcus neoformans Requires CLP1, a Target of the Homeodomain Transcription Factors Sxi1{alpha} and Sxi2a

Sexual development in the human fungal pathogen Cryptococcusneoformans is a multistep process that results in the formationof spores, the likely infectious particles. A critical stepin this developmental process is the transition from bud-formgrowth to filamentous growth. This transition is controlledby the homeodomain transcription factors Sxi1 ${alpha}$ and Sxi2a, whosetargets are largely unknown. Here we describe the discoveryof a gene, CLP1, that is regulated by Sxi1 ${alpha}$ and Sxi2a and isessential for sexual development. In vitro binding studies alsoshow that the CLP1 promoter is bound directly by Sxi1 ${alpha}$ and Sxi2a.The deletion of CLP1 leads to a block in sexual developmentafter cell fusion but before filament formation, and cells withoutCLP1 are unable to grow vegetatively after cell fusion. Ourfindings lead to a model in which CLP1 is a downstream targetof the Sxi proteins that functions to promote growth after matingand to establish the filamentous state, a critical step in theproduction of spores.

INTRODUCTION

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INTRODUCTION

Cryptococcus neoformans is an environmental fungus that hasthe capacity to infect and cause disease in mammalian hosts(6). Immunocompromised individuals, such as people with AIDS,chemotherapy patients, and those undergoing immunosuppressivetherapies, are most at risk of developing cryptococcal meningitis.Infection appears to occur through a respiratory route in whichC. neoformans particles are inhaled and lodge in the lung alveoli.The likely infectious particle in C. neoformans infections isthe spore. One mechanism by which spores can be produced issexual development (1, 13). During this process, cells of oppositemating types (a and ${alpha}$ ) sense one another, fuse cytoplasms (butnot nuclei), and form filaments. Each filament cell containstwo nuclei of opposite mating types that remain distinct untilthe terminal filament cell forms a specialized structure calleda basidium. In the basidium, nuclear fusion and meiosis takeplace, and their products are repeatedly replicated, packaged,and expressed as buds on the surface of the basidium in fourlong chains of spores (18). The formation of filaments is acritical step in the spore formation process; dikaryotic filamentsare largely aerial, and moving spores off solid substrates islikely critical for dispersal (1). Dikaryons are common amongbasidiomycete fungi, the phylum to which C. neoformans belongs(7). This phylogenetic group includes the corn smut, Ustilagomaydis, as well as most mushrooms, including the ink cap mushroom,Coprinopsis cinerea (5, 17). Fungi in this group have very differentlife cycles, but those that have been studied in detail allinclude a phase in which filament cells grow with distinct nucleiprior to developing fruiting bodies and spores. This criticalphase allows host cell penetration in the case of U. maydisand the ability to forage for nutrients in C. cinerea (5, 17).By and large, however, the genes required for this stage ofdevelopment are not known. What is known is that the dikaryotictransition is controlled by homeodomain transcription factors(15). In U. maydis, the proteins bE and bW must interact withone another to initiate dikaryon formation (24). Similar proteins,HD1 and HD2, control the process in C. cinerea, and the Sxi1 ${alpha}$ and Sxi2a proteins are required in C. neoformans (11, 16).

Efforts to determine potential targets of Sxi1 ${alpha}$ and Sxi2a resultedin the identification of a gene with similarity to the clamplessgene of C. cinerea. With C. cinerea, Inada et al. carried outa screen for dikaryons that could not form clamp cells, specializedcells required for proper nuclear migration (14). They identifieda mutant in which clamp cells were not formed and named it theclampless-1 mutant. Cloning and sequencing of the clamplessgene revealed a predicted protein with no identifiable structuralfeatures and a predicted promoter region with putative homeodomainbinding sites conforming to the sequence GATGN_xACA, suggestingdirect regulation by HD1 and HD2. A CLP1 gene was also identifiedin U. maydis and is required for clamp cell formation as wellas sexual development (23).

Based on sequence similarity to the Clp1 proteins from U. maydisand C. cinerea, we identified a putative Clp1 protein in C.neoformans and investigated its potential role in C. neoformanssexual development. We found that the CLP1 homolog in C. neoformansis essential for the formation of dikaryotic filaments duringsexual development, functions after cells of opposite matingtypes fuse, and is regulated by Sxi1 ${alpha}$ and Sxi2a. Along with otherdata presented here, these findings lead to a model of sexualdevelopment in which CLP1 is required for cells to initiategrowth after cell fusion.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Strain manipulations and media. All strains used were of the serotype D background, and theirgenotypes are given in Table 1. All were handled using standardtechniques and media as described previously (2, 25). Sexualdevelopment assays were conducted on V8 medium at room temperaturein the dark for 2 to 4 days. Sexual development was evaluatedby observing the periphery of test spots on V8 medium. The matingtester strains used were JEC20 (a) and JEC21 ( ${alpha}$ ) (19). For confrontationassays, strains were streaked on yeast extract-peptone-dextrose(YPD) agar and incubated for 2 days and then streaked near oneanother on low-nitrogen agar and incubated at room temperaturein the dark for 4 days before they were photographed. Fusionassays were carried out by resuspending cells at 1 x 10⁸ cells/mland mixing equal numbers of mating partners. Ten microlitersof each mix was spotted onto a V8 agar plate, and plates wereincubated at room temperature in the dark. After 24 h, the cellswere scraped off the V8 plates, resuspended in 100 µlwater, and spread on minimal medium (SD) containing 200 µg/mlG418. Plates were incubated at 30°C for 5 days, and theresulting colonies were counted.

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TABLE 1. Strains used in this study

Constructing clp1 deletion strains. clp1 ${Delta}$ constructs contained either a URA5, neomycin resistance(Neo^r), or nourseothricin (Nat^r) cassette flanked by $~$ 1 kb ofsequence from upstream and downstream of the CLP1 open readingframe (ORF). The CLP1 5'-flanking region was amplified withprimers CHO624 (5'-GACGGTACCGGATCCAATAAGCATGGCAACTGTG-3') andCHO625 (5'-GACACTAGTGGCGAATGGATGGAAGGATG-3'), and the 3'-flankingregion was amplified with CHO626 (5'-GACGCGGCCGCATAGAAAAGTCATTACTCATC-3')and CHO627 (5'-GACCTCGAGGGATCCCTCTCCTTGGCGAGGGCAAG-3'). PCRfragments were cloned into pCR2.1, using a TOPO TA cloning kit(Invitrogen). One CLP1 disruption construct (clp1::URA5) wasmade by cloning the 5' flank and the 3' flank into a plasmidcontaining a URA5 cassette to create pCH317. The second disruptionconstruct (clp1::Neo^r) was made by replacing the URA5 cassetteof pCH317 with the Neo^r cassette from pJF1 (pCH361) to makepCH318. A third deletion cassette (clp1::Nat^r) was made by replacingthe URA5 cassette of pCH317 with the Nat^r cassette from pCH233(Nat^r cassette in pCR2.1) to make pCH574. The clp1::URA5 andclp1::Neo^r deletion cassettes were transformed into serotypeD ura5 strains JEC34 (a) and JEC43 ( ${alpha}$ ) by biolistic transformation,grown on medium containing 1 M sorbitol, and selected on mediumeither lacking uracil or containing 200 µg/ml G418 (28).The clp1::Nat^r cassette was transformed into serotype D strainJEC21 ( ${alpha}$ ) and selected on medium containing 200 µg/ml nourseothricin.Transformants were screened by PCR for the proper integrationof the deletion construct, and positive clones were confirmedby Southern blot analysis (4). The resulting independent clp1::URA5strains were designated CHY1069 (a) and CHY1072 ( ${alpha}$ ), the clp1::Neo^rura5 strains were designated CHY1179 (a) and CHY1177 ( ${alpha}$ ), andthe clp1::Nat^r strain was designated CHY1421 ( ${alpha}$ ).

Construction of CLP1-reconstituted strains. A construct for reconstitution of clp1 deletion strains withCLP1 was constructed by cloning a fragment containing the entireORF with $~$ 1-kb flanking sequences into a pCnTEL-URA derivative(pCH390), using BamHI, to create pCH454. The complementationfragment was liberated and transformed into CHY1177 ( ${alpha}$ clp1::Neo^rura5). Transformed cells were selected on SD plates containing1 M sorbitol and crossed with CHY1069 (a clp1::URA5) to assayfor recovery of sexual development. Positive isolates were confirmedvia Southern blotting.

Protein expression and purification. A fragment corresponding to the homeodomain of Sxi2a cDNA wascloned into the BamHI site of the pRSET-A expression vector(with a six-histidine tag) to create pCH292. Protein expressionwas carried out in Escherichia coli BL21(DE3)/pLysS cells, whichwere induced in Zymo Research EB/OB medium according to themanufacturer's instructions. Proteins were purified by resuspendinginduced cells in histidine binding buffer (500 mM NaCl, 20 mMTris, pH 8.0, 5 mM imidazole, 50 mM phenylalanine, 50 mM isoleucine)containing a protease inhibitor cocktail and Igepal detergent(0.01%), sonicating them, and centrifuging them at 4°C for30 min at 14,000 rpm. The supernatant was equilibrated withQiagen nickel resin with gentle agitation and applied to a gravity-flowcolumn at room temperature. The resin was washed with histidinebinding buffer, and proteins were eluted with histidine elutionbuffer (500 mM NaCl, 20 mM Tris, pH 8.0, 0.5 M imidazole, 50mM phenylalanine, 50 mM isoleucine). The eluate was concentratedusing a Microcon microconcentrator according to the manufacturer'sinstructions.

EMSA. To generate radiolabeled probes for electrophoretic mobilityshift assays (EMSAs), PCRs with mixtures containing [ ${alpha}$ -³²P]dCTPwere performed. To generate probes, a plasmid containing 1 kbof genomic DNA upstream of the CLP1 ORF (pCH320) was used asthe template in combination with the following primers: forprobe A, CHO628 (5'-CGGAATTATGCATTCCTGCTTGCCCGACGGC-3') andCHO629 (5'-CGGAATTGCTGGAGTTGACGAGCAAATGAAG-3'); for probe B,CHO572 (5'-CGGAATTCGCATTGACGGATGAGTGG-3') and CHO605 (5'-AATAAAAGTGTCTGTAAGTGAAGGC-3');and for probe C, CHO573 (5'-CGGAATTCGGCGAATGGATGGAAGGATG-3')and CHO604 (5'-CACGACGCAAGGACCTTGCACGCCGCCT-3'). The PCR-generatedprobes were purified in a nondenaturing polyacrylamide gel.The resulting probes were used in binding reactions in a buffercontaining 100 mM NaCl, 0.5 mM EDTA, 60 mM Tris-Cl, pH 7.9,5 mM MgCl₂, 5 mg/ml bovine serum albumin, 50 µg/ml poly(dI-dC),and 10% glycerol. Probes and the purified Sxi2a homeodomainwere incubated at 4°C for 30 min. Reaction mixtures wereelectrophoresed in a 5% nondenaturing polyacrylamide gel (200V for 3.5 hours) at 4°C. Gels were dried and exposed toKodak film to visualize shifts.

Northern blot analysis. RNAs were prepared from C. neoformans cells by using a hot phenolmethod (4). Strains were grown on solid V8 medium for 24 h atroom temperature before they were harvested by scraping offthe agar surface. Northern blots were carried out accordingto standard protocols, with 10 µg of total RNA used foreach sample (4). The glycerol-3-phosphate dehydrogenase gene(GPD1) probe was generated by PCR, using CHO651 (5'-CGTCGTTGAATCTACCGGTG-3')and CHO652 (5'-CACCAGCAATGTAAGAGATG-3'), and radiolabeled probes(Decaprime II kit; Ambion) were used in hybridization reactionsat 65°C as described previously (9). A CLP1 riboprobe templatewas made by amplifying a 450-bp fragment from genomic DNA, usingCHO834 (5'-AGTCATCTAGAATGGCTACTTACCTTGCTCCTCCGGTCTC-3') andCHO835 (5'-TGACAGGCATGCTTCAATTGAAGGGAACCTAGGATAAGGC-3'); digestingthe resulting product; and cloning it into pDP18 (Ambion). Radiolabeledriboprobe was generated using ${alpha}$ -³²P-labeled UTP and T7 polymerase,using a Maxiscript SP6/T7 kit (Ambion) according to the manufacturer'sprotocol. Hybridizations and washes were carried out accordingto the manufacturer's instructions.

Sequence manipulations. Sequence comparisons were conducted against the C. neoformansgenome sequence (C. neoformans Genome Project; Stanford GenomeTechnology Center and The Institute for Genomic Research) byusing the BLAST algorithm (3). The C. neoformans CLP1 sequencecan be accessed in GenBank under accession number BK006302.

Microscopy and staining. Light microscopy was carried out on a Zeiss Axioplan microscopefitted with a 20x long-working-distance objective. Photographswere taken with a Nikon Coolpix 5400 camera mounted on the microscope.Fluorescence microscopy was carried out with a Zeiss Axioskop2 fluorescence microscope fitted with an Axiocam MRM REV3 digitalcamera and corresponding AV4 software. For staining of fusionevents and filaments, cells from crosses were plated on a thinlayer of V8 medium on a microscope slide and incubated at roomtemperature for 24 h. Cells were fixed in 10% formaldehyde-1xphosphate-buffered saline (PBS) for 20 min, washed three timeswith PBS, permeabilized with 1% Triton X-100-1x PBS for 10 min,and washed three times with PBS. To visualize septa and nuclei,cells were incubated in 1x PBS containing 0.4 µg/ml calcofluorwhite and 1 nM Sytox green for 20 min, washed three times withPBS, and mounted on slides in 50% glycerol.

5' and 3' RACE. Rapid amplification of cDNA ends (RACE) was performed on RNAsisolated from crosses between wild-type strains JEC20 and JEC21and sxi ${Delta}$ deletion strains CHY610 (sxi1 ${alpha}$ ${Delta}$ ) and CHY768 (sxi2a ${Delta}$ ). Both5' and 3' RACE were performed using a First Choice RLM RACEkit from Ambion according to the manufacturer's instructions.The gene-specific primers for 5' RACE were CHO922 (5'-ATATCGCTGAGGGCGATGTTAGGT-3'[outer primer]) and CHO923 (5'-ACTGGATCCTAGAAGAGACCGGAGGAGCAAGGTAA-3'[inner primer]). Gene-specific primers for 3' RACE were CHO975(5'-CAGAGGTCGAGTTCATTGACC-3' [outer primer]) and CHO976 (5'-CGAGACCTGTCAAGGACGAC-3'[inner primer]). PCR fragments of the predicted sizes were TOPOcloned into pCR2.1 (Invitrogen) and sequenced. Resulting sequenceswere compared with the genomic CLP1 sequence.

Construction of clp1/clp1 diploids. Diploids were created by mixing differentially marked strains,spotting them on V8 medium for 24 h, plating them on selectivemedium, and incubating them at 37°C for several days. Diploidswith both copies of CLP1 deleted were made by crossing CHY1422(clp1 ${Delta}$ ), which contains pCH454 (pCLP1), with CHY1421 (clp1 ${Delta}$ ).Diploids were selected on YPD containing 100 µg/ml G418and 100 µg/ml nourseothricin. Colonies that grew wereconfirmed as diploids by PCR for SXI1 ${alpha}$ , using primers CHO408(5'-CGAAGGGCAAAGTCGAAAACG-3') and CHO409 (5'-CCGAAATAATGGGAACTCC-3'),and for SXI2a, using CHO500 (5'-ATGGGCAGCAACCTTGACATC-3') andCHO534 (5'-TGTTTTCTTGCCTCGATTCCT-3'). Strains were assayed forloss of the pCLP1 plasmid by PCR for CLP1, using primers CHO662(5'-GCCAAAGCACGAGGACG-3') and CHO663 (5'-CCAGAGATGGCATCAAG-3').

RESULTS

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RESULTS

Clp1 is required for sexual development. Based on the sequences of the Coprinopsis cinerea and Ustilagomaydis Clp1 proteins (14, 23), we identified a putative Clp1homolog in C. neoformans. Although the overall sequence similarityis low ( $~$ 23% over 472 amino acids), there is a carboxy-terminalregion of $~$ 60 residues with sequence similarity of $~$ 35%, suggestinga significant relationship between the protein sequences. Inan analysis of the U. maydis Clp1 protein, Scherer et al. identifiedthe same potential homolog from C. neoformans and also designatedit Clp1 (23). The Clp1 proteins do not have any identifiabledomains or features, and no proteins with similarity to Clp1can be identified outside the basidiomycete fungi. Similaritiesto the other basidiomycete proteins prompted us to investigatethe role that a Clp1 protein might play in C. neoformans.

We began by deleting the predicted ORF for CLP1 from both matingtypes (a and ${alpha}$ ), complementing each deletion strain with a wild-typecopy of the gene, and assaying all strains for phenotypes underan array of conditions. Multiple, independent clp1 deletionstrains exhibited no discernible phenotypes with respect tohaploid growth under any of the conditions tested (data notshown); however, they did have profound defects in sexual development.When strains containing deletions of CLP1 in both a and ${alpha}$ cellswere crossed with one another under conditions favorable forsexual development (e.g., growth on V8 juice agar), there wasa complete absence of proper sexual development (Fig. 1A), thatis, the strains failed to form dikaryotic filaments, basidia,or spores. However, in unilateral crosses (wild-type a x ${alpha}$ clp1 ${Delta}$ cells or a clp1 ${Delta}$ x wild-type ${alpha}$ cells), sexual development wasindistinguishable from that of the wild type, suggesting thata single copy of CLP1 is sufficient to drive sexual development(Fig. 1B). We confirmed that deletion of the CLP1 gene was responsiblefor the defect in sexual development by transforming the clp1 ${Delta}$ strains with a wild-type copy of the CLP1 gene and carryingout complementation tests. Four independent transformants confirmedto have a single, randomly integrated copy of CLP1 by Southernblotting ( ${alpha}$ clp1 ${Delta}$ mutant plus CLP1) were crossed with clp1 deletionstrains (a clp1 ${Delta}$ ). Full sexual development was completely restoredand was indistinguishable from wild-type sexual developmentin all cases. A representative transformant is shown in (Fig.1A). The complementing gene restored sexual development to wild-typelevels, consistent with a single copy of CLP1 being sufficientfor sexual development.

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FIG. 1. CLP1 is required for sexual development. (A) clp1 deletion and reconstitution phenotypes. (Left) Sexual development of a cross between wild-type a and ${alpha}$ strains (JEC20 x JEC21). (Middle) Cross between two representative a clp1 ${Delta}$ and ${alpha}$ clp1 ${Delta}$ strains (CHY1069 x CHY1072). (Right) Cross between an a clp1 ${Delta}$ strain and a representative ${alpha}$ clp1 ${Delta}$ strain containing an ectopically integrated copy of the CLP1 gene under the control of its own promoter (CHY1069 x CHY1187). (B) Phenotypes of unilateral clp1 ${Delta}$ crosses. (Left) Cross between a wild-type a strain and an ${alpha}$ clp1 ${Delta}$ strain (JEC20 x CHY1072). (Right) Cross between an a clp1 ${Delta}$ strain and a wild-type ${alpha}$ strain (CHY1179 x JEC21). All assays were carried out on V8 juice agar at room temperature in the dark and photographed after 48 h.

clp1 ${Delta}$ strains are defective in dikaryotic filament formation. To understand where the defect in sexual development occurred,we carried out assays to evaluate each stage of sexual developmentup to the point at which a defect was observed (i.e., mate recognition,cell fusion, and dikaryotic filament formation). To evaluatethe capacity of the clp1 ${Delta}$ strains to detect a mating partner,we carried out confrontation assays in which wild-type and clp1 ${Delta}$ strains were placed near each other on solid medium and evaluatedfor the ability to either swell (a cells) or produce germ tubes( ${alpha}$ cells) in response to an opposite mating partner. All combinationsof wild-type and clp1 ${Delta}$ strains were tested against one another,and there were no detectable defects or changes in the abilityof the clp1 ${Delta}$ strains to respond to or elicit a response froma mating partner (data not shown). This result suggested thatclp1 ${Delta}$ strains both make and respond to mating pheromone at levelssimilar to those of wild-type strains. To assess potential defectsin the next step of sexual development, we evaluated the capacityof the clp1 ${Delta}$ strains to fuse with a mating partner by carryingout fusion assays. Differentially marked wild-type and clp1 ${Delta}$ strains (Ura^– Neo^r x Ura⁺ Neo^s) were mixed under sexualdevelopment conditions (V8) for 24 h and then plated on selectivemedium (minimal medium containing neomycin). Only strains thatfused with a mating partner would have the ability to form coloniesunder selection. We observed that clp1 ${Delta}$ strains did not havethe ability to form colonies in fusion assays, suggesting adefect in cell fusion (Table 2). However, this result was difficultto reconcile with the fact that unilateral crosses (wild typex clp1 ${Delta}$ mutant) were indistinguishable from wild-type crosses,suggesting that CLP1 functions after cell fusion. Upon carefulmicroscopic observation, we found that a clp1 ${Delta}$ x ${alpha}$ clp1 ${Delta}$ crosseshad a phenotype different from that of strains that simply cannotfuse with one another. As shown in Fig. 2A, wild-type a x wild-type ${alpha}$ and a clp1 ${Delta}$ x ${alpha}$ clp1 ${Delta}$ crosses resulted in elongated, dumbbell-shapedcells that contained two nuclei at early time points. Theseapparent fusion products have been observed by others and appearto be the result of fusion between cells of opposite matingtypes (20). These binucleate cells did not form in control crossesbetween cells of the same mating type, either wild type or clp1 ${Delta}$ mutant (data not shown). At later time points, the differencebetween wild-type and clp1 ${Delta}$ strains became apparent. After 17h under sexual development conditions, wild-type cells fused,and the fusion products had begun to form the next developmentalstage, dikaryotic filaments. As shown in Fig. 2B, wild-typecells formed long filaments with two nuclei and characteristicclamp cells. These filaments continued to grow and completesexual development. In contrast, the clp1 ${Delta}$ strains elongatedsomewhat but did not form dikaryotic filaments. The fusion productsarrested as elongated dumbbells and did not continue to growor divide, suggesting that cell fusion can occur but that outgrowthcannot.

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TABLE 2. Fusion assay results^a

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FIG. 2. CLP1 is required for growth after cell fusion. (A) Wild-type and clp1 ${Delta}$ strains show similar phenotypes early in sexual development. All panels show representative fields of fusion products from crosses after 10 h on V8 juice medium. The top two panels show wild-type a x ${alpha}$ strains; the bottom two panels show a clp1 ${Delta}$ x ${alpha}$ clp1 ${Delta}$ strains. (B) clp1 ${Delta}$ strains do not progress after cell fusion. All panels show representative fields of cells from crosses after 17 h on V8 juice medium. The top two panels show wild-type a x ${alpha}$ strains forming dikaryotic filaments; white arrows indicate dikaryotic nuclei in filament cells. The bottom three panels show a clp1 ${Delta}$ x ${alpha}$ clp1 ${Delta}$ strains as stalled fusion products; there are no dikaryons visible. The cells in all panels were stained with calcofluor white to visualize the cell walls and Sytox green to visualize the nuclei.

Because clp1 mutants appeared to be able to fuse but not toundergo sexual development, we tested whether they could formdiploids. Diploid strains of C. neoformans var. neoformans canbe outgrown in the laboratory by crossing marked strains andselecting fusion products at 37°C (13). These mononucleate,budding yeast cells can be maintained at 37°C and inducedto undergo sexual development at 25°C (26). To test fordiploid formation, wild-type and clp1 ${Delta}$ strains with differentselectable markers were crossed for 24 h on V8 medium and grownunder selection at 37°C. Colonies were recovered efficientlyfrom crosses between wild-type strains, but no colonies wereformed from crosses of clp1 ${Delta}$ strains (Fig. 3A). This inabilityto form diploids suggests that the clp1 ${Delta}$ phenotype is not dueto a defect in the ability to form filaments but rather representsan inability to grow after cell fusion. To test this hypothesis,we carried out a selection for diploids with CLP1 carried ona plasmid in one of the strains. In this cross, diploids wererecovered, but only when the strains contained CLP1 (data notshown). Strains harboring plasmids without CLP1 were unableto form diploids. These clp1 ${Delta}$ /clp1 ${Delta}$ (pCLP1) diploids were outgrownto induce plasmid loss, and their genotypes were confirmed byPCR (Fig. 3B). The resulting clp1 ${Delta}$ /clp1 ${Delta}$ diploids grew like wild-typediploids on YPD, indicating that once the diploids had formed,CLP1 was not required for diploid growth (Fig. 3B).

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FIG. 3. Diploid formation requires CLP1. (A) CLP1 is required for diploid formation. Crosses between wild-type a and wild-type ${alpha}$ strains (CHY1345 x CHY1348) and a clp1 ${Delta}$ and ${alpha}$ clp1 ${Delta}$ strains (CHY1422 x CHY1421) were carried out on V8 agar for 24 h at room temperature. Resulting mixes were then transferred to selective plates and grown at 37°C to induce diploid formation. Panels show petri plates of diploids formed in each cross. (B) clp1 ${Delta}$ /clp1 ${Delta}$ diploids grow like wild-type diploids. PCR to assess genotypes was carried out with primers for SXI1 ${alpha}$ , SXI2a, and CLP1 on genomic DNAs from the indicated strains. Products were visualized in an agarose gel. Lane 1, wild-type a haploid (JEC20); lane 2, wild-type ${alpha}$ haploid (JEC21); lane 3, wild-type a/ ${alpha}$ diploid (CHY875); lanes 4 to 6, clp1 ${Delta}$ /clp1 ${Delta}$ diploid strains 1 to 3 (CHY1457 to CHY1459). The petri plate shows growth of wild-type and clp1 ${Delta}$ /clp1 ${Delta}$ diploids on rich medium for 3 days at 37°C.

CLP1 transcription is upregulated during sexual development and is controlled by Sxi1 ${alpha}$ and Sxi2a. To determine the expression profile of CLP1, transcript levelswere evaluated under several different conditions. RNAs wereisolated from wild-type and clp1 ${Delta}$ haploid a and ${alpha}$ cells as wellas from crosses under both high-nutrient (YPD) and sexual development-inducing(V8) conditions. Transcript levels were evaluated by Northernblotting using a probe specific to CLP1. The CLP1 transcriptwas not detectable in haploid cells under any conditions tested,including sexual development conditions (data not shown). Asshown in Fig. 4A, it was also undetectable in crosses underhigh-nutrient conditions (lane 1). However, under sexual developmentconditions in crosses between wild-type strains, the CLP1 transcriptwas readily detectable, indicating that CLP1 is induced duringsexual development (Fig. 4A, lane 2). It was also detected readilyin crosses between wild-type strains and clp1 ${Delta}$ strains (lanes3 and 4). However, as expected, in crosses between a clp1 ${Delta}$ and ${alpha}$ clp1 ${Delta}$ strains, no CLP1 transcript was detectable (lane 5).

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FIG. 4. CLP1 is regulated by SXI1 ${alpha}$ and SXI2a. (A) The CLP1 transcript was evaluated by Northern analysis under a variety of growth conditions. RNAs were isolated from the following crosses: lane 1, a x ${alpha}$ (JEC20 x JEC21) under high-nutrient conditions (YPD); lane 2, a x ${alpha}$ (JEC20 x JEC21) under sexual development conditions (V8); lane 3, a x ${alpha}$ clp1 ${Delta}$ (JEC20 x CHY1072); lane 4, a clp1 ${Delta}$ x ${alpha}$ (CHY1069 x JEC21); lane 5, a clp1 ${Delta}$ x ${alpha}$ clp1 ${Delta}$ (CHY1069 x CHY1072); lane 6, a x sxi1 ${alpha}$ ${Delta}$ (JEC20 x CHY768); lane 7, sxi2a ${Delta}$ x ${alpha}$ (CHY610 x JEC21); and lane 8, sxi1 ${alpha}$ ${Delta}$ x sxi2a ${Delta}$ (CHY610 x CHY768). All of the RNAs in lanes 2 through 8 came from crosses carried out on V8 juice medium. Genotypes and conditions are indicated over the lanes. The top arrow indicates the CLP1 transcript. The bottom arrow indicates the GPD1 transcript used as a loading and hybridization control. (B) Architecture of the CLP1 mRNA transcript. Hatched lines indicate the CLP1 ORF. Shaded regions indicate the 5' and 3' UTRs. The total transcript size is 1,686 bases. Two introns are spliced out of the transcript, at positions 141 and 479. Intron 1 is 63 bases in length, and intron 2 is 51 bases in length. Intron 1 resides in the 5' UTR. The CLP1 transcript is polyadenylated with a poly(A) tail of $~$ 200 bases.

Because Sxi1 ${alpha}$ and Sxi2a are crucial regulators of the dikaryoticstate, we also tested whether these proteins regulated transcriptionof the CLP1 gene. RNAs from crosses between wild-type and sxi1 ${alpha}$ ${Delta}$ and/or sxi2a ${Delta}$ strains under sexual development conditions wereevaluated for the presence of the CLP1 transcript. As shownin Fig. 4A, CLP1 transcript levels in sxi ${Delta}$ strains dropped dramatically(lanes 6 to 8), suggesting that Sxi1 ${alpha}$ and Sxi2a strongly upregulatethe expression of CLP1, either directly or indirectly. It isinteresting that in the sxi ${Delta}$ strains, the wild-type CLP1 transcriptwas diminished but not absent. This transcript is dependenton the presence of the CLP1 gene, but its role is unknown.

To further characterize the CLP1 transcript, we carried out5' and 3' RACE analysis, cDNA analysis, and poly(A) tail lengthanalysis. We found that the CLP1 mRNA transcript is 1,686 baseslong and includes both 5' and 3' untranslated regions (UTRs)and a poly(A) tail (Fig. 4B). Interestingly, the pre-mRNA isinterrupted by two introns, one of which is in the 5' UTR ofthe transcript. Introns in UTRs are rare, and although we donot know the significance of the 5' UTR intron in CLP1, suchsequences in other systems have been implicated in regulationof specific transcripts (8, 22). No differences in architecturewere detected between the CLP1 transcript from wild-type crossesand the CLP1 transcript from sxi ${Delta}$ crosses (data not shown).

CLP1 is a direct target of Sxi1 ${alpha}$ and Sxi2a in vitro. Inspection of the predicted promoter region of the CLP1 generevealed the presence of potential homeodomain binding sites(GATGN_xACA) approximately 211 and 510 base pairs upstream ofthe predicted ATG. To test the possibility that these sequencescould be binding sites for Sxi1 ${alpha}$ and Sxi2a, we carried out EMSAsusing protein fragments purified from E. coli. The purifiedproteins were tested for the ability to bind three fragmentsof the CLP1 promoter. As shown in Fig. 5A, we divided the CLP1promoter into three fragments of 274, 165, and 177 base pairs.Each was radiolabeled and used as an EMSA probe. In the caseof Sxi2a, a 60-amino-acid fragment containing the homeodomainregion was purified and tested in EMSAs on each fragment. Asshown in Fig. 5B, we detected binding to two of the three regions(lanes 5 to 12); however, binding was strong and specific onlyfor fragment C, a 177-bp fragment located immediately upstreamof the CLP1 ORF (lanes 8 to 12). We tested the specificity ofthis binding by titrating competing, unlabeled fragments ofeither the same sequence as the probe or a nonspecific sequenceinto the binding reaction mixtures. Binding to fragment C wascompeted with only the specific competitor, indicating thatbinding by the Sxi2a homeodomain fragment occurred with highspecificity (data not shown). This finding was surprising becausethe predicted homeodomain binding sites were located in theother two promoter fragments (A and B), and no DNA sequenceswith recognizable similarity to the GATGN_xACA consensus werefound in fragment C. For Sxi1 ${alpha}$ , we were not successful in recoveringsubstantial quantities of active protein from E. coli. However,a small amount of an amino-terminal fragment of the protein(175 amino acids) containing the amino terminus through thehomeodomain region was purified and tested, and it showed weakbut specific binding to fragment C (Fig. 5B, lanes 13 to 15)but no binding to fragment A or B (data not shown). There wasno enhancement of binding when the partial fragments of eachprotein were combined with fragment C, but based on two-hybridinteraction data, we predict that larger fragments of the proteinswould be required for direct protein-protein interactions (11;B. C. Stanton and C. M. Hull, unpublished data). We concludedthat Sxi1 ${alpha}$ and Sxi2a each have the capacity to bind with specificityto fragment C. In particular, binding by the homeodomain regionof Sxi2a is strong and specific and calls into question whetherthe predicted homeodomain binding sites in fragments A and Bhave any relevance in regulating CLP1 or other genes in C. neoformans.

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FIG. 5. Sxi1 ${alpha}$ and Sxi2a bind directly to the CLP1 promoter in vitro. (A) The CLP1 promoter contains predicted homeodomain binding sites. The hatched box represents the CLP1 gene in the genome. The black line represents the DNA region upstream of the predicted start codon of the gene. This region is divided into three regions, designated A, B, and C, whose lengths are indicated. The predicted homeodomain binding sites reside in regions A and B. (B) Sxi1 ${alpha}$ and Sxi2a bind fragment C. Fragments of Sxi2a and Sxi1 ${alpha}$ proteins purified from E. coli were incubated in binding reaction mixtures with radiolabeled DNA fragments of the CLP1 promoter region. Each set of four lanes in the first three panels contains 0, 1, 5, and 10 nM Sxi2a homeodomain protein. Lanes 1 to 4 contain a 274-bp probe (A) representing sequences farthest away from the CLP1 gene. Lanes 5 to 8 contain a 165-bp probe (B), and lanes 9 to 12 contain a 177-bp probe (C), representing sequences closest to the CLP1 gene. The fourth panel, lanes 13 to 15, contains probe C and increasing concentrations of the Sxi1 ${alpha}$ amino-terminal fragment, at 0, 16, and 32 nM, respectively.

CLP1 is required for ${alpha}$ fruiting. Finally, we evaluated what role CLP1 might play in another developmentalprocess. In addition to the sexual development process carriedout by a and ${alpha}$ haploid cells, there is a developmental processcarried out by ${alpha}$ cells, known as ${alpha}$ fruiting or monokaryotic fruiting(30). In response to severe nutrient limitation and desiccation,haploid ${alpha}$ cells spontaneously filament and form basidia and sporesin the absence of a mating partner. Interestingly, this processis independent of Sxi1 ${alpha}$ and Sxi2a (i.e., sxi1 ${alpha}$ ${Delta}$ strains undergofruiting like wild-type ${alpha}$ strains, and a cells generally do notfruit), placing at least some of the early initiating signalsoutside the sexual development pathway controlled by Sxi1 ${alpha}$ andSxi2a (12). Although we observed that CLP1 is under the controlof SXI1 ${alpha}$ and SXI2a, we also observed that clp1 ${Delta}$ strains cannotundergo ${alpha}$ fruiting. The top panels of Fig. 6 show the responsesof wild-type a and a clp1 ${Delta}$ strains to fruiting conditions. Asexpected, fruiting did not occur in either case, as a cellsdo not undergo ${alpha}$ fruiting. The bottom panels of Fig. 6 show theresponses of wild-type ${alpha}$ and ${alpha}$ clp1 ${Delta}$ strains, as well as an ${alpha}$ clp1 ${Delta}$ strain harboring a wild-type copy of CLP1, to fruiting conditions.The wild-type ${alpha}$ strain fruited as expected; however, the ${alpha}$ clp1 ${Delta}$ strain showed no signs of filamentation. Fruiting was restoredin the strain complemented with a single copy of the CLP1 gene.This finding indicates that unlike SXI1 ${alpha}$ and SXI2a, CLP1 is essentialfor processes common to both sexual development and monokaryoticfruiting.

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FIG. 6. CLP1 is required for ${alpha}$ fruiting. The top panels show wild-type a (JEC20) and a clp1 ${Delta}$ strains (CHY1069). The bottom panels show a wild-type ${alpha}$ strain (JEC21), an ${alpha}$ clp1 ${Delta}$ strain (CHY1072), and an ${alpha}$ clp1 ${Delta}$ strain containing a complementing copy of the CLP1 gene (CHY1187). All strains were photographed after 10 days at room temperature in the dark on filament agar.

DISCUSSION

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DISCUSSION

Sexual development is an essential part of the life cycles ofmost eukaryotes. In C. neoformans and its basidiomycete relatives,the formation of a dikaryotic filament is a key stage in thisprocess, and it is controlled by the homeodomain transcriptionfactors Sxi1 ${alpha}$ and Sxi2a (11, 18). We discovered that CLP1, apreviously uncharacterized gene in this system, is absolutelyrequired for sexual development, and it is the first identifieddirect target of Sxi1 ${alpha}$ and Sxi2a. The Clp1 protein, which hasno identifiable predicted structural features, is not requiredfor mate recognition or fusion with a mating partner but iscritical for development after cell fusion. Cells without CLP1cannot progress after cell fusion, suggesting a defect in theability to form dikaryons. However, this effect is more generalthan dikaryon formation alone, as we also observed defects in ${alpha}$ fruiting and diploid formation. Although we cannot rule outthat CLP1 may play a downstream role in filament formation,it is clearly required for an early event after cell fusion.

CLP1 and cell cycle control. In S. cerevisiae and other budding yeast species, a G₁ cellcycle arrest occurs upon mate recognition, allowing the cellsto prepare for fusion with a mating partner. After mating, theresulting diploids begin to grow vegetatively or undergo meiosisimmediately (27, 29). In U. maydis, haploid cells arrest inthe G₂ phase of the cell cycle in response to mating pheromone.In fact, in U. maydis, CLP1 is required for dikaryotic growthin planta, and experiments suggest that Clp1 overcomes the pheromone-inducedG₂ cell cycle block to allow dikaryon proliferation (23). ForC. neoformans, little is known about the cell cycle in responseto a mating partner. What is known is that in response to acells, ${alpha}$ cells form filaments (called germ tubes) in the directionof the a cells. The a cells, on the other hand, become swollenin response to ${alpha}$ cells (13). It appears that fusion occurs betweenan ${alpha}$ germ tube and the a partner, and it seems likely, basedon related fungal systems, that some form of cell cycle arrestwould occur to synchronize cells prior to this fusion event.

Based on our finding that clp1 ${Delta}$ cells can fuse with one anotherbut cannot outgrow afterwards, we propose that CLP1 in C. neoformansinfluences the cell cycle, acting as a regulator of growth reinitiationafter cell fusion. Alternatively, one could argue that CLP1is simply required for filament formation; however, the abilityto grow after fusion is also impaired during the formation ofdiploids (where no filaments are formed). It seems that CLP1in C. neoformans is required for escaping fusion arrest andrestoring regular cell cycles, whether they be in the filamentcells seen in di- and monokaryons or in the budding yeast cellsformed by diploids.

CLP1 is a target of Sxi1 ${alpha}$ and Sxi2a. Sxi1 ${alpha}$ and Sxi2a are both required for sexual development, butlittle is known about the genes they control. It is clear fromthis work that CLP1 is a target of Sxi protein regulation. CLP1levels were very low in haploids under all conditions testedand increased greatly during both sexual development and indiploids. For these cell types, the levels of CLP1 transcriptwere greatly diminished in sxi ${Delta}$ strains, indicating that CLP1is activated by the Sxi proteins. This is also true for CLP1in U. maydis, where bE and bW are regulators of CLP1, and theCLP1 promoter contains the bE and bW binding site GATGN_xACA(also known as a bbs) (21, 23). Finding such sequences in thepredicted promoter region of C. neoformans CLP1 partially motivatedour study of its role in sexual development, so it is interestingthat we did not detect binding to these sites by purified proteinsin vitro. Instead, we observed specific binding to a regionmuch closer to the ORF which does not contain the GATGN_xACA(or a closely related) sequence. It is possible that the "consensus"sequence for fungal homeodomain binding proteins based on a1- ${alpha}$ 2binding in S. cerevisiae and bE-bW binding in U. maydis doesnot apply as broadly as previously suspected (10, 21). Futurestudies with C. neoformans will refine the Sxi binding regionin the CLP1 promoter and reveal the sequences through whichSxi1 ${alpha}$ and Sxi2a regulate gene expression during sexual development.

Another interesting observation is that CLP1 levels are simplyreduced, not eliminated, in sxi ${Delta}$ strains, suggesting that theremay be low levels of Clp1 protein. sxi ${Delta}$ strains do not have defectsin cell fusion, and they can grow vegetatively after fusion;they simply do not carry out sexual development. This findingsuggests that there must be a bypass mechanism for sxi ${Delta}$ strainsto continue to grow in the presence of CLP1 that cannot be utilizedin the absence of CLP1. It is likely that the low level of CLP1transcript remaining in sxi ${Delta}$ strains is the critical factor thatallows sxi ${Delta}$ strains to escape arrest after cell fusion and togrow as budding yeast, something that clp1 ${Delta}$ strains are unableto do. This is consistent with our observation that very lowlevels of CLP1 transcript are sufficient to restore wild-typelevels of sexual development in mutant backgrounds (Stantonand Hull, unpublished data).

It is also possible that these lower levels of Sxi-independentCLP1 transcript play a role in monokaryotic fruiting. Clearly,some amount of CLP1 is required for fruiting of ${alpha}$ strains because ${alpha}$ clp1 ${Delta}$ strains cannot carry out this form of development; however,during fruiting, CLP1 cannot be under the control of the Sxiproteins because there is no SXI2a present, and SXI1 ${alpha}$ has beenshown previously to be dispensable for fruiting (12). Takentogether, these results indicate that during the fruiting process,CLP1 must be under the control of a distinct pathway (independentof the Sxi proteins). The processes of monokaryotic fruitingand sexual development both require CLP1, but control of CLP1expression is managed differently between these two forms ofdevelopment.

Nature of the CLP1 transcript. To confirm the predicted structure of the CLP1 transcript, wecarried out 5' and 3' RACE as well as cDNA analysis and poly(A)tail length analysis. Our findings were generally consistentwith our predictions, and the ORF we defined correlates withexpressed sequence tag data for CLP1 from the TIGR genome sequencingproject. We did not detect additional sense transcripts likethose found in U. maydis (23). There is, however, an expressedsequence tag in the TIGR database that corresponds to a CLP1antisense transcript. To determine whether this transcript mightplay a role in the regulation of CLP1, we carried out Northernassays with strand-specific probes for exon regions. Our Northernanalysis consistently showed expression and regulation of theCLP1 sense transcript. We were unable to detect the antisensetranscript under any of the conditions tested, leading us toconclude that the antisense transcript is unlikely to play arole in sexual development. We cannot rule out that this RNAis significant under other conditions, leaving another pathwayto explore for the role of this transcript under conditionssuch as those necessary for fruiting.

Summary. Using C. neoformans as a model of fungal sexual developmentprovides an opportunity to understand how transcriptional regulationleads to developmental changes in simple eukaryotes. In C. neoformans,sexual development results in the production of spores, thelikely infectious particles in human infections. The work presentedhere indicates that CLP1, a previously uncharacterized genein this system, is essential for the development process andfunctions to allow developmental progression after cells ofopposite mating types fuse with one another. During sexual development,CLP1 is under the control of the transcriptional regulatorsSxi1 ${alpha}$ and Sxi2a and is a direct target of these proteins in vitro.Taken together, these findings allow us to formulate a modelin which Sxi1 ${alpha}$ and Sxi2a act in concert during development toupregulate the expression of the CLP1 gene after cell fusion,allowing CLP1 to reinitiate growth (Fig. 7). This CLP1 functionis also required for other forms of C. neoformans development,indicating its critical role in cell growth and, ultimately,in the production of spores.

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FIG. 7. Model for the role of Clp1 during sexual development in C. neoformans. (1) Partner recognition, cell cycle arrest, and cell fusion occur between a and ${alpha}$ haploids. (2) In the resulting fusion product, Sxi1 ${alpha}$ and Sxi2a interact to induce expression of CLP1. (3) The Clp1 protein then acts to reinitiate cell growth. (4) After reinitiation, fused cells grow either as dikaryotic filaments or as diploid budding yeast cells, depending on the environmental conditions. Oval shapes represent cells. A thick circle represents the a nucleus, and a thin circle represents the ${alpha}$ nucleus. The yellow star represents Sxi2a, the blue oval represents Sxi1 ${alpha}$ , and the green square represents Clp1.

ACKNOWLEDGMENTS

We thank P. Ortiz-Bermúdez and C. Kowalski for technicalassistance and R. Borchardt and K. Klein for laboratory support.We thank M. Botts, R. Brazas, S. Giles, E. Kruzel, and M. Staudtfor critical readings of and comments on the manuscript.

This work was supported by a March of Dimes Basil O'Connor StarterScholar Award to C.M.H., a Burroughs Wellcome Fund Career Awardin the Biomedical Sciences to C.M.H., and grant R01-AI064287-02to C.M.H. from the National Institutes of Health. The C. neoformansGenome Project is a project of the Stanford Genome TechnologyCenter, funded by the NIAID/NIH under cooperative agreementU01 AI47087, and The Institute for Genomic Research, fundedby the NIAID/NIH under cooperative agreement U01 AI48594.

FOOTNOTES

* Corresponding author. Mailing address: University of Wisconsin, Madison, 587 Medical Science Center, 1300 University Avenue, Madison, WI 53706. Phone: (608) 265-5441. Fax: (608) 262-5253. E-mail: cmhull{at}wisc.edu

Published ahead of print on 9 November 2007.

Present address: Department of Ophthalmology, University ofIowa, Carver College of Medicine, 375 Newton Road, 4111 MedicalEducation & Research Facility, Iowa City, IA 52242.

REFERENCES

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