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Eukaryotic Cell, August 2005, p. 1420-1433, Vol. 4, No. 8
1535-9778/05/$08.00+0     doi:10.1128/EC.4.8.1420-1433.2005
Copyright © 2005, American Society for Microbiology. All Rights Reserved.

Cryptococcus neoformans Gene Expression during Murine Macrophage Infection

Weihua Fan,¹ Peter R. Kraus,^1, Marie-Josee Boily,^1, and Joseph Heitman^1,2,3,4*

Departments of Molecular Genetics and Microbiology,¹ Medicine,² Pharmacology and Cancer Biology,³ Howard Hughes Medical Institute, Duke University Medical Center, Durham, North Carolina 27710⁴

Received 5 May 2005/ Accepted 3 June 2005

	ABSTRACT

Top Abstract Introduction Materials and Methods Results Discussion References

 
The fungal pathogen Cryptococcus neoformans survives phagocytosis by macrophages and proliferates within, ultimately establishing latent infection as a facultative intracellular pathogen that can escape macrophage control to cause disseminated disease. This process is hypothesized to be important for C. neoformans pathogenesis; however, it is poorly understood how C. neoformans adapts to and overcomes the hostile intracellular environment of the macrophage. Using DNA microarray technology, we have investigated the transcriptional response of C. neoformans to phagocytosis by murine macrophages. The expression profiles of several genes were verified using quantitative reverse transcription-PCR and a green fluorescent protein reporter strain. Multiple membrane transporters for hexoses, amino acids, and iron were up-regulated, as well as genes involved in responses to oxidative stress. Genes involved in autophagy, peroxisome function, and lipid metabolism were also induced. Interestingly, almost the entire mating type locus displayed increased expression 24 h after internalization, suggesting an intrinsic connection between infection and the MAT locus. Genes in the Gpa1-cyclic AMP-protein kinase A pathway were also up-regulated. Both gpa1 and pka1 mutants were found to be compromised in macrophage infection, confirming the important role of this virulence pathway. A large proportion of the repressed genes are involved in ribosome-related functions, rRNA processing, and translation initiation/elongation, implicating a reduction in translation as a central response to phagocytosis. In summary, this gene expression profile allows us to interpret the adaptation of C. neoformans to the intracellular infection process and informs the search for genes encoding novel virulence attributes.

	INTRODUCTION

Top Abstract Introduction Materials and Methods Results Discussion References

 
The basidiomycetous fungus Cryptococcus neoformans is an opportunistic pathogen that is common in AIDS patients and the major cause of fungal meningitis worldwide (9). C. neoformans is a free-living organism commonly found in many environmental niches, including soil, trees, and bird guano. It is prototrophic for amino acids, sugars, and lipids and can utilize a variety of carbon sources for growth (9). C. neoformans has a bipolar mating system with a and mating types and can undergo sexual reproduction or monokaryotic fruiting to produce basidiospores, which are thought to be the infectious propagule (28, 59).

Several features of C. neoformans have been characterized as critical for its infectivity. These include the ability to grow at host body temperature (37°C) (44), formation of a polysaccharide capsule (10), production of melanin (89), and secretion of degradative enzymes such as urease (17), phospholipase B (16), and proteases (13). Expression of these virulence factors has been shown to be regulated by several signal transduction pathways (37, 46). The cyclic AMP-protein kinase A (cAMP/PKA) pathway controls capsule formation, melanin production, mating, and virulence (46). This pathway is activated by environmental stimuli, such as glucose, through an as-yet-unknown G-protein-coupled receptor and the G protein, Gpa1 (3, 4, 25, 26). Both the Ras (Ras1 and Ras2) and calcineurin pathways regulate the ability of this pathogenic organism to grow at 37°C (1, 61, 90). A mitogen-activated protein kinase cascade regulates filamentous growth and morphological differentiation in the mating process in response to activation by pheromones (14, 20, 32, 74, 90).

C. neoformans infection is likely to begin when cryptococcal cells, either in the yeast or the spore form, are inhaled. One of the first lines of innate defense in the host is the alveolar macrophage within the lung. Although C. neoformans can be efficiently phagocytosed and killed by macrophages, it can also inhibit and evade phagocytosis with its polysaccharide capsule. However, following phagocytosis, this yeast is able to survive the exposure to antifungal compounds produced by the activated macrophage and adapts to the intracellular environment of the phagosome (29). While residing within the macrophage, C. neoformans may then be able to shield itself from other innate defense mechanisms, such as complement, antibodies, serum, and alveolar immune factors, or even antifungal drugs (9, 29, 30). It has also been proposed that residency with macrophages provides a route for C. neoformans to enter the bloodstream and lymphatic system, enabling dissemination from the lung to distant organs, including its propensity to invade the central nervous system (9, 29, 30). However, how C. neoformans adapts to the intracellular environment of the macrophage and what signal transduction pathways control its intracellular growth and maintenance are largely unknown.

The completion of the C. neoformans genome has enabled global gene expression profiling with microarray technology (50; http://cneo.genetics.duke.edu/index.html). We previously developed a genomic microarray comprising >6,000 PCR-amplified genomic DNA fragments. This microarray has been employed to identify the gene expression profile in response to growth at high temperature (42) and genes controlled by the Gpa1 virulence cascade (64). Herein we report and analyze the transcriptional profile of C. neoformans during intracellular growth within murine macrophages.

	MATERIALS AND METHODS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Fungal strains and media. H99, a well-characterized virulent clinical isolate of C. neoformans serotype A, was used as the wild-type strain. pka1 (25), gpa1 (3), lac1 (64), fhb1 mutant strains, and the FHB1-reconstituted strain (FHB1) (21) have been described previously. C. neoformans was grown on rich YPD (1% yeast extract, 1% Bacto Peptone, 2% dextrose) medium. Solid media contained 2% Bacto agar. Selective YPD medium contained 100 mg/liter of nourseothricin (Werner BioAgents, Jena-Cospeda, Germany). For melanin production, glucose-free asparagine medium (1 g/liter L-asparagine, 0.5 g/liter MgSO₄, 3 g/liter KH₂PO₄, 1 mg/liter thiamine) plus 1 mM L-Dopa was used.

Macrophage assay. J774A.1 (ATCC TIB-67) is a murine (BALB/c; haplotype H-2^d) macrophage-like cell line derived from a reticulum sarcoma (66). Cells were maintained at 37°C in 10% CO₂ in Dulbecco's modified Eagle's medium (Invitrogen, Carlsbad, CA) supplemented with 10% heat-inactivated fetal calf serum (Atlanta Biologicals, Atlanta, GA), 1% nonessential amino acids (Invitrogen), 100 µg/ml penicillin-streptomycin (Invitrogen), and 10% NCTC-109 medium (Invitrogen). The cell line was used between passages 4 and 15.

For microarray analysis, H99 cells were grown in YPD medium for 16 h at 30°C with 2% glucose. The cells were pelleted, resuspended in fresh YPD with 2% glucose, and incubated for another 3 h at 30°C. H99 cells were pelleted, washed three times with 1x phosphate-buffered saline (PBS; Gibco), and counted using a hemocytometer under a microscope. Macrophage cells were cultured in T-150 canted neck culture bottles (Corning Inc.) to near confluence, replaced with fresh medium supplemented with 1 µg/ml monoclonal antibody 18B7, which binds to the capsular polysaccharide and is opsonic (8), 50 U/ml of recombinant mouse gamma interferon (IFN-; Roche Molecular Biochemicals), and 0.3 µg/ml lipopolysaccharide (LPS; Sigma) for activating macrophages. H99 cells were added to the macrophage culture at a multiplicity of infection (MOI) of 2:1 and incubated for 2 h at 37°C with 5% CO₂. As a control, H99 cells were also added to culture bottles with the same volume of macrophage culture medium as described above and incubated under the same conditions (5% CO₂, 37°C). Extracellular H99 cells were washed off by gently rinsing the macrophage culture bottle with prewarmed (37°C) PBS three times. The macrophage-H99 culture was then either harvested at this time point (2-hour culture) or allowed to incubate for 24 hours and harvested (24-hour culture). At both the 2- and 24-h time points, the extracellular C. neoformans cells and detached macrophages were rinsed off with prewarmed PBS and the remaining intracellular H99 cells within the attached macrophage cells were scraped off the bottles and resuspended in ice-cold distilled H₂O. Macrophage cells were lysed by adding a 0.05% sodium lauryl sulfate (SDS; Sigma) solution. At this SDS concentration, the macrophage cells are lysed while H99 cells remain intact and viable (tested by hemocytometer counting and plating for CFU). The remaining yeast cells were washed three times with ice-cold water by centrifugation and resuspension and then pelleted and frozen at –80°C until RNA preparation. Typically, each sample yielded about 5 x 10⁷ H99 cells.

For the virulence assay, macrophages were cultured in 96-well cell culture plates under the conditions described above and activated with mouse IFN-, monoclonal antibody 18B7, and LPS. C. neoformans H99 and mutant cells were cultured in YPD medium at 30°C to mid-logarithmic phase, washed three times with PBS, and inoculated to the macrophages. After 1 h of incubation, unattached cryptococcal cells were washed off with prewarmed PBS (37°C). Growth of C. neoformans cells was measured by lysing the macrophages and plating the lysate on YPD for CFU, as described above.

RNA preparation. Total RNA from C. neoformans cells was extracted with the hot phenol protocol adopted from Schmitt et al. (72). Yeast cells were resuspended in AE buffer (50 mM NaAc, 10 mM EDTA, pH 5.3), and a 1/10 volume of 10% SDS was added. After mixing, an equal volume of preheated phenol (equilibrated with AE buffer) was added, and the mixture was incubated at 65°C for 5 min. Then, the samples were centrifuged and the supernatant was transferred to fresh microcentrifuge tubes and extracted with an equal volume of 25:24:1 of phenol-chloroform-amyl alcohol. RNA was then precipitated by adding 2 volumes of ethanol to the supernatant and incubated at –80°C for 2 h. RNA was pelleted and resuspended in nuclease-free water and further purified with the RNeasy Mini RNA purification kit (QIAGEN) according to the manufacturer's instructions.

RNA amplification. Purified total RNA was amplified using the MessageAmp aRNA kit from Ambion, according to the manufacturer's instructions. Briefly, first-strand cDNA was synthesized by reverse transcription primed with the T7 oligo(dT) primer, which has a T7 promoter sequence attached to its 3' end. Second-strand cDNA was synthesized with the DNA polymerase supplied in the MessageAmp aRNA kit to provide double-stranded DNA template for in vitro transcription. The amplified RNA (aRNA) was produced by T7 RNA polymerase, transcribed from the T7 promoter incorporated in the cDNA. Using this method, 14 to 120 µg aRNA was produced from 0.1 to 1 µg of total RNA templates.

Microarray hybridization and analysis. The genomic DNA microarray construction was described in detail previously (42). Briefly, 6,144 PCR products were amplified from a 1.6- to 3.2-kb genomic library made with strain H99 genomic DNA, and arrays were printed on polylysine-coated glass slides. Because of their sizes, about 23% of the probes overlap with more than one gene. Fluorescence-labeled cDNA was generated by incorporating amino-allyl-dUTP during reverse transcription of 10 µg aRNA. Cy3 or Cy5 dye (Amersham, Piscataway, N.J.) was coupled to the aminoallyl group as described previously (24). The aRNA from H99 grown in YPD medium at 30°C was labeled with Cy3 as the reference sample for all hybridizations. A sample from each time point was individually labeled with Cy5 and competitively hybridized against the reference sample. After hybridization as described previously (42), arrays were scanned with a GenePix 4000B scanner (Axon Instruments, Foster City, Calif.) and analyzed by using GenePix Pro v 4.0 and BRB array tools (developed by Richard Simon and Amy Peng Lam at the National Cancer Institute; http://linus.nci.nih.gov/BRB-ArrayTools.html). Data were normalized using lowess smoothing, and differential expression was determined using a randomized variance t/F test. The threshold P value for determining differential expression was P < 0.05.

The genome sequence of C. neoformans serotype A strain H99 is available (http://cneo.genetics.duke.edu/menu.html) but not yet fully annotated. Therefore, the array element sequences were analyzed by BLAST searches against the serotype D sequence database from The Institute of Genome Research (TIGR; http://www.tigr.org/tdb/e2k1/cna1/). In some cases genes annotated in the TIGR database as unknown or hypothetical were found to have significant (E value < e^–50) homologs via translated BLAST (BLASTX) searches against the nonredundant database at GenBank using the H99 probe sequences. In those cases the best homologs were assigned to the sequences (see the supplemental material).

Construction of the LAC1^pro-GFP reporter. A 2,002-bp fragment upstream of the LAC1 gene coding sequence that included the first 15 LAC1 codons was amplified with primers 5'-ACTCTAGAAAGATACCACTGCCTGCTGG (XbaI site underlined) and 5'-CACCTAGGTACTGTGAGTGTCGGTATAGCT (AvrII site underlined). A GFP gene with a terminator sequence from the C. neoformans GAL7 gene (courtesy of Connie Nichols) was amplified with primers 5'-ATGGCGCGCCATGGTGAGCAAGGGCGAGGAGCT (AscI site underlined) and 5'-TGCGACCGTTTAAACTAGCAAAAGTGACTCTATTC (PmeI site underlined). The amplified fragment was digested with PmeI and AscI and cloned into a binary vector for Agrobacterium tumefaciens-mediated transformation, pPZP-NAT (15, 39), to generate plasmid pWF06. The amplified LAC1 promoter was digested with XbaI and AvrII and cloned into pWF06 to generate an in-frame fusion of green fluorescent protein (GFP) with the first 15 codons of LAC1, resulting in plasmid pWF09.

Transformation of C. neoformans. For targeted disruption of genes, C. neoformans strain H99 was transformed by using biolistic techniques as previously described (83). The overlap PCR constructs for gene disruption were constructed as described elsewhere (18), using a modified NAT resistance cassette (39). A. tumefaciens-mediated transformation of C. neoformans was performed as described by Idnurm et al. (39). Briefly, A. tumefaciens strain LBA4404 carrying the plasmid pWF09 was used to transform C. neoformans strain H99, and the transformants were selected on YPD medium with nourseothricin and cefotaxime (each at 100 µg/ml) and verified by Southern blot analysis.

Real-time PCR. RNA was extracted, and first-strand cDNA was synthesized as described above. This cDNA was used as a template in a real-time PCR using SYBR Green PCR reagents (Bio-Rad) according to the manufacturer's recommendations. The iCycler iQ real-time PCR detection system (Bio-Rad, Richmond, CA) was used to detect and quantify the PCR products. Each set of PCR included a triplicate of each target gene, as well as a triplicate of the housekeeping gene ACT1 as control. The data were normalized to ACT1 cDNA expression amplified in each set of PCRs.

	RESULTS

Top Abstract Introduction Materials and Methods Results Discussion References

 
Microarray analysis of phagocytosis-induced gene expression. To analyze the global changes in transcriptional response to phagocytosis by macrophages, C. neoformans H99 cells were opsonized with mouse monoclonal antibody 18B7 and phagocytosed by macrophages activated by LPS and IFN-. Internalization of the C. neoformans cells were verified by immunofluorescence staining with Texas Red-conjugated antibody against mouse immunoglobulin G (data not shown). Total RNAs were extracted from the internalized H99 cells and from H99 cells incubated in the same medium and conditions as macrophage cell culture, as controls. Samples were taken at two time points, 2 hours, for the early response, and 24 hours, for later responses. The RNAs were fluorescently labeled and hybridized to a PCR product partial genomic DNA microarray of 0.5x coverage and a total of 6,274 probe elements (42). Three independent replicate experiments were carried out to generate the data set (see the supplemental material).

The data were normalized using lowess smoothing, and differential expression was determined by a randomized variance t/F test. A total of 525 genes with a P value of <0.05 were included for further analysis (see the supplemental material). The magnitude of change in phagocytosis-specific gene expression was deduced by comparing the internalized samples with that from media control samples at each time point. Those with twofold or greater changes in the internalized samples were analyzed further. In this set, 15 genes showed early induction, but their up-regulation was not sustained at the 24-hour time point. Another 35 genes were induced at 2 h postinternalization, and this induction persisted at 24 hours. On the other hand, 73 genes were significantly induced only at 24 hours. A total of 157 genes were significantly down-regulated in the internalized samples relative to the control, in comparison with the 123 up-regulated genes. Among the 157 repressed genes, 17 were repressed only at the earlier time point, 23 were repressed throughout the course, and 117 genes were repressed at the 24-hour time point. The identities of these genes were determined by BLAST search in the C. neoformans serotype D genome database at TIGR (http://www.tigr.org/tdb/e2k1/cna1). Whenever possible, their homologs in Saccharomyces cerevisiae were identified by BLAST search of the Saccharomyces genome database (http://www.yeastgenome.org/).

Membrane transporter genes were induced by macrophage internalization. Upon phagocytosis, 19 genes encoding membrane-associated transporters were up-regulated (Table 1). The primary functions of these transporters are likely to be in the import of molecules across the plasma membrane. This may reflect increased uptake and assimilation activities in the fungal cell, presumably due to the limited nutrients available in the phagosome. One class of transporters includes those for carbohydrates, such as the hexose transporter Itr1 (11.7-fold), a homolog of the high-affinity glucose sensor Rgt2 (2.3-fold), and the glucose transporter Gth1 (4.2- and 3.7-fold), which is important for Cryptococcus melanin production and virulence (J. A. Alspaugh, unpublished data); the inducible high-affinity maltose transporter Agt1 (3.2- and 4.8-fold); and the alpha-glucoside transporter Mph2 (2.9-fold) (Table 1). Interestingly, an inorganic phosphate transporter similar to Saccharomyces Pho84 was induced >16-fold at the 2-hour time point but reduced by 3.8-fold at the 24-hour time point (Table 1). In S. cerevisiae Pho84 may sense nutrient signals and activate the protein kinase A pathway in concert with glucose sensors (35). Phagocytosis of C. neoformans also induces transporters for nicotinic acid (Tna1) and cytosine/purine (similar to S. cerevisiae Fcy2 and Fcy21, named CPP2 for cryptococcus purine/cytosine permease 2).

In S. cerevisiae, Fet3, a ferro-O₂-oxidoreductase required for high-affinity iron uptake, and Ftr1, a high-affinity iron permease, form a complex required for transport of iron across the plasma membrane. In phagocytosed C. neoformans cells, FET3 was induced 2.7-fold at the 2-hour time point, while FTR1 was induced 2.5- and 2.1-fold at the 2- and 24-hour time points, respectively (Table 1). Both the FET3 and FTR1 genes are also induced in C. neoformans cells grown in capsule-producing low-iron medium (48). The multicopper oxidase Fet3 is conserved in fungi and is required for cellular iron acquisition (87). Disruption of the FET3 gene in Candida albicans did not affect its virulence (27), but a C. albicans strain lacking FTR1 displayed attenuated virulence (67).

In addition to the plasma membrane-localized transporters, a few organellar transporters were also up-regulated. These included two peroxisomal fatty acid transporters similar to the adrenoleukodystrophy-related protein in humans and a peroxisomal ATP carrier protein similar to Saccharomyces Ant1. Two homologs of PXA1, which encode peroxisomal fatty acid transporters similar to the human adrenoleukodystrophy protein, were induced 3.2- to 5.9-fold at both time points. PEX5 and PEX7 encode proteins whose homologs are required for peroxisomal protein transport and peroxisome biogenesis (71), and they were induced 2.0- to 4.4-fold in phagocytosed cells (Table 2), reflecting a potential increase in peroxisome activity.

Phagocytosis induced genes involved in lipid degradation and fatty acid catabolism. A gene encoding a triacylglycerol lipase (CGL1, for cryptococcus glycerol lipase 1) (Table 2) was induced 2.1-fold at 2 hours after internalization. The amino acid sequence of Cgl1 indicates that it may be a secreted protein and thus likely functions in degrading extracellular lipids. Phagocytosis induced a gene encoding an acetyl coenzyme A acetyltransferase homologous to yeast Cat2 (2.8-fold), which functions in ß-oxidation (Table 2). A Cat2 homolog in C. albicans has been shown to be induced by macrophage phagocytosis (63). ICL1, which encodes isocitrate lyase, a central component of the glyoxylate shunt pathway, was also up-regulated 3.0-fold at the 2-hour time point (Table 3).

We also found that two essential components of the exocyst, Sec6 and Sec8, were up-regulated in phagocytosed cells by 3.0- and 3.1-fold, respectively, at the 24-hour time point (Table 3). The exocyst is a multiprotein complex required for exocytosis in eukaryotic cells (81). SAC1, which encodes the phosphatidylinositol phosphatase that controls endocytosis and exocytosis, was also induced 2.0-fold at the 24-hour time point. One potential class of cargo for exocytosis could be cell wall or capsular components. Indeed, we found that several genes that encode proteins related to synthesis of extracellular polysaccharides or cell wall were induced: ALG3 (2.5-fold, 24 hours), which encodes the Dol-P-Man:Man5GlcNAc2-PP-Dol mannosyltransferase involved in biosynthesis of lipid-linked oligosaccharides in yeast (73); WSC2 (3.1-fold, 24 hours), which encodes a novel transmembrane protein involved in cell wall integrity, cell surface sensing, and growth at 37°C (65); and a homolog of C. albicans NIK1 (2.8-fold, 24 hours) (Table 2), which encodes a two-component hybrid kinase regulator involved in hyphal development and virulence (76, 91).

Activation of the mating type locus. The mating type locus of the serotype A MAT strain H99 is over 100 kb in length and has 26 protein-encoding open reading frames, including four copies of the -pheromone gene MF (32, 47). We observed that genes in the MAT locus were overrepresented in up-regulated genes at the 24-hour time point. Among the 21 MAT locus genes that are present on the microarray, 11 were up-regulated at least twofold (52%), while 5 others showed some induction, although less than our twofold cutoff for significance. In contrast, only 108 out of 525 genes were up-regulated at the 24-hour time point. The overrepresentation of MAT locus genes thus has a statistical confidence of P < 0.001 (chi-square test).

Our genomic DNA microarray also contains 96 sequences (average length, 1.1 kb) derived from the serotype D MAT strain JEC21 tiling through the MAT locus region. The density of the probes in this region therefore is much higher than that of the entire genome. This allowed us to examine the gene expression in the MAT locus in greater detail. A set of 96 array elements randomly selected from the genome showed a more random pattern, in which only 4 genes (4.2%) were up-regulated twofold while 14 were down-regulated (Fig. 1). In contrast, among the 94 array elements in the MAT locus, 41 (44%) were up-regulated twofold or more while only 5 (5.3%) were reduced.

View larger version (32K): [in this window] [in a new window]   FIG. 1. Activation of MAT locus transcription during phagocytosis. Log-transformed microarray data of a random set of genes and of genes spanning the MAT locus are plotted here, as well as log-transformed data from real-time RT-PCR analysis of selected genes in the MAT locus. The lines at 1 and –1 indicate the threshold of significance (twofold increase or decrease). A diagram of the serotype A MAT locus indicates the position of genes in this region. The RT-PCR was performed three times in duplicate with unamplified total RNA as template. The expression value of each gene was determined by the threshold cycle method, and the value of ACT1 (encoding actin) was used to normalize the expression of genes of interest. For each gene, the relative induction was determined by comparing its normalized expression values in the macrophage-ingested sample with the medium control. The average values from six replicates are shown here.

To verify this expression profile, a real-time quantitative RT-PCR assay was conducted on eight genes in the MAT locus, using unamplified total RNA isolated from phagocytosed H99 cells at the 24-hour time point as template. As shown in Fig. 1, six of the eight genes, SXI1, CAP1, ZNF1, MF1, STE11, and GEF1, displayed induction values in quantitative RT-PCR similar to that found by microarray analysis. Although PRT1 was induced as shown by the quantitative RT-PCR assay, the induction was less pronounced compared to the microarray analysis. A noncoding transcript, NCM1, was found to be induced by more than eightfold in microarray, while in the quantitative RT-PCR assay, little induction was detected. This may be due to differential sensitivity or specificity of the two methods, differences introduced during the RNA amplification, or variability among experiments.

It is not clear what function activation of MAT locus transcription serves, since C. neoformans cells do not undergo the typical morphological changes, i.e., cell fusion or filamentous growth, during intracellular infection. One hypothesis is that mating occurs in response to nutrient limitation, and the MF pheromone gene is known to be induced by both pheromone and nutrient limitation in vivo in rabbit central nervous system (19, 23). The intracellular conditions present in the macrophage phagosome may therefore mirror those conditions that normally trigger mating type gene expression. In summary, these findings forge a further link between mating type and virulence.

Induction of genes with known virulence roles. Many genes contribute to virulence of C. neoformans. We found that a number of these genes are transcriptionally regulated following phagocytosis by macrophages. These findings indicate a strong correlation between the up-regulated genes and their possible important biological roles in macrophage infection. Indeed, IPC1, an inositol-phosphoryl ceramide synthase gene required for virulence in J774.16 murine macrophages, was induced at 24 hours (4.1-fold) (Table 3) (54). Phagocytosis also induced both of the laccase-encoding genes LAC1 (3.8-fold at 2 hours) and LAC2 (3.0- and 3.4-fold at 2 and 24 hours, respectively) (Table 3). Melanin production is important for C. neoformans virulence as an intracellular pathogen (49, 55, 78).

Capsule not only prevents C. neoformans cells from being ingested by macrophages but also protects phagocytosed cells from macrophage killing (22, 29, 30). Among the capsule-related genes, CAP10 was induced more than twofold in phagocytosed cryptococcal cells compared to control (Table 3). However, other capsule genes, such as CAP59, CAP60, and CAP64, did not show higher expression in the internalized cells. Capsule formation is activated in C. neoformans cells incubated in the macrophage culture medium by the presence of serum and 5% CO₂ (92). Therefore, genes required for the biosynthesis of capsule polysaccharides might not be expected to be further induced in internalized C. neoformans cells. It is also possible that CAP59 and CAP64 are not transcriptionally regulated, because little difference in their expression levels was found under capsule-inducing and noninducing conditions (48). On the other hand, two CAP64 homologs, CAS31 and CAS32, as well as the CAS1 and CAS2 genes, which are all involved in modifying capsule structure (40, 57, 58), were up-regulated 2.0- to 2.8-fold (Table 3). These findings suggest that internalized C. neoformans cells may produce a capsule of different structure or composition from that of free-living cells. This is consistent with the previous proposal that capsule structure may change in response to specific environments (84).

The G protein -subunit Gpa1, the cAMP pathway, and Pka1 are essential for C. neoformans virulence (3, 4, 25, 26). Interestingly, 9 of 17 Gpa1 target genes, as identified by Pukkila-Worley et al. (64), were induced in phagocytosed cells. These include the capsule genes CAS1, CAS2, CAP10, and CAS31 and the laccase genes LAC1 and LAC2, as well as GPA2, SMG1, and THR4. This is consistent with previous findings that the Gpa1-cAMP pathway regulates capsule and melanin production, as well as virulence (3, 4, 25, 64). Another gene in the cAMP pathway, PKA1, was also induced (2.1-fold) (Table 3). A multicopy suppressor of the melanin defect of the gpa1 mutant, SMG1, which encodes an aryl alcohol oxidase homolog, was also induced at both the early and late time points (2.7- and 5.7-fold, respectively).

Calcineurin has been shown to be critical for virulence in both C. neoformans and C. albicans (6, 31, 61). It is also indispensable for growth at 37°C, although neither the CNA1 nor the CNB1 calcineurin gene is induced by high temperature (42). The CNA1 gene was induced by phagocytosis (3.0-fold at 24 hours), suggesting that calcineurin may also be important for intracellular infection.

A gene similar to a highly conserved bacterial gene LepA (E value = –152 to Legionella pneumophila and Listeria inoculans LepA) was found to be induced at the 24-hour time point. LepA encodes a membrane GTPase that is highly conserved from bacteria to humans and is important for L. pneumophila virulence in amoebae (12).

Repression of translation in response to phagocytosis. In C. albicans, a wholesale repression of the translation machinery occurs rapidly after phagocytosis by macrophages (51). Repressed genes include those encoding ribosomal proteins, translation initiation factors, translation elongation factors, and tRNA synthetases. Similarly, we observed that genes involved in translation-related functions were down-regulated upon internalization by macrophages, albeit with slower kinetics than C. albicans (Table 4). For instance, only a few genes were down-regulated at the early time point, while most were repressed later. Most of the repressed genes are involved in assembly, maturation, and maintenance of the ribosome, processing of pre-rRNA, or translation initiation and elongation (Table 4). On the other hand, only two (RPS8 and RPL1) encode core ribosomal proteins. Similar to C. albicans, repression of the translation apparatus likely reflects an adaptation to the limited nutrient environment present within the phagosome. But the fact that ribosomal protein genes were not uniformly repressed in C. neoformans may reflect differences in the regulation of ribosome production between these two organisms.

View larger version (28K): [in this window] [in a new window]   FIG. 2. Expression and functional analysis of phagocytosis-induced genes. A. Quantitative real-time RT-PCR analysis of the CZC1, CGL1, and CPP2 genes. RT-PCR was performed three times in duplicate at each time point with unamplified total RNA as template. The expression value of each gene was determined by the threshold cycle method, and the value of ACT1 (encoding actin) was used to normalize the expression of genes of interest. For each gene, the relative induction was determined by comparing its normalized expression in the macrophage-ingested sample with the medium control. The average inductions deduced from RT-PCR and from microarray are shown here. B. Growth of the deletion mutants in macrophages. Cells of two independent mutant isolates for CZC1 (czc1-3 and czc1-4) or CPP2 (cpp2-11 and cpp2-18) and the fhb1 mutant and its complemented strain (FHB1) (21) were inoculated into macrophages at an MOI of 2:1, and cryptococcal cells were reisolated after 24 h of incubation. Growth was measured by plating reisolated cells and determining CFU. Open columns, growth in macrophages; closed columns, growth in culture medium under conditions for macrophage culture. The experiments were repeated three times, and error bars represent the standard deviation of the mean.

czc1

cpp2

czc1

cpp2

In addition, lac1, gpa1, and pka1 mutants were also tested in macrophages. The growth of these mutant strains in macrophages was significantly reduced compared with the wild-type strain H99 (Fig. 3A). The fhb1 mutant lacking flavohemoglobin denitrosylase, previously shown to be important for survival in macrophages (21), served as a control. All of these mutants grew normally in the macrophage culture medium at 37°C and 5% CO₂ (Fig. 3B), indicating that the observed growth defect in macrophages is attributable to macrophage killing.

View larger version (10K): [in this window] [in a new window]   FIG. 3. Growth of C. neoformans mutants in macrophages. Cryptococcal cells of the gpa1, pka1, lac1, or fhb1 mutants were inoculated with macrophages at an MOI of 2:1, and cryptococcal cells were reisolated after 24 h of incubation. Growth was measured by plating the reisolated cells and counting CFU. A. Growth in macrophages. Open columns, initial inoculum; solid columns, growth after 24-h incubation in macrophages. B. Growth in macrophage culture medium alone at 37°C and 5% CO2.

View larger version (76K): [in this window] [in a new window]   FIG. 4. Expression of the LAC1pro-GFP reporter. The LAC1pro-GFP reporter strain was constructed in the H99 background, and its expression was monitored by fluorescence microscopy. A. Induction of the LAC1pro-GFP reporter under melanin-inducing conditions. Cryptococcus cells of the H99 or the LAC1pro-GFP strain were grown in asparagine medium with 0.1% glucose at 30°C for 4 h before examination by fluorescence microscopy. Upper panels are images from light microscopy; lower panels are fluorescent images. B. Re-repression of the LAC1pro-GFP reporter by glucose. The LAC1pro-GFP reporter strain was incubated in asparagine medium with 0.1% glucose for 4 h before shifting to YPD with 2% glucose with continued incubation for 2 or 4 h. Upper panels, light images; lower panels, fluorescent images. Arrows indicate a bud lacking GFP. C. Expression of the LAC1pro-GFP reporter gene in macrophages. H99 or the LAC1pro-GFP reporter strain was inoculated into macrophages and incubated for either 4 or 16 h before examination by fluorescence microscopy. Upper panels, light images; lower panels, fluorescence images. "Extracellular" indicates H99 cells not ingested by macrophages.

	DISCUSSION

Top Abstract Introduction Materials and Methods Results Discussion References

 
The opportunistic pathogen C. neoformans is a facultative intracellular pathogen that can survive and divide inside phagocytic cells such as neutrophils and macrophages (22, 30). Intracellular survival may be the basis for latency, dissemination, and resistance to eradication by antifungal agents (9, 30). However, the molecular mechanisms by which C. neoformans survives and adapts to the hostile intracellular environment of the macrophage are not clear. To gain a global view of this process, we identified the transcriptional profile of C. neoformans in response to internalization by macrophages using genomic DNA microarrays.

For microarray analysis, total RNA from opsonized and internalized cryptococcal cells was isolated from macrophages. Because only limited quantities of Cryptococcus cells were isolated, RNA amplification was necessary to produce sufficient amounts of aRNA for labeling and hybridization to the microarray. It has been shown by comparative hybridization to microarrays and quantitative RT-PCR that the relative abundance of tested genes is not significantly altered in amplified samples (5, 36, 79, 85, 86, 93). The expression of selected genes was examined by quantitative RT-PCR using unamplified RNA as the template. Nine of 11 genes tested showed expression profiles consistent with microarray data. Our microarray analysis also revealed the induction of a number of genes with previously established virulence roles. Several of these genes were shown to be important for growth in macrophages. Furthermore, as an example, phagocytosis-induced expression of LAC1 was confirmed using a LAC1^pro-GFP reporter strain. Taken together, these findings corroborate that microarray analysis defined genes that function in the intracellular infection process.

By comparing gene expression in internalized C neoformans cells with those growing in the same medium at 37°C, we excluded genes responsive to high temperature alone. Indeed, in comparison with the temperature-responsive gene expression data of Kraus et al. (42) and Steen et al. (77), only a few of those genes (THR4, SMG1, and CHL1) were further induced by phagocytosis. Moreover, while many components of the translation machinery are up-regulated by high temperature (42), a large number of these genes were repressed following phagocytosis (Table 4). This may indicate that C. neoformans executes distinct transcriptional programs in response to phagocytosis and to heat stress.

The nutrient composition of the macrophage phagosome is largely unknown. However, it has been hypothesized that the phagosome contains limiting amounts of glucose or certain amino acids (52). The responses of S. cerevisiae and C. albicans to phagocytosis by murine macrophages differ from responses to human neutrophils. Phagocytosis by neutrophils elicits a typical response to amino acid starvation, suggesting that the intracellular environment is deficient in amino acids (69). However, when ingested by murine macrophages, neither C. albicans nor S. cerevisiae activates genes in amino acid biosynthetic pathways (52). Similarly, C. neoformans cells ingested by murine macrophages activated only a few amino acid biosynthetic genes. On the other hand, both C. neoformans and C. albicans induce amino acid transporters upon phagocytosis by macrophages. It has been suggested that macrophage phagosomes are endoplasmic reticulum derived and thus contain limited amounts of amino acids, while the plasma membrane-derived phagosomes of neutrophils might be depleted of amino acids by transporters working in reversed orientation (69). Therefore, the fungal responses to macrophage ingestion may mainly involve acquiring amino acids from phagosomes instead of de novo synthesis.

Phagocytosed fungal cells are subject to carbon limitation. The microarray data revealed that phagocytosed cryptococcal cells execute transcriptional programs resembling responses to carbon starvation. This is indicated by the up-regulation of transporters for glucose and other carbohydrates in phagocytosed C. albicans (51) and C. neoformans cells. However, it remains to be investigated whether these transporters function in intracellular infection by signaling phagosomal glucose concentrations or by direct glucose transport into cryptococcal cells.

Multiple enzymes in the glyoxylate cycle, including isocitrate lyase (Icl1), malate synthase (Mls1), malate dehydrogenase (Mdh2), and citrate synthase (Cit2), are all induced in C. albicans following phagocytosis (51, 52, 62, 63). In contrast, only Icl1 was induced in phagocytosed C. neoformans cells. Moreover, while C. albicans icl1 mutants are avirulent, neither icl1 nor mls1 mutants of C. neoformans showed defects in virulence in murine models (70; A. Idnurm, personal communication) and in murine macrophages (data not shown). The main function of the glyoxylate cycle is to convert two-carbon compounds generated by lipid ß-oxidation to provide substrates for gluconeogenesis. While genes encoding key enzymes in gluconeogenesis were up-regulated in C. albicans in response to phagocytosis (51), no gluconeogenesis genes were induced in internalized cryptococcal cells. This may reflect different strategies of C. neoformans and C. albicans to cope with glucose starvation.

In response to carbon starvation in the phagosome, C. neoformans does induce genes involved in the utilization of alternative carbon sources. These include genes encoding extracellular lipases that may digest host lipids into fatty acids, transporters for importing the fatty acids into the peroxisome, enzymes and carriers involved in ß-oxidation, and factors for peroxisome formation and maintenance. In several phytopathogenic fungi, acetyl coenzyme A derived from peroxisomal fatty acid ß-oxidation is used for the biosynthesis of melanin and glycerol (41, 82), which are important for both infectivity and development. In addition to utilizing material in the extracellular space in the phagosome, C. neoformans may also engage in active recycling of its own cytosolic components by promoting autophagy. This is indicated by the induction of two autophagy genes. Autophagy and proteasomes are the two major pathways for degrading cellular components. The microarray data did not reveal any induction of proteasome genes in internalized cells, suggesting that C. neoformans may utilize autophagy as the main route for degradation and recycling of cellular components when nutrients are limited.

Another common feature of the response to phagocytosis and the response to starvation is repression of the translation machinery. Our microarray analysis indicates that a large number of genes repressed during intracellular infection are involved in rRNA transcription and maturation, ribosome assembly and maintenance, and translation initiation and elongation. This is similar to the responses of C. albicans to macrophage ingestion, where a large number of genes involved in translation were repressed. However, many ribosomal proteins were down-regulated in C. albicans, while only a few were repressed in C. neoformans. This may reflect differing regulatory mechanisms for ribosomal functions.

We found that phagocytosis activates the mating type locus. The serotype D MAT locus is linked to virulence, as strains are more virulent than a strains (43). The C. neoformans MAT locus is unusually large (>100 kb) and encodes proteins involved in signal transduction (Ste20 and Ste11), polar growth and organelle transport (Myo2), and transcription (Ste12 and Sxi1) (32). Some genes in the MAT locus function in virulence, or have been hypothesized to do so, such as CAP1, STE12 (11), and STE20 (88). C. albicans cells undergo phenotypic switching and begin filamentous growth soon after internalization by macrophages (51). In comparison, C. neoformans does not undergo any phenotypic changes associated with mating or fruiting, despite the induction of the MAT locus. It will be of interest to establish if any aspect of the mating process, such as cell fusion or pheromone responses, occurs during intracellular infection.

In bacterial pathogens, genes related to pathogenesis are often localized in clusters on the chromosome, forming pathogenicity islands, from which genes are expressed in a highly concerted manner. In Aspergillus nidulans, 25 genes involved in the biosynthesis of sterigmatocystin are localized in a gene cluster and transcriptionally coregulated (7). Our data suggest that genes in the C. neoformans MAT locus may be similarly coregulated. This coordinated transcription could be a result of chromatin modification, such as histone acetylation. Coincidentally, we have found that histone acetyltransferase genes, such as Tra1 and Iki3, are up-regulated in phagocytosed C. neoformans cells.

The gene expression profile during intracellular growth of C. neoformans suggests a central role for the Gpa1-cAMP-PKA pathway. A majority of the genes whose expression is dependent on Gpa1 (64) were found to be up-regulated in phagocytosed C. neoformans cells. These genes include those that function in capsule and melanin production and also threonine synthesis. Consistent with the fact that capsule and melanin are essential for C. neoformans virulence, our data show that gpa1 and pka1 strains both have reduced growth in macrophages. In addition to controlling capsule formation and melanin production, Gpa1 and Pka1 also regulate mating, filamentous growth, and responses to glucose (37). The microarray data suggest that the Gpa1-Pka1 pathway coordinates transcription of genes involved in capsule and melanin production as well as responses to nutrient limitation during phagosome residence. The role of the Gpa1/cAMP/Pka1 pathway in mating may also contribute to the concerted induction of MAT locus genes upon phagocytosis.

	ACKNOWLEDGMENTS

 
We thank Arturo Casadevall for kindly providing the 18B7 monoclonal antibody against C. neoformans polysaccharide, Emily Wenink for technical assistance, Steve Giles for advice on macrophage cell culture, Alex Idnurm for assistance with Agrobacterium-mediated transformation of C. neoformans, Raphael Valdivia for advice on immunofluorescent staining, John Perfect and Andrew Alspaugh for critical reading of the manuscript, and Andrew Alspaugh for sharing unpublished data.

This work was supported by NIAID R01 grants AI50113 and AI50438 to J. Heitman and by NIAID P01 program project grant AI44975 to the Duke University Mycology Research Unit. Joseph Heitman is a Burroughs Wellcome Scholar in Molecular Pathogenic Mycology and an Investigator of the Howard Hughes Medical Institute.

	FOOTNOTES

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

Supplemental material for this article may be found at http://ec.asm.org/.

Present address: Department of Molecular, Cellular, and Developmental Biology, Yale University, New Haven, CT 06620.

Present address: Département Chimie-biologie, Université du Québec à Trois-Rivières, 3351 Boul. des Forges, Trois-Rivières, Québec G9A 5H7, Canada.

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