Signaling through adenylyl cyclase is essential for hyphal growth and virulence in the pathogenic fungus Candida albicans.

The human fungal pathogen Candida albicans switches from a budding yeast form to a polarized hyphal form in response to various external signals. This morphogenetic switching has been implicated in the development of pathogenicity. We have cloned the CaCDC35 gene encoding C. albicans adenylyl cyclase by functional complementation of the conditional growth defect of Saccharomyces cerevisiae cells with mutations in Ras1p and Ras2p. It has previously been shown that these Ras homologues regulate adenylyl cyclase in yeast. The C. albicans adenylyl cyclase is highly homologous to other fungal adenylyl cyclases but has less sequence similarity with the mammalian enzymes. C. albicans cells deleted for both alleles of CaCDC35 had no detectable cAMP levels, suggesting that this gene encodes the only adenylyl cyclase in C. albicans. The homozygous mutant cells were viable but grew more slowly than wild-type cells and were unable to switch from the yeast to the hyphal form under all environmental conditions that we analyzed in vitro. Moreover, this morphogenetic switch was completely blocked in mutant cells undergoing phagocytosis by macrophages. However, morphogenetic switching was restored by exogenous cAMP. On the basis of epistasis experiments, we propose that CaCdc35p acts downstream of the Ras homologue CaRas1p. These epistasis experiments also suggest that the putative transcription factor Efg1p and components of the hyphal-inducing MAP kinase pathway depend on the function of CaCdc35p in their ability to induce morphogenetic switching. Homozygous cacdc35 Delta cells were unable to establish vaginal infection in a mucosal membrane mouse model and were avirulent in a mouse model for systemic infections. These findings suggest that fungal adenylyl cyclases and other regulators of the cAMP signaling pathway may be useful targets for antifungal drugs.

Ras links cellular morphogenesis to virulence by regulation of the MAP kinase and cAMP signalling pathways in the pathogenic fungus Candida albicans.

The pathogenic fungus Candida albicans is capable of responding to a wide variety of environmental cues with a morphological transition from a budding yeast to a polarized filamentous form. We demonstrate that the Ras homologue of C. albicans, CaRas1p, is required for this morphological transition and thereby contributes to the development of pathogenicity. However, CaRas1p is not required for cellular viability. Deletion of both alleles of the CaRAS1 gene caused in vitro defects in morphological transition that were reversed by either supplementing the growth media with cAMP or overexpressing components of the filament-inducing mitogen-activated protein (MAP) kinase cascade. The induction of filament-specific secreted aspartyl proteinases encoded by the SAP4-6 genes was blocked in the mutant cells. The defects in filament formation were also observed in situ after phagocytosis of C. albicans cells in a macrophage cell culture assay and, in vivo, after infection of kidneys in a mouse model for systemic candidiasis. In the macrophage assay, the mutant cells were less resistant to phagocytosis. Moreover, the defects in filament formation were associated with reduced virulence in the mouse model. These results indicate that, in response to environmental cues, CaRas1p is required for the regulation of both a MAP kinase signalling pathway and a cAMP signalling pathway. CaRas1p-dependent activation of these pathways contributes to the pathogenicity of C. albicans cells through the induction of polarized morphogenesis. These findings elucidate a new medically relevant role for Ras in cellular morphogenesis and virulence in an important human infectious disease.

Htm1p, a mannosidase-like protein, is involved in glycoprotein degradation in yeast.

Misfolded proteins are recognized in the endoplasmic reticulum (ER), transported back to the cytoplasm and degraded by the proteasome. Processing intermediates of N-linked oligosaccharides on incompletely folded glycoproteins have an important role in their folding/refolding, and also in their targeting to proteolytic degradation. In Saccharomyces cerevisiae, we have identified a gene coding for a non-essential protein that is homologous to mannosidase I (HTM1) and that is required for degradation of glycoproteins. Deletion of the HTM1 gene does not affect oligosaccharide trimming. However, deletion of HTM1 does reduce the rate of degradation of the mutant glycoproteins such as carboxypeptidase Y, ABC-transporter Pdr5-26p and oligosaccharyltransferase subunit Stt3-7p, but not of mutant Sec61-2p, a non-glycoprotein. Our results indicate that although Htm1p is not involved in processing of N-linked oligosaccharides, it is required for their proteolytic degradation. We propose that this mannosidase homolog is a lectin that recognizes Man8GlcNAc2 oligosaccharides that serve as signals in the degradation pathway.

Molecular cloning of the CRM1 gene from Candida albicans.

In a screen for Candida albicans genes capable of supressing a ste20Delta mutation in Saccharomyces cerevisiae, a homologue of the exportin-encoding gene CRM1 was isolated. The CaCRM1 gene codes for a protein of 1079 amino acids with a predicted molecular weight of 124 029 and isoelectric point of 5.04. Crm1p from C. albicans displays significant amino acid sequence homology with Crm1p from Saccharomyces cerevisiae (65% identity, 74% similarity), Schizosaccharomyces pombe (55% identity, 66% similarity), Caenorhabditis elegans (45% identity, 57% similarity), and Homo sapiens (48% identity, 59% similarity). Interestingly, CaCRM1 encodes a threonine rather than a cysteine at position 533 in the conserved central region, suggesting that CaCrm1p is leptomycin B-insensitive, like S. cerevisiae Crm1p. CaCRM1 on a high copy vector can complement a thermosensitive allele of CRM1 (xpo1-1) in S. cerevisiae, showing that CaCrm1p and S. cerevisiae Crm1p are functionally conserved. Southern blot analysis suggests that CaCRM1 is present at a single locus within the C. albicans genome. The nucleotide sequence of the CaCRM1 gene has been deposited at GenBank under Accession No. AF178855.

Cloning and characterization of mammalian UDP-glucose glycoprotein: glucosyltransferase and the development of a specific substrate for this enzyme.

The endoplasmic reticulum enzyme UDP-glucose glycoprotein:glucosyltransferase (UGGT) has the unique property of recognizing incompletely folded glycoproteins and, if they carry an N -linked Man(9)GlcNAc(2)oligosaccharide, of catalyzing the addition of a glucose residue from UDP-glucose. Using peptide sequence information, we have isolated the complete cDNA of rat liver UGGT and expressed it in insect cells. The cDNA specifies an open reading frame which codes for a protein of 1527 residues including an 18 amino acid signal peptide. The protein has a C-terminal tetrapeptide (HEEL) characteristic of endoplasmic reticulum luminal proteins. The purified recombinant enzyme shows the same preference for unfolded polypeptides with N -linked Man(9)GlcNAc(2)glycans as the enzyme purified from rat liver. A genetically engineered Saccharomyces cerevisiae strain capable of producing glyco-proteins with Man(9)GlcNAc(2)core oligosaccharides was constructed and secreted acid phosphatase (G0-AcP) was purified. G0-AcP was used as an acceptor glycoprotein for UGGT and found to be a better substrate than the previously used soybean agglutinin and thyroglobulin. Recombinant rat UGGT has a K (m) of 44 microM for UDP-glucose. A proteolytic fragment of UGGT was found to retain enzymatic activity thus localizing the catalytic site of the enzyme to the C-terminal 37 kDa of the protein. Using site-directed mutagenesis and photoaffinity labeling, we have identified residues D1334, D1336, Q1429, and N1433 to be necessary for the catalytic activity of the enzyme.

Molecular characterization of SIG1, a Saccharomyces cerevisiae gene involved in negative regulation of G-protein-mediated signal transduction.

Two recessive mutations in the Saccharomyces cerevisiae SIG1 (suppressor of inhibitory G-protein) gene have been identified by their ability to suppress the signalling defect of dominant-negative variants of the mating response G-protein beta-subunit. The mutations and deletion of SIG1 enhance the sensitivity of the cells to pheromone and stimulate the basal transcription of a mating specific gene, FUS1, suggesting that Sig1p plays a negatively regulatory role in G beta gamma-mediated signal transduction. An additional function of Sig1p in vegetatively growing cells is suggested by the finding that the mutations and deletion of SIG1 cause temperature-sensitive growth defects. The SIG1 gene encodes a protein with a molecular weight of 65 kDa that contains at the amino-terminus two zinc finger-like sequence motifs. Epistasis experiments localize the action of Sig1p within the pheromone signalling pathway at a position at or shortly after the G-protein. We propose that Sig1p represents a novel negative regulator of G beta gamma-mediated signal transduction.

Interactions among the subunits of the G protein involved in Saccharomyces cerevisiae mating.

The SCG1 (GPA1), STE4, and STE18 genes of Saccharomyces cerevisiae encode mating-pathway components whose amino acid sequences are similar to those of the alpha, beta, and gamma subunits, respectively, of mammalian G proteins. Genetic evidence suggests that the STE4 and STE18 gene products interact. The mating defects of a set of ste4 mutants were partially suppressed by the overexpression of STE18, and, moreover, a combination of partially defective ste4 and ste18 alleles created a totally sterile phenotype, whereas such synthetic sterility was not observed when the ste18 allele was combined with a weakly sterile ste11 allele. Others have provided genetic evidence consistent with an interaction between the SCG1 (GPA1) and STE4 gene products. We have examined the physical interactions of these subunits by using an in vivo protein association assay. The STE4 and STE18 gene products associated with each other, and this association was disrupted by a mutation in the STE4 gene product whose phenotype was partially suppressed by overexpression of STE18. The STE4 and SCG1 (GPA1) gene products also interacted in the assay, whereas we detected no association of the SCG1 (GPA1) and STE18 gene products.

Mutagenesis of Ste18, a putative G gamma subunit in the Saccharomyces cerevisiae pheromone response pathway.

The yeast STE18 gene product has sequence and functional similarity to the gamma subunits of G proteins. The cloned STE18 gene was subjected to a saturation mutagenesis using doped oligonucleotides. The populations of mutant genes were screened for two classes of STE18 mutations, those that allowed for increased mating of a strain containing a defective STE4 gene (compensators) and those that inhibited mating even in the presence of a functional STE18 gene (dominant negatives). Three amino acid substitutions that enhanced mating in a specific STE4 (G beta) point mutant background were identified. These compensatory mutations were allele specific and had no detectable phenotype of their own; they may define residues that mediate an association between the G beta and G gamma subunits or in the association of the G beta gamma subunit with other components of the signalling pathway. Several dominant negative mutations were also identified, including two C terminal truncations. These mutant proteins were unable to function in signal transduction by themselves, but they prevented signal transduction mediated by pheromone, as well as the constitutive signalling which is present in cells defective in the GPA1 (G alpha) gene. These mutant proteins may sequester G beta or some other component of the signalling machinery in a nonfunctional complex.

Dominant negative selection of heterologous genes: isolation of Candida albicans genes that interfere with Saccharomyces cerevisiae mating factor-induced cell cycle arrest.

We have used a genomic library of Candida albicans to transform Saccharomyces cerevisiae and screened for genes that act similarly to dominant negative mutations by interfering with pheromone-mediated cell cycle arrest. Six different plasmids were identified from 2000 transformants; four have been sequenced. One gene (CZF1) encodes a protein with structural motifs characteristic of a transcription factor. A second gene (CCN1) encodes a cyclin homologue, a third (CRL1) encodes a protein with sequence similarity to GTP-binding proteins of the RHO family, and a fourth (CEK1) encodes a putative kinase of the ERK family. Since CEK1 confers a phenotype similar to that of the structurally related S. cerevisiae gene KSS1 but cannot complement a KSS1 defect, it is evident that dominant negative selection can identify proteins that complementation screens would miss. Because dominant negative mutations exert their influence even in wild-type strain backgrounds, this approach should be a general method for the analysis of complex cellular processes in organisms not amenable to direct genetic analysis.

Screening and identification of a gene, PSE-1, that affects protein secretion in Saccharomyces cerevisiae.

Utilizing a screening method designed for the identification of genes involved with enhanced protein secretion in Saccharomyces cerevisiae we identified a gene, which we named PSE-1 (Protein Secretion Enhancer). Overexpression of PSE-1 in a multi-copy plasmid, as shown by Northern hybridization, gave a fourfold enhancement in total protein secretion. The repertoire of proteins that are found to be secreted in greater quantities include three known biologically active proteins: k1 killer toxin, alpha-factor, and acid phosphatase. The PSE-1 gene is located on chromosome XII of the yeast genome and codes for a hydrophobic protein containing 1089 amino acids. Haploid yeast cells that contained a LEU2 insertion mutation in PSE-1 grow very poorly, a phenotype similar to other conditional SEC mutants at restrictive temperature.

The yeast KEX-2-processing endoprotease is active in the Golgi apparatus of transfected NIH 3T3 fibroblasts.

Proteolytic processing of polyprotein precursors at pairs of basic amino acids is a prerequisite for the generation of bioactive peptide hormones. While the mammalian endoproteases responsible for these cleavages are yet to be identified, this function has been unequivocally assigned in yeast to the product of the KEX-2 gene. To study the molecular mechanisms involved in polyprotein processing, we have transfected the yeast KEX-2 gene into mouse NIH 3T3 fibroblasts and established a new cell line (called 2N-DK) where the KEX-2 endoprotease is permanently expressed. Immunofluorescence studies show that the KEX-2 enzyme is retained within the Golgi of the 2N-DK cells. The evidence for this cellular location is supported by measurement of intracellular and extracellular KEX-2 enzyme activity. In this permanently transfected cell line, KEX-2 activity is exclusively intracellular, in contrast to the situation previously described in transiently infected cell lines, where extracellular KEX-2 activity was detected. Furthermore, infection of 2N-DK cells with a recombinant retrovirus expressing a cDNA coding for porcine proopiomelanocortin (POMC) resulted in the synthesis of POMC and its efficient processing into beta-lipotropin and beta-endorphin, two of its physiologically authentic maturation products. These results suggest that in the fibroblast cell line 2N-DK, proteolytic processing of POMC by KEX-2 endoprotease occurs in the Golgi apparatus.

The STE4 and STE18 genes of yeast encode potential beta and gamma subunits of the mating factor receptor-coupled G protein.

The STE4 and STE18 genes are required for haploid yeast cell mating. Sequencing of the cloned genes revealed that the STE4 polypeptide shows extensive homology to the beta subunits of mammalian G proteins, while the STE18 polypeptide shows weak similarity to the gamma subunit of transducin. Null mutations in either gene can suppress the haploid-specific cell-cycle arrest caused by mutations in the SCG1 gene (previously shown to encode a protein with similarity to the alpha subunit of G proteins). We propose that the products of the STE4 and STE18 genes comprise the beta and gamma subunits of a G protein complex coupled to the mating pheromone receptors. The genetic data suggest pheromone-receptor binding leads to the dissociation of the alpha subunit from beta gamma (as shown for mammalian G proteins), and the free beta gamma element initiates the pheromone response.

Yeast KEX1 gene encodes a putative protease with a carboxypeptidase B-like function involved in killer toxin and alpha-factor precursor processing.

The yeast KEX1 gene product has homology to yeast carboxypeptidase Y. A mutant replacing serine at the putative active site of the KEX1 protein abolished activity in vivo. A probable site of processing by the KEX1 product is the C-terminus of the alpha-subunit of killer toxin, where toxin is followed in the precursor by 2 basic residues. Processing involves endoproteolysis following these basic residues and trimming of their C-terminal by a carboxypeptidase. Consistent with the KEX1 product being this carboxypeptidase is its role in alpha-factor pheromone production. In wild-type yeast, KEX1 is not essential for alpha-factor production, as the final pheromone repeat needs no C-terminal processing. However, in a mutant in which alpha-factor production requires a carboxypeptidase, pheromone production is KEX1-dependent.

The structure of HSAG-1, a middle repetitive genetic element which elicits a leukemia-related cellular surface antigen.

HSAG-1 is a cloned member of a heterogeneous middle repetitive family of genetic elements which is capable of eliciting a leukemia-related surface antigen detected with a monoclonal antibody after DNA transformation of mouse cells. HSAG-1 was originally isolated from a Chinese hamster-human leukemia hybrid cell gene library both by sib-selection for antigen producing activity and by hybridization with labelled human genomic human DNA. We show here that the human labelled site is at the right hand end of the insert, while the antigen-eliciting portion is included in a 1450 bp fragment at the left hand end of the insert. We also present the complete nucleotide sequence of the 3369 bp insert. The sequence contains 12 elements which bear a significant resemblance to accepted consensus sequences for Alu repetitive elements. The right hand end contains adjacent elements with close sequence similarity to portions of the human and hamster type I and type II Alu consensus sequences. All of the other Alu-related elements have diverged relative to the Alu consensus sequences by additions, long deletions and substitutions. The left hand portion of the insert which has the antigen-producing activity contains four of these diverged elements representing a relatively high proportion (26%) of the nucleotide sequence. The sequence is thus consistent with our previous observations of a repetitive family with biological function.