Abstract:
The present invention to an isolated DNA which codes for a gene essential for cell wall glucan synthesis of  Candida albicans , wherein the gene is referred to as CaKRE9, wherein the sequence of the DNA is as set forth in FIG.  1 . The present invention relates to antifungal in vitro and in vivo screening assays for identifying compounds which inhabit the synthesis, assembly and/or regulation of β1,6-glucan. There is also disclosed an in vitro method for the diagnosis of disease caused by fungal infection in a patient.

Description:
BACKGROUND OF THE INVENTION 
     (a) Field of the Invention 
     The invention relates to a novel gene, CaKRE9, isolated in the yeast pathogen,  Candida albicans , that is a functional homolog of the  S. cerevisiae  KRE9 gene and which is essential for cell wall glucan synthesis, and to novel antifungal screening assays. 
     (b) Description of Prior Art 
     Fungi constitute a vital part of our ecosystem but once they penetrate the human body and start spreading they cause infections or “mycosis” and they can pose a serious threat to human health. Fungal is infections have dramatically increased in the last 2 decades with the development of more sophisticated medical interventions and are becoming a significant cause of morbidity and mortality. Infections due to pathogenic fungi are frequently acquired by debilitated patients with depressed cell-mediated immunity such as those with human immunodeficiency virus (HIV) and now also constitute a common complication of many medical and surgical therapies. Risk factors that predispose individuals to the development of mycosis include neutropenia, use of immunosuppressive agents at the time of organ transplants, intensive chemotherapy and irradiation for hematopoietic malignancies or solid tumors, use of corticosteroids, extensive surgery and prosthetic devices, indwelling venous catheters, hyperalimentation and intravenous drug use, and when the delicate balance of the normal flora is altered through antimicrobial therapy. 
     The yeast genus Candida constitutes one of the major groups that cause systemic fungal infections and the five medically relevant species which are most often recovered from patients are  C. albicans, C. tropicalis, C. glabrata, C. parapsilosis  and  C. krusei.    
     Much of the structure of fungal and animal cells along with their physiology and metabolism is highly conserved. This conservation in cellular function has made it difficult to find agents that selectively discriminate between pathogenic fungi and their human hosts, in the way that antibiotics do between bacteria and man. Because of this, the common antifungal drugs, like amphotericin B and the azole-based compounds are often of limited efficacy and are frequently highly toxic. In spite of these drawbacks, early initiation of antifungal therapy is crucial in increasing the survival rate of patients with disseminated candidiasis. Moreover, resistance to antifungal drugs is becoming more and more prominent. For example, 6 years after the introduction of fluconazole, an alarming proportion of Candida strains isolated from infected patients have been found to be resistant to this drug and this is especially the case with vaginal infections. There is thus, a real and urgent need for specific antifungal drugs to treat mycosis. 
     The Fungal Cell Wall: a Resource for New Antifungal Targets 
     In recent years, we have focused our attention on the fungal extracellular matrix, where the cell wall constitutes an essential, fungi-specific organelle that is absent from human/mammalian cells, and hence offers an excellent potential target for specific antifungal antibiotics. The cell wall of fungi is essential not only in maintaining the osmotic integrity of the fungal cell but also in cell growth, division and morphology. 
     The cell wall contains a range of polysaccharide polymers, including chitin, β-glucans and O- and N-linked mannose sidechains of glycoproteins. β-glucans, homopolymers of glucose, are the main structural component of the yeast cell wall, and constitute up to 60% of the dry weight of the cell wall. Based on their chemical linkage, two different types of polymers can be found: β1,3-glucan and β1,6-glucan. The β1,3-glucan is the most abundant component of the cell wall and it contains on average 1500 glucose residues per molecule. It is mainly a linear molecule but contains some 1,6-linked branchpoints. The β1,6-glucan is a smaller and highly branched molecule comprised largely of 1,6-linked glucose residues with a small proportion of 1,3-linked residues. The average size of β1,6-glucan is approximately 400 residues per molecule. The β1,6-glucan polymer is essential for cell viability as it acts as the “glue” covalently linking glycoproteins and the cell wall polymers β1,3-glucan and chitin together in a crosslinked extracellular matrix. 
     It would be highly desirable to be provided with the identification and subsequent validation of new cell wall related targets that can be used in specific enzymatic and cellular assays leading to the discovery of new clinically useful antifungal compounds. 
     SUMMARY OF THE INVENTION 
     One aim of the present invention is to provide the identification and subsequent validation of a new target that can be used in specific enzymatic and cellular assays leading to the discovery of new clinically useful antifungal compounds. 
     Although a gene involved in the cellular growth of  S. cerevisiae  was identified, there are no certainties that there would be a homolog in  Candida albicans  or if present that it would have the same function. 
     In accordance with the present invention a gene was isolated, CaKRE9, in the yeast pathogen,  Candida albicans , that is a functional homolog of the  S. cerevisiae  KRE9 gene and which is essential for cell wall glucan synthesis. The gene is not found in humans and when it is inactivated in  C. albicans , the cell cannot survive when grown on glucose, thus, validating it as a wholly new target for antifungal drug discovery. 
     Using the gene of the present invention, we intend to utilize novel drug screening assays for which we possess all the genetic tools. 
     In accordance with the present invention there is provided an isolated DNA which codes for a gene essential for cell wall glucan synthesis of  Candida albicans , wherein the gene is referred to as CaKRE9, wherein the sequence of the DNA is as set forth in FIG.  1 . 
     In accordance with the present invention there is also provided an antifungal screening assay for identifying a compound which inhibits the synthesis, assembly and/or regulation of β1,6-glucan, which comprises the steps of: 
     a) synthesizing β1,6-glucans in vitro from activated sugar monomer/polymer and specific β1,6-glucan synthetic proteins; 
     b) subjecting step a) to a high throughput compound screen determining absence or presence of β1,6-glucan, wherein absence of β1,6-glucan is indicative of an antifungal compound. 
     In accordance with the present invention there is also provided an in vivo antifungal screening assay for identifying compounds which inhibit the synthesis, assembly and/or regulation of β1,6-glucan, which comprises the steps of: 
     a) separately cultivating a mutant yeast strain lacking one gene for synthesis of β1,6-glucans and a wild type yeast strain with activated sugar monomer/polymer UDP-glucose; 
     b) subjecting both yeast strains of step a) to the screened compound and determining if the compound selectively inhibits growth of wild type strain which is indicative of an antifungal compound. 
     In accordance with the present invention there is also provided an in vitro method for the diagnosis of diseases caused by fungal infection in a patient, which comprises the steps of: 
     a) obtaining a biological sample from the patient; 
     b) subjecting the sample to PCR using a primer pair specific for CaKRE9 gene, wherein a presence of the gene is indicative of the presence of fungal infection. 
     In accordance with the present invention, the gene is CaKRE9. 
     In accordance with the present invention there is also provided an in vitro method for the diagnosis of diseases caused by fungal infection in a patient, which comprises the steps of: 
     a) obtaining a biological sample from the patient; 
     b) subjecting the sample to an antibody specific for CaKre9p antigen, wherein a presence of the antigen is indicative of the presence of fungal infection. 
     In accordance with one embodiment of the present invention, the fungal infection may be caused by Candida. 
     In accordance with the present invention there is also provided the use of at least one of KRE9 and CaKre9 nucleic acid sequences and fragments thereof as a probe for the isolation of KRE9 homologs in all fungi. 
     For the purpose of the present invention the following terms are defined below. 
     The term a “mutant yeast strain” is intended to mean any yeast strain lacking one gene for synthesis of β1,6-glucan, such as KRE9 and homologs thereof. 
     The term a “wild type yeast strain” is intended to mean any yeast strain containing the KRE9 gene or a homolog thereof or a plasmid overexpressing the KRE9 gene or a homolog thereof. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 illustrates the complete nucleotide and predicted amino acid sequence of CaKRE9 (SEQ ID NO:1-2). 
     FIG. 2 illustrates the comparison of the sequence of Kre9p from  Candida albicans  (SEQ ID NO:2) and Kre9p (SEQ ID NO:3) and Knh1p (SEQ ID NO:4) from  Saccharomyces cerevisiae;    
     FIG. 3 illustrates the CaKRE9-dependent effect on the growth (A) and Killer phenotype (B) of kre9Δ null mutants; 
     FIG. 4A illustrates the schematic representation of the strategy for disruption of the  Candida albicans  KRE9 gene; 
     FIG. 4B illustrates the Southern blot verification of the correct integration of the hisG-URA3-hisG disruption module into the CaKRE9 gene and proper CaURA3 excision after 5-FOA treatment; and 
     FIG. 5 illustrates the quantification of β1,6-Glucan levels of different  Candida albicans  strains. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     In accordance with the present invention, the synthesis and the assembly of the cell wall polymer β1,6 glucan which plays a central role in the organization of the yeast cell wall and which is indispensable for cell viability were extensively studied. Although the biochemistry of β1,6 glucosylation is incompletely understood, a genetic analysis of genes required for 1,6 synthesis has been performed in  Saccharomyces cerevisiae , and has identified many genes required for this process. These encode products acting in the endoplasmic reticulum, the Golgi complex and at the cell surface. 
     In accordance with the present invention a novel gene was identified, KRE9, whose product is required for the synthesis of β1,6 linked glucans (Brown J L. et al. (1993)  Molecular  &amp;  Cellular Biology  13:6346-6356). KRE9 appears to be a fungal specific gene, as it is absent from animal lineages based on data base searches of the  Caernorhabditis elegans , mouse and  Homo sapiens  genomes and it also appears to be absent from the plant, bacterial and archaebacterial lineages. 
     KRE9 and its Homolog KNH1 
     KRE9 encodes a 30-kDa secretory pathway protein involved in the synthesis of cell wall β1,6 glucan (Brown J L. et al. (1993)  Molecular &amp; Cellular Biology  13:6346-6356). Disruption of KRE9 in  S. cerevisiae  leads to serious growth impairment and an altered cell wall containing less than 20% of the wild-type amount of β1,6 glucan. Analysis of the glucan material remaining in a kre9 null mutant indicated a polymer with a reduced average molecular mass (Brown J L. et al. (1993)  Molecular  &amp;  Cellular Biology  13:6346-6356). The kre9 null mutants also displayed several additional cell-wall-related phenotypes, including an aberrant multiple budded morphology, a mating defect, and a failure to form projections in the presence of alpha-factor. Antibodies generated against Kre9p detected an O-glycoprotein of approximately 55 to 60 kDa found in the extracellular medium of a strain overproducing Kre9p, indicating it is normally localized at the cell surface. 
     In the yeast genome a KRE9 homolog was recently found, KNH1, whose product, Knh1p, shares 46% overall identity with Kre9p (Dijkgraaf G J. et al. (1996)  Yeast  12:683-692). Disruption of the KNH1 locus has no effect on growth, killer toxin sensitivity or β1,6-glucan levels. Overexpression of KNH1 suppressed the severe growth defect of a kre9 null mutant and restored the level of alkali-insoluble β1,6-glucan to almost wild type levels. When overproduced, Knh1p, like Kre9p, can be found in the extracellular culture medium as an O-glycoprotein, and is likely also a cell surface protein under conditions of normal expression. The disruption of both KNH1 and KRE9 is lethal. Transcription of KNH1 is carbon-source and KPE9 dependent. The severe growth defect of a kre9Δ null mutant observed on glucose can be partially restored when galactose becomes the major carbon source. Transcription of the KNH1 gene is normally low in wild type cells grown on glucose but increases approximately five fold in galactose grown cells, where it partially compensates for the loss of Kre9p and allows partial suppression of the slow growth phenotype of kre9Δ cells. These results 25 suggest that KRE9 and KNH1 are specialized in vivo to function under different environmental conditions (Dijkgraaf G J. et al. (1996)  Yeast  12:683-692). 
     The essential nature of the KRE9/KNH1 gene pair, and the putative extracellular location of their gene products make these proteins a new and potentially valuable target for antifungal compounds that need not enter the fungal cell. 
     β1,6-glucan in Pathogenic Fungi 
     The yeast  Saccharomyces cerevisiae , although not a pathogen, is a proven model organism for pathogenic fungi as it is closely related taxonomically to opportunistic pathogens like the dimorphic yeast  Candida albicans . The composition of the cell wall of  C. albicans  resembles that of  S. cerevisiae  in containing β1,3- and β1,6-glucans, chitin, and mannoproteins (Mio, T. et al.,  J. Bacteriol . 179:2363-2372 Analyses of the  Candida albicans  genes involved in extracellular matrix assembly are limited but indicate that the proteins responsible for synthesis of the polymers often resemble those found in the more extensively studied yeast,  Saccharomnyces cerevisiae . The β1,6 glucosylation of proteins appears to be widespread among fungal groups, and the polymer varies in abundance between fungal species. In  C. albicans  this polymer is particularly abundant, comprising approximately half of the alkali insoluble glucan. Comparative studies with  C. albicans  have so far identified three genes involved in β1,6 =glucosylation based on their relatedness to those in  S. cerevisiae , indicating that synthesis of this polymer is functionally conserved and essential for the growth of  Candida albicans.    
     Isolation of the CaKRE9 Gene 
     In order to validate KRE9 as a possible new antifungal target, we have examined if genes related to  S. cerevisiae  KRE9 were present in  C. albicans . Using complementation of the  S. cerevisiae  kre9 mutant phenotype as a screen, we have isolated a  C. albicans  gene that encodes a protein similar to the  S. cerevisiae  KRE9 gene product. 
     CaKRE9 was identified by a plasmid shuffle approach as a gene being able to restore the slow growth of a  Saccharomyces cerevisiae  kre9::HIS3 disrupted strain. A diploid strain heterozygous for a kre9::HIS3 deletion was transformed with a centromeric LYS2-based pRS317 vector containing a wild type copy of the  S. cerevisiae  KRE9 gene. Transformants were selected by prototrophic growth on minimal media, sporulated and a haploid kre9::HIS3 strain containing a plasmid-based copy of KRE9 was obtained by tetrad dissection and spore progeny analysis. This strain was shown to possess wild type growth and killer toxin sensitivity and was subsequently transformed with a  Candida albicans  genomic library contained within the multicopy YEp352-plasmid harboring the URA3 gene as a selectable marker. In order to screen for plasmids that could restore growth to a kre9::HIS3 mutant, about 20,000 His3 +  Lys2 +  Ura3 +  cells were replica plated on minimal medium containing α-aminoadipate as a primary nitrogen source to select for cells that have lost the LYS2 plasmid-based copy of KRE9 but are still able to grow, indicating that a copy of the complementing CaKRE9 gene could be present in such growing cells. These cells were further tested for loss of the pRS317-KRE9 plasmid by failure to grow on medium lacking lysine. YEp352-based  Candida albicans  genomic DNA was recovered from cells that grew in the presence of lysine but did not grow in its absence. Upon retransformation in yeast, only 2 different genomic inserts were able to partially restore growth of the kre9::HIS3 haploid strain. DNA from both inserts were sequenced. 
     The CaKRE9 gene was contained in only one of the  C. albicans  clones. Complete sequencing of the 8-kb fragment containing the CaKRE9 gene revealed an open reading frame of 813 bp encoding a 29-kDA secretory protein of 271 amino acid residues (see FIG.  1 ). As is the case with Kre9p and Knh1p (Brown J L. et al. (1993)  Molecular  &amp;  Cellular Biology  13:6346-6356; Dijkgraaf G J. et al. (1996)  Yeast  12:683-692), the hydrophobic N-terminal region of CaKre9p comprises an eukaryotic signal sequence, with the most likely cleavage site occurring between amino acid residues 21 and 22. CaKre9p shares 43% overall identity with Kre9p and 32% with Knh1p (see FIG.  2 ). The amino acid residues are shown in single-letter amino acid code. Sequences were aligned with gaps to maximize homology. Dots represent a perfect match between all sequences while a vertical slash indicates conservative substitution at a given position. The most conserved region between the 3 proteins encompasses a large part of the central region and most of the C-terminal portion, with the N-terminal part being largely unique to each protein. Kre9p, Knh1p and CaKre9p share a high proportion of serine and threonine residues (26%), potential sites for O-glycosylation, a modification known to occur on Kre9p and Knh1p, and characteristic of many yeast cell surface proteins. In addition, all 3 proteins have lysine and arginine rich C-termini and lack potential N-linked glycosylation sites. 
     The functional capacity of CaKre9p was assessed in  Saccharomyces cerevisiae  by measuring its ability to restore the growth and killer toxin sensitivity of a kre9 null mutant. Firstly, the YEp352-based  Candida albicans  genomic DNA containing the CaKRE9 gene was transformed into a diploid strain of  S. cerevisiae  heterozygous for a kre9::HIS3 deletion, sporulated and a haploid kre9::HIS3 strain containing a plasmid-based copy of CaKRE9 was obtained from spore progeny following tetrad dissection. As can be seen in FIG. 3A, a strain harboring the CaKRE9 gene grows at a slower rate than a wild type strain or the mutant strain harboring a copy of KRE9 but significantly faster than the kre9 null mutant which has a severe growth phenotype. Secondly, the haploid kre9 strain carrying the CaKRE9 was submitted to a killer toxin sensitivity assay (FIG.  3 B). K1 killer yeast strains secrete a small poreforming toxin that requires an intact cell wall receptor for function. KRE9 null mutations lead to a considerable decrease in the level of β1,6-glucan disrupting the toxin receptor (Brown J L. et al. (1993)  Molecular &amp; Cellular Biology  13:6346-6356), leading to killer resistance and showing no killing zone in the assay. The killer phenotype of the kre9 mutant allowed a test of possible suppression by CaKre9p. Overexpression of CaKRE9 in the  S. cerevisiae  haploid strain carrying a disrupted copy of KRE9 partially suppressed the killer resistance phenotype (FIG.  3 B). 
     These results imply that Kre9p and CaKre9p both play very similar roles in β1,6-glucan assembly in  S. cerevisiae  and  C. albicans.    
     Disruption of the CaKRE9 Gene 
     Experimental Strategy: 
     The gene disruption was performed by the URA blaster protocol using the hisG-CaURA3-hisG module. A 1.6-kb DraI DNA fragment containing the CaKRE9 gene was subcloned from the original insert into the SmaI site and the blunted XbaI site (treated with the Klenow fragment of DNA polymerase I) of YEp352 (see FIG. 4A) Extracted genomic DNAs are from: CAI4 wild type cells (lane 1), CaKRE9/Cakre9::hisG-URA-hisG heterozygous mutant (lane 2), CaKRE9/Cakre9::hisG heterozygous mutant obtained after 5-FOA treatment (lane 3) and Cakre9/Cakre9::hisG-URA-hisG homozygous null mutant which is able to grow only when galactose is used as the sole source of carbon. 
     The CaKRE9 gene was disrupted by deleting a 485 bp BstxI-BamHI fragment of the open reading frame and replacing it by a 4.0 kb BglII/BamHI fragment carrying the hisG-URA3-hisG module from plasmid pCUB-6 (see FIG.  4 A). The sticky ends were enzymatically treated to accommodate the ligation. This disruption plasmid was digested by HindIII and KpnI, precipitated with ethanol and sodium acetate and 100 μg of the 5.2 kb-disruption fragment was transformed into CAI4  Candida albicans  cells by the lithium acetate method. 
     Putative heterozygous disruptants were selected on minimal medium carrying glucose or galactose as carbon sources but lacking uracil. In preparation for a second round of gene disruption, the CaURA gene was excised using a 5-FOA selection. The second round of transformation was performed in the same way as the primary one. 
     The accurate integration of the hisG-CaURA3-hisG cassette into the CaKRE9 gene and its excision from genomic DNA was verified by Southern hybridization using 3 different probes: 
     (1) a 405-bp fragment from  C. albicans  genomic DNA containing coding and 31 flanking sequences of CaKRE9; 
     (2) a 783 bp DNA fragment obtained by PCR and covering the entire CaURA3 coding region; and 
     (3) a 898 bp fragment amplified by PCR that encompasses the whole of the  Salmonella typhimurium  hisG gene (see FIG.  4 B). 
     All genomic DNAs were digested with the BamHI and SalI restriction enzymes. 
     Results: 
     In the first round of transformation where transformants were selected on glucose containing plates, the Southern blotting results revealed that the hisG-CaURA3-hisG module correctly integrated into the  Candida albicans  KRE9 gene (see FIG.  4 ). When genomic DNA of putative heterozygous CaKRE9 disruptions was digested with the SalI and BamHI restriction enzymes and probed with the CaKRE9 405-bp SalI-BstXI DNA fragment along with the hisG and the CaURA3 probes, 2 expected bands could be detected (see FIG. 4B, lane 2, for representative result): a 773 bp band corresponding to the wild type gene that could only be detected by the CaKRE9 probe and a 4318 bp diagnostic band, revealed by all 3 probes, indicating successful disruption of one copy of the CaKRE9 gene. After removal of the CaURA3 using 5-FOA, the 773 bp wild type band could still be visualized but the disrupted band from which the CaURA3 was excised shifted to an anticipated 1428 bp when probed with the CaKRE9 and hisG probes but not with the CaURA3 probe (see FIG. 4B, lane 3). 
     In order to assess if the CaKRE9 gene is essential in  C. albicans , a second round of disruptions was undertaken in the heterozygous strain where the CaURA3 gene was eliminated. However, in view of the nature of the carbon source regulation of the KRE9/KNH1 pair in  S. cerevisiae , the second round of transformation was executed using both glucose and galactose as carbon sources. 32 Ura +  colonies from the glucose plated transformation were analyzed by Southern blot hybridization using the 3 different probes and only yeast cells heterozygous at the CaKRE9 locus could be found. The absence of the expected homozygous double disruption among the transformants is consistent with the fact that CaKRE9 is an essential gene in  C. albicans  when glucose is the sole carbon source. Demonstration of CaKRE9 as an essential gene under these conditions validates the CaKRE9 gene product as a therapeutic target in  Candida albicans.    
     The population of transformants growing on galactose was heterogeneous with large and small sized colonies occurring. As a first assessment of a possible carbon source dependence, a total of 26 colonies of different sizes were plated from galactose to glucose. Among the smaller ones, 8 did not grow on glucose, suggesting that they could be homozygous disruptants. Southern blot hybridizations were performed on these 8 transformants and they were shown to be homozygous disruptants for the CaKRE9 locus: one copy corresponded to the disrupted gene in which CaURA3 has been removed (1428 bp) and the second one represented the inactivation of the remaining wild type copy by the hisG-caURA3-hisG module (4318 bp; FIG. 4B, lane 4). Thus a homozygous disruption of kre9 in  C. albicans  is lethal when glucose constitutes the exclusive carbon source. Further, it should be appreciated that glucose is the main source of carbon of human beings. 
     β1,6-Glucan Analysis of  C. albicans  CaKRE9 Mutants 
     Experimental Strategy: 
     Yeast total-cell protein extracts were prepared from exponentially growing cultures by cell lysis with glass beads. Cellular extracts were standardized for total cellular protein and equivalent amounts of protein were alkali extracted (0.75M NaOH final 1 h, 75° C.). The alkali soluble fractions were then spotted onto nitrocellulose and immunoblots were carried out. Briefly, blots were treated in TBST buffer (10 mM Tris pH 8.0, 150 mM NaCl, 0.05% Tween™ 20, containing 5% non fat dried milk powder) and subsequently incubated with 25 affinity purified rabbit anti-β1,6-glucans antibodies (prepared as described Montijn, R. C. et al. (1994)  J. Biol. Chem . 296:19338-19342) in the same buffer. After antibody binding, membranes were washed in TBST and a second antibody directed against rabbit immunoglobulins and conjugated with horseradish peroxidase, was then added. The blots were again washed and whole cell β1,6 glucans detected using an enhanced chemiluminescence procedure. 
     Results 
     In order to directly measure the effect of inactivating CaKRE9 on β1,6-glucan synthesis and assembly, a specific rabbit anti-β1,6-glucan antiserum was raised against BSA-coupled pustulan (a commercially available β1,6 glucan), affinity purified, and used to detect antigen-antibody complexes by Western blotting of total cell protein extracts of different yeast strains grown on galactose. As expected, wild type cells yielded a strong β1,6-glucan signal (see FIG.  5 ). The affinity purified Ab detected about a quarter of the glucan in the  C. albicans  heterozygous Δcakre9 whereas no β1,6-glucan could be detected from a  C. albicans  homozygous Δcakre9 disruptant grown on galactose (FIG.  5 ). 
     Discussion 
     The essential nature of the KRE9 gene in  C. albicans , and the possible extracellular location of its gene product make this protein a new and potentially valuable target for antifungal compounds that need not enter the fungal cell. The precise role of Kre9p in β-glucan synthesis remains to be precisely determined but does not prevent the establishment of a antifungal drug screening assay. 
     The present invention will be more readily understood by referring to the following examples which are given to illustrate the invention rather than to limit its scope. 
     EXAMPLE I 
     In Vitro Screening Method for Specific Antifungal Agents (Enzymatic-Based Assay) 
     The primary objective is to identify novel compounds inhibiting the synthesis, assembly and/or regulation of β1,6-glucans. This enzymatic assay would utilize some of the gene products (KRE) involved in β1,6-glucan synthesis, including using an in vitro assay for CaKre9p. Using specific reagents such as an antibody to β1,6-glucan, and a specific glucanase for the polymer, the approach is to synthesize the polymer in vitro from the activated sugar monomer UDP-glucose. This task can be accomplished by existing methodologies such as the production of large amounts of each protein and by the availability of genetic tools, such as the ability to delete or overexpress gene products that are involved in synthesis of this and the other major polymers. Once the assay has been established it will permit the screening of possible compounds that inhibit steps in the synthesis of this essential polymer. When such inhibitors will be found, they will then be evaluated as candidates for specific antifungal agents. 
     The effects of such compounds on β1,6-glucan levels may be directly measured using the anti-β1,6-glucan antibody. This approach can be used on all type of fungi and can be adapted to a high throughput immunoassay to find β1,6-glucan inhibitors. 
     EXAMPLE II 
     In Vivo Screening Method for Specific Antifungal Agents (Cellular-Based Assay) 
     Yeast strains possessing or lacking β1,6-glucans permit a differential screen for compounds inhibiting synthesis of this cell wall polymer. Specifically, an antifungal drug screen can be devised based on a wholecell assay in which the fungal-specific CaKre9p would be targeted. 
     The strains that may be used in accordance with the present invention include, without limitation, any yeast strain mutant for CaKRE9 and homologs thereof disrupted strain, conditional mutants, overexpression strains and suppressed disrupted strains. 
     Compounds can be tested for their ability to inhibit growth or kill a wild type  C. albicans  strain while having no effect on a Cakre9 suppressor strain. In addition, compounds leading to hypersensitivity in a CaKRE9 deletion will also be of value as candidate antifungal drugs. The finding of new antifungal compounds will be greatly simplified by these types of screens. The direct scoring on cells of the level of efficacy of a particular compound (natural product extracts, pure chemicals . . . ) alleviates the costly and labor intensive establishment of an in vitro enzymatic assay. The availability of genetic tools, such as the ability to delete or overexpress gene products that are involved in synthesis of this and the other major polymers will permit the establishment of this new screening method. When such inhibitors will be found, they will then be evaluated as candidates for specific antifungal agents. 
     EXAMPLE III 
     The use of CaKRE9 in the Diagnosis of Fungal Infection 
     Detection Based on PCR 
     Candida spp. and other pathogenic fungi are traditionally identified by morphological and metabolic characteristics and often this require days to weeks to isolate on culture from a patient&#39;s sample. Identification is time-consuming and often unreliable and this impedes the selection of antimicrobial agents in cases in which species identification of the organism is necessary. Moreover, culture-based diagnostic methods are not within the scope of many routine microbiology laboratories and are frequently limited to detection of pathogenic organisms in patients at an advanced stage of disease or even at autopsy. The detection of disseminated Candida mycosis is an area where there is an urgency for new sophisticated techniques of identification. Polymerase Chain Reaction (PCR) based tests to establish the presence of a fungal infection are at this point highly desirable for laboratory diagnosis and management of patients with serious fungal diseases. The CaKRE9 gene is fungi specific and could be used to develop new diagnostic procedures of mycosis based on the PCR. Such diagnostic tests would be predicted to be highly sensitive and specific. Ultimately, simple kits permitting the diagnosis of fungal infections will be sold to hospitals and specialized clinics. Current trends in the hospital microbiology laboratories indicate that there will be a considerable future increase in use of the PCR as a diagnostic tool. 
     Detection Based on Anti-CaKre9p Antibodies 
     CaKre9p is thought to be localized at the cell surface and as such could be detected as a circulating candidal antigen by an enzyme-linked immunoabsorbent assay (ELISA) detection kit based on antibodies directed against CaKre9p. Antibodies directed against CaKre9p could allow levels of specificity and sensitivity high enough to permit commercialization of a diagnostic kit. 
     EXAMPLE IV 
     The use of Kre9p in all Fungi 
     Isolation and use of functional homologs of KRE9/CaKRE9 from all fungi. Most fungi have β1,6-glucans and likely have KRE9 homologs in their genome. The kre9 mutant can allow isolation of similar genes by functional complementation from other pathogenic fungi as what was done to isolate CaKRE9. KRE9 could also serve as a probe to isolate by homology KRE9 homologs from other yeasts. In addition, Kre9p allows isolation of homologs in other species by the techniques of reverse genetics where antibodies raised against Kre9p could be used to screen expression libraries of pathogenic fungi for expression of KRE9 homologs that would immunologically cross react with antibodies raised against  S. cerevisiae  KRE9 and  C. albicans  CaKRE9. These putative KRE9 homologs in these pathogenic fungi could serve as targets for potential new antifungals. 
     Other methods are used to find proteins which interact with Kre9p and homologs thereof, such as two-hybrid, co-immunoprecipitation and chromatography using an activated Kre9p matrix. 
     While the invention has been described in connection with specific embodiments thereof, it will be understood that it is capable of further modifications and this application is intended to cover any variations, uses, or adaptations of the invention following, in general, the principles of the invention and including such departures from the present disclosure as come within known or customary practice within the art to which the invention pertains and as may be applied to the essential features hereinbefore set forth, and as follows in the scope of the appended claims. 
     
       
         
           
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             DNA 
             Candida albicans CaKRE9 
           
            1
atgagacaat ttcaaatcat attaatttcc cttgttgttt ccataataag atgtgttgtt     60
gcagatgttg acatcacatc accaaagagt ggagaaactt tttctggtag ttctggatca    120
gcaagtatca agattacctg ggatgattca gacgattcag actcaccgaa atctttggat    180
aatgccaaag ggtacacaat ttctttatgt actggaccta cttcagatgg ggatatccag    240
tgtttggatc cattagtcaa gaacgaagct attgcaggta aatctaaaac agtttctatt    300
ccccagaact cagtacctaa tggttattac tatttccaaa tttacgttac tttcactaat    360
ggaggtacca ctattcatta ttcaccacgt ttcaaattga ctggtatgtc tggtccaact    420
gccactttag atgtcaccga aacaggatcg gtgccagcgg atcaagcttc aggatttgat    480
actgcaacta ctgccgactc caaatctttc acagttccat ataccctaca aacagggaag    540
accagatacg caccaatgca aatgcaacca ggtaccaaag tgactgctac aacctggagt    600
atgaagttcc caactagtgc tgttacttac tactcaacaa aggctggcac accaaatgtg    660
gcctctacta ttaccccagg ttggagttat actgctgaat ctgccgttaa ctatgctagt    720
gttgctccat atccaacata ctggtatcct gccagtgaac gagtgagtaa ggctacaatt    780
agtgctgcta caaagagaag aagatggttg gattga                              816
 
           
             2 
             271 
             PRT 
             Candida albicans CaKRE9 
           
            2
Met Arg Gln Phe Gln Ile Ile Leu Ile Ser Leu Val Val Ser Ile Ile
 1               5                  10                  15
Arg Cys Val Val Ala Asp Val Asp Ile Thr Ser Pro Lys Ser Gly Glu
            20                  25                  30
Thr Phe Ser Gly Ser Ser Gly Ser Ala Ser Ile Lys Ile Thr Trp Asp
        35                  40                  45
Asp Ser Asp Asp Ser Asp Ser Pro Lys Ser Leu Asp Asn Ala Lys Gly
    50                  55                  60
Tyr Thr Ile Ser Leu Cys Thr Gly Pro Thr Ser Asp Gly Asp Ile Gln
65                  70                  75                  80
Cys Leu Asp Pro Leu Val Lys Asn Glu Ala Ile Ala Gly Lys Ser Lys
                85                  90                  95
Thr Val Ser Ile Pro Gln Asn Ser Val Pro Asn Gly Tyr Tyr Tyr Phe
            100                 105                 110
Gln Ile Tyr Val Thr Phe Thr Asn Gly Gly Thr Thr Ile His Tyr Ser
        115                 120                 125
Pro Arg Phe Lys Leu Thr Gly Met Ser Gly Pro Thr Ala Thr Leu Asp
    130                 135                 140
Val Thr Glu Thr Gly Ser Val Pro Ala Asp Gln Ala Ser Gly Phe Asp
145                 150                 155                 160
Thr Ala Thr Thr Ala Asp Ser Lys Ser Phe Thr Val Pro Tyr Thr Leu
                165                 170                 175
Gln Thr Gly Lys Thr Arg Tyr Ala Pro Met Gln Met Gln Pro Gly Thr
            180                 185                 190
Lys Val Thr Ala Thr Thr Trp Ser Met Lys Phe Pro Thr Ser Ala Val
        195                 200                 205
Thr Tyr Tyr Ser Thr Lys Ala Gly Thr Pro Asn Val Ala Ser Thr Ile
    210                 215                 220
Thr Pro Gly Trp Ser Tyr Thr Ala Glu Ser Ala Val Asn Tyr Ala Ser
225                 230                 235                 240
Val Ala Pro Tyr Pro Thr Tyr Trp Tyr Pro Ala Ser Glu Arg Val Ser
                245                 250                 255
Lys Ala Thr Ile Ser Ala Ala Thr Lys Arg Arg Arg Trp Leu Asp
            260                 265                 270
 
           
             3 
             276 
             PRT 
             Saccharomyces cerevisiae Kre9P 
           
            3
Met Arg Leu Gln Arg Asn Ser Ile Ile Cys Ala Leu Val Phe Leu Val
 1               5                  10                  15
Ser Phe Val Leu Gly Asp Val Asn Ile Val Ser Pro Ser Ser Lys Ala
            20                  25                  30
Thr Phe Ser Pro Ser Gly Gly Thr Val Ser Val Pro Val Glu Trp Met
        35                  40                  45
Asp Asn Gly Ala Tyr Pro Ser Leu Ser Lys Ile Ser Thr Phe Thr Phe
    50                  55                  60
Ser Leu Cys Thr Gly Pro Asn Asn Asn Ile Asp Cys Val Ala Val Leu
65                  70                  75                  80
Ala Ser Lys Ile Thr Pro Ser Glu Leu Thr Gln Asp Asp Lys Val Tyr
                85                  90                  95
Ser Tyr Thr Ala Glu Phe Ala Ser Thr Leu Thr Gly Asn Gly Gln Tyr
            100                 105                 110
Tyr Ile Gln Val Phe Ala Gln Val Asp Gly Gln Gly Tyr Thr Ile His
        115                 120                 125
Tyr Thr Pro Arg Phe Gln Leu Thr Ser Met Gly Gly Val Thr Ala Tyr
    130                 135                 140
Thr Tyr Ser Ala Thr Thr Glu Pro Thr Pro Gln Thr Ser Ile Gln Thr
145                 150                 155                 160
Thr Thr Thr Asn Asn Ala Gln Ala Thr Thr Ile Asp Ser Arg Ser Phe
                165                 170                 175
Thr Val Pro Tyr Thr Lys Gln Thr Gly Thr Ser Arg Phe Ala Pro Met
            180                 185                 190
Gln Met Gln Pro Asn Thr Lys Val Thr Ala Thr Thr Trp Thr Arg Lys
        195                 200                 205
Phe Ala Thr Ser Ala Val Thr Tyr Tyr Ser Thr Phe Gly Ser Leu Pro
    210                 215                 220
Glu Gln Ala Thr Thr Ile Thr Pro Gly Trp Ser Tyr Thr Ile Ser Ser
225                 230                 235                 240
Gly Val Asn Tyr Ala Thr Pro Ala Ser Met Pro Ser Asp Asn Gly Gly
                245                 250                 255
Trp Tyr Lys Pro Ser Lys Arg Leu Ser Leu Ser Ala Arg Lys Ile Asn
            260                 265                 270
Met Arg Lys Val
        275
 
           
             4 
             267 
             PRT 
             Saccharamyces cerevisiae Knh1p 
           
            4
Met Leu Ile Val Leu Phe Leu Thr Leu Phe Cys Ser Val Val Phe Arg
 1               5                  10                  15
Thr Ala Tyr Cys Asp Val Ala Ile Val Ala Pro Glu Pro Asn Ser Val
            20                  25                  30
Tyr Asp Leu Ser Gly Thr Ser Gln Ala Val Val Lys Val Lys Trp Met
        35                  40                  45
His Thr Asp Asn Thr Pro Gln Glu Lys Asp Phe Val Arg Tyr Thr Phe
    50                  55                  60
Thr Leu Cys Ser Gly Thr Asn Ala Met Ile Glu Ala Met Ala Thr Leu
65                  70                  75                  80
Gln Thr Leu Ser Ala Ser Asp Leu Thr Asp Asn Glu Phe Asn Ala Ile
                85                  90                  95
Ile Glu Asn Thr Val Gly Thr Asp Gly Val Tyr Phe Ile Gln Val Phe
            100                 105                 110
Ala Gln Thr Ala Ile Gly Tyr Thr Ile His Tyr Thr Asn Arg Phe Lys
        115                 120                 125
Leu Lys Gly Met Ile Gly Thr Lys Ala Ala Asn Pro Ser Met Ile Thr
    130                 135                 140
Ile Ala Pro Glu Ala Gln Thr Arg Ile Thr Thr Gly Asp Val Gly Ala
145                 150                 155                 160
Thr Ile Asp Ser Lys Ser Phe Thr Val Pro Tyr Asn Leu Gln Thr Gly
                165                 170                 175
Val Val Lys Tyr Ala Pro Met Gln Leu Gln Pro Ala Thr Lys Val Thr
            180                 185                 190
Ala Lys Thr Trp Lys Arg Lys Tyr Ala Thr Ser Glu Val Thr Tyr Tyr
        195                 200                 205
Tyr Thr Leu Arg Asn Ser Val Asp Gln His Thr Thr Val Thr Pro Gly
    210                 215                 220
Trp Ser Tyr Ile Ile Thr Ala Asp Ser Asn Tyr Ala Thr Ala Pro Met
225                 230                 235                 240
Pro Ala Asp Asn Gly Gly Trp Tyr Asn Pro Arg Lys Arg Leu Ser Leu
                245                 250                 255
Thr Ala Arg Lys Val Asn Ala Leu Arg His Arg
            260                 265