The entire DNA sequence of chromosome III of the yeast Saccharomyces cerevisiae has been determined. This is the first complete sequence analysis of an entire chromosome from any organism. The 315-kilobase sequence reveals 182 open reading frames for proteins longer than 100 amino acids, of which 37 correspond to known genes and 29 more show some similarity to sequences in databases. Of 55 new open reading frames analysed by gene disruption, three are essential genes; of 42 non-essential genes that were tested, 14 show some discernible effect on phenotype and the remaining 28 have no overt function.
A hyphally regulated gene (HYR1) from the dimorphic human pathogenic fungus Candida albicans was isolated and characterized. Northern (RNA) analyses showed that the HYR1 mRNA was induced specifically in response to hyphal development when morphogenesis was stimulated by serum addition and temperature elevation, increases in both culture pH and temperature, or N-acetylglucosamine addition. The HYR1 gene sequence revealed a 937-codon open reading frame capable of encoding a protein with an N-terminal signal sequence, a C-terminal glycosylphosphatidylinositol-anchoring domain, 17 potential N glycosylation sites, and a large domain rich in serine and threonine (51% of 230 residues). These features are observed in many yeast cell wall proteins, but no homologs are present in the databases. In addition, Hyr1p contained a second domain rich in glycine, serine, and asparagine (79% of 239 residues). The HYR1 locus in C. albicans CAI4 was disrupted by "Ura-blasting," but the resulting homozygous ⌬hyr1/⌬hyr1 null mutant displayed no obvious morphological phenotype. The growth rates for yeast cells and hyphae and the kinetics of germ tube formation in the null mutant were unaffected. Aberrant expression of HYR1 in yeast cells, when an ADH1-HYR1 fusion was used, did not stimulate hyphal formation in C. albicans or pseudohyphal growth in Saccharomyces cerevisiae. HYR1 appears to encode a nonessential component of the hyphal cell wall.Candida albicans is a major fungal pathogen in humans (44,45). Most frequently it causes superficial, irritating infections of the oral and urogenital tracts. However, serious deep-seated or systemic infections can develop, particularly in immunocompromised individuals.A number of factors are thought to promote the virulence of C. albicans. Many of these factors relate to properties of the C. albicans cell surface, for example, the ability to adhere to host tissues (7,8,27) and the immunomodulatory effects of various cell wall components (40,72). Another potential virulence factor is the ability to undergo a morphological transition from a budding yeast to a hyphal form, but this has not been established unambiguously (12,39,48,57,60,61). Changes in the C. albicans cell surface accompany the morphological transition (9,15,16,31,38,64), and hence morphogenesis is intimately linked with other virulence factors such as adherence. Processes germane to the regulation of the yeast-to-hypha transition are therefore important in establishing the role of this transition in the pathogenicity of C. albicans.Several factors influenced our experimental approach. First, classical genetic approaches were inappropriate because C. albicans is asexual and diploid (55). Second, nonstandard usage of the CTG codon in C. albicans (52,53,78) precluded the use of standard reporter genes, and until recently (62), no sensitive reporter genes for C. albicans were available. Hence, we attempted to identify C. albicans genes which are regulated specifically in response to morphogenesis. Using various approaches, we identifie...
In the dimorphic fungus Cad Chitin is a fibrous polymer off-1,4-N-acetylglucosamine that constitutes a major structural component of the cell wall of many species of fungi, including those species that are pathogenic in humans. Because chitin is not found in mammals and its biosynthesis is normally essential for the shape and viability of the fungal cell (1, 2), chitin synthesis is an attractive target for the design of antifungal drugs. The most common medical mycosis is caused by Candida albicans, which is a diploid organism with no sexual cycle. This fungus is capable ofdimorphic growth where growth can occur by unicellular budding or filamentous hyphal extension and branch formation (3). The hyphal cell wall has three to five times the chitin content of the yeast cell wall (4, 5) and the cells have up to 10 times the in vivo chitin synthase activity (6). Three genes encoding chitin synthases have been cloned and sequenced in C. albicans (7,8,37). Two encode chitin synthase zymogens (CHSI and CHS2), homologous to the CHS genes of Saccharomyces cerevisiae. The third chitin synthase gene, CHS3, is homologous to the S. cerevisiae CSD2 (9) gene (also called CALI) and is apparently the structural gene for an enzyme, which in S. cerevisiae, does not require proteolysis for its activity. Northern blot analysis of the C. albicans CHS genes showed that CHS2 mRNA levels were elevated in cells undergoing hyphal development, whereas the CHS1 mRNA was expressed only at low levels early in germ-tube formation (8).The role of each of the chitin synthase activities described in S. cerevisiae has been investigated by disrupting each of the relevant genes (for a review, see ref. 10). Gene disruptions are more difficult in C. albicans because the organism is constitutively diploid and because stable multiply marked strains are required for sequential gene disruptions. Sequential gene disruption of HEM3 of C. albicans has been achieved with two genetic markers (11), but host strains with sufficient markers for the disruption of more than one structural gene are not yet available. In this study, we employed the "ura-blaster" protocol originally described by Alani et al.(12) for use with S. cerevisiae, to disrupt all alleles of the hyphal-specific C. albicans CHS2 gene. This method allows the sequential disruption of target alleles. by using Ura3 auxotrophy as a single selectable marker. Because the selectable marker can be regenerated after the disruption of each allele, this method overcomes the need for multiply marked host strains and is, therefore, ideally suited for the analysis of families of genes such as the CHS genes in C. albicans. We show that the chs2 null mutant was still able to form germ tubes, albeit with a reduced chitin content compared with the isogenic wild-type parent. A prototrophic chs2-null mutant was still able to cause disease in normal and immunosuppressed mice and had a similar virulence to the parental CHS2 strain. A preliminary report of the construction of the Achs2::hisG null mutant has a...
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