Chitin synthase 2 is essential for septum formation and cell division in Saccharomyces cerevisiae

A Bni4-Glc7 phosphatase complex that recruits chitin synthase to the site of bud emergence

Bni4 is a scaffold protein in the yeast Saccharomyces cerevisiae that tethers chitin synthase III to the bud neck by interacting with septin neck filaments and with Chs4, a regulatory subunit of chitin synthase III. We show herein that Bni4 is also a limiting determinant for the targeting of the type 1 serine/threonine phosphatase (Glc7) to the bud neck. Yeast cells containing a Bni4 variant that fails to associate with Glc7 fail to tether Chs4 to the neck, due in part to the failure of Bni4(V831A/F833A) to localize properly. Conversely, the Glc7-129 mutant protein fails to bind Bni4 properly and glc7-129 mutants exhibit reduced levels of Bni4 at the bud neck. Bni4 is phosphorylated in a cell cycle-dependent manner and Bni4(V831A/F833A) is both hyperphosphorylated and mislocalized in vivo. Yeast cells lacking the protein kinase Hsl1 exhibit increased levels of Bni4-GFP at the bud neck. GFP-Chs4 does not accumulate at the incipient bud site in either a bni4::TRP1 or a bni4(V831A/F833A) mutant but does mobilize to the neck at cytokinesis. Together, these results indicate that the formation of the Bni4-Glc7 complex is required for localization to the site of bud emergence and for subsequent targeting of chitin synthase.

Maintenance of cell integrity in the gas1 mutant of Saccharomyces cerevisiae requires the Chs3p-targeting and activation pathway and involves an unusual Chs3p localization

Chitin synthase III is essential for the increase in chitin level and for cell integrity in cells lacking Gas1p, a beta(1,3)-glucanosyltransferase. In order to discover whether the upregulation of chitin synthesis proceeds through the canonical transport and activation pathway of Chs3p or through an alternative one, here we studied the effects of the inactivation of the GAS1 and CHS4-5-6-7 genes. All the double-null mutants showed a temperature-sensitive cell lysis phenotype that could be suppressed by the presence of an osmotic stabilizer. In liquid YEPD at 30 degrees C, chs4 delta gas1 delta, chs5 delta gas1 delta, chs6 deltagas1 delta and chs7 delta gas1 delta mutants were unable to grow, whereas they grew very slowly in minimal medium and showed low viability. High osmolarity suppressed the defective phenotype and restored growth. In chs4 gas1, chs5 gas1 and chs7 gas1, chitin levels did not increase and were reduced to only 10%, while in chs6 gas1 the value of gas1 was reduced to 20-40%. To investigate at which level the upregulation of chitin synthesis could occur, mRNA levels were monitored. The expression of CHS4-5-6-7 did not change significantly in gas1 delta. In strains expressing HA-tagged forms, the localization of Chs3p and Chs5p was examined. In the gas1 mutant the fluorescence pattern was affected and the proteins appeared abnormally present in the bud. The results indicate that: (a) the function of the CHS4-7 genes is required for chitin hyperaccumulation in gas1 mutant and for cell integrity; (b) homologous genes do not replace their function; (c) the regulation of CHS4-7 genes does not occur at transcriptional level. Control of the position of chitin synthesis could be important in protecting the bud from lysis.

The zygomycetous fungus, Benjaminiella poitrasii contains a large family of differentially regulated chitin synthase genes

Benjaminiella poitrasii is a zygomycetous, non-pathogenic dimorphic fungus. Chitin synthases are the membrane bound enzymes involved in the synthesis of chitin and are key enzymes in the cell wall metabolism. Multiplicity of these enzymes is a common occurrence. Here, we identify eight distinct CHS genes in B. poitrasii as confirmed through DNA sequence and Southern analysis. These genes are related to other fungal CHS genes. BpCHS1-4 are class I-III chitin synthases while BpCHS5-8 are class IV-V chitin synthases. These eight genes are differentially expressed during morphogenesis and under different growth conditions. Two of these genes viz. BpCHS2 and BpCHS3 appear to be specific to the mycelial growth form. These are the first B. poitrasii sequences to be reported. Based on CHS gene sequences, B. poitrasii chitin synthase genes place it with other zygomycetes on a fungal phylogenetic tree.

In budding yeast, contraction of the actomyosin ring and formation of the primary septum at cytokinesis depend on each other

Saccharomyces cerevisiae chs2 mutants are unable to synthesize primary septum chitin, and myo1 mutants cannot construct a functional contractile ring. The morphology of the two mutants, as observed by electron microscopy, is very similar. In both cases, neither an invagination of the plasma membrane, which normally results from contraction of the actomyosin ring, nor generation of a chitin disc, the primary septum, is observed. Rather, both mutants are able to complete cytokinesis by an abnormal process in which lateral walls thicken gradually and finally meet over an extended region, giving rise to a thick septum lacking the normal trilaminar structure and often enclosing lacunae. Defects in chs2 or myo1 strains were not aggravated in a double mutant, an indication that the corresponding proteins participate in a common process. In contrast, in a chs3 background the chs2 mutation is lethal and the myo1 defect is greatly worsened, suggesting that the synthesis of chitin catalyzed by chitin synthase III is necessary for the functionality of the remedial septa. Both chs2 and myo1 mutants show abnormalities in budding pattern and a decrease in the level of certain proteins associated with budding, such as Bud3p, Bud4p and Spa2p. The possible reasons for these phenotypes and for the interdependence between actomyosin ring contraction and primary septum formation are discussed.

WdChs2p, a class I chitin synthase, together with WdChs3p (class III) contributes to virulence in Wangiella (Exophiala) dermatitidis

The chitin synthase structural gene WdCHS2 was isolated by screening a subgenomic DNA library of Wangiella dermatitidis by using a 0.6-kb PCR product of the gene as a probe. The nucleotide sequence revealed a 2,784-bp open reading frame, which encoded 928 amino acids, with a 59-bp intron near its 5' end. Derived protein sequences showed highest amino acid identities with those derived from the CiCHS1 gene of Coccidioides immitis and the AnCHSC gene of Aspergillus nidulans. The derived sequence also indicated that WdChs2p is an orthologous enzyme of Chs1p of Saccharomyces cerevisiae, which defines the class I chitin synthases. Disruptions of WdCHS2 produced strains that showed no obvious morphological defects in yeast vegetative growth or in ability to carry out polymorphic transitions from yeast cells to hyphae or to isotropic forms. However, assays showed that membranes of wdchs2Delta mutants were drastically reduced in chitin synthase activity. Other assays of membranes from a wdchs1Deltawdchs3Deltawdchs4Delta triple mutant showed that their residual chitin synthase activity was extremely sensitive to trypsin activation and was responsible for the majority of zymogenic activity. Although no loss of virulence was detected when wdchs2Delta strains were tested in a mouse model of acute infection, wdchs2Deltawdchs3Delta disruptants were considerably less virulent in the same model, even though wdchs3Delta strains also had previously shown no loss of virulence. This virulence attenuation in the wdchs2Deltawdchs3Delta mutants was similarly documented in a limited fashion in more-sensitive cyclophosphamide-induced immunocompromised mice. The importance of WdChs2p and WdChs3p to the virulence of W. dermatitidis was then confirmed by reconstituting virulence in the double mutant by the reintroduction of either WdCHS2 or WdCHS3 into the wdchs2Deltawdchs3Delta mutant background.

Chs1 of Candida albicans is an essential chitin synthase required for synthesis of the septum and for cell integrity

CaCHS1 of the fungal pathogen Candida albicans encodes an essential chitin synthase that is required for septum formation, viability, cell shape and integrity. The CaCHS1 gene was inactivated by first disrupting one allele using the ura-blaster protocol, then placing the remaining allele under the control of the maltose-inducible, glucose-repressible MRP1 promoter. Under repressing conditions, yeast cell growth continued temporarily, but daughter buds failed to detach from parents, resulting in septumless chains of cells with constrictions defining contiguous compartments. After several generations, a proportion of the distal compartments lysed. The conditional Deltachs1 mutant also failed to form primary septa in hyphae; after several generations, growth stopped, and hyphae developed swollen balloon-like features or lysed at one of a number of sites including the hyphal apex and other locations that would not normally be associated with septum formation. CHS1 therefore synthesizes the septum of both yeast and hyphae and also maintains the integrity of the lateral cell wall. The conditional mutant was avirulent under repressing conditions in an experimental model of systemic infection. Because this gene is essential in vitro and in vivo and is not present in humans, it represents an attractive target for the development of antifungal compounds.

Membrane and cell wall targets in Aspergillus fumigatus

Antifungal drugs directed against the human opportunistic fungal pathogen Aspergillus fumigatus are limited in number and ergosterol-targeted: the polyenes bind to the membrane ergosterol and the azoles block the ergosterol biosynthesis pathway. The efficacy of the drugs currently available for clinical use (amphotericin B and itraconazole) is limited and the frequent occurrence of therapeutic failures in the treatment of invasive aspergillosis emphasizes the need for the development of new agents. Cell wall biosynthetic pathways have been recognized for a long time as essential and unique specific drug targets. Recent studies of the chemical organization of the cell wall of A. fumigatus together with comparative analysis of yeast cell wall data have shown that beta 1-3 glucan branching and chitin-beta 1-3 glucan binding are essential exocellular enzymatic steps in cell wall biosynthesis. The enzymes involved in the biosynthesis and remodeling of cell wall polysaccharides especially in A. fumigatus are reviewed.

Identification of a novel inhibitor specific to the fungal chitin synthase. Inhibition of chitin synthase 1 arrests the cell growth, but inhibition of chitin synthase 1 and 2 is lethal in the pathogenic fungus Candida albicans

As in Saccharomyces cerevisiae, the pathogenic fungus Candida albicans harbors three chitin synthases called CaChs1p, CaChs2p, and CaChs3p, which are structurally and functionally analogous to the S. cerevisiae ScChs2p, ScChs1p, and ScChs3p, respectively. In S. cerevisiae, ScCHS1, ScCHS2, and ScCHS3 are all non-essential genes; only the simultaneous disruption of ScCHS2 and ScCHS3 is lethal. The fact that a null mutation of the CaCHS1 is impossible, however, implies that CaCHS1 is required for the viability of C. albicans. To gain more insight into the physiological importance of CaCHS1, we identified and characterized a novel inhibitor that was highly specific to CaChs1p. RO-09-3143 inhibited CaChs1p with a K(i) value of 0.55 nm in a manner that was non-competitive to the substrate UDP-N-acetylglucosamine. RO-09-3143 also hampered the growth of the C. albicans cells with an MIC(50) value of 0.27 microm. In the presence of RO-09-3143, the C. albicans cells failed to form septa and displayed an aberrant morphology, confirming the involvement of the C. albicans Chs1p in septum formation. Although the effect of RO-09-3143 on the wild-type C. albicans was fungistatic, it caused cell death in the cachs2Delta null mutants but not in the cachs3Delta null mutants. Thus, it appears that in C. albicans, inhibition of CaChs1p causes cell growth arrest, but simultaneous inhibition of CaChs1p and CaChs2p is lethal.

Chitin synthesis in a gas1 mutant of Saccharomyces cerevisiae

The existence of a compensatory mechanism in response to cell wall damage has been proposed in yeast cells. The increase of chitin accumulation is part of this response. In order to study the mechanism of the stress-related chitin synthesis, we tested chitin synthase I (CSI), CSII, and CSIII in vitro activities in the cell-wall-defective mutant gas1 delta. CSI activity increased twofold with respect to the control, a finding in agreement with an increase in the expression of the CHS1 gene. However, deletion of the CHS1 gene did not affect the phenotype of the gas1 delta mutant and only slightly reduced the chitin content. Interestingly, in chs1 gas1 double mutants the lysed-bud phenotype, typical of chs1 null mutant, was suppressed, although in gas1 cells there was no reduction in chitinase activity. CHS3 expression was not affected in the gas1 mutant. Deletion of the CHS3 gene severely compromised the phenotype of gas1 cells, despite the fact that CSIII activity, assayed in membrane fractions, did not change. Furthermore, in chs3 gas1 cells the chitin level was about 10% that of gas1 cells. Thus, CSIII is the enzyme responsible for the hyperaccumulation of chitin in response to cell wall stress. However, the level of enzyme or the in vitro CSIII activity does not change. This result suggests that an interaction with a regulatory molecule or a posttranslational modification, which is not preserved during membrane fractionation, could be essential in vivo for the stress-induced synthesis of chitin.

Chitin synthases in yeast and fungi

The polysaccharide chitin is an important structural component of the cell walls of many fungi. Chitin synthesis is directly governed by an enzymatic activity called chitin synthase (CS). The use of the budding yeast Saccharomyces cerevisiae as a biological model allowed the identification of three distinct chitin synthase activities: CSI, involved in repair functions at the end of cytokinesis; CSII, responsible for the synthesis of the primary septum that separates mother and daughter cells; and CSIII, responsible for the formation of the ring (bud scar) where most of the cell wall chitin is located. These chitin synthases differ not only in functions but also in catalytic properties. The catalytic subunit of each of these activities is encoded by separated genes, CHS1, CHS2 and CHS3, respectively, although it has been shown in S. cerevisiae that CSIII activity also depends on the products of other genes. To date, several chitin synthase (CHS) genes have been also identified in other fungi; most of them are similar to ScCHS1 and ScCHS2 genes and are classified in chitin synthases classes I, II and III in terms of sequence similarity. The rest are defined as two CHS classes, IV and V, highly similar to ScCHS3. While CHS class V genes have been only identified in filamentous fungi and their functions are unknown, class IV genes, which includes ScCHS3, are involved in the synthesis of most chitin in yeast cells.

Biochemistry of chitin synthase

This article compiles the papers dealing with the biochemistry of chitin synthase (CS) published during the last decade, provides up-to-date information on the state of knowledge and understanding of chitin synthesis in vitro, and points out some firmly entrenched ideas and tenets of CS biochemistry that have become of age without hardly ever having been critically re-evaluated. The subject is dealt with under the headings "Components of the CS reaction" (educt, cation requirement and intermediates; product), "Regulation of CS" (cooperativity and allostery; non-allosteric activation or priming of CS; latency), "Concerted action of CS and enzymes of chitinolysis", "Inhibition of CS", "Multiplicity of CSs", and "Structure of CS" (the putative UDPGlcNAc-binding domain of CS; identification of CS polypeptides; glycoconjugation). The prospects are outlined of obtaining a refined three-dimensional (3D) model of the catalytic site of CS for biotechnological applications.

A novel family of cell wall-related proteins regulated differently during the yeast life cycle

The Saccharomyces cerevisiae Ygr189c, Yel040w, and Ylr213c gene products show significant homologies among themselves and with various bacterial beta-glucanases and eukaryotic endotransglycosidases. Deletion of the corresponding genes, either individually or in combination, did not produce a lethal phenotype. However, the removal of YGR189c and YEL040w, but not YLR213c, caused additive sensitivity to compounds that interfere with cell wall construction, such as Congo red and Calcofluor White, and overexpression of YEL040w led to resistance to these compounds. These genes were renamed CRH1 and CRH2, respectively, for Congo red hypersensitive. By site-directed mutagenesis we found that the putative glycosidase domain of CRH1 was critical for its function in complementing hypersensitivity to the inhibitors. The involvement of CRH1 and CRH2 in the development of cell wall architecture was clearly shown, since the alkali-soluble glucan fraction in the crh1Delta crh2Delta strain was almost twice the level in the wild-type. Interestingly, the three genes were subject to different patterns of transcriptional regulation. CRH1 and YLR213c (renamed CRR1, for CRH related) were found to be cell cycle regulated and also expressed under sporulation conditions, whereas CRH2 expression did not vary during the mitotic cycle. Crh1 and Crh2 are localized at the cell surface, particularly in chitin-rich areas. Consistent with the observed expression patterns, Crh1-green fluorescent protein was found at the incipient bud site, around the septum area in later stages of budding, and in ascospore envelopes. Crh2 was found to localize mainly at the bud neck throughout the whole budding cycle, in mating projections and zygotes, but not in ascospores. These data suggest that the members of this family of putative glycosidases might exert a common role in cell wall organization at different stages of the yeast life cycle.

Inhibition of fungal cell wall synthesizing enzymes by trans-cinnamaldehyde

This study examined the inhibitory effects of trans-cinnamaldehyde (CA), an aromatic aldehyde derived from Cinnamomi Cortex, on Saccharomyces cerevisiae cell wall synthesizing enzymes in vitro. This compound was found to be a noncompetitive inhibitor of beta-(1,3)-glucan synthase and a mixed inhibitor of chitin synthase 1 with 50% inhibitory concentrations (IC50) of 0.84 and 1.44 mM, respectively. Chitin synthases 2 and 3 were less sensitive than chitin synthase 1 to CA. CA can be useful as a model compound of cell wall inhibitors for the development of effective antifungal agents.

The yeast Chs4 protein stimulates the trypsin-sensitive activity of chitin synthase 3 through an apparent protein-protein interaction

Inducible overexpression of the CHS4 gene under the control of the GAL1 promoter increased Chs3p (chitin synthase 3) activity in Saccharomyces cerevisiae several fold. Approximately half of the Chs3p activity in the membranes of cells overexpressing Chs4p was extracted using CHAPS and cholesteryl hemisuccinate. The detergent-extractable Chs3p activity appeared to be non-zymogenic because incubation with trypsin decreased enzyme activity in both the presence and absence of the substrate, UDP-N-acetylglucosamine. Western blotting confirmed that Chs3p was extracted from membranes by CHAPS and cholesteryl hemisuccinate and revealed that Chs4p was also solubilized using these detergents. Yeast two-hybrid analysis with truncated Chs4p demonstrated that the region of Chs4p between amino acids 269 and 563 is indispensable not only for eliciting the non-zymogenic activity of Chs3p but also for binding of Chs4p to Chs3p. Neither the EF-hand motif nor a possible prenylation site in Chs4p was required for these activities. Thus, it was demonstrated that stimulation of non-zymogenic Chs3p activity by Chs4p requires the amino acid region from 269 to 563 of Chs4p, and it seems that Chs4p activates Chs3p through protein-protein interaction.

Proper ascospore maturation requires the chs1+ chitin synthase gene in Schizosaccharomyces pombe

We have cloned chs1+, a Schizosaccharomyces pombe gene with similarity to class II chitin synthases, and have shown that it is responsible for chitin synthase activity present in cell extracts from this organism. Analysis of this activity reveals that it behaves like chitin synthases from other fungi, although with specific biochemical characteristics. Deletion or overexpression of this gene does not lead to any apparent defect during vegetative growth. In contrast, chs1+ expression increases significantly during sporulation, and this is accompanied by an increase in chitin synthase activity. In addition, spore formation is severely affected when both parental strains carry a chs1 deletion, as a result of a defect in the synthesis of the ascospore cell wall. Finally, we show that wild-type, but not chs1-/chs1-, ascospore cell walls bind wheatgerm agglutinin. Our results clearly suggest the existence of a relationship between chs1+, chitin synthesis and ascospore maturation in S. pombe.

Increased chitin synthesis in response to type II myosin deficiency in Saccharomyces cerevisiae

We reported previously that the chitin content in cell walls of type II myosin-deficient Saccharomyces cerevisiae strains is increased relative to wild-type cells suggesting that increased chitin synthesis is induced in these strains. In the present study, we have performed enzyme activity assays for chitin synthases 1, 2, and 3 to determine the enzyme isoform(s) involved. To determine if transcriptional regulation is involved, we conducted quantitative mRNA assays of the corresponding chitin synthase genes. We show that the enzyme activities of all three chitin synthases increase substantially over the wild-type strain while eight- and twofold increases in the mRNA levels for chitin synthases 1 and 3 were detected. Increases in enzyme activities and mRNA levels were not proportional. We conclude that the enzyme activities for all three chitin synthases are elevated in this strain and that this increase is mediated mainly by a posttranslational mechanism(s). The heightened sensitivity to osmotic stress and the corresponding increase in cell wall chitin content reported in these strains are consistent with a compensatory "stress response" mechanism induced by abnormal cell wall assembly.

WdChs4p, a homolog of chitin synthase 3 in Saccharomyces cerevisiae, alone cannot support growth of Wangiella (Exophiala) dermatitidis at the temperature of infection

By using improved transformation methods for Wangiella dermatitidis, and a cloned fragment of its chitin synthase 4 structural gene (WdCHS4) as a marking sequence, the full-length gene was rescued from the genome of this human pathogenic fungus. The encoded chitin synthase product (WdChs4p) showed high homology with Chs3p of Saccharomyces cerevisiae and other class IV chitin synthases, and Northern blotting showed that WdCHS4 was expressed at constitutive levels under all conditions tested. Reduced chitin content, abnormal yeast clumpiness and budding kinetics, and increased melanin secretion resulted from the disruption of WdCHS4 suggesting that WdChs4p influences cell wall structure, cellular reproduction, and melanin deposition, respectively. However, no significant loss of virulence was detected when the wdchs4Delta strain was tested in an acute mouse model. Using a wdchs1Delta wdchs2Delta wdchs3Delta triple mutant of W. dermatitidis, which grew poorly but adequately at 25 degrees C, we assayed WdChs4p activity in the absence of activities contributed by its three other WdChs proteins. Maximal activity required trypsin activation, suggesting a zymogenic nature. The activity also had a pH optimum of 7.5, was most stimulated by Mg(2+), and was more inhibited by polyoxin D than by nikkomycin Z. Although the WdChs4p activity had a broad temperature optimum between 30 to 45 degrees C in vitro, this activity alone did not support the growth of the wdchs1Delta wdchs2Delta wdchs3Delta triple mutant at 37 degrees C, a temperature commensurate with infection.

Chs6p-dependent anterograde transport of Chs3p from the chitosome to the plasma membrane in Saccharomyces cerevisiae

Chitin synthase III (CSIII), an enzyme required to form a chitin ring in the nascent division septum of Saccharomyces cerevisiae, may be transported to the cell surface in a regulated manner. Chs3p, the catalytic subunit of CSIII, requires the product of CHS6 to be transported to or activated at the cell surface. We find that chs6Delta strains have morphological abnormalities similar to those of chs3 mutants. Subcellular fractionation and indirect immunofluorescence indicate that Chs3p distribution is altered in chs6 mutant cells. Order-of-function experiments using end4-1 (endocytosis-defective) and chs6 mutants indicate that Chs6p is required for anterograde transport of Chs3p from an internal endosome-like membrane compartment, the chitosome, to the plasma membrane. As a result, chs6 strains accumulate Chs3p in chitosomes. Chs1p, a distinct chitin synthase that acts during or after cell separation, is transported normally in chs6 mutants, suggesting that Chs1p and Chs3p are independently packaged during protein transport through the late secretory pathway.

Regulation of chitin synthesis during dimorphic growth of Candida albicans

Candida albicans has three genes encoding chitin synthase enzymes. In wild-type strains, the expression of CHS2 and CHS3 peaked 1-2 h after the induction of hyphal growth, whilst mRNA levels in a non-germinative strain, CA2, remained low under the same conditions. CHS1 gene expression did not peak during germ tube formation but remained at low levels in both yeast and hyphal growth. The pattern of gene expression did not predict the changes in measured chitin synthase activities or changes in chitin content during dimorphic transition. Chitin synthase activity increased steadily, and did not peak shortly after germ tube induction, and activity profiles were similar in germ-tube-competent and germ-tube-negative strains. The phenotype of a delta chs2 null mutant suggested that CHS2 encoded the major enzyme activity in vitro and was largely responsible for elevated chitin synthase activities in microsomal preparations from hyphal cells compared to yeast cells. However, CaChs3p was responsible for synthesis of most chitin in both yeast and hyphae. Three independent chitin assays gave markedly different estimates of the relative chitin content of yeast and hyphae and wild-type and chs mutants. Only one of the methods gave a significantly higher chitin content for hyphal compared to yeast cell walls and a lower chitin content for hyphae of the delta chs2 null mutant compared to the parental strain.

Umchs5, a gene coding for a class IV chitin synthase in Ustilago maydis

A fragment corresponding to a conserved region of a fifth gene coding for chitin synthase in the plant pathogenic fungus Ustilago maydis was amplified by means of the polymerase chain reaction (PCR). The amplified fragment was utilized as a probe for the identification of the whole gene in a genomic library of the fungus. The predicted gene product of Umchs5 has highest similarity with class IV chitin synthases encoded by the CHS3 genes from Saccharomyces cerevisiae and Candida albicans, chs-4 from Neurospora crassa, and chsE from Aspergillus nidulans. Umchs5 null mutants were constructed by substitution of most of the coding sequence with the hygromycin B resistance cassette. Mutants displayed significant reduction in growth rate, chitin content, and chitin synthase activity, specially in the mycelial form. Virulence to corn plantules was also reduced in the mutants. PCR was also used to obtain a fragment of a sixth chitin synthase, Umchs6. It is suggested that multigenic control of chitin synthesis in U. maydis operates as a protection mechanism for fungal viability in which the loss of one activity is partially compensated by the remaining enzymes.

Characterization of CHS4 (CAL2), a gene of Saccharomyces cerevisiae involved in chitin biosynthesis and allelic to SKT5 and CSD4

We have cloned CHS4, a gene that complements the resistance to Calcofluor of the Saccharomyces cerevisiae cal2 mutant. We show that CHS4 is allelic to the previously described SKT5 and CSD4 genes. CHS4 encodes a 696 amino acids protein with no potential transmembrane domain. chs4-null mutants are resistant to Calcofluor white and exhibit a considerable reduction in cell wall chitin and in chitin synthase III (CSIII) activity. Biochemical characterization of chitin synthase III from these null mutants indicates that the defect is due to a reduced V(max) of the enzyme. This defect can be overcome in vitro by trypsin treatment of the membrane preparations. Chs4p does not act as a transcriptional or translational regulator of CHS3, the gene coding for the catalytic subunit of CSIII activity, and we therefore propose that Chs4p would be an essential component of the CSIII complex, acting as a post-translational regulator of this activity. In addition to the chitin defect, the chs4 mutant shows a severe defect in mating.

CHS5, a gene involved in chitin synthesis and mating in Saccharomyces cerevisiae

The CHS5 locus of Saccharomyces cerevisiae is important for wild-type levels of chitin synthase III activity. chs5 cells have reduced levels of this activity. To further understand the role of CHS5 in yeast, the CHS5 gene was cloned by complementation of the Calcofluor resistance phenotype of a chs5 mutant. Transformation of the mutant with a plasmid carrying CHS5 restored Calcofluor sensitivity, wild-type cell wall chitin levels, and chitin synthase III activity levels. DNA sequence analysis reveals that CHS5 encodes a unique polypeptide of 671 amino acids with a molecular mass of 73,642 Da. The predicted sequence shows a heptapeptide repeated 10 times, a carboxy-terminal lysine-rich tail, and some similarity to neurofilament proteins. The effects of deletion of CHS5 indicate that it is not essential for yeast cell growth; however, it is important for mating. Deletion of CHS3, the presumptive structural gene for chitin synthase III activity, results in a modest decrease in mating efficiency, whereas chs5delta cells exhibit a much stronger mating defect. However, chs5 cells produce more chitin than chs3 mutants, indicating that CHS5 plays a role in other processes besides chitin synthesis. Analysis of mating mixtures of chs5 cells reveals that cells agglutinate and make contact but fail to undergo cell fusion. The chs5 mating defect can be partially rescued by FUS1 and/or FUS2, two genes which have been implicated previously in cell fusion, but not by FUS3. In addition, mating efficiency is much lower in fus1 fus2 x chs5 than in fus1 fus2 x wild type crosses. Our results indicate that Chs5p plays an important role in the cell fusion step of mating.

Targeting of chitin synthase 3 to polarized growth sites in yeast requires Chs5p and Myo2p

Chitin is an essential structural component of the yeast cell wall whose deposition is regulated throughout the yeast life cycle. The temporal and spatial regulation of chitin synthesis was investigated during vegetative growth and mating of Saccharomyces cerevisiae by localization of the putative catalytic subunit of chitin synthase III, Chs3p, and its regulator, Chs5p. Immunolocalization of epitope-tagged Chs3p revealed a novel localization pattern that is cell cycle-dependent. Chs3p is polarized as a diffuse ring at the incipient bud site and at the neck between the mother and bud in small-budded cells; it is not found at the neck in large-budded cells containing a single nucleus. In large-budded cells undergoing cytokinesis, it reappears as a ring at the neck. In cells responding to mating pheromone, Chs3p is found throughout the projection. The appearance of Chs3p at cortical sites correlates with times that chitin synthesis is expected to occur. In addition to its localization at the incipient bud site and neck, Chs3p is also found in cytoplasmic patches in cells at different stages of the cell cycle. Epitope-tagged Chs5p also localizes to cytoplasmic patches; these patches contain Kex2p, a late Golgi-associated enzyme. Unlike Chs3p, Chs5p does not accumulate at the incipient bud site or neck. Nearly all Chs3p patches contain Chs5p, whereas some Chs5p patches lack detectable Chs3p. In the absence of Chs5p, Chs3p localizes in cytoplasmic patches, but it is no longer found at the neck or the incipient bud site, indicating that Chs5p is required for the polarization of Chs3p. Furthermore, Chs5p localization is not affected either by temperature shift or by the myo2-66 mutation, however, Chs3p polarization is affected by temperature shift and myo2-66. We suggest a model in which Chs3p polarization to cortical sites in yeast is dependent on both Chs5p and the actin cytoskeleton/Myo2p.

Chs1p and Chs3p, two proteins involved in chitin synthesis, populate a compartment of the Saccharomyces cerevisiae endocytic pathway

In Saccharomyces cerevisiae, the synthesis of chitin, a cell-wall polysaccharide, is temporally and spatially regulated with respect to the cell cycle and morphogenesis. Using immunological reagents, we found that steady-state levels of Chs1p and Chs3p, two chitin synthase enzymes, did not fluctuate during the cell cycle, indicating that they are not simply regulated by synthesis and degradation. Previous cell fractionation studies demonstrated that chitin synthase I activity (CSI) exists in a plasma membrane form and in intracellular membrane-bound particles called chitosomes. Chitosomes were proposed to act as a reservoir for regulated transport of chitin synthase enzymes to the division septum. We found that Chs1p and Chs3p resided partly in chitosomes and that this distribution was not cell cycle regulated. Pulse-chase cell fractionation experiments showed that chitosome production was blocked in an endocytosis mutant (end4-1), indicating that endocytosis is required for the formation or maintenance of chitosomes. Additionally, Ste2p, internalized by ligand-induced endocytosis, cofractionated with chitosomes, suggesting that these membrane proteins populate the same endosomal compartment. However, in contrast to Ste2p, Chs1p and Chs3p were not rapidly degraded, thus raising the possibility that the temporal and spatial regulation of chitin synthesis is mediated by the mobilization of an endosomal pool of chitin synthase enzymes.

Differential trafficking and timed localization of two chitin synthase proteins, Chs2p and Chs3p

The deposition of the polysaccharide chitin in the Saccharomyces cerevisiae cell wall is temporally and spatially regulated. Chitin synthase III (Chs3p) synthesizes a ring of chitin at the onset of bud emergence, marking the base of the incipient bud. At the end of mitosis, chitin synthase II (Chs2p) deposits a disk of chitin in the mother-bud neck, forming the primary division septum. Using indirect immunofluorescence microscopy, we have found that these two integral membrane proteins localize to the mother-bud neck at distinct times during the cell cycle. Chs2p is found at the neck at the end of mitosis, whereas Chs3p localizes to a ring on the surface of cells about to undergo bud emergence and in the mother-bud neck of small-budded cells. Cell synchronization and pulse-chase experiments suggest that the timing of Chs2p localization results from cell cycle-specific synthesis coupled to rapid degradation. Chs2p degradation depends on the vacuolar protease encoded by PEP4, indicating that Chs2p is destroyed in the vacuole. Temperature-sensitive mutations that block either the late secretory pathway (sec1-1) or the internalization step of endocytosis (end4-1) also prevent Chs2p degradation. In contrast, Chs3p is synthesized constitutively and is metabolically stable, indicating that Chs2p and Chs3p are subject to different modes of regulation. Differential centrifugation experiments show that a significant proportion of Chs3p resides in an internal compartment that may correspond to a vesicular species called the chitosome (Leal-Morales, C.A., C.E. Bracker, and S. Bartnicki-Garcia. 1988, Proc. Natl. Acad. Sci. USA. 85:8516-8520; Flores Martinez, A., and J. Schwencke. 1988. Biochim. Biophys. Acta. 946:328-336). Fractionation of membranes prepared from mutants defective in internalization (end3-1 and end4-1) indicate that the Chs3p-containing vesicles are endocytically derived. Collectively, these data suggest that the trafficking of Chs2p and Chs3p diverges after endocytosis; Chs3p is not delivered to the vacuole, but instead may be recycled.

Yeast chitin synthases 1 and 2 consist of a non-homologous and dispensable N-terminal region and of a homologous moiety essential for function

Predicted protein sequences of fungal chitin synthases can be divided into a non-homologous N-terminal region and a C-terminal region that shows significant homology among the various synthases. We have explored the function of these domains by constructing a series of nested deletions, extending from either end, in the CHS1 and CHS2 genes of Saccharomyces cerevisiae. In both cases, most or all of the sequences encoding the non-homologous N-terminal region (one-third of the protein for Chs1p and about one-fourth for Chs2p) could be excised, with little effect on the enzymatic activity in vitro of the corresponding synthase or on its function in vivo. However, further small deletions (20-25 amino acids) into the homologous region were deleterious to enzymatic activity and function, and often led to changes in the zymogenic character of the enzymes. Similarly, relatively small (about 75 amino acids) deletions from the C-terminus resulted in loss of enzymatic activity and function of both synthases. Thus, it appears that all the information necessary for membrane localization, enzymatic activity and function resides in the homologous regions of Chs1p and Chs2p, a situation that may also apply to other chitin synthases.

Identification of the conserved coding sequences of three chitin synthase genes in Fonsecaea pedrosoi

Primers having designs based on highly conserved stretches in the deduced amino acid sequences of chitin synthase (CHS) genes were used in PCR reactions to amplify 600 bp and 366 bp products from the genomic DNA of three major causal agents of chromoblastomycosis. Cloning and sequencing of the PCR products of one of these fungi, Fonsecaea pedrosoi, identified three CHS sequences designated as FpCHS1, FpCHS2 and FpCHS3. FpCHS1 and FpCHS2 were homologous to regions of CHS1 and CHS2 of Saccharomyces cerevisiae, and their derived amino acid sequences fell into chitin synthase classes I and II, respectively. FpCHS3 was homologous to a region of the CAL1/CSD2 gene of S. cerevisiae, which codes for the chitin synthase three (Chs3) enzyme in that fungus. Phylogenetic trees constructed using the deduced amino acid sequences of PCR-amplified CHS products from many fungi clustered F. pedrosoi with other dematiaceous fungi, providing new molecular evidence for the genetic relatedness of these organisms. The identification of these CHS genes in F. pedrosoi will facilitate future studies of the functional roles of chitin synthases in the unique in vivo dimorphism exhibited by chromoblastomycotic fungi.

Two chitin synthase genes from Ustilago maydis

PCR was used to amplify fragments corresponding to CHS genes from Ustilago maydis, utilizing as primers oligonucleotides devised according to the conserved regions of fungal CHS genes. The PCR product was employed as a probe to screen a genomic library of the fungus. Two different CHS genes (Umchs1 and Umchs2) were thus identified in the positive clones recovered. Their sequence revealed high similarity with the CHS genes previously cloned from other fungi, especially in their central region. Alignment with the deduced protein sequences of all CHS genes reported up to date showed the existence of seven conserved domains. Transcripts from both genes were detected in the yeast and mycelial forms. In general, the transcripts from the Umchs1 gene appeared to be present at a higher level than the transcripts from the Umchs2 gene; the transcripts from both genes appeared to be more abundant in the mycelial form. Gene replacement of either gene and analysis of the resulting phenotype demonstrated that they are non-essential. Nevertheless, growth, chitin synthase activity levels, and chitin content of mycelial cells induced by cultivation in acidic media were all reduced in chs1 and chs2 mutants. However, mating, virulence and dimorphic behaviour were unaffected. Overall, the results indicate that the CHS1 and CHS2 genes encode products with redundant functions in U. maydis.

Molecular basis of cell integrity and morphogenesis in Saccharomyces cerevisiae

In fungi and many other organisms, a thick outer cell wall is responsible for determining the shape of the cell and for maintaining its integrity. The budding yeast Saccharomyces cerevisiae has been a useful model organism for the study of cell wall synthesis, and over the past few decades, many aspects of the composition, structure, and enzymology of the cell wall have been elucidated. The cell wall of budding yeasts is a complex and dynamic structure; its arrangement alters as the cell grows, and its composition changes in response to different environmental conditions and at different times during the yeast life cycle. In the past few years, we have witnessed a profilic genetic and molecular characterization of some key aspects of cell wall polymer synthesis and hydrolysis in the budding yeast. Furthermore, this organism has been the target of numerous recent studies on the topic of morphogenesis, which have had an enormous impact on our understanding of the intracellular events that participate in directed cell wall synthesis. A number of components that direct polarized secretion, including those involved in assembly and organization of the actin cytoskeleton, secretory pathways, and a series of novel signal transduction systems and regulatory components have been identified. Analysis of these different components has suggested pathways by which polarized secretion is directed and controlled. Our aim is to offer an overall view of the current understanding of cell wall dynamics and of the complex network that controls polarized growth at particular stages of the budding yeast cell cycle and life cycle.

Characterization of chitin synthase 2 of Saccharomyces cerevisiae. Implication of two highly conserved domains as possible catalytic sites

Chitin synthase 2 of Saccharomyces cerevisiae was characterized by means of site-directed mutagenesis and subsequent expression of the mutant enzymes in yeast cells. Chitin synthase 2 shares a region whose sequence is highly conserved in all chitin synthases. Substitutions of conserved amino acids in this region with alanine (alanine scanning) identified two domains in which any conserved amino acid could not be replaced by alanine to retain enzyme activity. These two domains contained unique sequences, Glu561-Asp562-Arg563 and Gln601-Arg602-Arg603-Arg604-Trp605, that were conserved in all types of chitin synthases. Glu561 or arginine at 563, 602, and 603 could be substituted by glutamic acid and lysine, respectively, without significant loss of enzyme activity. However, even conservative substitutions of Asp562 with glutamic acid, Gln601 with asparagine, Arg604 with lysine, or Trp605 with tyrosine drastically decreased the activity, but did not affect apparent Km values for the substrate significantly. In addition to these amino acids, Asp441 was also found in all chitin synthase. The mutant harboring a glutamic acid substitution for Asp441 severely lost activity, but it showed a similar apparent Km value for the substrate. Amounts of the mutant enzymes in total membranes were more or less the same as found in the wild type. Furthermore, Asp441, Asp562, Gln601, Arg604, and Trp605 are completely conserved in other proteins possessing N-acetylglucosaminyltransferase activity such as NodC proteins of Rhizobium bacterias. These results suggest that Asp441, Asp562, Gln601, Arg604, and Trp605 are located in the active pocket and that they function as the catalytic residues of the enzyme.

Use of the polymerase chain reaction to identify coding sequences for chitin synthase isozymes in Phialophora verrucosa

Based on conserved amino-acid regions predicted for the chitin synthases (Chs) of Saccharomyces cerevisiae, two different primer sets were synthesized and used in polymerase chain reactions (PCRs) to amplify 614-bp and 366-bp sequences from genomic DNA of the zoopathogenic fungus Phialophora verrucosa. DNA-sequencing and Southern-blotting analyses of the 614-bp DNA amplification products suggested that portions of two distinct P. verrucosa chitin synthase genes (PvCHS1, PvCHS2), coding for two different zymogenic-type PvChs isozymes, had been identified. The deduced amino-acid sequence of each fell into different Chs classes, namely class I and class II. In addition, the 366-bp DNA segment was shown to code for a conserved region having homology with the CSD2/CAL1 gene of S. cerevisiae, which encodes a nonzymogenic-type enzyme, Chs3, in that fungus. The amino-acid sequence derived from PvCHS3 exhibits 88.2% similarity and 78.4% identity to the same amino-acid region of the S. cerevisiae enzyme. These results provide a critical first step toward investigating the molecular and pathogenic importance of CHS gene regulation in this fungus and for exploring steps leading to Chs function as potential targets for the design of new therapeutic agents.

A multigene family related to chitin synthase genes of yeast in the opportunistic pathogen Aspergillus fumigatus

Two approaches were used to isolate fragments of chitin synthase genes from the opportunistic human pathogen Aspergillus fumigatus. Firstly, regions of amino acid conservation in chitin synthases of Saccharomyces cerevisiae were used to design degenerate primers for amplification of portions of related genes, and secondly, a segment of the S. cerevisiae CSD2 gene was used to screen an A. fumigatus lambda genomic DNA library. the polymerase chain reaction (PCR)-based approach led to the identification of five different genes, designated chsA, chsB, chsC, chsD and chsE. chsA, chsB, and chsC fall into Classes I, II and III of the 'zymogen type' chitin synthases, respectively. The chsD fragment has approximately 35% amino acid sequence identity to both the zymogen type genes and the non-zymogen type CSD2 gene. chsF appears to be a homologue of CSD2, being 80% identical to CSD2 over 100 amino acids. An unexpected finding was the isolation by heterologous hybridization of another gene (chsE), which also has strong sequence similarity (54% identity at the amino acid level over the same region as chsF) to CSD2. Reverse transcriptase-PCR was used to show that each gene is expressed during hyphal growth in submerged cultures.

Nikkomycin Z supersensitivity of an echinocandin-resistant mutant of Saccharomyces cerevisiae

Echinocandins and nikkomycins are antibiotics that inhibit the synthesis of the essential cell wall polysaccharide polymers 1,3-beta-glucan and chitin, respectively. Some 40 echinocandin-resistant Saccharomyces cerevisiae mutants were isolated and assigned to five complementation groups. Four complementation groups contained mutants with 38 recessive mutations. The fifth complementation group comprised mutants with one dominant mutation, etg1-3 (strain MS10), and one semidominant mutation, etg1-4 (strain MS14). MS10 and MS14 are resistant to the semisynthetic pneumocandin B, L-733,560, and to aculeacin A but not to papulacandin. In addition, microsomal membranes of both mutant strains contain 1,3-beta-glucan synthase activity that is resistant to L-733,560 but not to papulacandin. Furthermore, MS14 is also supersensitive to nikkomycin Z. The echinocandin resistance and the nikkomycin Z supersensitivity of MS14 cosegregated in genetic crosses. The wild-type gene (designated ETG1 [C. Douglas, J. A. Marrinan, and M. B. Kurtz, J. Bacteriol. 176:5686-5696, 1994, and C. Douglas, F. Foor, J. A. Marrinan, N. Morin, J. B. Nielsen, A. Dahl, P. Mazur, W. Baginsky, W. Li, M. El-Sherbeini, J. A. Clemas, S. Mandala, B. R. Frommer, and M. B. Kurtz, Proc. Natl. Acad. Sci. USA, in press]) was isolated from a genomic library in the plasmid YCp50 by functional complementation of the nikkomycin Z supersensitivity phenotype. The cloned DNA also partially complements the echinocandin resistance phenotype, indicating that the two phenotypes are due to single mutations. The existence of a single mutation, in MS14, simultaneously affecting sensitivity to a glucan synthase inhibitor and a chitin synthase inhibitor implies a possible interaction between the two polymers at the cell surface.

Are yeast chitin synthases regulated at the transcriptional or the posttranslational level?

The three chitin synthases of Saccharomyces cerevisiae, Chs1, Chs2, and Chs3, participate in septum and cell wall formation of vegetative cells and in wall morphogenesis of conjugating cells and spores. Because of the differences in the nature and in the time of execution of their functions, the synthases must be specifically and individually regulated. The nature of that regulation has been investigated by measuring changes in the levels of the three synthases and of the messages of the three corresponding genes, CHS1, CHS2, and CAL1/CSD2/DIT101/KTI2 (referred to below as CAL1/CSD2), during the budding and sexual cycles. By transferring cells carrying CHS2 under the control of a GAL1 promoter from galactose-containing medium to glucose-containing medium, transcription of CHS2 was shut off. This resulted in a rapid disappearance of Chs2, whereas the mRNA decayed much more slowly. Furthermore, Chs2 levels experienced pronounced oscillations during the budding cycle and were decreased in the sexual cycle, indicating that this enzyme is largely regulated by a process of synthesis and degradation. For CHS1 and CAL1/CSD2, however, a stop in transcription was followed by a slow decrease in the level of zymogen (Chs1) or an increase in the level of activity (Chs3), despite a rapid drop in message level in both cases. In synchronized cultures, Chs1 levels were constant during the cell cycle. Thus, for Chs1 and Chs3, posttranslational regulation, probably by activation of latent forms, appears to be predominant. Since Chs2, like Chs1, is found in the cell in the zymogenic form, a posttranslational activation step appears to be necessary for this synthase also.

Are yeast chitin synthases regulated at the transcriptional or the posttranslational level?

The three chitin synthases of Saccharomyces cerevisiae, Chs1, Chs2, and Chs3, participate in septum and cell wall formation of vegetative cells and in wall morphogenesis of conjugating cells and spores. Because of the differences in the nature and in the time of execution of their functions, the synthases must be specifically and individually regulated. The nature of that regulation has been investigated by measuring changes in the levels of the three synthases and of the messages of the three corresponding genes, CHS1, CHS2, and CAL1/CSD2/DIT101/KTI2 (referred to below as CAL1/CSD2), during the budding and sexual cycles. By transferring cells carrying CHS2 under the control of a GAL1 promoter from galactose-containing medium to glucose-containing medium, transcription of CHS2 was shut off. This resulted in a rapid disappearance of Chs2, whereas the mRNA decayed much more slowly. Furthermore, Chs2 levels experienced pronounced oscillations during the budding cycle and were decreased in the sexual cycle, indicating that this enzyme is largely regulated by a process of synthesis and degradation. For CHS1 and CAL1/CSD2, however, a stop in transcription was followed by a slow decrease in the level of zymogen (Chs1) or an increase in the level of activity (Chs3), despite a rapid drop in message level in both cases. In synchronized cultures, Chs1 levels were constant during the cell cycle. Thus, for Chs1 and Chs3, posttranslational regulation, probably by activation of latent forms, appears to be predominant. Since Chs2, like Chs1, is found in the cell in the zymogenic form, a posttranslational activation step appears to be necessary for this synthase also.

Identification of three chitin synthase genes in the dimorphic fungal pathogen Sporothrix schenckii

Degenerate PCR primers were used to amplify a 600-bp conserved gene region for chitin synthases from genomic DNA of Sporothrix schenckii, a dimorphic fungal pathogen of humans and animals. Three chitin synthase gene homologs were amplified as shown by DNA sequence analysis and by Southern blotting experiments. Based on differences among the predicted amino acid sequences of these homologs, each was placed within one of three different chitin synthase classes. Phylogenies constructed with the sequences and the PAUP 3.1.1 program showed that S. schenckii consistently clustered most closely with Neurospora crassa in each of the three chitin synthase classes. These findings are significant because the phylogenies support by a new method the grouping of the imperfect fungus S. schenckii with the Pyrenomycetes of the Ascomycota.

Nikkomycin Z is a specific inhibitor of Saccharomyces cerevisiae chitin synthase isozyme Chs3 in vitro and in vivo

Nikkomycin Z inhibits chitin synthase in vitro but does not exhibit antifungal activity against many pathogens. Assays of chitin synthase isozymes and growth assays with isozyme mutants were used to demonstrate that nikkomycin Z is a selective inhibitor of chitin synthase 3. The resistance of chitin synthase 2 to nikkomycin Z in vitro is likely responsible for the poor activity of this antibiotic against Saccharomyces cerevisiae.

Chitin synthase 3 from yeast has zymogenic properties that depend on both the CAL1 and the CAL3 genes

In previous studies, chitin synthase 3 (Chs3), the enzyme responsible for synthesis of most of the chitin present in the yeast cell, was found to be inactivated by incubation with trypsin, in contrast to other yeast chitin synthases (Chs1 and Chs2), which are stimulated by this treatment (chitin synthase; UDP-N-acetyl-D-glucosamine:chitin 4-beta-N-acetylglucosaminyl-transferase, EC 2.4.1.16). It has now been found that the substrate UDPGlcNAc protects Chs3 against proteolytic inactivation. Treatment of Chs3-containing membranes with detergents drastically reduced the enzymatic activity. Activity could, however, be restored by subsequent incubation with trypsin or other proteases in the presence of UDPGlcNAc. Under such conditions, protease treatment stimulated activity as much as 10-fold. A change in divalent cation specificity after trypsin treatment suggests that the protease directly affects the enzyme molecule. Experiments with mutants in the three genes involved in Chs3 activity--CAL1, CAL2, and CAL3--showed that only CAL1 and CAL3 are required for the protease-elicited (zymogenic) activity. It is concluded that Chs3 is a zymogen and that the CAL2 product functions as its activator. The differences and possible similarities between Chs3 and the other chitin synthases are discussed.

Disruption of two genes for chitin synthase in the phytopathogenic fungus Ustilago maydis

The phytopathogenic fungus Ustilago maydis exhibits a dimorphic transition in which non-pathogenic, yeast-like cells mate to form a pathogenic, filamentous dikaryon. Northern analysis indicated that two chitin synthase genes, chs1 and chs2, from U. maydis are expressed at similar levels in yeast-like cells and in cells undergoing the mating reaction leading to the filamentous cell type. A mutation was constructed in each of the chitin synthase genes by targeted gene disruption. Each mutant showed a reduction in the level of trypsin-activated enzyme activity, compared with a wild-type strain, but retained the wild-type morphology, the ability to mate and the ability to form the filamentous pathogenic cell type.

The yeast KRE9 gene encodes an O glycoprotein involved in cell surface beta-glucan assembly

The yeast KRE9 gene encodes a 30-kDa secretory pathway protein involved in the synthesis of cell wall (1-->6)-beta-glucan. Disruption of KRE9 leads to serious growth impairment and an altered cell wall containing less than 20% of the wild-type amount of (1-->6)-beta-glucan. Analysis of the glucan material remaining in a kre9 delta null mutant indicated a polymer with a reduced average molecular mass. kre9 delta null mutants also displayed several additional cell-wall-related phenotypes, including an aberrant multiply budded morphology, a mating defect, and a failure to form projections in the presence of alpha-factor. Double mutants were generated by crossing kre9 delta strains with strains harboring a null mutation in the KRE1, KRE6, or KRE11 gene, and each of these double mutants was found to be inviable in the SEY6210 background. Similar crosses with null mutations in the KRE5 and SKN1 genes indicated that these double mutants were no more severely affected than kre5 delta or kre9 delta single mutants alone. Antibodies were generated against Kre9p and detected an O glycoprotein of approximately 55 to 60 kDa found in the extracellular medium of a strain overproducing Kre9p.

The yeast KRE9 gene encodes an O glycoprotein involved in cell surface beta-glucan assembly

The yeast KRE9 gene encodes a 30-kDa secretory pathway protein involved in the synthesis of cell wall (1-->6)-beta-glucan. Disruption of KRE9 leads to serious growth impairment and an altered cell wall containing less than 20% of the wild-type amount of (1-->6)-beta-glucan. Analysis of the glucan material remaining in a kre9 delta null mutant indicated a polymer with a reduced average molecular mass. kre9 delta null mutants also displayed several additional cell-wall-related phenotypes, including an aberrant multiply budded morphology, a mating defect, and a failure to form projections in the presence of alpha-factor. Double mutants were generated by crossing kre9 delta strains with strains harboring a null mutation in the KRE1, KRE6, or KRE11 gene, and each of these double mutants was found to be inviable in the SEY6210 background. Similar crosses with null mutations in the KRE5 and SKN1 genes indicated that these double mutants were no more severely affected than kre5 delta or kre9 delta single mutants alone. Antibodies were generated against Kre9p and detected an O glycoprotein of approximately 55 to 60 kDa found in the extracellular medium of a strain overproducing Kre9p.

Chitin synthetase mutants of Phycomyces blakesleeanus

Mutants resistant to nikkomycin, an inhibitor of chitin biosynthesis, were isolated after exposure of wild-type spores of the fungus Phycomyces blakesleeanus to N-methyl-N'-nitro-N-nitrosoguanidine. Genetic analysis revealed that nikkomycin resistance was due to mutations in a single gene, chsA. Mutants and wild type grew equally well in the absence of nikkomycin. In contrast to the wild type, whose spore germination and mycelial growth were inhibited by 5 microM nikkomycin, chsA mutants grew reasonably well in the presence of 50 microM nikkomycin. Chitin synthesis in vivo was much less affected by the drug in the mutants than in the wild type. Resistance was not due to impaired uptake or detoxification of the drug. Analysis of the kinetics of chitin synthesis in vitro showed that the mutants had a decreased Ka for the allosteric activator, N-acetylglucosamine, and gross alterations in nikkomycin inhibition kinetics. These results indicate that chsA is the structural gene for chitin synthetase, or at least for the polypeptide that bears the catalytic and allosteric sites.

Identification of a Saccharomyces cerevisiae mutation that allows cells to grow without chitin synthase 1 or 2

Chitin is a component of the yeast cell wall which is localized to the septum between mother and daughter cells. Previous work in Saccharomyces cerevisiae has shown that this organism possesses three chitin synthases, 1, 2, and 3. Disruption experiments have shown that loss of chitin synthase 2 has a more profound effect on cell viability than loss of either of the other two and is lethal in complete media. We report here the finding of an S. cerevisiae strain which does not require the chitin synthase 2 structural gene for viability. We present evidence that there is a gene in this strain which suppresses the lethality of disruption of the chitin synthase 2 structural gene and is genetically distinct from the structural genes for chitin synthase 1 and chitin synthase 2. We show that an S. cerevisiae mutant containing the suppressor and lacking both structural genes for chitin synthase 1 and 2 has normal amounts of chitin in its cell wall. We hypothesize that the suppressor gene encodes or controls the expression of chitin synthase 3.

Effect of digitonin on membrane-bound and chitosomal chitin synthetase activity in protoplasts from yeast cells of Candida albicans

The effect of digitonin on chitin synthetase present in membrane (MMF) and cytoplasmic fractions (chitosomes) (CF) from C. albicans yeast protoplasts has been determined. The zymogen is preferentially, but not exclusively, solubilized by digitonin from MMF. Centrifugation of distinct solubilized preparations, containing either zymogen, in vivo active enzyme and/or trypsin activated enzyme, on linear sucrose gradients suggests that both zymogen and trypsin activated enzyme sediment slightly slower than the active enzyme, pointing out differences between the activation processes in vivo and in vitro or, alternatively, that both enzyme activities (active in vivo and zymogenic) correspond to different gene products. The detection of a zymogenic activity under certain conditions (0.5 mg ml-1 of digitonin and 64 micrograms ml-1 of trypsin) also suggests the existence of more than one pool of zymogenic enzyme in the MMF. Digitonin sensitizes the chitosomal (CF) proenzyme to trypsin: activation is enhanced by low digitonin concentrations in the presence of 8 micrograms ml-1 of protease, whereas activity strongly decreases in the presence of 64 micrograms ml-1 of trypsin. Digitonin does not produce zymogen activation per se in absence of exogenous protease. Furthermore, chitosome structure is modified into particles with low buoyant densities.

Nikkomycin-resistant mutants of Mucor rouxii: physiological and biochemical properties

We isolated three nikkomycin-resistant mutants of the dimorphic fungus M. rouxii which were physiologically characterized regarding their response to yeast-phase inducing conditions and their sensitivity to bacilysin. Mutant strains G21 and G23, showed a qualitatively normal, though delayed, dimorphic transition and partial cross-resistance to bacilysin. Mutant strain G27 showed an altered dimorphism, producing a high proportion (50%) of hyphal cells, and a wild-type sensitivity to bacilysin. Cell-free extracts from this mutant exhibited an activity of both basal and protease-activated chitin synthetase which was overexpressed as compared with the parental strain and mutants G21 and G23. Results are discussed in terms of the different genetic background of the mutants.