CSD2, CSD3, and CSD4, genes required for chitin synthesis in Saccharomyces cerevisiae: the CSD2 gene product is related to chitin synthases and to developmentally regulated proteins in Rhizobium species and Xenopus laevis.

In Saccharomyces cerevisiae, chitin forms the primary division septum and the bud scar in the walls of vegetative cells. Three chitin synthetic activities have been detected. Two of them, chitin synthase I and chitin synthase II, are not required for synthesis of most of the chitin present in vivo. Using a novel screen, I have identified three mutations, designated csd2, csd3, and csd4, that reduce levels of chitin in vivo by as much as 10-fold without causing any obvious perturbation of cell division. The csd2 and csd4 mutants lack chitin synthase III activity in vitro, while csd3 mutants have wild-type levels of this enzyme. In certain genetic backgrounds, these mutations cause temperature-sensitive growth on rich medium; inclusion of salts or sorbitol bypasses this phenotype. Gene disruption experiments show that CSD2 is nonessential; a small amount of chitin, about 5% of the wild-type level, is detected in the disruptants. DNA sequencing indicates that the CSD2 protein has limited, but statistically significant, similarity to chitin synthase I and chitin synthase II. Other significant similarities are to two developmental proteins: the nodC protein from Rhizobium species and the DG42 protein of Xenopus laevis. The relationship between the nodC and CSD2 proteins suggests that nodC may encode an N-acetylglucosaminyltransferase that synthesizes the oligosaccharide backbone of the nodulation factor NodRm-1.

Genetics and molecular biology of chitin synthesis in fungi.

In Saccharomyces cerevisiae, three chitin synthases have been detected. Chitin synthases I and II, the products of the CHS1 and CHS2 genes, respectively, are closely related proteins that require partial proteolysis for activity in vitro. In contrast, chitin synthase III is active in vitro without protease treatment, and three genes, CSD2 (= CAL1), CSD4 (= CAL2), and CAL3, are required for its activity. In the cell, the three enzymes have different functions. Chitin synthase I and II make only a small portion, < 10%, of the cellular chitin. In acidic media, chitin synthase I is required for normal budding. Chitin synthase II is required for normal morphology, septation, and cell separation. Chitin synthase III is required for the synthesis of 90% of the cellular chitin, including the chitin in the bud scars and lateral wall. Mutants defective in chitin synthase III are resistant to Calcofluor and Kluyveromyces lactis killer toxin, they lack alkali-insoluble glucan, and under certain circumstances, they are temperature-sensitive for growth. The available data suggest that many fungi have more than one chitin synthase and that these synthases are related to the S. cerevisiae CHS and CSD gene products.

The biosynthesis of gram-negative endotoxin. Identification and function of UDP-2,3-diacylglucosamine in Escherichia coli.

Escherichia coli mutants defective in the pgsB gene are phosphatidylglycerol-deficient in certain genetic settings and accumulate novel, glucosamine-derived phospholipids (Nishijima, M., and Raetz, C. R. H. (1979) J. Biol. Chem. 254, 7837-7844). The simplest of these compounds is 2,3-diacylglucosamine 1-phosphate (2,3-diacyl-GlcN-1-P) ("lipid X" of E. coli), in which beta-hydroxymyristoyl moieties are the sole fatty acid substituents (Takayama, K., Qureshi, N., Mascagni, P., Nashed, M. A., Anderson, L., and Raetz, C. R. H. (1983) J. Biol. Chem. 258, 7379-7385). We now report a sensitive radiochemical method for detection of 2,3-diacyl-GlcN-1-P in wild type E. coli and demonstrate that there are about 4000 molecules/cell (0.02% of the total CHCl3-soluble phosphorus). In mutants bearing the pgsB1 lesion, the levels are 100- to 300-fold higher. In addition, we have discovered a novel liponucleotide, UDP-2,3-diacyl-GlcN, that also accumulates in conjunction with the pgsb1 mutation. This material represents 0.005% of the wild type phospholipid and accumulates 50- to 100-fold in the mutant. The identification of UDP-2,3-diacyl-GlcN in E. coli is based on: 1) migration of a minor 32P-labeled lipid from wild type and mutant cells with a UDP-2,3-diacyl-GlCn standard during two-dimensional thin layer chromatography; 2) susceptibility of this 32P-labeled material to cleavage by a liponucleotide-specific pyrophosphatase; and 3) chromatographic identification of [32P]UMP and [32P]2,3-diacyl-GlcN-1-P (lipid X) as the sole products of the enzymatic degradation. As shown in the accompanying article, this novel nucleotide is crucial for biosynthesis of lipid A disaccharides in extracts of E. coli and Salmonella typhimurium.

Chitin synthase I and chitin synthase II are not required for chitin synthesis in vivo in Saccharomyces cerevisiae.

In Saccharomyces cerevisiae, the polysaccharide chitin forms the primary division septum between mother cell and bud. Two related enzymes, chitin synthase I and chitin synthase II (UDP-acetamido-2-deoxy-D-glucose:chitin 4-beta-acetamidodeoxyglucosyltransferase, EC 2.4.1.16), have been identified and their structural genes, CHS1 and CHS2, respectively, have been cloned and sequenced. Gene disruption experiments led to the conclusion that CHS2 is essential for cell division [Silverman, S.J., Sburlati, A., Slater, M.L. & Cabib, E. (1988) Proc. Natl. Acad. Sci. USA 85, 4735-4739], whereas CHS1 is not. We repeated the disruption of CHS2 and determined that it is not essential for vegetative growth. The viability of chs1::HIS3 chs2::TRP1 spores is influenced by strain background and germination conditions. The double disruption mutant has no detectable chitin deficiency in vivo, as judged by quantitative assay and by staining cells with Calcofluor. Assay of membrane preparations from the double disruption mutant indicates the presence of chitin synthetic activity. Unlike the CHS gene products, this third activity is not stimulated by trypsin. Characterization of the double disruption mutant revealed abnormalities in morphology and nuclear migration.

Isolation and characterization of Escherichia coli strains defective in CDP-diglyceride hydrolase.

CDP-diglyceride, an obligatory intermediate in the biosynthesis of the glycerophospholipids in Escherichia coli, is cleaved in vitro to phosphatidic acid and CMP by a membrane-bound hydrolase. Previous work from our laboratory (Bulawa, C.E., Hermes, J.D., and Raetz, C. R. H. (1983) J. Biol. Chem. 258, 14974-14980) has demonstrated that this enzyme also catalyzes the transfer of CMP from CDP-diglyceride to phosphate and numerous phosphomonoesters. We now report the isolation of E. coli mutants which are defective in CDP-diglyceride hydrolase. These mutations, designated cdh, map at minute 88 between pfkA and tpi. This information permitted the identification of a ColE1 hybrid plasmid, pLC16-4, which causes the overproduction of hydrolase activity. The isolation of deletion and Tn10 insertion mutants at cdh suggests that the hydrolase is nonessential for cell growth. Hydrolase mutants are defective in both CDP-diglyceride hydrolysis and CDP-diglyceride-dependent cytidylylation, indicating that both activities are encoded by the cdh gene. Although previously described as a ribospecific enzyme, we have found that incubation of the partially purified hydrolase with [alpha-32P]dCDP-diglyceride and phosphate yields two products, [32P]dCMP and [alpha-32P]dCDP. That a single enzyme utilizes both CDP- and dCDP-diglyceride is demonstrated by the following. (i) The hydrolysis of [alpha-32P]CDP-diglyceride is inhibited by nonradioactive dCDP-diglyceride and vice versa. (ii) Utilization of both liponucleotides is inhibited by AMP. (iii) Mutants in the cdh gene are defective in both CDP- and dCDP-diglyceride hydrolysis, while cdh clones overproduce both activities. (iv) Hydrolase mutants accumulate both CDP- and dCDP-diglyceride.

Biosynthesis of lipid A precursors in Escherichia coli. A membrane-bound enzyme that transfers a palmitoyl residue from a glycerophospholipid to lipid X.

Certain phosphatidylglycerol-deficient mutants of Escherichia coli accumulate two fatty acylated monosaccharides related to lipid A biosynthesis that have been identified as 2,3-diacylglucosamine 1-phosphate (lipid X) and triacylglucosamine 1-phosphate (lipid Y) (Raetz, C. R. H. (1984) Rev. Infect. Dis. 6, 463-472). Lipid Y has the same structure as lipid X, except that it bears an additional palmitoyl moiety, esterified to the 3-OH of the N-linked R-3-hydroxymyristoyl residue. We now describe a membrane-associated system for the enzymatic conversion of lipid X to lipid Y. Removal of glycerophospholipids form such membranes by washing with cold ethanol abolishes the activity. The system can be reactivated by the addition of exogenous phospholipids dispersed as mixed micelles with Triton X-100. When reconstituted in this manner, the formation of lipid Y is strictly dependent upon a glycerophospholipid donor bearing a palmitoyl residue in the sn-1 position. The enzyme system does not utilize palmitoyl coenzyme A or palmitoyl acyl carrier protein. It does not catalyze efficient transfer of fatty acids differing from palmitate by only one carbon atom. In contrast, the enzyme has relatively little specificity for the polar headgroup of the phospholipid donor, and it also appears to utilize a disaccharide precursor of lipid A as an alternative palmitoyl acceptor. Since the in vitro synthesis of lipid Y proceeds with a high yield, we have isolated the product and verified its structure by 1H NMR spectroscopy and mass spectrometry. The transesterification reaction that converts lipid X to lipid Y may be a model for the enzymatic synthesis of other acyloxyacyl structures, known to occur in mature lipid A.

Two interacting mutations causing temperature-sensitive phosphatidylglycerol synthesis in Escherichia coli membranes.

A conditionally lethal mutant of Escherichia coli lacking phosphatidylglycerol in vivo at 42 degrees C has been previously isolated by two-stage mutagenesis (M. Nishijima and C. R. H. Raetz, J. Biol. Chem. 254:7837-7844, 1979). In the first step (designated pgsA444) the phosphatidylglycerophosphate synthetase is partially inactivated, but the resulting strain continues to make about two-thirds of the normal level of phosphatidylglycerol and is not temperature sensitive. The second lesion, termed pgsB1, causes temperature-sensitive growth and phosphatidylglycerol synthesis in strains harboring pgsA444. The pgsA locus appears to be the structural gene for the synthetase and maps near min 42. In the present study we mapped the pgsB1 mutation and characterized its interaction with pgsA444 by genetic and biochemical methods. Unexpectedly, pgsB1 was not a second lesion in the pgsA structural gene, but rather mapped at a distinct site near minute 4. P1 vir-mediated contransduction suggested the gene order pantonA-dapD-pgsB-dnaE (clockwise). Independent evidence for the genetic mapping was provided by the identification of two hybrid ColE1 plasmids (pLC26-43 and pLC34-20. L. Clarke and J. Carbon, Cell 9:91-99, 1976) which both carry pgsB+ and dnaE+. Introduction of either the pgsA+ or the pgsB+ gene (via episomes, hybrid plasmids or P1 vir transduction) suppressed the temperature sensitivity of the double mutant (pgsA444 pgsB1) and restored normal levels of phosphatidylglycerol at 42 degrees C. In addition, strains with the pgsA+ pgsB1 genotype produced a novel lipid (X) at all temperatures, whereas the double mutant (pgsA444 pgsB1) contained two unusual lipids (X and Y) after 3 h at 42 degrees C. Both X and Y are precursors of lipopolysaccharide, and introduction of pgsB+ into the double mutant caused the disappearance of X and Y. Although the biochemical basis of the pgsB1 lesion is unknown, its existence suggests a previously unrecognized link between lipopolysaccharide and phosphatidylglycerol syntheses in E. coli.

Molecular cloning and sequencing of the gene for CDP-diglyceride hydrolase of Escherichia coli.

Previous work from this laboratory had demonstrated that CDP-diglyceride hydrolase of Escherichia coli is encoded by the cdh gene that maps near minute 88 (Bulawa, C. E., and Raetz, C. R. H. (1984) J. Biol. Chem. 259, 11257-11264). We now report the construction of hybrid plasmids and the sequencing of a 1,243-base pair insert carrying cdh. The further construction of BAL31 deletions of this insert, in conjunction with maxicell experiments and in vitro enzyme assay, has led to the identification of a 756-base pair coding sequence for the cdh polypeptide. The molecular weight of the primary translation product deduced from the DNA sequence of the cdh gene is 28,450, in agreement with maxicell experiments. Parallel purification of the enzyme from extracts of wild-type and overproducing strains confirms the presence of a 27-kDa polypeptide in the overproducer, as judged by polyacrylamide gel electrophoresis of the most purified fractions. Inspection of the DNA sequence reveals a very hydrophobic N-terminal domain that may be either a signal peptide or a special region, anchoring the hydrolase to the membrane. In contrast to the CDP-diglyceride synthetase, the overall amino acid composition of the CDP-diglyceride hydrolase is not extraordinarily hydrophobic. Although both CDP-diglyceride synthetase and CDP-diglyceride hydrolase can transfer the CMP moiety of CDP-diglyceride to a suitable acceptor, the primary structures and mechanisms of action of these two enzymes are very different.

The biosynthesis of gram-negative endotoxin. Formation of lipid A precursors from UDP-GlcNAc in extracts of Escherichia coli.

The Gram-negative bacterium Escherichia coli has previously been shown to utilize two unique glucosamine (GlcN)-derived phospholipids in the biosynthesis of lipid A disaccharides (Bulawa, C.E., and Raetz, C. R.H. (1984) J. Biol. Chem. 259, 4846-4851; Ray, B. L., Painter, G.L., and Raetz, C.R.H. (1984) J. Biol. Chem. 259, 4852-4859. We now present evidence that these compounds, UDP-2,3-diacyl-GlcN and 2,3-diacyl-GlcN-1-phosphate (2,3-diacyl-GlcN-1-P), are generated in extracts of E. coli by fatty acylation of UDP-GlcNAc. The initial reaction is an O-acylation of the glucosamine ring, presumably of the 3-OH group, with (R)-beta-hydroxymyristate, followed by removal of the acetyl moiety, and further fatty acylation of the N atom with (R)-beta-hydroxymyristate to yield UDP-2,3-diacyl-GlcN. Hydrolysis of the pyrophosphate bridge in this molecule gives 2,3-diacyl-GlcN-1-P + UMP. In vivo pulse labeling with 32Pi supports this postulated pathway, since UDP-2,3-diacyl-GlcN is labeled prior to 2,3-diacyl-GlcN-1-P. UDP-glucosamine is inactive as a substrate in the initial acylation reaction. These acylations show an absolute specificity for fatty acyl moieties activated with acyl carrier protein. No reaction is detected with fatty acyl-CoA or free fatty acid. The fatty acylation of sugar nucleotides has not been reported previously in E. coli or any other organism.

Chloroform-soluble nucleotides in Escherichia coli. Role of CDP-diglyceride in the enzymatic cytidylylation of phosphomonoester acceptors.

CDP-diglyceride, the precursor of all the phospholipids in Escherichia coli, is cleaved in vitro to phosphatidic acid and CMP by a membrane-bound hydrolase. Since the physiological function of CDP-diglyceride hydrolase is unknown, we have explored the possibility that this enzyme acts in vivo as either a phosphatidyl- or cytidylyltransferase. To distinguish between these two alternatives, partially purified hydrolase was incubated with CDP-diglyceride in the presence of 50% H218O. Analysis of the reaction products by 31P NMR showed that 18O is incorporated exclusively into CMP, suggesting that the enzyme is a cytidylyltransferase. This conclusion is further supported by the following experimental results: (i) the hydrolase catalyzes the transfer of CMP from CDP-diglyceride to Pi; (ii) numerous phosphomonoesters, such as glycerol 3-phosphate, phosphoserine, and glucose 1-phosphate also function as CMP acceptors, but the corresponding compounds lacking the phosphate residues are not substrates for the enzyme; and (iii) CDP-diglyceride hydrolase exchanges [32P]phosphatidic acid for the phosphatidyl moiety of CDP-diglyceride and 32Pi for the beta-phosphate residue of CDP, indicating the involvement of a novel CMP-enzyme complex. These data suggest a biosynthetic role for CDP-diglyceride hydrolase, and extend the possible functions of CDP-diglyceride in the E. coli envelope.

Enzymatic sorting of bacterial colonies on filter paper replicas: detection of labile activities.

To utilize autoradiographic colony-sorting techniques (C. R. H. Raetz, Proc. Natl. Acad. Sci. U.S.A. 72:2274-2278, 1975) for the isolation of mutants with unstable enzymes, we report a new desiccation-induced lysis method, compatible with low temperatures. Furthermore, a general, two-step protocol is presented for clonal detection of hydrolytic reactions. The advantages of these critical modifications are demonstrated with the membrane enzymes glycerol 3-phosphate acyltransferase and cytidine 5'-diphosphate-diglyceride hydrolase.

Attenuated virulence of chitin-deficient mutants of Candida albicans.

We have analyzed the role of chitin, a cell-wall polysaccharide, in the virulence of Candida albicans. Mutants with a 5-fold reduction in chitin were obtained in two ways: (i) by selecting mutants resistant to Calcofluor, a fluorescent dye that binds to chitin and inhibits growth, and (ii) by disrupting CHS3, the C. albicans homolog of CSD2/CAL1/DIT101/KT12, a Saccharomyces cerevisiae gene required for synthesis of approximately 90% of the cell-wall chitin. Chitin-deficient mutants have no obvious alterations in growth rate, sugar assimilation, chlamydospore formation, or germ-tube formation in various media. When growing vegetatively in liquid media, the mutants tend to clump and display minor changes in morphology. Staining of cells with the fluorescent dye Calcofluor indicates that CHS3 is required for synthesis of the chitin rings found on the surface of yeast cells but not formation of septa in either yeast cells or germ tubes. Despite their relatively normal growth, the mutants are significantly less virulent than the parental strain in both immunocompetent and immunosuppressed mice; at 13 days after infection, survival was 95% in immunocompetent mice that received chs3/chs3 cells and 10% in immunocompetent mice that received an equal dose of chs3/CHS3 cells. Chitin-deficient strains can colonize the organs of infected mice, suggesting that the reduced virulence of the mutants is not due to accelerated clearing.

The S. cerevisiae structural gene for chitin synthase is not required for chitin synthesis in vivo.

The chitin synthase of Saccharomyces is a plasma membrane-bound zymogen. Following proteolytic activation, the enzyme synthesizes insoluble chitin that has chain length and other physical properties similar to chitin found in bud scars. We isolated mutants lacking chitin synthase activity (chs1) and used these to clone CHS1. The gene has an open reading frame of 3400 bases and encodes a protein of 130 kd. The fission yeast S. pombe lacks chitin synthase and chitin. When a plasmid encoding a CHS1-lacZ fusion protein is introduced into S. pombe, both enzymatic activities are expressed in the same ratio as in S. cerevisiae, demonstrating that CHS1 encodes the structural gene of chitin synthase. Three CHS1 gene disruption experiments were performed. In all cases, strains with the disrupted gene have a recognizable phenotype, lack measurable chitin synthase activity in vitro but are viable, contain normal levels of chitin in vivo, and mate and sporulate efficiently.

Altered expression of selectable marker URA3 in gene-disrupted Candida albicans strains complicates interpretation of virulence studies.

The ura-blaster technique for the disruption of Candida albicans genes has been employed in a number of studies to identify possible genes encoding virulence factors of this fungal pathogen. In this study, the URA3-encoded orotidine 5'-monophosphate (OMP) decarboxylase enzyme activities of C. albicans strains with ura-blaster-mediated genetic disruptions were measured. All strains harboring genetic lesions via the ura-blaster construct showed reduced OMP decarboxylase activities compared to that of the wild type when assayed. The activity levels in different gene disruptions varied, suggesting a positional effect on the level of gene expression. Because the URA3 gene of C. albicans has previously been identified as a virulence factor for this microorganism, our results suggest that decreased virulence observed in strains constructed with the ura-blaster cassette cannot accurately be attributed, in all cases, to the targeted genetic disruption. Although revised methods for validating a URA3-disrupted gene as a target for antifungal drug development could be devised, it is clearly desirable to replace URA3 with a different selectable marker that does not influence virulence.

The chsB gene of Aspergillus nidulans is necessary for normal hyphal growth and development.

The chsB gene from Aspergillus nidulans encodes a class III chitin synthase, an enzyme class found in filamentous fungi but not in yeast-like organisms. Using a novel method, we isolated haploid segregants carrying a disrupted chsB allele from heterozygous diploid disruptants. The haploid disruptants grow as minute colonies that do not conidiate. Hyphae from the disruptants have enlarged tips, a high degree of branching, and disorganized lateral walls. The mycelium is not deficient in chitin content and shows no evidence of lysis. The disruptant phenotype is not remedied by osmotic stabilizers. The results indicate that chitin synthesized by the chsB-encoded enzyme does not substantially contribute to the rigidity of the cell wall but is necessary for normal hyphal growth and organization. The properties of the A. nidulans disruptant are similar to those for Neurospora crassa strains with a disrupted chs-1 gene, which also encodes a class III chitin synthase. The morphology of an A. nidulans heterokaryon containing both the wild-type and the disrupted chsB alleles indicates that chsB acts in local areas of the mycelium. The heterokaryon produces conidia of both parental genotypes in nearly equal numbers, indicating that the wild-type chsB gene is not necessary for conidium formation. In addition, we identified and sequenced a second, previously undescribed, homolog of chsB from the closely related opportunistic pathogen, A. fumigatus. The finding of two class III chitin synthase genes in A. fumigatus and a single gene of this class in A. nidulans illustrates limitations of using A. nidulans as a genetic model for A. fumigatus.

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.

The chsD and chsE genes of Aspergillus nidulans and their roles in chitin synthesis.

Two chitin synthase genes, chsD and chsE, were identified from the filamentous ascomycete Aspergillus nidulans. In a region that is conserved among chitin synthases, the deduced amino acid sequences of chsD and chsE have greater sequence identity to the polypeptides encoded by the Saccharomyces cerevisiae CHS3 gene (also named CSD2, CAL1, DIT101, and KTI1) and the Candida albicans CHSE gene than to other chitin synthases. chsE is more closely related to the CHS3 genes, and this group constitutes the class IV chitin synthases. chsD differs sufficiently from the other classes of fungal chitin synthase genes to constitute a new class, class V. Each of the wild-type A. nidulans genes was replaced by a copy that had a substantial fraction of its coding region replaced by the A. nidulans argB gene. Hyphae from both chsD and chsE disruptants contain about 60-70% of the chitin content of wild-type hyphae. The morphology and development of chsE disruptants are indistinguishable from those of wild type. Nearly all of the conidia of chsD disruption strains swell excessively and lyse when germinated in low osmotic strength medium. Conidia that do not lyse produce hyphae that initially have normal morphology but subsequently lyse at subapical locations and show ballooned walls along their length. The lysis of germinating conidia and hyphae of chsD disruptants is prevented by the presence of osmotic stabilizers in the medium. Conidiophore vesicles from chsD disruption strains frequently swell excessively and lyse, resulting in colonies that show reduced conidiation. These properties indicate that chitin synthesized by the chsD-encoded isozyme contributes to the rigidity of the walls of germinating conidia, of the subapical region of hyphae, and of conidiophore vesicles, but is not necessary for normal morphology of these cells. The phenotypes of chsD and chsE disruptants indicate that the chitin synthesized by each isozyme serves a distinct function. The propensity of a chsD disruptant for osmotically induced lysis was compared to that of strains carrying two other mutations (tsE6 and orlA::trpC) which also result in reduced chitin content vegetative cell lysis. The concentration of osmotic stabilizer necessary to remedy the lysis of strains carrying the three mutations is inversely related to the chitin content of each strain. This finding directly demonstrates the importance of chitin to the integrity of the cell wall and indicates that agents that inhibit the chsD-encoded chitin synthase could be useful anti-Aspergillus drugs.