Biosynthesis of yeast mannan. Properties of a mannosylphosphate transferase in Saccharomyces cerevisiae.

A homogenate of mechanically broken, freshly grown Saccharomyces cerevisiae X2180 cells catalyzes the transfer of mannosylphosphate units from guanosine diphosphate mannose to reduced alpha1 leads to 2-[3H]mannotetraose to yield reduced mannosylphosphoryl [3H]-mannotetraose. The product is analogous in structure to the phosphorylated mannan side chains, which suggests that the enzymic activity is involved in mannoprotein biosynthesis in the intact cell. The mannosylphosphate transferase activity, localized in a membrane fraction obtained by differential centrifugation at 100,000 x g, was solubilized by Triton X-155 and purified 250-fold by ammonium sulfate precipitation and by ion exchange and gell filtration chromatographies. The enzyme requires MN2+ OR Co2+ ions for activity and is stimulated by various detergents. The mnn2 and mnn3 mannan mutants of S. cerevisiae possess normal levels of mannosylphosphate transferase activity, whereas the mnn4 mutant cells contain very low, if any, activity. This is consistent with a previous conclusion that the mnn4 mutation affects the mannosylphosphate transferase activity, whereas the mnn2 and mnn3 strains possess phosphate-deficient mannans because they are unable to synthesize the appropriate side chain precursors. A new mannan mutant class with the mnn4 chemotype was isolated, but the mutation proved to be recessive and nonallelic with the mnn4 locus. This new locus is designated mnn6.     

Fungal cell wall phosphomannans facilitate the toxic activity of a plant PR-5 protein

Osmotin is a plant PR-5 protein. It has a broad spectrum of antifungal activity, yet also exhibits specificity for certain fungal targets. The structural bases for this specificity remain unknown. We show here that full sensitivity of Saccharomyces cerevisiae cells to the PR-5 protein osmotin is dependent on the function of MNN2, MNN4 and MNN6. MNN2 is an alpha-1, 2-mannosyltransferase catalyzing the addition of the first mannose to the branches on the poly l,6-mannose backbone of the outer chain of cell wall N-linked mannans. MNN4 and MNN6 are required for the transfer of mannosylphosphate to cell wall mannans. Null mnn2, mnn4 or mnn6 mutants lack phosphomannans and are defective in binding osmotin to the fungal cell wall. Both antimannoprotein antibody and the cationic dye alcian blue protect cells against osmotin cytotoxicity. MNN1 is an alpha-1,3-mannosyltransferase that adds the terminal mannose to the outer chain branches of N-linked mannan, masking mannosylphosphate. Null mnn1 cells exhibit enhanced osmotin binding and sensitivity. Several cell wall mannoproteins can bind to immobilized osmotin, suggesting that their polysaccharide constituent determines osmotin binding. Our results demonstrating a causal relationship between cell surface phosphomannan and the susceptibility of a yeast strain to osmotin suggest that cell surface polysaccharides of invading pathogens control target specificity of plant PR-5 proteins.     

Loss of cell wall mannosylphosphate in Candida albicans does not influence macrophage recognition

The outer layer of the cell wall of the human pathogenic fungus Candida albicans is enriched with heavily mannosylated glycoproteins that are the immediate point of contact between the fungus and cells of the host, including phagocytes. Previous work had identified components of the acid-labile fraction of N-linked mannan, comprising beta-1,2-linked mannose residues attached via a phosphodiester bond, as potential ligands for macrophage receptors and modulators of macrophage function. We therefore isolated and disrupted the CaMNN4 gene, which is required for mannosyl phosphate transfer and hence the attachment of beta-1,2 mannose oligosaccharides to the acid-labile N-mannan side chains. With the mannosylphosphate eliminated, the mnn4Delta null mutant was unable to bind the charged cationic dye Alcian Blue and was devoid of acid-labile beta-1,2-linked oligomannosaccharides. The mnn4Delta mutant was unaffected in cell growth and morphogenesis in vitro and in virulence in a murine model of systemic C. albicans infection. The null mutant was also not affected in its interaction with macrophages. Mannosylphosphate is therefore not required for macrophage interactions or for virulence of C. albicans.     

Yeast mannan structure necessary for co-aggregation with Lactobacillus plantarum ML11-11

Lactic acid bacteria (LAB) Lactobacillus plantarum ML11-11, an isolate from Fukuyama pot vinegar, and yeast Saccharomyces cerevisiae form significant mixed-species biofilm with direct cell-cell contact. Co-aggregation of L. plantarum ML11-11 and S. cerevisiae cells, mediated by the interaction between surface protein(s) on L. plantarum ML11-11 cells and surface mannan of S. cerevisiae cells, contributes significantly to mixed-species biofilm formation. In this study, co-aggregation activities of yeast mutants that were deleted of genes related to mannan biosynthesis were investigated to clarify the mannan structures essential for interaction with L. plantarum ML11-11. Among the 12 deletion mutants which had various incomplete mannan structures, only the mnn2 mutant lost the co-aggregation activity. In the mnn2 mutant, the gene coding the activity of attaching first branching mannose residue to mannan main chain is deleted and therefore the mnn2 mutant has unbranched mannan. From this result, it is clarified that the specific structure, consisted of mannan main chain to which are attached side chains containing one or more mannose residues, is critical for co-aggregation with L. plantarum ML11-11.     

The mnn2 mutant of Saccharomyces cerevisiae is affected in phosphorylation of N-linked oligosaccharides

We studied the phosphorylation of the inner core region of N-linked oligosaccharides in the mannan defective mutant Saccharomyces cerevisiae mnn2 which was described as unable to synthesize branches on the outer chain. We performed structural studies of the N-oligosaccharides synthesized by the strains mnn2, mnn1mnn2mnn9 and mnn1mnn9ldb8, and the results are compared with previously published structural data of mnn1mnn2mnn10 and mnn1mnn9 [Hernández, L.M., Ballou, L., Alvarado, E., Tsai, P.-K. and Ballou, C.E. (1989) J. Biol. Chem. 264, 13648-13659]. We conclude that the mnn2/ldb8 mutation is responsible for the inhibition of incorporation of phosphate to mannose A(3) (see below), a particular phosphorylation site of the inner core, while phosphorylation at the other possible site (mannose C(1)) is allowed, although it is also reduced. *Phosphorylation sites in mnn1mnn9. (see structure below)     

Biosynthesis of yeast mannan. Isolation of Kluyveromyces lactis mannan mutants and a study of the incorporation of N-acetyl-D-glucosamine into the polysaccharide side chains.

One side chain in the cell wall mannan of the yeast Kluyveromyces lactis has the structure (see article). (Raschke, W. C., and Ballou, C. E. (1972) Biochemistry 11, 3807). This (Man)4GNAc unit (the N-acetyl-D-glucosamine derivative of mannotetroase) and the (Man)4 side chain, aMan(1 yields 3)aMan(1 yields 2)aMan(1 yields 2)Man, are the principle immunochemical determinants on the cell surface. Two classes of mutants were obtained which lack the N-acetyl-D-glucosamine-containing determinant. The mannan of one class, designated mmnl, lacks both the (Man)4GNAc and (Man)4 side chains. Apparently, it has a defective alpha-1 yields 3-mannosyltransferase and the (Man)4 unit must be formed to serve as the acceptor before the alpha-1 yields 2-N-acetyl-glucosamine transferase can act. The other mutant class, mnn2, lacks only the (Man)4GNAc determinant and must be defective in adding N-acetylglucosamine to the mannotetrasose side chains. Two members of this class were obtained, one which still showed a wild type N-acetylglucosamine transferase activity in cell-free extracts and the other lacking it. They are allelic or tightly linked, and were designated mnn2-1 mnn2-2. Protoplast particles from the wild type cells catalyzed a Mn2+-dependent transfer of N-acetylglucosamine from UDP-N-acetylglucosamine to the mannotetraose side chain of endogenous acceptors. Exogenous mannotetraose also served as an acceptor in a Mn2+-dependent reaction and yielded (Man)4GNAc. Related oligosaccharides with terminal alpha (1 yields 3)mannosyl units were also good acceptors. The product from the reaction with alphaMan(1 yields 3)Man had the N-acetylglucosamine attached to the mannose unit at the reducing end, which supports the conclusion that the cell-free glycosyltransferase activity is identical with that involved in mannan synthesis. The reaction was inhibited by uridine diphosphate. Protoplast particles from the mmnl mutants showed wild type N-acetylglucosamine transferase activity with exogenous acceptor, but they had no endogenous activity because the endogenous mannan lacked acceptor side chains. Particles from the mnn2-1 mutant failed to catalyze N-acetylglucosamine transfer. In contrast, particles from the mnn2-2 mutant were indistinguishable from wild type cells in their transferase activity. Some event accompanying cell breakage and assay of the mnn2-2 mutant allowed expression of a latent alpha-1 yields 2-N-acetylglucosamine transferase with kinetic properties similar to those of the wild type enzyme.     

黑曲霉mnn9基因缺失株的构建及其功能分析

本研究通过分析比较黑曲霉基因组与酿酒酵母基因组序列同源性,分离鉴定了黑曲霉mnn9基因。通过同源重组,在黑曲霉GICC2773(ΔAP4:pGPT-laccase)菌株中敲除了mnn9基因。该黑曲霉mnn9基因缺失使外源蛋白漆酶的分泌表达提高了14%,内源蛋白葡萄糖淀粉酶的分泌表达则降低了4%。     

Biosynthesis of yeast mannan. Characterization of mannan-synthesizing enzyme systems from mutants defective in mannan structure

The yeastSaccharomyces cerevisiae X2180-1A (wild) and its mutants X2180-1A-4 (mnn 1) and X2180-1A-5 (mnn 2) defective in mannan biosynthesis were used as enzyme sources to catalyzein vitro mannosyl transfer from GDP-[¹⁴C-U]-mannose to endogenous glycoproteins as well as to exogenous, low-molecular weight acceptors. While the enzyme preparation from the wild strain exhibited all mannosyl transferase activities involved in mannan biosynthesis by catalyzing the synthesis of characteristic mannoprotein, the enzyme frommnn 1 mutant failed to catalyze the synthesis of α(1→3) mannoside linkages both with endogenous as well as with exogenous acceptors. The enzyme preparation from themnn 2 mutant catalyzed the formation of mannoprotein very similar to that obtained with the enzyme from the wild strain. The most important difference was the formation of a higher number of unsubstituted mannosyl units in the α(1→ 6) linked mannan backbone. The observed results support the hypothesis that in themnn 1 the mutation has altered the structural gene involved in biosynthesis of an α(1→3) mannosyl transferase catalyzing the addition of α(1→3) linked mannosyl units to α(1→2) linked mannotrioses in the polysaccharide side chains and in the oligosaccharides attached to serine and/or threonine in the protein part of mannan molecule. Themnn 2 mutant represents most probably a kind of regulatory mutation where the activity of an α(1→2) mannosyl transferase adding the mannosyl units directly to α(1→6) linked backbone in the outer region of polysacoharide part of yeast mannan is repressedin vivo but becomes significantin vitro.     

Surface hydrophobicity changes of two Candida albicans serotype B mnn4delta mutants

Cell surface hydrophobicity (CSH) of Candida species enhances virulence by promoting adhesion to host tissues. Biochemical analysis of yeast cell walls has demonstrated that the most significant differences between hydrophobic and hydrophilic yeasts are found in the acid-labile fraction of Candida albicans phosphomannoprotein, suggesting that this fraction is important in the regulation of the CSH phenotype. The acid-labile fraction of C. albicans is unique among fungi, in that it is composed of an extended polymer of beta-1,2-mannose linked to the acid-stable region of the N-glycan by a phosphodiester bond. C. albicans serotype A and B strains both contain a beta-1,2-mannose acid-labile moiety, but only serotype A strains contain additional beta-1,2-mannose in the acid-stable region. A knockout of the C. albicans homolog of the Saccharomyces cerevisiae MNN4 gene was generated in two serotype B C. albicans patient isolates by using homologous gene replacement techniques, with the anticipation that they would be deficient in the acid-labile fraction and, therefore, demonstrate perturbed CSH. The resulting mnn4delta-deficient derivative has no detectable phosphate-linked beta-1,2-mannose in its cell wall, and hydrophobicity is increased significantly under conditions that promote the hydrophilic phenotype. The mnn4delta mutant also demonstrates an unanticipated perturbation in the acid-stable mannan fraction. The present study reports the first genetic knockout constructed in a serotype B C. albicans strain and represents an important step for dissecting the regulation of CSH.     

Purification of an alpha-N-acetylglucosaminyltransferase from the yeast Kluyveromyces lactis and a study of mutants defective in this enzyme activity

An enzyme activity in Kluyveromyces lactis that catalyzes the transfer of N-acetylglucosamine from uridine diphosphate N-acetylglucosamine to alpha Man(1 leads to 3) alpha Man ( 1 leads to 2) alpha Man (1 leads to 2)Man to yield alpha Man(1 leads to 3) [alpha GlcNAc(1 leads to 2)] alpha Man(1 leads to 2) alpha Man (1 leads to 2)Man, a mannoprotein side-chain unit, has been solubilized by Triton X-100 and purified 18000-fold by a combination of ion-exchange chromatography, gel filtration, hydrophobic chromatography, and adsorption to a lectin column. The enzyme activity from a K. lactis mutant (mnn2-2) that made mannoprotein lacking N-acetylglucosamine in its side chains, but that possessed a normal level of transferase activity in cell extracts, was purified and compared with the enzyme from the wild-type strain. Both transferase activities are integral membrane proteins found in particles associated with endoplasmic reticulum. The two purified enzymes had the same apparent size, heat stability, Mn2+ requirement, and Km for donor and acceptor and a similar Vmax. Wild-type and mutant cells had similar pool sizes of sugar nucleotide donor, and they incorporated labeled N-acetylglucosamine into chitin at similar rates. No evidence was obtained for an inactive enzyme precursor in mutant cells that was activated upon breaking the cells, nor did the mutant cells contain a transferase inhibitor or a hexosaminidase that could remove the sugar from the mannoprotein during processing and secretion. The mnn2-2 locus appears to be allelic with a second mutant, mnn2-1, that has the same phenotype but that lacks transferase activity in cell extracts. This suggests that the two mutations affect the structural gene for the transferase, and we conclude that the mnn2-2 mutant could contain an altered enzyme that fails to function because it is improperly localized or oriented in the membrane.     

Structure of the phosphorylated N-linked oligosaccharides from the mnn9 and mnn10 mutants of Saccharomyces cerevisiae

The N-linked oligosaccharides, from Saccharomyces cerevisiae mnn1 mnn9 mutant mannoprotein extracted from the cells in hot citrate buffer, were separated by ion exchange into a monophosphate diester, a monophosphate monoester, a diphosphate diester, and a diphosphate monoester diester. The structures of the major components with diesterified phosphate were assigned as follows (where M = mannose), according to a recently revised oligosaccharide structure for the mnn mutants (Hernandez, L. M., Ballou, L., Alvarado, E., Gillece-Castro, B. L., Burlingame, A. L., and Ballou, C. E. (1989) J. Biol. Chem. 264, 11849-11856). formula; see text The monoester derivatives were mixtures of the possible isomers produced by removal of one or the other phosphoglycosyl-linked mannose units, and they were shown to arise by chemical degradation during isolation. The mnn1 mnn2 mnn10 acidic oligosaccharide fraction contained a mono- and a diphosphate ester. The monophosphate consisted predominantly of a single isomer with a mannosyl phosphate unit located at the end of the outer chain in an oligosaccharide with the following structure, where x may range from 2 to 12. The diphosphate had a mannosyl phosphate in this formula; see text position as well as one on the terminal alpha 1----6-linked mannose in the core. The presence in the mnn1 mnn9 or mnn1 mnn2 mnn10 background of the mnn4 or mnn6 mutations, which are known to regulate phosphorylation in yeast, reduced phosphorylation by 90% but did not eliminate it. AI-12522     

A new Saccharomyces cerevisiae mnn mutant N-linked oligosaccharide structure

We find that the N-linked Man8GlcNAc2- core oligosaccharide of Saccharomyces cerevisiae mnn mutant mannoproteins is enlarged by the addition of the outer chain to the alpha 1----3-linked mannose in the side chain that is attached to the beta 1----4-linked mannose rather than by addition to the terminal alpha 1----6-linked mannose. This conclusion is derived from structural studies on a phosphorylated oligosaccharide fraction and from mass spectral fragment analysis of neutral core oligosaccharides.     

Protein glycosylation defects in the Saccharomyces cerevisiae mnn7 mutant class. Support for the stop signal proposed for regulation of outer chain elongation

Total cell mannoprotein was isolated from Saccharomyces cerevisiae X2180 mutants that have defects in elongation of the outer chain attached to the N-linked core oligosaccharides (mnn7, mnn8, mnn9, and mnn10) (Ballou, L., Cohen, R. E., and Ballou, C. E. (1980) J. Biol. Chem. 255, 5986-5991). Comparison of the oligosaccharides released by endoglucosaminidase H digestion confirmed that the mnn9 mutation eliminates all but two mannoses of the outer chain, whereas the mnn8 and mnn10 strains produce outer chains of variable but similar lengths. The isolate designated mnn7 was found to be allelic with mnn8. Haploid mutants of the type mnn8 mnn9 or mnn9 mnn10 had the mnn9 phenotype, which established that the mnn9 defect is dominant and presumably acts at a processing step prior to the steps affected by mnn8 and mnn10. Analysis of the mnn1 mnn2 mnn10 oligosaccharides revealed that the heterogeneous outer chain contained 6-16 alpha 1----6-linked mannose units and each was terminated by a single alpha 1----2-linked mannose unit, whereas the core lacked one such unit that was present in the mnn9 oligosaccharide. The results are consistent with and support the hypothesis (Gopal, P. K., and Ballou, C. E. (1988) Proc. Natl. Acad. Sci. U.S.A. 84, 8824-8828) that addition of such a side-chain mannose unit is associated with termination of outer chain elongation in these mutants and may serve as a stop signal that regulates outer chain synthesis in the parent wild-type strain.     

The involvement of mnn4 and mnn6 mutations in mannosylphosphorylation of O-linked oligosaccharide in yeast Saccharomyces cerevisiae

The structure of O-linked acidic oligosaccharide from Saccharomyces cerevisiae was analyzed. The chitinase, exclusively O-glycosylated extracelluar protein, was purified from strains mnn1, mnn1 mnn4, mnn1 mnn6 and Δkre2 and the oligosaccharides were hydrolyzed by O-linked sugar chain specific hydrazinolysis. The mannosylphosphorylated mannotriose (M3-P-M) was detected in strain mnn1, but not in the other three strains (mnn1 mnn4, mnn1 mnn6 and Δkre2). α-Mannosidase treatment and matrix-assisted laser desorption ionization time-of-flight mass spectrometry of mannosylphosphorylated mannotriose revealed that mannosylphosphate was attached to a middle mannose of α-1,2-linked mannotriose. This result indicates that the mnn4 and mnn6 mutations affect the mannosylphosphorylation of O-linked oligosaccharide, together with that of N-linked oligosaccharide. The amount of mannosylphosphorylated mannotriose was 7% of total O-linked oligosaccharides (20% of neutral mannotriose) of chitinase in strain mnn1.     

Different composition of the cell wall polysaccharides in Saccharomyces cerevisiae S288 and in an osmosis sensitive mutant]

Determination of the polysaccharide contents and structural studies on the mannan by acetolysis and permethylation analysis shows an altered polysaccharide biosynthesis of the osmotic-sensitive mutant VY 1160 of Saccharomyces cerevisiae S 288. The mutant contains more glucan, less mannan, and less alkali-soluble glycogen. Its mannan is characterized by more short side chains and less long side chains. Its main chain is 1 leads to 6-linked, but its side chains consist of more 1 leads to 3- than 1 leads to 2-linked mannose units.     

Localization of alpha 1----3-linked mannoses in the N-linked oligosaccharides of Saccharomyces cerevisiae mnn mutants

Neutral and phosphorylated N-linked oligosaccharides were isolated from Saccharomyces cerevisiae mnn9 and mnn9 gls1 mutant mannoproteins and separated into homologues that differed in the number of terminal alpha 1----3-linked mannoses. In each type of oligosaccharide, the addition of such mannose was shown to occur in an ordered rather than a random fashion. The results confirm and extend an earlier report that dealt with the N-linked oligosaccharides from yeast invertase [Trimble, R.B., & Atkinson, P.H. (1986) J. Biol. Chem. 261, 9815-9824], and they suggest that the postulated processing pathway can be generalized to include phosphorylated and glucose-containing N-linked oligomannosides. We conclude that this processing pathway is identical for the analogous oligosaccharides from the mnn9 and wild-type strains of S. cerevisiae. Analysis of the mnn2 mnn10 mannoprotein revealed that a similar modification occurred at the branched terminus of the outer chain as well as in the core in this mutant.     

Alcian Blue Pyridine Variant-a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

Identification of Two Mannoproteins Released from Cell Walls of a Saccharomyces cerevisiae mnn1 mnn9 Double Mutant by Reducing Agents

In this report, we present the identification of the main polypeptides that are extracted from purified cell walls of a Saccharomyces cerevisiae mnn1 mnn9 strain by reducing agents. Treatment of the purified cell walls of this strain with beta-mercaptoethanol releases several mannoproteins, of which three, with apparent sizes of 120, 45, and 40 kDa, are the most abundant. Analysis of the amino-terminal sequences revealed that the 120-kDa mannoprotein is Bar1p, the protease involved in the so-called barrier activity in yeast cells, and that the 45- and 40-kDa mannoproteins are the Kex2-unprocessed and Kex2-processed forms of the gene product of open reading frame (ORF) YJL158c, an ORF that belongs to the PIR (protein with internal repeats) family of genes, composed thus far of PIR1, PIR2/HSP150, and PIR3. Accordingly we have named this gene PIR4, and Pir4 denotes the 40-kDa Kex2-processed form of the mannoprotein. We have characterized Pir4 and have shown the feasibility of using it as a fusion partner for the targeting of recombinant proteins to the cell wall.     

Alcian Blue Pyridine Variant–a Superior Alternative to Alcian Blue 8GX: Staining Performance and Stability

We compared the staining performance, dye content, solubility, and visual absorption maximum of two batches of alcian blue pyridine variant and of five batches of alcian blue 8GX (C.I. 74240). Whenever possible, we also compared results to those obtained with the same dye batches produced at an earlier date to provide information concerning dye stability. Both alcian blue pyridine variant batches were of high dye content, stable, of satisfactory solubility, and performed well in both the routine Mowry mucin stain and in the critical electrolyte concentration (CEC) stain. Of the five alcian blue 8GX samples, some were also of appropriate dye content, were sufficiently stable, and gave good staining in the two procedures. Two batches, however, were unstable, and three batches were unsatisfactory in staining performance and solubility in the CEC stain. Consequently alcian blue pyridine variant is a superior substitute for alcian blue 8GX.     

The role of the Candida albicans histidine kinase [CHK1) gene in the regulation of cell wall mannan and glucan biosynthesis

The human pathogen Candida albicans encodes at least three putative two-component histidine kinase signal transduction proteins, including Chk1p and a response regulator protein (Cssk1p). Strains deleted in CHK1 are avirulent in a murine model of hematogenously disseminated disease. The specific function of Chk1p has not been established, but hyphae of the chk1 mutant exhibit extensive flocculation while yeast forms are less adherent to reconstituted human esophageal tissue, indicating that this protein may regulate cell surface properties. Herein, we analyze glucan, mannan and chitin profiles in strains deleted in chk1 (CHK21) compared to a gene-reconstituted strain (CHK23) and a parental strain CAF2. Total alkali-soluble hexose from the cell wall of the chk1 mutant (strain CHK21) was significantly reduced. Western blots of cell wall extracts from CHK21, CHK23 and CAF2 reacted with a Mab to the acid-stable mannan fraction revealed extensive staining of lower molecular mass species in strain CHK21 only. FACE (fluorophore assisted carbohydrate electrophoresis) was used to characterize the oligosaccharide side chains of beta-eliminated (O-linked), acid-hydrolyzed (acid-labile phosphomannan) and acetolysis (acid-stable mannan) extracted fractions of total mannan. The profiles of O-linked as well as the acid-labile oligosaccharides were similar in both CAF2 and CHK21, but the acid-stable oligosaccharide side chains were significantly truncated. We also characterized the beta-glucan from each strain using NMR, and found that both the degree of polymerization and the ratio of (1-3)/(1-6) linkages was lower in CHK21 relative to wild-type cells. The sensitivity of CHK21 to antifungal drugs and inhibitors was unaffected. In summary, our data have identified a new function for a histidine kinase two-component signal protein in a human pathogenic fungus.