Crh1p and Crh2p are required for the cross-linking of chitin to beta(1-6)glucan in the Saccharomyces cerevisiae cell wall

In budding yeast, chitin is found in three locations: at the primary septum, largely in free form, at the mother-bud neck, partially linked to beta(1-3)glucan, and in the lateral wall, attached in part to beta(1-6)glucan. By using a recently developed strategy for the study of cell wall cross-links, we have found that chitin linked to beta(1-6)glucan is diminished in mutants of the CRH1 or the CRH2/UTR2 gene and completely absent in a double mutant. This indicates that Crh1p and Crh2p, homologues of glycosyltransferases, ferry chitin chains from chitin synthase III to beta(1-6)glucan. Deletion of CRH1 and/or CRH2 aggravated the defects of fks1Delta and gas1Delta mutants, which are impaired in cell wall synthesis. A temperature shift from 30 degrees C to 38 degrees C increased the proportion of chitin attached to beta(1-6)glucan. The expression of CRH1, but not that of CRH2, was also higher at 38 degrees C in a manner dependent on the cell integrity pathway. Furthermore, the localization of both Crh1p and Crh2p at the cell cortex, the area where the chitin-beta(1-6)glucan complex is found, was greatly enhanced at 38 degrees C. Crh1p and Crh2p are the first proteins directly implicated in the formation of cross-links between cell wall components in fungi.     

Rho1p mutations specific for regulation of beta(1-->3)glucan synthesis and the order of assembly of the yeast cell wall

In the yeast Saccharomyces cerevisiae, the GTP-binding protein Rho1 is required for beta(1-->3)glucan synthase activity, for activation of protein kinase C and the cell integrity pathway and for progression in G1, cell polarization and exocytosis. A genetic screen for cells that become permeabilized at non-permissive temperature was used to isolate in vitro-generated mutants of Rho1p. After undergoing a battery of tests, several of them appeared to be specifically defective in the beta(1-->3) glucan synthesis function of Rho1p. At the non-permissive temperature (37 degrees C), the mutants developed defects in the cell wall, especially at the tip of new buds. In the yeast cell wall, beta(1-->6)glucan is linked to both beta(1-->3)glucan and mannoprotein, as well as occasionally to chitin. We have used the rho1 mutants to study the order of assembly of the cell wall components. The incorporation of [(14)C]-glucose into beta(1-->3)glucan at 37 degrees C was decreased or abolished in the mutants. Concomitantly, a partial defect in the incorporation of label into cell wall mannoproteins and beta(1-->6)glucan was observed. In contrast, YW3458, an inhibitor of glycosylphosphatidylinositol anchor formation, prevented mannoprotein incorporation, whereas the beta(1-->3)-beta(1-->6)glucan complex was synthesized at almost normal levels. As beta(1-->3)glucan can be synthesized in vitro or in vivo independently, we conclude that the order of addition in vivo is beta(1-->3)glucan, beta(1-->6)glucan, mannoprotein. Previous observations indicate that chitin is the last component to be incorporated into the complex.     

A Cdc28 mutant uncouples G1 cyclin phosphorylation and ubiquitination from G1 cyclin proteolysis

Proteolysis of the yeast G(1) cyclins is triggered by their Cdc28-dependent phosphorylation. Phosphorylated Cln1 and Cln2 are ubiquitinated by the SCF-Grr1 complex and then degraded by the 26 S proteasome. In this study, we identified a cak1 allele in a genetic screen for mutants that stabilize the yeast G(1) cyclins. Further characterization showed that Cln2HA was hypophosphorylated, unable to bind Cdc28, and stabilized in cak1 mutants at the restrictive temperature. Hypophosphorylation of Cln2HA could thus explain its stabilization. To test this possibility, we expressed a Cak1-independent mutant of Cdc28 (Cdc28-43244) in cak1 mutants and found that Cln2HA phosphorylation was restored, but surprisingly, the phospho-Cln2HA was stabilized. When bound to Cdc28-43244, Cln2HA was recognized and polyubiquitinated by SCF-Grr1. The Cdc28-43244 mutant thus reveals an unexpected complexity in the degradation of polyubiquitinated Cln2HA by the proteasome.     

Synthase III-dependent chitin is bound to different acceptors depending on location on the cell wall of budding yeast

In yeast, chitin is laid down at three locations: a ring at the mother-bud neck, the primary septum and, after cytokinesis, the cell wall of the daughter cell. Some of the chitin is free and the remainder attached to beta(1-3)glucan or beta(1-6)glucan. We recently reported that the chitin ring contributes to the prevention of growth at the mother-bud neck and hypothesized that this inhibition is achieved by a preferential binding of chitin to beta(1-3)glucan at that site. Here, we devised a novel strategy for the analysis of chitin cross-links in [14C]glucosamine-labeled cell walls, involving solubilization in water of alkali-treated walls by carboxymethylation. Intact cell walls or their digestion products with beta(1-3)glucanase or beta(1-6)glucanase were carboxymethylated and fractionated on size columns, and the percentage of chitin bound to different polysaccharides was calculated. Chitin dispersed in the wall was labeled in maturing unbudded cells and that of the ring in early budding cells. The former was mostly attached to beta(1-6)glucan and the latter to beta(1-3)glucan. This confirmed our hypothesis and indicated that the cell has mechanisms to attach chitin, a water-insoluble substance, synthesized here through chitin synthase III, to different acceptors, depending on location. In contrast, most of the chitin synthase II-dependent chitin of the primary septum was free, with the remainder linked to beta(1-3)glucan.     

Loss of cell wall alpha(1-3) glucan affects Cryptococcus neoformans from ultrastructure to virulence

Yeast cell walls are critical for maintaining cell integrity, particularly in the face of challenges such as growth in mammalian hosts. The pathogenic fungus Cryptococcus neoformans additionally anchors its polysaccharide capsule to the cell surface via alpha(1-3) glucan in the wall. Cryptococcal cells disrupted in their alpha glucan synthase gene were sensitive to stresses, including temperature, and showed difficulty dividing. These cells lacked surface capsule, although they continued to shed capsule material into the environment. Electron microscopy showed that the alpha glucan that is usually localized to the outer portion of the cell wall was absent, the outer region of the wall was highly disorganized, and the inner region was hypertrophic. Analysis of cell wall composition demonstrated complete loss of alpha glucan accompanied by a compensatory increase in chitin/chitosan and a redistribution of beta glucan between cell wall fractions. The mutants were unable to grow ina mouse model of infection, but caused death in nematodes. These studies integrate morphological and biochemical investigations of the role of alpha glucan in the cryptococcal cell wall.     

MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及机理探究

【目的】研究MIG1基因和葡萄糖对扣囊复膜孢酵母细胞形态变化的影响及其机理探究。【方法】扣囊复膜孢酵母在不同浓度葡萄糖的YPD培养基中培养,敲除MIG1基因菌株在常规YPD培养基中培养,研究细胞内葡聚糖酶和几丁质酶活性以及细胞壁β-葡聚糖和几丁质含量与细胞形态变化之间的关系。【结果】培养基中葡萄糖浓度越低,扣囊复膜孢酵母菌丝体越少,单细胞酵母越多,且葡聚糖酶和几丁质酶活性越高,β-葡聚糖和几丁质含量越低;葡萄糖浓度对敲除MIG1基因菌株没有显著影响,葡聚糖酶和几丁质酶活性始终保持在较高水平,β-葡聚糖和几丁质含量也较低,菌体多以单细胞酵母形式存在。【结论】MIG1基因和葡萄糖通过葡萄糖阻遏作用调节葡聚糖酶和几丁质酶活性,进而影响细胞壁的葡聚糖和几丁质含量,最终影响扣囊复膜孢酵母细胞的形态变化。     

Mutants of Saccharomyces cerevisiae cell division cycle defective in cytokinesis. Biosynthesis of the cell wall and morphology

The four temperature-sensitive mutants of Saccharomyces cerevisiae in the cell division cycle defective in cytokinesis (cdc, 3, 10, 11 and 12), have been analyzed with respect to the biosynthesis of the cell wall polymers. After 3 hours of incubation at the non-permissive temperature (37°C) these strains stop growing. The synthesis of glucan, mannan and chitin (wall polymers) level off in a similar time, but glucan, mannan and chitin synthases remained active for at least 4 hours.If the mutants are analyzed by transmission and scanning electron microscopy different pictures emerge. Two of the mutants cdc 10 and cdc 12, after 3 hours of incubation at 37°C present apparently normal cytoplasms and cell wall surfaces with multiple elongated buds. The other two mutants, cdc 3 and cdc 11, present a completely disarranged cytoplasmic content and damage at the level of the plasma membrane is evident.These and other observations, suggest that between the execution points of cdc 3 (0.27) and cdc 10 (0.58), essential processes in the assembly of cell membrane occur.This work was supported in part by a grant from la Comisión de Investigación Científica y Técnica of the Spanish Ministerio de Educación y Ciencia (Project no. 4593-1980).     

Effect of aculeacin A, a wall-active antibiotic, on synthesis of the yeast cell wall

A wall-active, amphophilic antibiotic aculeacin A significantly but incompletely inhibited in vitro the activity of beta-(1,3)glucan synthase prepared from highly susceptible yeasts Saccharomyces cerevisiae and Candida albicans. In contrast, comparable cell-free preparations from S. cerevisiae active in chitin synthase or mannan synthase were insensitive to the antibiotic, suggesting selectivity of its action in synthesis of the yeast cell wall. An electron microscopic study of the effects of aculeacin A at 0.31 micrograms/ml, the optimally active concentration, on osmotically stabilized C. albicans cells revealed morphological alterations in both cell walls and cell membranes. Deformation in contour and derangement of the layered structure of the cell wall were prominent. In addition, massive fibrous material of beta-glucan-like microfibrils was occasionally extruded from the cell surface. Accompanying this effect on the cytology of the cell wall, ultrastructural and functional impairment of the cell membrane was demonstrated by transmission and freeze-fracture electron microscopic techniques. These data suggest that aculeacin A affects synthesis of the yeast cell wall through not only selective blockage of beta-(1,3)glucan synthase, as a result of a primary interaction with the cell membrane, but also inhibition of the fabrication of beta-glucan or other wall components into well-organized cell walls.     

A Highlights from MBoC Selection: Distinct roles of cell wall biogenesis in yeast morphogenesis as revealed by multivariate analysis of high-dimensional morphometric data

The cell wall of budding yeast is a rigid structure composed of multiple components. To thoroughly understand its involvement in morphogenesis, we used the image analysis software CalMorph to quantitatively analyze cell morphology after treatment with drugs that inhibit different processes during cell wall synthesis. Cells treated with cell wall–affecting drugs exhibited broader necks and increased morphological variation. Tunicamycin, which inhibits the initial step of N-glycosylation of cell wall mannoproteins, induced morphologies similar to those of strains defective in α-mannosylation. The chitin synthase inhibitor nikkomycin Z induced morphological changes similar to those of mutants defective in chitin transglycosylase, possibly due to the critical role of chitin in anchoring the β-glucan network. To define the mode of action of echinocandin B, a 1,3-β-glucan synthase inhibitor, we compared the morphology it induced with mutants of Fks1 that contains the catalytic domain for 1,3-β-glucan synthesis. Echinocandin B exerted morphological effects similar to those observed in some fks1 mutants, with defects in cell polarity and reduced glucan synthesis activity, suggesting that echinocandin B affects not only 1,3-β-glucan synthesis, but also another functional domain. Thus our multivariate analyses reveal discrete functions of cell wall components and increase our understanding of the pharmacology of antifungal drugs.     

Increase in chitin as an essential response to defects in assembly of cell wall polymers in the ggp1delta mutant of Saccharomyces cerevisiae.

The GGP1/GAS1 gene codes for a glycosylphosphatidylinositol-anchored plasma membrane glycoprotein of Saccharomyces cerevisiae. The ggp1delta mutant shows morphogenetic defects which suggest changes in the cell wall matrix. In this work, we have investigated cell wall glucan levels and the increase of chitin in ggp1delta mutant cells. In these cells, the level of alkali-insoluble 1,6-beta-D-glucan was found to be 50% of that of wild-type cells and was responsible for the observed decrease in the total alkali-insoluble glucan. Moreover, the ratio of alkali-soluble to alkali-insoluble glucan almost doubled, suggesting a change in glucan solubility. The increase of chitin in ggp1delta cells was found to be essential since the chs3delta ggp1delta mutations determined a severe reduction in the growth rate and in cell viability. Electron microscopy analysis showed the loss of the typical structure of yeast cell walls. Furthermore, in the chs3delta ggp1delta cells, the level of alkali-insoluble glucan was 57% of that of wild-type cells and the alkali-soluble/alkali-insoluble glucan ratio was doubled. We tested the effect of inhibition of chitin synthesis also by a different approach. The ggp1delta cells were treated with nikkomycin Z, a well-known inhibitor of chitin synthesis, and showed a hypersensitivity to this drug. In addition, studies of genetic interactions with genes related to the construction of the cell wall indicate a synthetic lethal effect of the ggp1delta kre6delta and the ggp1delta pkc1delta combined mutations. Our data point to an involvement of the GGP1 gene product in the cross-links between cell wall glucans (1,3-beta-D-glucans with 1,6-beta-D-glucans and with chitin). Chitin is essential to compensate for the defects due to the lack of Ggp1p. Moreover, the activities of Ggp1p and Chs3p are essential to the formation of the organized structure of the cell wall in vegetative cells.     

Presence of a large β(1-3)glucan linked to chitin at the Saccharomyces cerevisiae mother-bud neck suggests involvement in localized growth control

Previous results suggested that the chitin ring present at the yeast mother-bud neck, which is linked specifically to the nonreducing ends of β(1-3)glucan, may help to suppress cell wall growth at the neck by competing with β(1-6)glucan and thereby with mannoproteins for their attachment to the same sites. Here we explored whether the linkage of chitin to β(1-3)glucan may also prevent the remodeling of this polysaccharide that would be necessary for cell wall growth. By a novel mild procedure, β(1-3)glucan was isolated from cell walls, solubilized by carboxymethylation, and fractionated by size exclusion chromatography, giving rise to a very high-molecular-weight peak and to highly polydisperse material. The latter material, soluble in alkali, may correspond to glucan being remodeled, whereas the large-size fraction would be the final cross-linked structural product. In fact, the β(1-3)glucan of buds, where growth occurs, is solubilized by alkali. A gas1 mutant with an expected defect in glucan elongation showed a large increase in the polydisperse fraction. By a procedure involving sodium hydroxide treatment, carboxymethylation, fractionation by affinity chromatography on wheat germ agglutinin-agarose, and fractionation by size chromatography on Sephacryl columns, it was shown that the β(1-3)glucan attached to chitin consists mostly of high-molecular-weight material. Therefore, it appears that linkage to chitin results in a polysaccharide that cannot be further remodeled and does not contribute to growth at the neck. In the course of these experiments, the new finding was made that part of the chitin forms a noncovalent complex with β(1-3)glucan.     

Isolation and characterization of Saccharomyces cerevisiae mutants resistant to Calcofluor white.

Calcofluor is a fluorochrome that exhibits antifungal activity and a high affinity for yeast cell wall chitin. We isolated Saccharomyces cerevisiae mutants resistant to Calcofluor. The resistance segregated in a Mendelian fashion and behaved as a recessive character in all the mutants analyzed. Five loci were defined by complementation analysis. The abnormally thick septa between mother and daughter cells caused by Calcofluor in wild-type cells were absent in the mutants. The Calcofluor-binding capacity, observed by fluorescence microscopy, in a S. cerevisiae wild-type cells during alpha-factor treatment was also absent in some mutants and reduced in others. Staining of cell walls with wheat germ agglutinin-fluorescein complex indicated that the chitin uniformly distributed over the whole cell wall in vegetative or in alpha-factor-treated cells was almost absent in three of the mutants and reduced in the two others. Cell wall analysis evidenced a five- to ninefold reduction in the amount of chitin in mutants compared with that in the wild-type strain. The total amounts of cell wall mannan and beta-glucan in wild-type and mutant strains were similar; however, the percentage of beta-glucan that remained insoluble after alkali extraction was considerably reduced in mutant cells. The susceptibilities of the mutants and the wild-type strains to a cell wall enzymic lytic complex were rather similar. The in vitro levels of chitin synthase 2 detected in all mutants were similar to that in the wild type. The significance of these results is discussed in connection with the mechanism of chitin synthesis and cell wall morphogenesis in S. cerevisiae.     

Die Zellwand der Pilze als Korsett

Form follows function: The fungal cell wall as a support structure Within the domain of Eukarya, the fungi form a seperate kingdom. The typical formation of branched mycelia from single hyphae is based on cell wall production at the growing hyphal tip. There, excretory vesicle fuse with the membrane releasing cell wall synthesis enzymes like chitin synthase forming the polymer of N‐acetyl glucosamin, the backbone of fungal cell walls. In addition, glucan synthases form the structural component β‐1.3‐glucan. Via β‐1,6‐glucan, cell wall proteins can be linked to the maturing cell wall, and α‐1,3‐glucan can form a matrix within the cell wall, but also a slimy matrix secreted into the medium. A layer of hydrophobins allows for growth into the air, but also facilitates formation of macroscopic structures like mushrooms.     

Molecular Evolution Allows Bypass of the Requirement for Activation Loop Phosphorylation of the Cdc28 Cyclin-Dependent Kinase

Many protein kinases are regulated by phosphorylation in the activation loop, which is required for enzymatic activity. Glutamic acid can substitute for phosphothreonine in some proteins activated by phosphorylation, but this substitution (T169E) at the site of activation loop phosphorylation in the Saccharomyces cerevisiae cyclin-dependent kinase (Cdk) Cdc28p blocks biological function and protein kinase activity. Using cycles of error-prone DNA amplification followed by selection for successively higher levels of function, we identified mutant versions of Cdc28p-T169E with high biological activity. The enzymatic and biological activity of the mutant Cdc28p was essentially normally regulated by cyclin, and the mutants supported normal cell cycle progression and regulation. Therefore, it is not a requirement for control of the yeast cell cycle that Cdc28p be cyclically phosphorylated and dephosphorylated. These CDC28 mutants allow viability in the absence of Cak1p, the essential kinase that phosphorylates Cdc28p-T169, demonstrating that T169 phosphorylation is the only essential function of Cak1p. Some growth defects remain in suppressed cak1 cdc28 strains carrying the mutant CDC28 genes, consistent with additional nonessential roles for CAK1.     

Differential cell wall remodeling of two chitin synthase deletants Δchs3A and Δchs3B in the pathogenic yeast Candida glabrata

It is known that cell wall remodeling and the salvaging pathway act to compensate for an impaired or a damaged cell wall. Lately, it has been indicated that this mechanism is partly required for resistance to the glucan synthesis inhibitor echinocandin. While cell wall remodeling has been described in mutants of glucan or mannan synthesis, it has not yet been reported in a chitin synthesis mutant. Here, we describe a novel cell wall remodeling and salvaging pathway in chitin synthesis mutants, Δchs3A and Δchs3B, of the pathogenic yeast Candida glabrata. Electron microscopic analysis revealed a thickened mannoprotein layer in Δchs3A cells and a thickened chitin-glucan layer of Δchs3B cells, and it indicated the hypothesis that mannan synthase and chitin-glucan synthase indemnify Δchs3A and Δchs3B cells, respectively. The double-mutant CHS3A and MNN10, encoding α-1,6-mannosyltransferase, showed synergistic stress sensitization, and the Δchs3B strain showed supersensitivity to echinocandins. Hence, these findings support the above hypothesis of remodeling. Furthermore, unlike Δchs3A cells, Δchs3B cells showed supersensitivity to calcineurin inhibitor FK506 and Tor1p kinase inhibitor rapamycin, indicating that the Δchs3B strain uses the calcineurin pathway and a Tor1p kinase for cell wall remodeling.     

Up-regulation of the cell integrity pathway in saccharomyces cerevisiae suppresses temperature sensitivity of the pgs1Delta mutant

We have previously shown that mutants in the cardiolipin (CL) pathway exhibit temperature-sensitive growth defects that are not associated with mitochondrial dysfunction. The pgs1Delta mutant, lacking the first enzyme of the CL pathway, phosphatidylglycerolphosphate synthase (Pgs1p), has a defective cell wall due to decreased beta-1,3-glucan (Zhong, Q., Gvozdenovic-Jeremic, J., Webster, P., Zhou, J., and Greenberg, M. L. (2005) Mol. Biol. Cell 16, 665-675). Disruption of KRE5, a gene involved in cell wall biogenesis, restores beta-1,3-glucan synthesis and suppresses pgs1Delta temperature sensitivity. To gain insight into the mechanisms underlying the cell wall defect in pgs1Delta, we show in the current report that pgs1Delta cells have reduced glucan synthase activity and diminished levels of Fks1p, the glucan synthase catalytic subunit. In addition, activation of Slt2p, the downstream effector of the protein kinase C (PKC)-activated cell integrity pathway, was defective in pgs1Delta. The kre5W1166X suppressor restored Slt2p activation and dramatically increased (>10-fold) mRNA levels of FKS2, the alternate catalytic subunit of glucan synthase, partially restoring glucan synthase activity. Consistent with these results, up-regulation of PKC-Slt2 signaling and overexpression of FKS1 or FKS2 alleviated sensitivity of pgs1Delta to cell wall-perturbing agents and restored growth at elevated temperature. These findings demonstrate that functional Pgs1p is essential for cell wall biogenesis and activation of the PKC-Slt2 signaling pathway.     

Analysis of beta-1,3-glucan assembly in Saccharomyces cerevisiae using a synthetic interaction network and altered sensitivity to caspofungin

Large-scale screening of genetic and chemical-genetic interactions was used to examine the assembly and regulation of beta-1,3-glucan in Saccharomyces cerevisiae. Using the set of deletion mutants in approximately 4600 nonessential genes, we scored synthetic interactions with genes encoding subunits of the beta-1,3-glucan synthase (FKS1, FKS2), the glucan synthesis regulator (SMI1/KNR4), and a beta-1,3-glucanosyltransferase (GAS1). In the resulting network, FKS1, FKS2, GAS1, and SMI1 are connected to 135 genes in 195 interactions, with 26 of these genes also interacting with CHS3 encoding chitin synthase III. A network core of 51 genes is multiply connected with 112 interactions. Thirty-two of these core genes are known to be involved in cell wall assembly and polarized growth, and 8 genes of unknown function are candidates for involvement in these processes. In parallel, we screened the yeast deletion mutant collection for altered sensitivity to the glucan synthase inhibitor, caspofungin. Deletions in 52 genes led to caspofungin hypersensitivity and those in 39 genes to resistance. Integration of the glucan interaction network with the caspofungin data indicates an overlapping set of genes involved in FKS2 regulation, compensatory chitin synthesis, protein mannosylation, and the PKC1-dependent cell integrity pathway.