Altered extent of cross-linking of beta1,6-glucosylated mannoproteins to chitin in Saccharomyces cerevisiae mutants with reduced cell wall beta1,3-glucan content.

The yeast cell wall contains beta1,3-glucanase-extractable and beta1,3-glucanase-resistant mannoproteins. The beta1,3-glucanase-extractable proteins are retained in the cell wall by attachment to a beta1,6-glucan moiety, which in its turn is linked to beta1,3-glucan (J. C. Kapteyn, R. C. Montijn, E. Vink, J. De La Cruz, A. Llobell, J. E. Douwes, H. Shimoi, P. N. Lipke, and F. M. Klis, Glycobiology 6:337-345, 1996). The beta1,3-glucanase-resistant protein fraction could be largely released by exochitinase treatment and contained the same set of beta1,6-glucosylated proteins, including Cwp1p, as the B1,3-glucanase-extractable fraction. Chitin was linked to the proteins in the beta1,3-glucanase-resistant fraction through a beta1,6-glucan moiety. In wild-type cell walls, the beta1,3-glucanase-resistant protein fraction represented only 1 to 2% of the covalently linked cell wall proteins, whereas in cell walls of fks1 and gas1 deletion strains, which contain much less beta1,3-glucan but more chitin, beta1,3-glucanase-resistant proteins represented about 40% of the total. We propose that the increased cross-linking of cell wall proteins via beta1,6-glucan to chitin represents a cell wall repair mechanism in yeast, which is activated in response to cell wall weakening.

Architecture of the yeast cell wall. Beta(1-->6)-glucan interconnects mannoprotein, beta(1-->)3-glucan, and chitin.

In a previous study (Kollár, R., Petráková, E., Ashwell, G., Robbins, P. W., and Cabib, E. (1995) J. Biol. Chem. 270, 1170-1178), the linkage region between chitin and beta(1-->3)-glucan was solubilized and isolated in the form of oligosaccharides, after digestion of yeast cell walls with beta(1-->3)-glucanase, reduction with borotritide, and subsequent incubation with chitinase. In addition to the oligosaccharides, the solubilized fraction contained tritium-labeled high molecular weight material. We have now investigated the nature of this material and found that it represents areas in which all four structural components of the cell wall, beta(1-->3)-glucan, beta(1-->6)-glucan, chitin, and mannoprotein are linked together. Mannoprotein, with a protein moiety about 100 kDa in apparent size, is attached to beta(1-->6)-glucan through a remnant of a glycosylphosphatidylinositol anchor containing five alpha-linked mannosyl residues. The beta(1-->6)-glucan has some beta(1-->3)-linked branches, and it is to these branches that the reducing terminus of chitin chains appears to be attached in a beta(1-->4) or beta(1-->2) linkage. Finally, the reducing end of beta(1-->6)-glucan is connected to the nonreducing terminal glucose of beta(1-->3)-glucan through a linkage that remains to be established. A fraction of the isolated material has three of the main components but lacks mannoprotein. From these results and previous findings on the linkage between mannoproteins and beta(1-->6)-glucan, it is concluded that the latter polysaccharide has a central role in the organization of the yeast cell wall. The possible mechanism of synthesis and physiological significance of the cross-links is discussed.

Rho1p, a yeast protein at the interface between cell polarization and morphogenesis.

The enzyme that catalyzes the synthesis of the major structural component of the yeast cell wall, beta(1-->3)-D-glucan synthase (also known as 1,3-beta-glucan synthase), requires a guanosine triphosphate (GTP) binding protein for activity. The GTP binding protein was identified as Rho1p. The rho1 mutants were defective in GTP stimulation of glucan synthase, and the defect was corrected by addition of purified or recombinant Rho1p. A protein missing in purified preparations from a rho1 strain was identified as Rho1p. Rho1p also regulates protein kinase C, which controls a mitogen-activated protein kinase cascade. Experiments with a dominant positive PKC1 gene showed that the two effects of Rho1p are independent of each other. The colocalization of Rho1p with actin patches at the site of bud emergence and the role of Rho1p in cell wall synthesis emphasize the importance of Rho1p in polarized growth and morphogenesis.

Architecture of the yeast cell wall. The linkage between chitin and beta(1-->3)-glucan.

To isolate the putative linkage region between chitin and beta(1-->3)-glucan, Saccharomyces cerevisiae cell walls were digested with beta(1-->3)-endoglucanase and the reducing ends of the enzyme-resistant glucose chain stubs were labeled by reduction with borotritide. The radioactive material was further digested with exochitinase to remove the bulk of the chitin, and the liberated oligosaccharides were fractionated on a sizing column. A single peak (compound I) was found to consist of N-acetylglucosamine, glucose, and glucitol residues in the ratio 1:2:1. By digestion with beta-N-acetylglucosaminidase and by NMR spectroscopy, N-acetylglucosamine was identified as the nonreducing terminus, linked to laminaritriitol by a beta(1-->4) bond. Five additional oligosaccharides were recovered, two being analogs of compound I, with 1 or 3 glucose units, respectively; the remaining three were shown to be the reduced analogs of laminaribiose, laminaritriose, and laminaritetraose. The presence of N-acetylglucosamine-containing oligosaccharides arises from the activity of chitinase in cleaving 2 sugar units sequentially in those chains containing an odd number of N-acetylglucosamine residues; correspondingly, oligosaccharides containing only glucose and sorbitol derived from even-numbered chitin chains, a result implying that chitinase can hydrolyze the linkage between N-acetylglucosamine and glucose. It is concluded that the terminal reducing residue of a chitin chain is attached to the nonreducing end of a beta(1-->3)-glucan chain by a beta(1-->4) linkage. Experiments with appropriate mutants showed that synthesis of the chitin combined with glucan is catalyzed by chitin synthetase 3. The timing and possible mechanism of formation of the chitin-glucan linkage is discussed.

Biochemical, morphological and cytochemical studies of enhanced autolysis of Saccharomyces cerevisiae. 2. Morphological and cytochemical studies.

Morphological and cytochemical observation of Saccharomyces cerevisiae undergoing of induced autolysis were done in response to various chemical inducers of autolysis (NaCl, ethanol, fresh autolyzate). Changes in the inner structure of yeast cells were monitored by transmission electron microscopy and the surface of the cell wall was observed by scanning electron microscopy during autolysis. Cytochemical characterization of autolyzed cells was performed using four synthetic substrates for determination of proteinase activities but only carboxypeptidase Y could be detected in the vacuolar membranes. The morphological studies supported the data obtained from biochemical studies and confirmed that optimized conditions of autolysis have a significant effect on the structural changes of autolyzed yeast.

Biochemical, morphological and cytochemical studies of enhanced autolysis of Saccharomyces cerevisiae. 1. Biochemical studies.

Biochemical aspects of induced autolysis of Saccharomyces cerevisiae were observed in the presence of various physical and chemical enhancers of autolysis (increased temperature, changes of pH, NaCl, ethanol, fresh autolyzate). Direct assays of proteinases, nucleases, glucanases and acid phosphatases in homogenized autolyzed cells were performed. In addition, the degradation products of proteins, nucleic acids, polysaccharides and phosphate from phosphorylated compounds were determined in the supernatant of autolyzate after centrifugation. These results suggested that the inducers affected transport processes and that they had mostly negative effects on the activities of the above-mentioned enzymes.