Rafael Sentandreu

Calcofluor White Alters the Assembly of Chitin Fibrils in Saccharomyces cerevisiae and Candida albicans Cells

In the presence of calcofluor white, budding scars and dividing cross-walls of Saccharomyces cerevisiae exhibited fluorescence, indicating that the brightener was a specific marker of fungal chitin. In addition, incubation of cells in the presence of the brightener did not stop protein and wall-polymer formation, but abnormal deposition of chitin occurred. Chitin synthesis was normal in regenerating protoplasts of Candida albicans in the presence of calcofluor, but formation of the crystalline lattice was blocked. These results suggest that crystallization of nascent subunits may occur by a self-assembly mechanism that was blocked by the stain.

Dimorphism in Candida albicans: contribution of mannoproteins to the architecture of yeast and mycelial cell walls

Wall mannoproteins of the two (yeast and mycelial) cellular forms of Candida albicans were solubilized by different agents. Boiling in 2% (w/v) SDS was the best method, as more than 70% of the total mannoprotein was extracted. Over 40 different bands (from 15 to 80 kDal) were detected on SDS-polyacrylamide gel electrophoresis of this material. The residual wall mannoproteins were released after enzymic (Zymolyase and endogenous wall beta-glucanases) degradation of wall glucan, suggesting that they are covalently linked to this structural polymer. Four bands (of 160 kDal, 205 kDal and higher molecular mass) were observed in the material released from yeast walls but only the two smaller components were detected in the material obtained from mycelial walls. Moreover, the mannoproteins of high molecular mass, which are covalently linked in walls of normal cells, were not incorporated into walls of regenerating protoplasts, but non-covalently linked mannoproteins were retained from the beginning of the process.

A role for the MAP kinase gene MKC1 in cell wall construction and morphological transitions in Candida albicans.

The Candida albicans MKC1 gene encodes a mitogen-activated protein (MAP) kinase, which has been cloned by complementation of the lytic phenotype associated with Saccharomyces cerevisiae slt2 (mpk1) mutants. In this work, the physiological role of this MAP kinase in the pathogenic fungus C. albicans was characterized and a role for MKC1 in the biogenesis of the cell wall suggested based on the following criteria. First, C. albicans mkc1 delta/mkc1 delta strains displayed alterations in their cell surfaces under specific conditions as evidenced by scanning electron microscopy. Second, an increase in specific cell wall epitopes (O-glycosylated mannoprotein) was shown by confocal microscopy in mkc1 delta/mkc1 delta mutants. Third, the sensitivity to antifungals which inhibit (1,3)-beta-glucan and chitin synthesis was increased in these mutants. In addition, evidence for a role for the MKC1 gene in morphological transitions in C. albicans is presented based on the impairment of pseudohyphal formation of mkc1 delta/mkc1 delta strains on Spider medium and on the effect of its overexpression on Sacch. cerevisiae colony morphology on SLADH medium. Using the two-hybrid system, it was also demonstrated that MKC1 is able to interact specifically with Sacch. cerevisiae Mkk1p and Mkk2p, the MAP-kinase kinases of the PKC1-mediated route of Sacch. cerevisiae, and to activate transcription in Sacch. cerevisiae when bound to a DNA-binding element. These results suggest a role for this MAP kinase in the construction of the cell wall of C. albicans and indicate its potential relevance for the development of novel antifungals.

Solubilization and Analysis of Mannoprotein Molecules from The Cell Wall of Saccharomyces cerevisiae

Purified walls from Saccharomyces cerevisiae were treated chemically to release intrinsic mannoproteins. Boiling in 2% SDS gave the best results, although treatment in 6 M-urea at room temperature also released significant amounts of mannoprotein radioactivity. Triton X-100, sodium deoxycholate and EDTA were poor solubilizers. Electrophoretic patterns of SDS- or urea-released mannoproteins in SDS-acrylamide gels indicated a great heterogeneity of molecular species, with more than 60 bands. Zymolyase, a glucan-digesting complex, released about half of the mannoproteins, but these species showed an altered mobility on SDS-acrylamide gels and had a lowered capacity for precipitation by ethanol. Action of the enzyme on isolated walls was favoured by dithiothreitol, as is the case with whole cells, and repeated treatments with SDS and Zymolyase released all of the mannoproteins from the wall. Solubilizing treatments other than SDS had a differential effect on recently or formerly incorporated mannoproteins in the wall. The results suggest an asymmetrical arrangement of molecules in the envelope and point to dynamic changes inside the wall as it thickens as a result of cell aging.

Structure of the Saccharomyces cerevisiae cell wall: Mannoproteins released by zymolyase and their contribution to wall architecture

Abstract Purified zymolyase containing β-glucanase activity preferentially released a 29 kDa mannoprotein from isolated yeast cell walls and a high-molecular-mass (greater than 120 kDa) material. Endo-β-N-acetylglucosaminidase H digestion indicated that the 29 kDa mannoprotein contains a unique core coligosaccharide N-glycosidically linked to a 26 kDa peptide moiety. Cells grown in the presence of tunicamycin incorporated the nonglycosylated 26 kDa peptide into the wall, but not the large mannoprotein molecules. Treatment of isolated walls with SDS solubilized more than 30 different mannoproteins, one of tehm being the 29 kDa species, but the large-size molecules were not affected. Regenerating protoplasts incorporated into the forming walls most of the SDS-solubilizable species seen in mature cell walls, but the zymolyase-solubilizable mannoproteins were absent. Wall mannoproteins have also been compared with those of the periplasmic space, most of the species being commonly present at both compartments. Turnover of individual species has been studied by pulse and chase experiments. While mannoproteins from the walls remain stable for long periods, periplasmic molecules exhibit a rapid turnover rate.

Wall Mannoproteins of the Yeast and Mycelial Cells of Candida albicuns: Nature of the Glycosidic Bonds and Polydispersity of Their Mannan Moieties

Zymolyase released between 20 and 25% of the total protein from purified walls of yeast (Y) and mycelial (M) cells of Candida albicans. The material released contained 92% carbohydrate (86% mannose and 6% glucose) and 7% protein. Over 85% of the carbohydrate was N-glycosidically linked to the protein and the rest (less than 15%) was linked O-glycosidically. Highly polydisperse, high molecular mass mannoproteins, resolved by electrophoresis as four defined bands in Y cells and two bands in M cells, had both types of sugar chains. A 34 kDa species found in both types of cells had a single 2.5 kDa N-glycosidically linked sugar chain and a 31.5 kDa protein moiety. Polydispersity in the high molecular mass mannoproteins was due to the N-linked sugar chains (mannan) with a molecular mass between 500 kDa and 20 kDa (average 100 kDa) in Y cells and between 400 kDa and 20 kDa (average 50 kDa) in M cells. Three mannoproteins of 34, 30 and 29 kDa secreted by protoplasts were associated with the high molecular mass mannoproteins, suggesting that this type of interaction might be related to the regeneration of the cell wall.

A study of the Candida albicans cell wall proteome

Considering the importance of proteins in the structure and function of the cell wall of Candida albicans, we analyzed the cell wall subproteome of this important human pathogen by LC coupled to MS (LC‐MS) using different protein extraction procedures. The analyzed samples included material extracted by hydrogen fluoride‐pyridine (HF‐pyridine), and whole SDS‐extracted cell walls. The use of this latter innovative procedure gave similar data as compared to the analysis of HF‐pyridine extracted proteins. A total of 21 cell wall proteins predicted to contain a signal peptide were identified, together with a high content of potentially glycosylated Ser/Thr residues, and the presence of a GPI motif in 19 of them. We also identified 66 “atypical” cell wall proteins that lack the above‐mentioned characteristics. After tryptic removal of the most accessible proteins in the cell wall, several of the same expected GPI proteins and the most commonly found “atypical” wall proteins were identified. This result suggests that proteins are located not only at the cell wall surface, but are embedded within the cell wall itself. These results, which include new identified cell wall proteins, and comparison of proteins in blastospore and mycelial walls, will help to elucidate the C. albicans cell wall architecture.

Cell wall composition and protoplast regeneration in Candida albicans.

The transition of blastospores to the mycelial phase in Candida albicans was induced after the blastospores were kept at 4°C for several hours and then transferred to a fresh medium prewarmed at 37°C. Glucan was the most abundant polymer in the wall in the two morphogenetic forms but the amount of chitin was higher in the mycelial form than in blastospores. Efficient protoplasting required reducing agents and proteases together with β-glucanases (zymolyase). Protein synthesis in regenerating protoplasts was initiated after about 30 min. Chitin synthetase, initially very low, was incorporated in important amounts into cell membranes mainly in a zymogenic state. After a few hours chitin was the most abundant polymer found in the aberrant wall of the regenerating protoplast.

Identification of pH-Regulated Antigen 1 Released from Candida albicans as the Major Ligand for Leukocyte Integrin αMβ2

Candida albicans is a common opportunistic fungal pathogen and is the leading cause of invasive fungal disease in immunocompromised individuals. The induction of cell-mediated immunity to C. albicans is of critical importance in host defense and the prime task of cells of the innate immune system. We previously demonstrated that the integrin αMβ2 (CD11b/CD18) is the major leukocyte receptor involved in C. albicans recognition, mediating both adhesive and migratory responses to the fungus. In the present study, we demonstrate that various C. albicans strains release a protease-sensitive activity into their conditioned medium that supports αMβ2-mediated cell adhesion and migration. The isolation and characterization of this protein was undertaken by two independent approaches: 1) immunoaffinity purification on a mAb raised to conditioned medium which blocked αMβ2-dependent adhesion and migration; and 2) affinity chromatography on purified αMβ2. Each approach led to the isolation of the same protein, which was unequivocally identified as pH-regulated Ag 1 (Pra1p), based on mass spectrometry and amino acid sequence analyses. C. albicans mutant strains lacking Pra1p were unable to support leukocyte adhesion or migration. In a neutrophil-mediated fungal killing assay, such mutant strains were resistant to killing and/or phagocytosis. Addition of purified Pra1p or reagents that block αMβ2 function prevented killing of Pra1p-expressing but not Pra1p-deficient strains of C. albicans. Together, these data indicate that Pra1p is a ligand of αMβ2 on C. albicans and that the soluble form of Pra1p may assist the fungus in escaping host surveillance.

Candida albicans mycelial wall structure: supramolecular complexes released by Zymolyase, chitinase and β-mercaptoethanol

Different techniques released from the wall of Candida albicans mycelial cells high molecular weight mannoprotein materials with different levels of complexity. SDS solubilized among others one protein of 180 kDa which reacted with a monoclonal antibody (MAb) specific of a O-glycosylated protein secreted by regenerating mycelial protoplasts [Elorza et al. (1989) Biochem Biophys Res Commun 162:1118–1125]. Zymolyase, chitinase and β-mercaptoethanol, released different types of high molecular highly polydisperse mannoprotein materials (>180 kDa) that also reacted with the same MAb. These materials had N-glycosidically linked sugar chains, in addition to the O-glycosidically bonded sugars, as their molecular masses were significantly reduced by Endo H digestion. Besides, the specific materials released by either zymolyase or chitinase seemed to be the same throughout the process of germ tube formation. Transmission electron microscopy of thin sections of cells and walls showed that mannoproteins and chitin are evenly distributed throughout the entire cell wall structure.