M. V. Elorza

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.

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.

Formation of a New Cell Wall by Protoplasts of Candida albicans: Effect of Papulacandin B, Tunicamycin and Nikkomycin

Incorporation of polysaccharides into the walls of regenerating protoplasts of Candida albicans was followed in the presence of papulacandin B, tunicamycin and nikkomycin. With the first drug, chitin was incorporated normally whereas incorporation of glucans and mannoproteins was significantly decreased. Tunicamycin decreased incorporation of all wall polymers when added at the beginning of the regeneration process but blocked only mannan and alkali-insoluble glucan incorporation when added after 5 h. Nikkomycin inhibited chitin synthesis, and the walls formed by the protoplasts were enriched in alkali-soluble glucan. Pulse-chase experiments suggested that a precursor-product relationship between the alkali-soluble and alkali-insoluble glucans existed in the wall. The results obtained with the antibiotics were confirmed and extended by cytological studies using wheat-germ agglutinin labelled with colloidal gold and concanavalin A-ferritin as specific markers of chitin and mannoproteins respectively. The results support the idea that regeneration of walls by protoplasts occurs in two steps: firstly, a chitin microfibrillar skeleton is formed, and in a later step glucan-mannoprotein complexes are added to the growing structure. The chitin skeleton probably allows the orderly spatial arrangement of the other polymers giving rise to the regenerated cell wall.

Synthesis of yeast wall glucan.

Saccharomyces cerevisiae was treated with a mixture of toluene and ethanol to make it permeable to small molecules. This treatment unmasked a glucan synthetase activity which was assayed with UDP-[U-14C]glucose. About 60% of the polymer formed was beta-(I leads to 3)glucan. No labelled lipids were detected. The 14C incorporated was recovered in a particulate membrane preparation isolated by differential centrifugation. When the particles themselves were assayed for glucosyl transfer activity none was found. The toluene-treated preparations also catalysed the transfer of mannosyl residues from GDP-mannose to polymeric materials by a process independent of glucosyl transfer.

Effect of papulacandin B and calcofluor white on the incorporation of mannoproteins in the wall of Candida albicans blastospores

Incorporation of mannoproteins into the walls of Candida albicans blastospores (yeast phase) was followed by continuous labelling and pulse-chase experiments. The effect in the process of compounds that interfere with synthesis (papulacandin B) or assembly (calcofluor white) of structural polymers was also assessed. Mannoproteins which are kept in place by non-covalent bonds (mainly hydrogen bonds) were incorporated rapidly after their release into the periplasmic space, this process being blocked by calcofluor white. The stain had no effect on the incorporation of covalently linked mannoproteins. Papulacandin B inhibited formation of beta-glucans and incorporation of covalently linked mannoprotein molecules, whereas incorporation of hydrogen-bonded species took place normally. The results suggest that the formation of the non-covalent bonds between the mannoproteins occurs once they are secreted into the periplasmic space, whereas the formation of covalent connections between mannoproteins and wall glucan takes place at the level of the plasma membrane.

Involvement of transglutaminase in the formation of covalent cross-links in the cell wall ofCandida albicans

Activity of the enzyme glutaminyl-peptide-γ-glutamylyl-transferase (EC 2.3.2.13; transglutaminase), which forms the interpeptidic cross-link N∈-(γ-glutamic)-lysine, was demonstrated in cell-free extracts obtained from both the yeast like and mycelial forms ofCandida albicans. Higher levels of enzymatic activity were observed in the cell wall fraction, whereas the cytosol contained only trace amounts of activity. Cystamine, a highly specific inhibitor of the enzyme, was used to analyze a possible role of transglutaminase in the organization of the cell wall structure of the fungus. Cystamine delayed protoplast regeneration and inhibited the yeast-to-mycelium transition and the incorporation of proteins into the cell wall. The incorporation of covalently bound high-molecular-weight proteins into the wall was sensitive to cystamine. Proteic epitopes recognized by two monoclonal antibodies, one of which is specific for the mycelial walls of the fungus, were also sensitive to cystamine. These data suggest that transglutaminase may be involved in the formation of covalent bonds between different cell wall proteins during the final assembly of the mature cell wall.

Wall formation by Candida albicans yeast cells : synthesis, secretion and incorporation of two types of mannoproteins

The mannoprotein components solubilized from the walls of Candida albicans blastoconidia following degradation of the glucan network with beta-glucanase (Zymolyase) have higher molecular masses than their probable precursors present in the supernatant of regenerating protoplasts. It therefore appears that the mannoproteins are released from the walls as part of supramolecular complexes. Immunological analysis using both polyclonal and monoclonal antibodies has demonstrated the probable relationship between molecules found in a mixed membrane preparation, those secreted by regenerating protoplasts, and those present in yeast cell walls. Some mannoproteins secreted by protoplasts incubated in the presence of tunicamycin had significantly increased mobility on SDS-PAGE, whereas others were not affected by the treatment. It is therefore possible that two types of mannoproteins are secreted by protoplasts: one carrying N-glycosylated chains (mannan) and one lacking them. All the proteins secreted in the presence of tunicamycin stained with Concanavalin A-peroxidase, demonstrating that they all, including the N-glycosylated ones, carried O-glycosylated sugar residues. Both classes of mannoproteins, secreted independently of each other, were found in the molecular complexes rendered soluble from the wall by Zymolyase digestion. Data obtained with a monoclonal antibody demonstrated the presence of a repeated epitope within one wall protein(s) detectable in a mixed membrane preparation and in the wall complexes released by Zymolyase.

Critical steps in fungal cell wall synthesis : strategies for their inhibition

Development of new effective antifungal drugs is limited by the absence of specific target sites in the fungal cells. Knowledge of the fungal cell wall structure and biosynthesis is of interest in searching for a potential target site for new chemotherapeutic agents. Our group has demonstrated that the fungal cell wall is a metabolically active structure where interaction between distinct components occurs to give rise to the mature cell wall structure. Mannoproteins play an essential role in the cell wall organization, and there is evidence for the formation of covalent bonds between these molecules and the structural polymers (glucans and chitin) outside the plasma membrane. Such interactions, which specifically occur at the fungal cell wall, are of great interest in defining target sites for potential new chemotherapeutic agents, which may inhibit the interactions and, thus, lead to a defective cell wall formation and cell death.

Cloning of cDNAs coding for Candida albicans cell surface proteins

Two cDNA libraries were constructed from mRNAs obtained from yeast cells and germ-tubes of Candida albicans in lambda gt11. Immunoscreening with polyclonal antibodies raised against cell wall components allowed the detection of 29 positive clones. Two of these clones were selected for their specific reactivity with antisera either from yeast (clone 11Y) or germ-tubes (clone 24M). cDNA fragments were isolated by the digestion of lambda DNA with EcoRI. Southern blot analysis with these fragments as probes demonstrated homology with C. albicans DNA, and by Northern analysis two mRNAs transcripts were detected with sizes of approximately 1.5 kb for 11Y and 1.1 kb for 24M. Both transcripts were present in yeast cells as well as in germ-tubes. The whole genes were isolated from a C. albicans genomic library in the YRp7 vector by hybridization with the cDNA probes. Monospecific antibodies were purified from polyclonal antisera by affinity for the fusion proteins. Western blot analysis with 11Y-specific antibodies revealed a cross-reactivity with material found in the yeast cell wall as well as in other subcellular fractions, whereas clone 24M codes for a 30 kDa protein detected mainly in the membrane fraction and in the SDS-solubilized material from mycelial cell walls. Sequencing of the cDNA molecules and restriction map of the cloned genes demonstrate that clone 11Y is an enolase previously characterized in C. albicans, whereas clone 24M does not show significant homology with any other cloned gene.