The mechanical properties of fungal cell walls are largely determined by composition and mutual cross-linking of their macromolecular components. Previous work showed that the Crh proteins are required for the formation of cross-links between chitin and glucan at the Saccharomyces cerevisiae cell wall. In the present study, the proteins encoded by CRH1 and CRH2 were heterologously expressed in Pichia pastoris and a sensitive fluorescence in vitro soluble assay was devised for determination of their transglycosylating activities. Both proteins act as chitin transglycosylases; they use soluble chitin derivatives, such as carboxymethyl chitin, glycol-chitin and/or N-acetyl chito-oligosaccharides of DP (degree of polymerization)≥5 as the oligoglycosyl donors, and oligosaccharides derived from chitin, β-(1,3)-glucan (laminarin) and β-(1,6)-glucan (pustulan), fluorescently labelled with sulforhodamine or FITC as acceptors. The minimal number of intact hexopyranose units required by Crh1 and/or Crh2 in the molecule of the acceptor oligosaccharide was two and the effectivity of the acceptor increased with the increasing length of its oligosaccharide chain. Products of the transglycosylation reactions were hybrid molecules composed of the acceptor and portions of carboxymethyl chitin attached to its non-reducing end. Both proteins exhibited a weak chitinolytic activity in different assays whereby the ratio of endo- compared with exo-chitinase activity was approximately 4-fold higher in Crh1 than in Crh2. The pH optimum of both enzymes was 3.5 and the optimum temperature was 37°C. The results obtained in vitro with different fluorescently labelled oligosaccharides as artificial chitin acceptors corroborated well with those observed in vivo.
BGTs [β-(1,3)-glucanosyltransglycosylases; EC 2.4.1.-] of the GH72 (family 72 of glycosylhydrolases) are GPI (glycosylphosphatidylinositol)-anchored proteins that play an important role in the biogenesis of fungal cell walls. They randomly cleave glycosidic linkages in β-(1,3)-glucan chains and ligate the polysaccharide portions containing newly formed reducing ends to C(3)(OH) at non-reducing ends of other β-(1,3)-glucan molecules. We have developed a sensitive fluorescence-based method for the assay of transglycosylating activity of GH72 enzymes. In the new assay, laminarin [β-(1,3)-glucan] is used as the glucanosyl donor and LamOS (laminarioligosaccharides) fluorescently labelled with SR (sulforhodamine) serve as the acceptors. The new fluorescent assay was employed for partial biochemical characterization of the heterologously expressed Gas family proteins from the yeast Saccharomyces cerevisiae. All the Gas enzymes specifically used laminarin as the glucanosyl donor and a SR-LamOS of DP (degree of polymerization) ≥5 as the acceptors. Gas proteins expressed in distinct stages of the yeast life cycle showed differences in their pH optima. Gas1p and Gas5p, which are expressed during vegetative growth, had the highest activity at pH 4.5 and 3.5 respectively, whereas the sporulation-specific Gas2p and Gas4p were most active between pH 5 and 6. The novel fluorescent assay provides a suitable tool for the screening of potential glucanosyltransferases or their inhibitors.
Proteins with internal repeats (Pir) belong to a minor group of covalently linked yeast cell wall proteins. They are not essential for viability but important for cell wall strength, reduced permeability against plant antifungal enzymes and maintenance of osmotic stability. Here we show the importance of Pir proteins of Saccharomyces cerevisiae for growth at low pH and in presence of various inhibitors. Cell wall analysis of Deltapir1,2,3,4 deletion strain revealed slightly increased chitin content and changes in relative proportion of alkali-soluble and insoluble glucan and chitin fractions. Activation of the cell wall integrity pathway was indicated by increased levels of double phosphorylated Mpk1p/Slt2p in the pir deletants.
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