Handbook of Enology: Volume 1. Pascal Ribéreau-Gayon

Handbook of Enology: Volume 1 - Pascal Ribéreau-Gayon


Скачать книгу
is 140. It links the different constituents of the cell wall together. It is also a receptor site for the killer factor (Section 1.7).

      The fibrous β‐1,3‐glucan (alkali‐insoluble) probably results from the incorporation of chitin in the amorphous β‐1,3‐glucan.

      Mannoproteins constitute 25–50% of the cell wall of S. cerevisiae. They can be extracted from the whole cell or from the isolated cell wall using chemical or enzymatic methods. Chemical methods make use of autoclaving in the presence of bases or a citrate buffer solution at pH 7. The enzymatic method frees the mannoproteins by digesting the glucan. This method does not denature the structure of the mannoproteins as much as chemical methods. Zymolyase, obtained from a bacterium (Arthrobacter luteus), is the enzymatic preparation most often used to extract the cell wall mannoproteins of S. cerevisiae. This enzymatic complex is effective primarily because of its β‐1,3‐glucanase activity. The action of protease contaminants in the zymolyase also combines with the aforementioned activity to liberate the mannoproteins. Glucanex, another industrial preparation of β‐glucanase, produced by a fungus (Trichoderma harzianum), has been demonstrated to possess endo‐ and exo‐β‐1,3‐ and endo‐β‐1,6‐glucanase activities (Dubourdieu and Moine, 1995). These activities also facilitate the extraction of the cell wall mannoproteins from the S. cerevisiae cell.

      The mannoproteins of S. cerevisiae have a molecular weight between 20 and 450 kDa. Their degree of glycosylation varies. However, some of them, containing about 90% mannose and 10% peptides, are hypermannosylated.

      The mannose in mannoproteins may form short, linear chains with one to five residues. They are linked to the peptide chain by O‐glycosyl linkages on serine and threonine residues. These glycosidic side‐chain linkages are α‐1,2 and α‐1,3.

Schematic illustration of the four types of glucosylation of cell wall yeast mannoproteins.

      A third type of glycosylation was also described. It can occur in mannoproteins, which make up the cell wall of the yeast. It consists of a glucomannan chain containing essentially α‐1,6‐linked mannose residues and α‐1,6‐linked glucose residues. The nature of the glycan–peptide point of attachment is not yet clear, but it may be an asparaginyl–glucose bond. Moreover, this type of glycosylation characterizes the proteins freed from the cell wall by the action of a β‐1,3‐glucanase. Therefore, in vivo, the glucomannan chain may also comprise β‐1,3‐linked glucose residues.

      The presence of lipids in the cell wall has not been clearly demonstrated. It is true that cell walls prepared in the laboratory contain some lipids (2–15% for S. cerevisiae), but this is most likely contamination by the lipids of the cytoplasmic membrane, adsorbed by the cell walls during their isolation. The cell wall can also adsorb lipids from its external environment, especially the various fatty acids that activate and inhibit fermentation (Section 3.6.2).

      Several enzymes are connected to the cell wall or situated in the periplasmic space. One of the most characteristic is invertase or β‐fructofuranosidase. This enzyme catalyzes the hydrolysis of sucrose into glucose and fructose. It is a thermostable mannoprotein anchored to a β‐1,6‐glucan of the cell wall. Its molecular weight is 270,000 Da. It contains approximately 50% mannose and 50% protein. Periplasmic acid phosphatase is also a mannoprotein.

Photo depicts microscopic image of proliferating S. cerevisiae cells. The budding scars on the mother cells can be observed.

      (Source: Photograph from M. Mercier, Department of Electron Microscopy, Université de Bordeaux I.)