Doctoral Degrees (Microbial, Biochemical and Food Biotechnology)

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Browsing Doctoral Degrees (Microbial, Biochemical and Food Biotechnology) by Subject "3-Hydroxy oxylipins"

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    The role of lipids in the flocculation of Saccharomyces cerevisiae
    (University of the Free State, 2005-11) Strauss, Catharina J; Kock, J. L. F.; Van Wyk, P. W. J.; Lodolo, E. J.
    English: Although beer production is one of the oldest biotechnologies in the world, a major constraint in brewing remains controlling flocculation. Evidence points towards a possible role of lipids, associated with the cell surfaces, as a major factor responsible for flocculation. Therefore, the aim in this study became to evaluate the contribution of lipids, especially oxylipins, in the flocculation of Saccharomyces cerevisiae UOFS Y-2330. Saccharomyces cerevisiae UOFS Y-2330 was selected as a model, since it was found to demonstrate both Flo1 and NewFlo phenotype flocculation behaviour, when cultivated in different media. In a defined medium with glucose as a sole carbon source, this strain immediately flocculated strongly and lost this ability before stationary phase was reached. In a complex medium containing glucose, this yeast strongly flocculated towards the stationary growth phase without losing this ability during this phase. This inverse pattern may be ascribed to a switch in sensitivity of the yeast to flocculate in the presence of glucose as well as pH level, which may, in turn, influence the availability of calcium ions. In both media, matured cells produced protuberances upon flocculation as observed by electron and immunofluorescence microscopy, which may be involved in cell adhesion. This was followed by further investigations into the role of lipids over the growth cycle of this yeast. Here, it was uncovered that Sacch. cerevisiae UOFS Y-2330 does not only demonstrate inverse flocculation, but is also characterised by two different lipid turnover patterns. During Flo1 phenotype flocculation, this yeast showed two neutral lipid accumulating stages (i.e. at 8 h and from 12 h). This is probably triggered by flocculation, which may be regarded as a survival mechanism where cells accumulate especially neutral lipids as reserve energy source - a similar mechanism is probably operative when cells enter stationary growth. Contrary to Flo1 behaviour, this strain in NewFlo phenotype mode demonstrates only a single lipid accumulation phase i.e. when cells enter stationary growth, which coincides with the increase in flocculation. In addition, an increase in phospholipids was experienced during active growth in both flocculation behaviours, probably as a result of active membrane production. These results prompted us to investigate the possible role of oxylipins present on the cell surfaces during the flocculation process. It was found that some strains of Sacch. cerevisiae (include strains used in fermentation processes) produce short chain (mainly 8 carbon) oxylipins and not potent inflammatory long chain (20 carbon) oxylipins such as prostaglandins. When aspirin was added to cultures of Sacch. cerevisiae UOFS Y-2330, flocculation was significantly inhibited as well as the production of 3-hydroxy (OH) 8:0 thereby linking flocculation and this oxylipin. Furthermore, no traces of 3-OH 8:0 could be detected before flocculation onset in this yeast. Next, the involvement of these oxylipins in co-flocculation was assessed. According to the lectin-theory, the yeast Schizosaccharomyces pombe lacks the specific receptors necessary to facilitate co-flocculation with Sacch. cerevisiae species. In this study we demonstrate oxylipin associated co-flocculation between Sacch. cerevisiae UOFS Y-2330 and S. pombe strains using differential cell staining, immunofluorescence and ultrastructural studies. Using a 3-OH oxylipin specific antibody coupled to a fluorescing compound, 3-OH oxylipins were found to be present on the cell surfaces of Sacch. cerevisiae and S. pombe. The presence of 3-OH oxylipins was confirmed using gas chromatography-mass spectrometry. Whether these 3- OH oxylipins play a role in affecting co-flocculation of Sacch. cerevisiae with S. pombe cells through possibly entropic-based hydrophobic interactions and/or hydrogen bonds still needs to be verified. Studies on the physiological, genetic as well as colloidal aspects of flocculation using this model strain may lead to important new insights in this fascinating phenomenon as well as applications in industry.