Masters Degrees (Viticulture and Oenology)

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Browsing Masters Degrees (Viticulture and Oenology) by Author "Brandt, Bianca Anina"

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    Generating lower ethanol yields in fermentations by Saccharomyces cerevisiae via diversion of carbon flux towards the production of fructo-oligosaccharides
    (Stellenbosch : Stellenbosch University, 2013-03) Brandt, Bianca Anina; Nieuwoudt, Helene; Stellenbosch University. Faculty of AgriSciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.
    ENGLISH ABSTRACT: There is a growing international consumer demand for the production of lower ethanol wines. This can be attributed to various qualitative, social, economic and health concerns that are associated with high ethanol wines (Kutyna et al., 2010; Varela et al., 2012). There is continuous development and research into methods and technologies to lower the ethanol concentration in wine. However, in addition to the added cost and complexity these technologies all have various shortcomings. The development of yeast strains with lower ethanol productivity, yet desirable organoleptic and fermentation capacity, therefore remains a highly sought after research and development target in the wine industry. Biologically based approaches aim to generate yeast strains with the capacity to divert carbon from ethanol production towards targeted metabolic endpoints (Kutyna et al., 2010). This should ultimately be achieved without the production of unwanted metabolites that can negatively affect wine characteristics. In the context of these challenges, this study aimed to investigate the use of fructans as carbon sinks during fermentation to divert fructose from glycolysis and ethanol production toward intracellular fructan production by generating levan producing strains. In addition, the impact of fructan production on metabolic carbon flux during fermentation by these strains was analyzed. This was the first attempt to analyze intracellular fructan production in Saccharomyces cerevisiae under fermentative conditions with fructans acting as carbon sinks. Fructans are fructose polymers that act as storage molecules in certain plants and function as part of the extracellular matrix in microbial biofilms, and are intensively studied due to their economic interest. Here we undertook the heterologous expression of a levansucrase (LS) M1FT from Leuconostoc mesenteroides, an enzyme producing β(2-6) levan-type fructans, in the S. cerevisiae BY4742Δsuc2 strains without invertase activity (encoded by SUC2). Levansucrases indeed utilize sucrose as both fructose donor and initial polymerization substrate, and the sucrose concentration is of import to maintain transfructosylation activity of enzyme. High intracellular sucrose accumulation was achieved by the heterologous expression of either a sucrose synthase (Susy; cloned from potato) or by growing strains expressing the spinach sucrose transporter (SUT) in sucrose containing media. Endogenous sucrose synthesis was of specific interest to the overall goal of the project, which was to reroute carbon flux away from glycolysis in grape must containing only hexoses as carbon source. In addition, this approach of combining intracellular sucrose production with intracellular levan production could be used in various applications to limit the need for sucrose in media as both carbon source and LS substrate. The extracellular LS M1FT was introduced into Susy and SUT strains as either the complete gene (M1FT) or 50bp truncation (M1FTΔsp) without the predicted signal peptide. The data show that intracellular levan accumulation occurred in aerobic, but not anaerobic conditions. The data also suggest that the production of levan did not impact negatively on general yeast physiology or metabolism in these conditions. However, no significant reduction in ethanol yields were observed, suggesting that further optimisation of the expression system is required. This is the first report of levan synthesis by S. cerevisiae, and contributes towards expanding the possibilities for further industrial applications of these compounds.