Doctoral Degrees (Institute for Wine Biotechnology)

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Browsing Doctoral Degrees (Institute for Wine Biotechnology) by Subject "Fermentation"

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    Maltotriose transport in yeast
    (Stellenbosch : Stellenbosch University, 2007-12) Smit, Annel; Cordero Otero, Ricardo R.; Pretorius, Isak S.; Du Toit, Maret; Stellenbosch University. Faculty of Agrisciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.
    ENGLISH ABSTRACT: The conversion of sugar into ethanol and carbon dioxide is a process that has been intertwined with human culture and long as civilized man has existed. This fermentation process has been dominated by the micro-organism Saccharomyces cerevisiae and from providing ancient seafaring explorers of a non perishable beverage to equipping bakers with a raising agent to turn flour into bread; this organism with its fermentative potential, has formed an essential part of most societies. In more recent times, many industries still rely on this basic principle. The complexities and efficiencies of the conversion of sugar into its various fermentative byproducts have been studied and optimised extensively to meet the specific demands of industries. Depending on the raw material used as starting point, the major beneficiaries of the useful characteristics have been alcoholic beverage producers (wine, beer, and whiskey amongst others), bakers (bread leavening) and biofuel producers. One of the obstacles in fermentation optimisation is the sugar consumption preferences displayed by the organism used. S. cerevisiae can consume a wide variety of sugars. Depending on the complexities of its structures, it shows a preference for the simpler saccharides. The fermentation of certain more complex sugars is delayed and runs the risk of being left residually after fermentation. Many of the crops utilised in fermentation-based products contain large amounts of starch. During the starch degradation process many different forms of sugars are made available for fermentation. Improved fermentation of starch and its dextrin products would benefit the brewing, whiskey, and biofuel industries. Most strains of Saccharomyces ferment glucose and maltose, and partially ferment maltotriose, but are unable to utilise the larger dextrin products of starch. This utilisation pattern is partly attributed to the ability of yeast cells to transport the aforementioned mono-, di- and trisaccharides into the cytosol. The inefficiency of maltotriose transport has been identified as the main cause for residual maltotriose. The maltotriose transporting efficiency also varies between different Saccharomyces strains. By advancing the understanding of maltotriose transport in yeast, efforts can be made to minimise incomplete fermentation. This aim can be reached by investigating the existing transporters in the yeast cell membrane that show affinity for maltotriose. This study focuses on optimising maltotriose transport through the comparison of the alpha glucoside transporter obtained from different strains of Saccharomyces. Through specific genetic manipulations the areas important for maltotriose transport could be identified and characterised. This study offers prospects for the development of yeast strains with improved maltose and maltotriose uptake capabilities that, in turn, could increase the overall fermentation efficiencies in the beer, whiskey, and biofuel industries.
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    Strategies for the control of malolactic fermentation : characterisation of Pediocin PD-1 and the gene for the malolactic enzyme from Pediococcus damnosus NCFB 1832
    (Stellenbosch : Stellenbosch University, 2004-12) Bauer, Rolene; Dicks, Leon Milner Theodore; Stellenbosch University. Faculty of AgriSciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.
    ENGLISH ABSTRACT: Malolactic fermentation (MLF) is conducted by lactic acid bacteria (LAB) and entails the decarboxylation of L-malate to L-Iactate through a reaction catalysed by the malolactic enzyme (MLE). The consequence of this conversion is a decrease in total acidity. MLF plays a part in microbial stabilisation and due to the metabolic activity of the bacteria the organoleptic profile of the wine is modified. In some wines MLF is considered as spoilage, especially in warm viticultural regions with grapes containing less malic acid. In addition to undesirable organoleptic changes, MLF can alter wine colour, and biogenic amines may be produced. To induce MLF we provided s. cerevisiae with the enzymatic activities required for MLF, which is then conducted by the yeast during alcoholic fermentation. The malolactic enzyme-encoding gene (mieD) was cloned from Pediococcus damnosus NCFB 1832, characterised and expressed in S. cerevisiae. The activity of this enzyme was compared to two other malolactic genes, mieS from Lactococcus lactis MG1363 and mleA from Oenococcus oeni La11, expressed in the same yeast strain. All three recombinant strains of S. cerevisiae converted L-malate to L-Iactate in synthetic grape must, reaching L-malate concentrations of below 0.3 gIL within 3 days. However, a lower conversion rate and a significant lower final L-Iactate level were observed with the yeast expressing mieD. In order to inhibit MLF, we show that the growth of O. oeni, the main organism responsible for MLF, could be safely repressed with a ribosomaly synthesised antimicrobial peptide, pediocin PD-1, produced by P. damnosus NCFB 1832, without effecting yeast growth. Pediocin PD-1 is stable in wine at 4°C-100°C, and ethanol or S02 does not affect its activity. The peptide was purified to homogeneity and sequence analysis suggests that the peptide is a member of the lantibiotic family of bacteriocins. The molecular mass was estimated by mass spectroscopy to be 2866.7 ± 0.4 Da. Pediocin PD-1 forms pores in sensitive cells, as indicated by the efflux of K+ from O. oeni, combined with inhibition of cell wall biosynthesis, leading to cell lysis. Loss of cell K+was reduced at low temperatures, presumably as a result of the increased ordering of the lipid hydrocarbon chains in the cytoplasmic membrane. Although pediocin PD-1 is active over a broad pH range, optimal activity was recorded at pH 5.0. The petide is, however, more stable between pH 2.0 and 5.0, with the best stability observed between pH 3.0 and 4.0. Pediocin PD-1 provides a safer biological alternative than chemical preservatives such as S02.