Browsing by Author "Bauer, Rolene"

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    Acolein in wine : bacterial origin and analytical detection
    (Stellenbosch : University of Stellenbosch, 2010-03) Bauer, Rolene; Crouch, A.; Burger, B.; University of Stellenbosch. Faculty of Science. Dept. of Chemistry and Polymer Science.
    ENGLISH ABSTRACT: Wine quality is compromised by the presence of 3-hydroxypropionaldehyde (3-HPA) due to spontaneous conversion into acrolein under wine making conditions. Acrolein is highly toxic and is presence has been correlated with the development of bitterness in wine. Lactic acid bacterial strains isolated from South African red wine, Lactobacillus pentosus and Lactobacillus brevis, are implicated in accumulating 3- HPA during anaerobic glycerol fermentation. The environmental conditions leading to its accumulation are elucidated. In aqueous solution 3-HPA undergoes reversible dimerization and hydration, resulting in an equilibrium state between different derivatives. Interconversion between 3-HPA derivatives and acrolein is a complex and highly dynamic process driven by hydration and dehydration reactions. Acrolein is furthermore highly reactive and its steady-state concentration in complex systems very low. As a result analytical detection and quantification in solution is problematic. This study highlights the roles played by natural chemical derivatives and shows that the acrolein dimer can be used as a marker for indicating the presence of acrolein in wines. Solid-phase microextraction (SPME) coupled to gas chromatograph mass spectrometry (GC-MS) was validated as a technique for direct detection of the acrolein dimer in wine. The potential of a recently introduced sorptive extractive technique with a sample enrichment probe (SEP) was also investigated. The SPME technique simplifies the detection process and allows for rapid sampling of the acrolein marker, while SEP is more sensitive.
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    Diverse exopolysaccharide producing bacteria isolated from milled sugarcane : implications for cane spoilage and sucrose yield
    (Public Library of Science, 2015) Hector, Stanton; Willard, Kyle; Bauer, Rolene; Mulako, Inonge; Slabbert, Etienne; Kossmann, Jens; George, Gavin M.
    Bacterial deterioration of sugarcane during harvesting and processing is correlated with significant loss of sucrose yield and the accumulation of bacterial polysaccharides. Dextran, a homoglucan produced by Leuconostoc mesenteroides, has been cited as the primary polysaccharide associated with sugarcane deterioration. A culture-based approach was used to isolate extracellular polysaccharide (EPS) producing bacterial strains from milled sugarcane stalks. Ribosomal RNA sequencing analysis grouped 25 isolates into 4 genera. This study identified 2 bacterial genera not previously associated with EPS production or sucrose degradation. All isolates produced polysaccharide when grown in the presence of sucrose. Monosaccharide analysis of purified polymers by Gas Chromatography revealed 17 EPSs consisting solely of glucose (homoglucans), while the remainder contained traces of mannose or fructose. Dextranase treatment of polysaccharides yielded full digestion profiles for only 11 extracts. Incomplete hydrolysis profiles of the remaining polysaccharides suggest the release of longer oligosaccharides which may interfere with sucrose crystal formation.
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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.