Browsing by Author "Smit, Anita Yolandi"

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    Evaluating the influence of winemaking practices on biogenic amine production by wine microorganisms
    (Stellenbosch : University of Stellenbosch, 2007-12) Smit, Anita Yolandi; Du Toit, M.; Du Toit, Wessel J.; University of Stellenbosch. Faculty of Agrisciences. Dept. of Viticulture and Oenology.
    Biogenic amines are nitrogenous compounds of low molecular weight found in most fermented foods, including wine. These biologically produced amines are essential at low concentrations for normal metabolic and physiological functions in animals, plants and micro-organisms. However, biogenic amines can have adverse effects at high concentrations and pose a health risk for sensitive individuals. Symptoms include nausea, hot flushes, headaches, red rashes, respiratory distress and fluctuations in blood pressure. A number of countries have implemented upper limits for histamine in food and wine. This development has already started to threaten commercial export transactions and may become more serious in the near future, especially in the competitive wine industry of today. The most important biogenic amines in wine include histamine, tyramine, putrescine, cadaverine and phenylethylamine which are produced from the amino acids histidine, tyrosine, ornithine, lysine and phenylalanine respectively. Biogenic amines are mainly produced in wine by microbial decarboxylation of the corresponding precursor amino acid. It may be produced by yeast during alcoholic fermentation, by lactic acid bacteria during malolactic fermentation, or potentially by spoilage microbes such as acetic acid bacteria and Brettanomyces. However, lactic acid bacteria are widely accepted as the main causative agents. Inoculation with commercial malolactic fermentation starter cultures that do not possess the relevant decarboxylase genes may inhibit the growth and activity of decarboxylase positive indigenous bacteria and as such control the production of biogenic amines in wine. In this study it was shown that co-inoculation of malolactic starter cultures together with alcoholic fermentation could reduce the incidence of biogenic amines in wine compared to conventional inoculation protocols; presumably because undesirable activities were restrained at an earlier stage during co-inoculation. It was also indicated in this work that in some cases the effect of co-inoculation on biogenic amine reduction may only be visible after a period of ageing. The frequency of biogenic amine occurrence in wines aged for a short period was generally higher in the presence of fermentation lees than in its absence. This work also included a preliminary investigation into the contribution of commercial wine yeast starter cultures to biogenic amine production. Diamines and polyamines (putrescine, spermidine and cadaverine) were produced to variable extents by all yeasts with very little or no production of physiologically important biogenic amines (histamine, tyramine and phenylethylamine). Another objective of this study was to evaluate the influence of common winemaking practices on biogenic amine production under winemaking conditions. We have shown that biogenic amine production by lactic acid bacteria could be influenced, amongst others, by the presence of precursor amino acids in the grape must or wine, the time of contact between juice or wine and grape skins, the time of contact between wine and yeast lees, the presence of microbial nutrients, wine pH, sulphite and ethanol levels, the phenolic composition of the wine and the number of decarboxylase positive lactic acid bacteria present in the wine. Lately, the wine industry is under increasing pressure to increase measures to ensure food safety and security and to eliminate any compound, present even in trace amounts that could reduce the wholesomeness of the wine. The need arises for a rapid and inexpensive method for quality control. In this study we investigated the potential to use Fourier transform infrared spectroscopy to rapidly screen for the presence of elevated levels of biogenic amines. This presents a novel method for the detection and quantification of total biogenic amines in wines.
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    The impact of nutrients on aroma and flavour production during wine fermentation
    (Stellenbosch : Stellenbosch University, 2013-03) Smit, Anita Yolandi; Bauer, Florian; Stellenbosch University. Faculty of AgriSciences. Dept. of Viticulture and Oenology. Institute for Wine Biotechnology.
    ENGLISH ABSTRACT: During wine fermentation, numerous grape must constituents serve as nutrients to wine yeast (Saccharomyces cerevisiae), which enable their growth and successful completion of alcoholic fermentation. Many of these nutritional factors, in particular nitrogen, also act as precursors for yeastderived flavour compounds such as higher alcohols, esters and volatile fatty acids. Yeast nitrogen metabolism thus plays a determining role in wine aroma and quality. Not only is the nitrogen source, concentration and supplementation timing important, but various environmental factors and the genetic constitution of the yeast strain used for fermentation will also contribute to fermentation outcomes. The main goal of this work was to explore the complex interactions between a number of contributing factors; namely nitrogen source, timing of addition, yeast strain and fermentation matrix. Broadly, this study assessed the impact of seven different nitrogen combinations, added either to the initial grape must or after the onset of fermentation, on fermentation performance and aroma compound production by nine commercial wine yeast strains. Fermentations were done in synthetic grape must, and validated for a subset of parameters in real grape must. The nitrogen treatments were designed according to the generally established order of preference of S. cerevisiae for individual amino acids as source of nitrogen under fermentative conditions, and the potential of certain amino acids to participate in metabolic pathways that produce specific aroma compounds. The results reveal that different nitrogen combinations can lead to unexpected aroma outcomes, depending strongly on the genetic background of individual yeast strains and the timing of nitrogen addition. Certain nitrogen treatments consistently resulted in significant increases or decreases in specific aroma compound concentrations in comparison to the treatment fermented on ammonium as only nitrogen source, for multiple yeast strains. These compounds were classified as nitrogen treatment dependent. Other aroma compounds were produced similarly for all nitrogen treatments and were designated as nitrogen treatment independent. The presence of specific amino acid groups (for example the branched-chain and aromatic amino acids) could be correlated to significantly altered production patterns of related (such as higher alcohols) or unrelated (diethyl succinate) aroma compounds relative to the other nitrogen treatments. Taken together, a number of interesting and novel hypotheses regarding the metabolic pathways involved could be derived from the data. Ultimately, this initial assessment of interactive effects during fermentation will contribute to practical guidelines for winemakers to allow matching grape must constituents (such as nutrients) with the intrinsic aroma production capabilities of specific yeast strains in order to modulate wine aroma, style and quality.
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    Managing your wine fermentation to reduce the risk of biogenic amine formation
    (Frontiers Research Foundation, 2012-03) Smit, Anita Yolandi; Engelbrecht, Lynn; Du Toit, Maret
    Biogenic amines are nitrogenous organic compounds produced in wine from amino acid precursors mainly by microbial decarboxylation. The concentration of biogenic amines that can potentially be produced is dependent on the amount of amino acid precursors in the medium, the presence of decarboxylase positive microorganisms and conditions that enable microbial or biochemical activity such as the addition of nutrients to support the inoculated starter cultures for alcoholic and malolactic fermentation(MLF). MLF can be conducted using co-inoculation or an inoculation after the completion of alcoholic fermentation that may also affect the level of biogenic amines in wine. This study focused on the impact of the addition of complex commercial yeast and bacterial nutrients and the use of different MLF inoculation scenarions on the production of biogenic amines in wine. Results showed that the addition of complex nutrients to real grape must could potentially increase histamine concentrations in wine. The same experiment in synthetic grape must showed a similar trend for putrescine and cadaverine. The effect of different MLF inoculation scenarios was examined in two cultivars, Pinotage and Shiraz. Conflicting results was obtained. In the Shiraz, coinoculation resulted in lower biogenic amine concentrations after MLF compared to before MLF, while the concentration was higher in the Pinotage. However,the production of biogenic amines was affected more by the presence of decarboxylase positive lactic acid bacteria than by the addition of complex nutrients or the inoculation scenario.