Abstract
At high levels, copper in grape mash can inhibit yeast activity and cause stuck fermentations. Wine yeast has limited tolerance of copper and can reduce copper levels in wine during fermentation. This study aimed to understand copper tolerance of wine yeast and establish the mechanism by which yeast decreases copper in the must during fermentation. Three strains of Saccharomyces cerevisiae (lab selected strain BH8 and industrial strains AWRI R2 and Freddo) and a simple model fermentation system containing 0 to 1.50 mM Cu2+ were used. ICP-AES determined Cu ion concentration in the must decreasing differently by strains and initial copper levels during fermentation. Fermentation performance was heavily inhibited under copper stress, paralleled a decrease in viable cell numbers. Strain BH8 showed higher copper-tolerance than strain AWRI R2 and higher adsorption than Freddo. Yeast cell surface depression and intracellular structure deformation after copper treatment were observed by scanning electron microscopy and transmission electron microscopy; electronic differential system detected higher surface Cu and no intracellular Cu on 1.50 mM copper treated yeast cells. It is most probably that surface adsorption dominated the biosorption process of Cu2+ for strain BH8, with saturation being accomplished in 24 h. This study demonstrated that Saccharomyces cerevisiae strain BH8 has good tolerance and adsorption of Cu, and reduces Cu2+ concentrations during fermentation in simple model system mainly through surface adsorption. The results indicate that the strain selected from China’s stress-tolerant wine grape is copper tolerant and can reduce copper in must when fermenting in a copper rich simple model system, and provided information for studies on mechanisms of heavy metal stress.
Highlights
Copper (Cu) is unavoidable in winemaking: long-term use of copper fungicide [1,2] may increase the copper level in soil [3,4] and grape berry; winemaking equipment [5] and copperPLOS ONE | DOI:10.1371/journal.pone.0128611 June 1, 2015Cu Tolerance and Biosorption of Yeast sulphate or copper citrate addition for eliminating H2S [6,7] may increase the copper content in must
Copper was clearly inhibiting yeast growth. These results demonstrate that strain F had the highest growth and was the earliest one reached stable-phase, indicating a greater copper tolerance
As there are many restrictions on natural grape juice, such as the supply of seasonal restrictions, the difference of grape juice composition caused by viticulture region and grape varieties, and the effect of solid composition of natural grape juice on separation of yeast cells, for a long time the studies on Saccharomyces cerevisiae with different researchers were hard to consistent
Summary
Copper (Cu) is unavoidable in winemaking: long-term use of copper fungicide [1,2] may increase the copper level in soil [3,4] and grape berry; winemaking equipment [5] and copperPLOS ONE | DOI:10.1371/journal.pone.0128611 June 1, 2015Cu Tolerance and Biosorption of Yeast sulphate or copper citrate addition for eliminating H2S [6,7] may increase the copper content in must. In a narrow range of low concentration, copper is an essential trace element in almost all organisms and plays an important positive role for organisms [8,9,10]. It would have inhibitory effect on cell when out of the useful range, even toxicity. With the increase of copper content in wines, existence with other heavy metals such as iron, manganese, zinc, nickel, lead, scandium etc, will cause harm to the health of consumers [14]. Maximum residue levels (MSL) of copper in European regulation is 20 mg/kg in grape must and 1 mg/L in wine [7]; China’s national regulation of wine, GB15037-2006, claims the same Cu MSL in wine but no limits in grape must
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