(1988). In addition, determination of yeast cultivation factors that can influence cell resistance to dehydration with concomitant reversible suspension of yeast metabolism has been reported previously.
For example, yeast cultivation in rich nutrient media has been shown to lead to the formation of more resistant OSI-906 cell line yeast populations compared with cells grown in poor synthetic nutrient media (Beker & Rapoport, 1987). Additionally, stationary-phase cells of bakers’ yeast, S. cerevisiae, are rather resistant to dehydration–rehydration, whereas the viability of exponential-phase cells following dehydration is severely compromised (Beker & Rapoport, 1987). It has been established that key metal ions, such as magnesium and calcium, play important roles in yeast physiology and biotechnology (Walker, 1994, 1999, 2004). Magnesium bioavailability dramatically influences yeast growth and metabolism in a beneficial manner, but calcium ions can antagonize essential magnesium-dependent functions in yeast (Walker, 1999). Sufficiency of intracellular free magnesium ions is absolutely required for the function of key enzymes and for ICG-001 cell membrane stabilization. Regarding the latter, magnesium acts in the physiological stress protection of yeast cells, by preventing increases in cell
membrane permeability caused by ethanol- and temperature-induced stress (Birch & Walker, 2000). The aim of the present investigation was to determine whether magnesium and calcium ions influenced the resistance of yeast cells to dehydration–rehydration. old Cultures of the yeast S. cerevisiae strain 14 used in this work were received from the collection of the Laboratory of Cell Biology, Institute of Microbiology and Biotechnology, University of Latvia. Cultures were grown on nutrient media containing (g L−1): molasses, 20; (NH4)2SO4, 3.7; MgSO4, 0.75; NaCl, 0.5; KH2PO4, 1.0;
K2HPO4, 0.13, pH 5.0; in flasks with total volume 250 mL in an orbital shaker (140 r.p.m.) at 30 °C. In some experiments, the nutrient medium did not contain MgSO4 or contained its higher concentration – 1.5 g L−1. In Ca2+-supplementation experiments, calcium salts were added to the medium in concentrations of 2.0 or 5.0 g L−1. Biomass yield was determined by its drying to a constant weight at 105 °C. Biomass dehydration was performed using a convective method in an oven at 30 °C for 24 h. The residual moisture reached in these conditions was 8–10%, determined by drying to a constant weight at 105 °C. At such residual moisture (if adequately dehydrated), yeast can maintain its viability due to being in a state of anhydrobiosis. The survival rates of dehydrated cultures were determined using fluorescence microscopy with the fluorochrome primulin. We have previously shown that, using certain conditions for yeast dehydration, this viability test corresponds very well to traditional tests based on agar plate counts (Rapoport & Meysel, 1985).