Use of supercritical carbon dioxide for proteins and alcohol dehydrogenase release from yeast Saccharomyces cerevisiae

[Display omitted] ► Saccharomyces cerevisiae suspension was incubated in a high-pressure batch reactor in SC CO2. ► Incubation time was changed regarding to the survival of the yeast S. cerevisiae. ► The protein concentration in suspension of S. cerevisiae in PDB and SPB medium after treatment in SC CO2 increased with increase in pressure. ► ADH from S. cerevisiae was obtained in the active form after incubation of cell suspension in SC CO2. ► Cytoplasmatic materials were extracted from the yeast cells. In this study, supercritical carbon dioxide (SC CO2) was used to obtain proteins and enzymes from yeast Saccharomyces cerevisiae. The changes in viability and cell morphology, the release of the cellular proteins and the activity alteration of the enzyme alcohol dehydrogenase (ADH) from S. cerevisiae resulting from the exposure to SC CO2 were investigated. Before the treatment of S. cerevisiae in SC CO2, the number of viable cells was cca. 105 colony forming units per mL of cell suspension (cfu/mL). The suspension of the S. cerevisiae culture was incubated in SC CO2 at different pressures (7.5, 15 and 30MPa) for different treatment times (30–300min) and at constant temperature (35°C). The influences of these parameters on total protein concentration, ADH activity and changes in absorbance of nucleic acids (NA) in the suspension of S. cerevisiae during SC CO2 treatment were studied. A decrease in number of living cells of S. cerevisiae in potato dextrose broth (PDB) or in sodium pyrophosphate buffer (SPB) exposed to SC CO2 at all studied pressures was determined when the treatment time was increased. The highest activity of ADH after treatment of the yeast culture suspended in PDB in SC CO2 was detected at a pressure of 7.5MPa and at the treatment time of 120min.The use of SC CO2 is a suitable option to achieve cell death and consequently the secretion of proteins and ADH from cells of S. cerevisiae.