Rhodamine-pink as a genetic marker for yeast populations in wine fermentation.

Winemaking with selected yeasts requires simple techniques to monitor the inoculated yeast. New high-concentration rhodamine-resistant mutants and low-concentration rhodamine-pink mutants, easy to detect by replica-plate assay, were obtained from selected wine yeasts. The rhodamine-pink mutations were dominant and were located at the pdr5 locus that encodes for the Pdr5 ATP-binding cassette multidrug resistance transporter.

Rapid asymmetrical evolution of Saccharomyces cerevisiae wine yeasts.

Genetic instability causes very rapid asymmetrical loss of heterozygosity (LOH) at the cyh2 locus and loss of killer K2 phenotype in some wine yeasts under the usual laboratory propagation conditions or after long freeze-storage. The direction of this asymmetrical evolution in heterozygous cyh2(R)/CYH2(S) hybrids is determined by the mechanism of asymmetrical LOH. However, the speed of the process is affected by the differences in cell viability between the new homozygous yeasts and the original heterozygous hybrid cells.

Genetic instability of heterozygous, hybrid, natural wine yeasts.

We describe a genetic instability found in natural wine yeasts but not in the common laboratory strains of Saccharomyces cerevisiae. Spontaneous cyh2(R)/cyh2(R) mutants resistant to high levels of cycloheximide can be directly isolated from cyh2(S)/cyh2(S) wine yeasts. Heterozygous cyh2(R)/cyh2(S) hybrid clones vary in genetic instability as measured by loss of heterozygosity at cyh2.