Ecology of yeasts associated with kernels of several durum wheat genotypes and their role in co-culture with Saccharomyces cerevisiae during dough leavening.

This work was performed to investigate on the yeast ecology of durum wheat to evaluate the interaction between kernel yeasts and the commercial baker's yeast Saccharomyces cerevisiae during dough leavening. Yeast populations were studied in 39 genotypes of durum wheat cultivated in Sicily. The highest level of kernel yeasts was 2.9 Log CFU/g. A total of 413 isolates was collected and subjected to phenotypic and genotypic characterization. Twenty-three yeast species belonging to 11 genera have been identified. Filobasidium oeirense, Sporobolomyces roseus and Aureobasidium pullulans were the species most commonly found in durum wheat kernels. Doughs were co-inoculated with yeasts isolated from wheat kernels and commercial Saccharomyces cerevisiae, in order to evaluate the interactions between yeasts and the leavening performance. Yeast populations of all doughs have been monitored as well as dough volume increase and weight loss (as CO2) measured after 2 h of fermentation. The doughs whose final volume was higher than control dough (inoculated exclusively with S. cerevisiae) were those inoculated with Naganishia albida, Vishniacozyma dimennae (118 mL each), and Candida parapsilosis (102 mL). The weight losses were variable, depending on the co-culture used with S. cerevisiae and the values were in the range of 0.08-1.00 g CO2/100 g. The kernel yeasts species C. parapsilosis, N. albida, P. terrestris, R. mucilaginosa and V. dimennae deserves future attention to be co-inoculated with the commercial starter S. cerevisiae in order to improve the sensory characteristics of bread.

Evidence for Two Main Domestication Trajectories in Saccharomyces cerevisiae Linked to Distinct Bread-Making Processes.

Production of leavened bread dates to the second millennium BCE. Since then, the art of bread making has developed, yet the evolution of bread-associated microbial species remains largely unknown. Nowadays, leavened bread is made either by using a pure commercial culture of the yeast Saccharomyces cerevisiae or by propagating a sourdough-a mix of flour and water spontaneously fermented by yeasts and bacteria. We studied the domestication of S. cerevisiae originating from industrial sources and artisanal sourdoughs and tested whether different bread-making processes led to population divergence. We found that S. cerevisiae bakery strains are polyphyletic with 67% of strains clustering into two main clades: most industrial strains were tetraploid and clustered with strains having diverse origins, including beer. By contrast, most sourdough strains were diploid and grouped in a second clade of strains having mosaic genomes and diverse origins, including fruits and natural environments. They harbored a higher copy number of genes involved in maltose utilization, and a high level of gene flow from multiple contributors was detected. Bakery strains displayed higher CO2 production than do strains from other domesticated lineages (such as beer and wine), revealing a specific phenotypic signature of domestication. Interestingly, industrial strains had a shorter fermentation onset than sourdough strains, which were better adapted to a sourdough-like environment, suggesting divergent selection by industrial and artisanal processes. Our results reveal that the domestication of bakery yeast has been accompanied by dispersion, hybridization, and divergent selection through industrial and artisanal processes.