Project description:This SuperSeries is composed of the following subset Series: GSE26617: Saccharomyces cerevisiae bottom of the fermentor vs. feeding GSE26618: Saccharomyces cerevisiae bottom of the fermentor vs. fermentation Refer to individual Series
Project description:The main objective was to identify genes regulated during different stages of fermentation: bottom of the fermentor, feeding and the fermentation stage. The experiment was further validated by microbiological assays.
Project description:The main objective was to identify genes regulated during different stages of fermentation: bottom of the fermentor, feeding and the fermentation stage. The experiment was further validated by microbiological assays.
Project description:The main objective was to identify genes regulated during different stages of fermentation: bottom of the fermentor, feeding and the fermentation stage. The experiment was further validated by microbiological assays. The control refers to the bottom of the fermentor. For analysis, feeding was compared to the control for two strains: CAT and PE-2.
Project description:The main objective was to identify genes regulated during different stages of fermentation: bottom of the fermentor, feeding and the fermentation stage. The experiment was further validated by microbiological assays. The control refers to the bottom of the fermentor. For analysis, fermentation was compared to the control for two strains: CAT and PE-2.
Project description:proteome-based techniques were used to compare changes of single culture fermentation and co-fermentation involving Lactobacillus plantarum Sx3 and Saccharomyces cerevisiae Sq7 in sourdough
Project description:The xylose fermentation capability of an industrainl Saccharomyces cerevisiae strain was enhanced by adaptive evolution. Eight homozygots were generated by tetrads dissection. The underlying molecular basis of the enhanced xylose fermentation capability was analyzed.
Project description:During fermentation Saccharomyces yeast produces various aroma-active metabolites determining the different characteristics of aroma and taste in fermented beverages. Amino acid utilization by yeast during brewer´s wort fermentation is seen as linked to flavour profile. To better understand the relationship between the biosynthesis of aroma relevant metabolites and the importance of amino acids, DNA microarrays were performed for Saccharomyces cerevisiae strain S81 and Saccharomyces pastorianus var. carlsbergensis strain S23, respectively. Thereby, changes in transcription of genes were measured, which are associated with amino acid assimilation and its derived aroma-active compounds during fermentation.