Cell Surface Phenotypic Diversity and Flocculation Gene Variability in Contaminant Industrial Fuel-Ethanol Yeast Strains Exhibiting Highly Foaming Phenotypes

Abstract: Many contaminant yeast strains able to survive inside fuel ethanol industrial vats show detrimental cell surface phenotypes, such as filamentation, invasive growth, flocculation, biofilm formation and excessive foam production. Previous studies have linked some of these phenotypes to the expression of FLO genes, and the presence of gene length polymorphisms causing the expansion of FLO gene size appears to result in stronger flocculation and biofilm formation phenotypes. We have performed here a molecular anal… Show more

“…In S. cerevisiae, deleting the primary activator of FLO genes (the FLO8 gene) from the genome of a contaminant and highly foaming industrial strain avoids complex foam formation by the engineered (FLO8Δ::Ble R /FLO8Δ::KanMX) yeast strain. 33 FLO8 regulates the expression of FLO11 and thus affects the hydrophobicity of the yeast cell surface. 34 Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis reveals that YALI0_A01892p was associated with the flocculation protein FLO11.…”

Screening of Foamless Yarrowia lipolytica Strain and Metabolic Engineering for Erythritol Production from Sucrose-Based Feedstocks

“…In S. cerevisiae, deleting the primary activator of FLO genes (the FLO8 gene) from the genome of a contaminant and highly foaming industrial strain avoids complex foam formation by the engineered (FLO8Δ::Ble R /FLO8Δ::KanMX) yeast strain. 33 FLO8 regulates the expression of FLO11 and thus affects the hydrophobicity of the yeast cell surface. 34 Kyoto Encyclopedia of Genes and Genomes (KEGG) analysis reveals that YALI0_A01892p was associated with the flocculation protein FLO11.…”

Screening of Foamless Yarrowia lipolytica Strain and Metabolic Engineering for Erythritol Production from Sucrose-Based Feedstocks