AUTHOR=Yang Leyun , Zheng Cheng , Chen Yong , Ying Hanjie 

TITLE=FLO Genes Family and Transcription Factor MIG1 Regulate Saccharomyces cerevisiae Biofilm Formation During Immobilized Fermentation

JOURNAL=Frontiers in Microbiology

VOLUME=9

YEAR=2018

URL=https://www.frontiersin.org/journals/microbiology/articles/10.3389/fmicb.2018.01860

DOI=10.3389/fmicb.2018.01860

ISSN=1664-302X

ABSTRACT=<p><italic>Saccharomyces cerevisiae</italic> immobilization is commonly used for efficient ethanol fuel production in industry due to the relatively higher ethanol stress resistance of <italic>S. cerevisiae</italic> in biofilms relative to planktonic cells. The mechanisms of biofilm formation and stress resistance, however, remain ambiguous. By analyzing biofilm and planktonic cell transcriptomes, this study observed that <italic>MIG1</italic> (encoding a transcription factor) expression in cells increases during the biofilm formation process. To identify the role of <italic>MIG1</italic> in yeast biofilm formation and the ethanol resistance of these cells, <italic>MIG1</italic> was deleted and complemented in <italic>S. cerevisiae</italic> 1308. Results showed the <italic>MIG1</italic> deletion mutant strain demonstrated weaker biofilm formation ability both on fibers and plastic than the wild-type and these could be restored by expressing <italic>MIG1</italic> in deletion mutant. To verify the ability of <italic>MIG1</italic> to regulate the expression of <italic>FLO</italic> genes, which encode adhesions responsible for yeast biofilm formation, <italic>FLO</italic> gene transcription levels were measured via qRT-PCR. Relative to wild-type <italic>S. cerevisiae</italic>, the adhesion genes <italic>FLO1, 5</italic>, and <italic>9</italic> which also demonstrate increased expression in the transcriptome of yeast cells during biofilm formation, but not <italic>FLO11</italic>, were down-regulated in the <italic>MIG1</italic> mutant strain. Additionally, the <italic>MIG1</italic> mutant lost a majority of its flocculation ability, which depended on cell-cell adhesions and its slightly invasive growth ability, dependent on cell-substrate adhesion. Deleting <italic>FLO1, 5</italic>, and <italic>9</italic> decreased biofilm formation on plastics, suggesting these <italic>FLO</italic> genes contribute to the biofilm formation process alongside <italic>FLO11</italic>. Moreover, the ethanol tolerance of yeast decreased in the <italic>MIG1</italic> deletion mutant as well as the <italic>FLO11</italic> deletion mutant, resulting in reduced biofilm formation during fermentation. It remains possible that in the later period of fermentation, when ethanol has accumulated, an over-expression of the <italic>FLO1, 5</italic>, and <italic>9</italic> genes regulated by <italic>MIG1</italic> would enhanced cell-cell adhesions and thus protect cells in the outer layer of biofilms from ethanol, a function primarily dependent on cell-cell adhesions. This work offers a possible explanation for how biofilm formation is regulated during the immobilized fermentation process, and can enhance environmental tolerance in industrial production.</p>