A Single Chromosome Strain of S. cerevisiae Exhibits Diminished Ethanol Metabolism and Tolerance

Abstract

AbstractThis study characterized the growth, metabolism, and transcriptional profile of a S. cerevisiae strain with a single large chromosome that was constructed via successive chromosomal fusions. The single chromosome strain exhibited a longer lag phase, increased doubling time, and lower final biomass concentration compared with a wildtype strain when grown on YPD. These phenotypes were amplified when ethanol was added to the medium or used as the sole carbon source. RNAseq analysis showed diminished induction of genes involved in diauxic shift, ethanol metabolism, fatty-acid ß-oxidation, and methylglyoxal catabolism during growth on ethanol compared to the reference strain. Enzyme-constrained metabolic modeling predicted that decreased flux through these poorly induced enzymes results in diminished ATP formation and decreased biomass accumulation observed. Together, these observations suggest that switch-like control of carbon source dependent gene expression in S. cerevisiae requires genome arrangement into multiple chromosomes.