[No authors listed]
BACKGROUND:Pyruvate-decarboxylase negative (Pdcâ») strains of Saccharomyces cerevisiae combine the robustness and high glycolytic capacity of this yeast with the absence of alcoholic fermentation. This makes Pdcâ»S. cerevisiae an interesting platform for efficient conversion of glucose towards pyruvate-derived products without formation of ethanol as a by-product. However, Pdcâ» strains cannot grow on high glucose concentrations and require Câ-compounds (ethanol or acetate) for growth under conditions with low glucose concentrations, which hitherto has limited application in industry. RESULTS:Genetic analysis of a Pdcâ» strain previously evolved to overcome these deficiencies revealed a 225 p in-frame internal deletion in MTH1, encoding a transcriptional regulator involved in glucose sensing. This internal deletion contains a phosphorylation site required for degradation, thereby hypothetically resulting in increased stability of the protein. Reverse engineering of this alternative MTH1 allele into a non-evolved Pdcâ» strain enabled growth on 20 g lâ»Â¹ glucose and 0.3% (v/v) ethanol at a maximum specific growth rate (0.24 hâ»Â¹) similar to that of the evolved Pdcâ» strain (0.23 hâ»Â¹). Furthermore, the reverse engineered Pdcâ» strain grew on glucose as sole carbon source, albeit at a lower specific growth rate (0.10 hâ»Â¹) than the evolved strain (0.20 hâ»Â¹). The observation that overexpression of the wild-type MTH1 allele also restored growth of Pdcâ»S. cerevisiae on glucose is consistent with the hypothesis that the internal deletion results in decreased degradation of Mth1. Reduced degradation of Mth1 has been shown to result in deregulation of hexose transport. In Pdcâ» strains, reduced glucose uptake may prevent intracellular accumulation of pyruvate and/or redox problems, while release of glucose repression due to the MTH1 internal deletion may contribute to alleviation of the Câ-compound auxotrophy. CONCLUSIONS:In this study we have discovered and characterised a mutation in MTH1 enabling Pdcâ» strains to grow on glucose as the sole carbon source. This successful example of reverse engineering not only increases the understanding of the glucose tolerance of evolved Pdcâ» S. cerevisiae, but also allows introduction of this portable genetic element into various industrial yeast strains, thereby simplifying metabolic engineering strategies.
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