Ryosuke Yamada
Osaka Prefecture University, Japan
Title: Acceleration of glycolysis and D-lactate production by novel global metabolic engineering in yeast
Biography
Biography: Ryosuke Yamada
Abstract
The use of renewable feedstocks for producing biofuels and bio-based chemicals by engineering metabolic pathways of yeast Saccharomyces cerevisiae has recently become an attractive option. Many researchers attempted to accelerate glycolysis by overexpressing some glycolytic enzymes because most target bio-based chemicals are derived through glycolysis. However these attempts have met with little success. In this study, to create a S. cerevisiae strain with high glycolytic flux, we used multi-copy integration to develop a novel global metabolic engineering strategy. Then a novel global metabolic engineering strategy was applied for D-lactate production.
Among approximately 350 metabolically engineered strains, YPH499/dPdA3-34 exhibited the highest glucose consumption rate. This strain showed 1.3-fold higher cell growth rate and glucose consumption rate than the control strain YPH499/dPdAW. Real-time PCR analysis revealed that transcription levels of glycolysis-related genes such as HXK2, PFK1, PFK2, PYK2, PGI1, and PGK1 in YPH499/dPdA3-34 were increased. Besides, by using global metabolic engineering strategy, D-lactate was efficinetly produced.
This study successfully developed a novel global metabolic engineering strategy for S. cerevisiae, improving glucose consumption rate through optimizing the expression of glycolysis-related enzymes. The method detailed here is a promising approach to optimize S. cerevisiae metabolic pathways, thereby improving bio-based chemicals production using this organism.