Abstract
Background: Saccharomyces cerevisiae has been widely used in the fermentation of plant-derived sugars to produce ethanol, called first-generation (1G) bioethanol, but made an impact on global food markets. Significant efforts have been therefore to employ non-food lignocellulosic feedstocks for bioethanol production, known as second-generation (2G) bioethanol. However, S. cerevisiae cannot naturally utilize xylose, a major component in lignocellulosic hydrolysates, and it has low tolerance to common carboxylic acid inhibitors present in lignocellulosic hydrolyzates. Metabolic engineering and evolutionary engineering have shown great power in strain improvement, which were also adopted here to solve these limiting factors in developing 2G bioethanol.Results: An efficient expression of a six-gene cluster, including XYL1/XYL2/XKS1/TAL1/PYK1/MGT05196, was achieved in the evolved S. cerevisiae diploid strain A21Z, showing the ability to use mixed glucose and xylose. The engineered strain A21Z expressing the six-gene cluster displayed a high xylose consumption after 96 h, reaching 90.7% of the theoretical yield in ethanol production. To investigate its industrial characteristics, A31Z was obtained by direct evolution of A21Z under the treatment of industrial hydrolysate from wheat straw. Under different fermentation conditions with 1G and 2G feedstock candidates, A31Z showed a markedly improved xylose fermentation performance. A31Z could produce more ethanol and less glycerol compared to the control Angel from corn starch during 120 h, with a final ethanol production at 122.32 g/L. The ability to produce higher ethanol production was also found under the fermentation using carbon source from hydrolysis of Dried Distillers Grains with Solubles (DDGS) or whole corn.Conclusions: Here, we report an effective strategy to improve xylose fermentation with an evolutionary engineering in the industrial S. cerevisiae diploid strain A31Z. This study demonstrated that a constructed A31Z has the higher xylose consumption and efficient ethanol production in mixed glucose and xylose with acetate. A31Z also gave a good ethanol production in 1G and 2G industrial feedstocks, indicating its significant contribution in the transition stage from the 1st generation to the 2nd generation bioethanol.
Feasibility Study for Co-Locating and Integrating Ethanol Production Plants from Corn Starch and Lignocellulosic Feedstocks (Revised)
