Metabolic engineering of Saccharomyces cerevisiae for ethanol and butanol biofuel production

Salman Khan, Asif Hussain, M. Hussain, Sahibzada Muhammad Aqeel, Samra Basharat, A. Hussain, Waleed Al-Ansi, Abdulqader M. Abdulqader, Nie Yao
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Abstract

The production of biofuels through biological processes has garnered increasing attention due to their potential benefits over conventional fuels, including lower greenhouse gas emissions, higher energy output, and reduced-price fluctuations. However, the metabolic processes of primitive microorganisms used in biofuel production are not compatible with those of fossil fuels. To address this, scholars have employed metabolic engineering techniques to modify the metabolisms of various microorganisms, including S. cerevisiae, for enhanced biofuel production. Specifically, overexpression of enzymes involved in bioethanol and biobutanol production, knockouts of competing pathways, improvements in carbon flux and tolerance have been applied to maximize the potential of S. cerevisiae for bioethanol and biobutanol production. This review focuses on the current state of metabolic engineering of S. cerevisiae for the production of bioethanol from lignocellulose and biobutanol from all kind of substrates, along with the potential use of cell surface technology in this field.
乙醇和丁醇生物燃料生产中酿酒酵母的代谢工程
通过生物过程生产生物燃料已引起越来越多的关注,因为它们比传统燃料有潜在的好处,包括减少温室气体排放、提高能源产出和减少价格波动。然而,用于生物燃料生产的原始微生物的代谢过程与化石燃料的代谢过程不相容。为了解决这个问题,学者们采用代谢工程技术来修改包括酿酒酵母在内的各种微生物的代谢,以提高生物燃料的产量。具体来说,过度表达参与生物乙醇和生物丁醇生产的酶,敲除竞争途径,改善碳通量和耐受性,已经被应用于最大化酿酒酵母生产生物乙醇和生物丁醇的潜力。本文综述了酿酒酵母从木质纤维素和各种底物中生产生物乙醇的代谢工程研究现状,以及细胞表面技术在该领域的潜在应用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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