酵母代谢工程前沿：超越乙醇和酿酒酵母的多元化。

Frontiers of yeast metabolic engineering: diversifying beyond ethanol and Saccharomyces.

机构信息

Department of Chemistry and Biochemistry, The University of Texas at Austin, 105 E. 24th Street Stop A5300, Austin TX 78712, United States.

出版信息

Curr Opin Biotechnol. 2013 Dec;24(6):1023-30. doi: 10.1016/j.copbio.2013.03.005. Epub 2013 Mar 28.

DOI:10.1016/j.copbio.2013.03.005

PMID:23541504

Abstract

Microbial systems provide an attractive, renewable route to produce desired organic molecules such as fuels and chemicals. While attention within the field of metabolic engineering has mostly focused on Escherichia coli, yeast is a potent host and growing host for industrial products and has many outstanding, biotechnologically desirable native traits. Thus, there has been a recent shift in focus toward yeast as production hosts to replace E. coli. As such, products have diversified in yeast beyond simply ethanol. Additionally, nonconventional yeasts have been considered to move beyond Saccharomyces cerevisiae. This review highlights recent advances in metabolic engineering of yeasts for producing value-added chemical compounds including alcohols, sugar derivatives, organic acids, fats, terpenes, aromatics, and polyketides. Furthermore, we will also discuss the future direction of metabolic engineering of yeasts.

摘要

微生物系统为生产所需的有机分子（如燃料和化学品）提供了一种有吸引力的、可再生的途径。虽然代谢工程领域的注意力主要集中在大肠杆菌上，但酵母是一种有潜力的工业产品宿主，并且具有许多出色的、生物技术上理想的天然特性。因此，人们最近将关注的焦点转向酵母作为生产宿主来替代大肠杆菌。因此，除了简单的乙醇之外，酵母的产品种类也在不断增加。此外，非常规酵母也被认为可以超越酿酒酵母。本文重点介绍了酵母代谢工程在生产有价值的化学化合物方面的最新进展，包括醇类、糖衍生物、有机酸、脂肪、萜类、芳香族化合物和聚酮化合物。此外，我们还将讨论酵母代谢工程的未来发展方向。

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酵母代谢工程前沿：超越乙醇和酿酒酵母的多元化。

Frontiers of yeast metabolic engineering: diversifying beyond ethanol and Saccharomyces.

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