大肠杆菌在生物燃料生产中的作用。

Role of Escherichia coli in Biofuel Production.

作者信息

Koppolu Veerendra, Vasigala Veneela Kr

机构信息

Scientist, Department of Analytical Biotechnology, MedImmune/AstraZeneca, Gaithersburg, MD, USA.; Former affiliation: Department of Molecular Biosciences, University of Kansas, Lawrence, KS, USA.

Rangaraya Medical College, NTR University of Health Sciences, Kakinada, AP, India.

出版信息

Microbiol Insights. 2016 Jul 14;9:29-35. doi: 10.4137/MBI.S10878. eCollection 2016.

DOI:10.4137/MBI.S10878

PMID:27441002

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4946582/

Abstract

Increased energy consumption coupled with depleting petroleum reserves and increased greenhouse gas emissions have renewed our interest in generating fuels from renewable energy sources via microbial fermentation. Central to this problem is the choice of microorganism that catalyzes the production of fuels at high volumetric productivity and yield from cheap and abundantly available renewable energy sources. Microorganisms that are metabolically engineered to redirect renewable carbon sources into desired fuel products are contemplated as best choices to obtain high volumetric productivity and yield. Considering the availability of vast knowledge in genomic and metabolic fronts, Escherichia coli is regarded as a primary choice for the production of biofuels. Here, we reviewed the microbial production of liquid biofuels that have the potential to be used either alone or in combination with the present-day fuels. We specifically highlighted the metabolic engineering and synthetic biology approaches used to improve the production of biofuels from E. coli over the past few years. We also discussed the challenges that still exist for the biofuel production from E. coli and their possible solutions.

摘要

能源消耗的增加，加上石油储备的枯竭和温室气体排放的增加，重新激发了我们通过微生物发酵从可再生能源中生产燃料的兴趣。这个问题的核心是选择一种微生物，它能够以高体积生产率和产率，从廉价且丰富的可再生能源中催化生产燃料。经过代谢工程改造以将可再生碳源转化为所需燃料产品的微生物被认为是获得高体积生产率和产率的最佳选择。考虑到基因组学和代谢领域的大量知识，大肠杆菌被视为生产生物燃料的首要选择。在此，我们综述了液态生物燃料的微生物生产，这些生物燃料有可能单独使用或与当今的燃料混合使用。我们特别强调了过去几年中用于提高大肠杆菌生物燃料产量的代谢工程和合成生物学方法。我们还讨论了大肠杆菌生物燃料生产中仍然存在的挑战及其可能的解决方案。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/545a/4946582/2235037bfe07/mbi-9-2016-029f1.jpg

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Potential production platform of n-butanol in Escherichia coli.

Metab Eng. 2015 Jan;27:76-82. doi: 10.1016/j.ymben.2014.11.001. Epub 2014 Nov 15.

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大肠杆菌在生物燃料生产中的作用。

Role of Escherichia coli in Biofuel Production.

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