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协同作用在发挥:连接两种乳酸菌的代谢以实现2-丁醇的高效生产。

Synergy at work: linking the metabolism of two lactic acid bacteria to achieve superior production of 2-butanol.

作者信息

Mar Mette J, Andersen Joakim M, Kandasamy Vijayalakshmi, Liu Jianming, Solem Christian, Jensen Peter R

机构信息

National Food Institute, Technical University of Denmark, Kemitorvet, Building 201, 2800 Kgs. Lyngby, Denmark.

出版信息

Biotechnol Biofuels. 2020 Mar 11;13:45. doi: 10.1186/s13068-020-01689-w. eCollection 2020.

DOI:10.1186/s13068-020-01689-w
PMID:32180827
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7065357/
Abstract

BACKGROUND

The secondary alcohol 2-butanol has many important applications, e.g., as a solvent. Industrially, it is usually made by sulfuric acid-catalyzed hydration of butenes. Microbial production of 2-butanol has also been attempted, however, with little success as witnessed by the low titers and yields reported. Two important reasons for this, are the growth-hampering effect of 2-butanol on microorganisms, and challenges associated with one of the key enzymes involved in its production, namely diol dehydratase.

RESULTS

We attempt to link the metabolism of an engineered strain, which possesses all enzyme activities required for fermentative production of 2-butanol from glucose, except for diol dehydratase, which acts on -2,3-butanediol (mBDO), with that of a strain which expresses a functional dehydratase natively. We demonstrate growth-coupled production of 2-butanol by the engineered strain, when co-cultured with . After fine-tuning the co-culture setup, a titer of 80 mM (5.9 g/L) 2-butanol, with a high yield of 0.58 mol/mol is achieved.

CONCLUSIONS

Here, we demonstrate that it is possible to link the metabolism of two bacteria to achieve redox-balanced production of 2-butanol. Using a simple co-cultivation setup, we achieved the highest titer and yield from glucose in a single fermentation step ever reported. The data highlight the potential that lies in harnessing microbial synergies for producing valuable compounds.

摘要

背景

仲醇2-丁醇有许多重要应用,例如作为溶剂。在工业上,它通常由硫酸催化丁烯水合制得。也有人尝试过通过微生物生产2-丁醇,然而,从报道的低滴度和产量来看,成效甚微。造成这种情况的两个重要原因是,2-丁醇对微生物有生长抑制作用,以及其生产过程中涉及的一种关键酶——二醇脱水酶存在相关挑战。

结果

我们试图将一种工程菌株的代谢与另一种天然表达功能性脱水酶的菌株的代谢联系起来。该工程菌株具备从葡萄糖发酵生产2-丁醇所需的所有酶活性,但作用于-2,3-丁二醇(mBDO)的二醇脱水酶除外。我们证明,当工程菌株与[具体菌株]共培养时,该工程菌株能够实现与生长耦合的2-丁醇生产。在对共培养设置进行微调后,2-丁醇的滴度达到80 mM(5.9 g/L),产率高达0.58 mol/mol。

结论

在此,我们证明了可以将两种细菌的代谢联系起来,以实现氧化还原平衡的2-丁醇生产。通过简单的共培养设置,我们在单个发酵步骤中从葡萄糖获得了有史以来最高的滴度和产率。这些数据凸显了利用微生物协同作用生产有价值化合物的潜力。

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