利用工程化的嗜盐栖热放线菌PCC 7002将CO光合转化为蒎烯

Photosynthetic Conversion of CO Into Pinene Using Engineered sp. PCC 7002.

作者信息

Yang Ruigang, Zhu Lingyun, Li Tao, Zhu Lv-Yun, Ye Zi, Zhang Dongyi

机构信息

Department of Biology and Chemistry, College of Liberal Arts and Sciences, National University of Defense Technology, Changsha, China.

State Key Laboratory of Freshwater Ecology and Biotechnology, Institute of Hydrobiology, Chinese Academy of Sciences, Wuhan, China.

出版信息

Front Bioeng Biotechnol. 2021 Dec 17;9:779437. doi: 10.3389/fbioe.2021.779437. eCollection 2021.

DOI:10.3389/fbioe.2021.779437

PMID:34976975

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8718756/

Abstract

Metabolic engineering of cyanobacteria has received much attention as a sustainable strategy to convert CO to various longer carbon chain fuels. Pinene has become increasingly attractive since pinene dimers contain high volumetric energy and have been proposed to act as potential aircraft fuels. However, cyanobacteria cannot directly convert geranyl pyrophosphate into pinene due to the lack of endogenous pinene synthase. Herein, we integrated the gene encoding pinene synthase into the model cyanobacterium sp. PCC 7002 through homologous recombination. The genetically modified cyanobacteria achieved a pinene titer of 1.525 ± 0.l45 mg L in the lab-scale tube photobioreactor with CO aeration. Specifically, the results showed a mixture of - and -pinene (∼33:67 ratio). The ratio of -pinene in the product was significantly increased compared with that previously reported in the engineered . Furthermore, we investigated the photoautotrophic growth performances of overlaid with different concentrations of dodecane. The work demonstrates that the engineered is a suitable potential platform for -pinene production.

摘要

蓝藻的代谢工程作为一种将CO转化为各种更长碳链燃料的可持续策略受到了广泛关注。由于蒎烯二聚体具有高体积能量，并被提议用作潜在的飞机燃料，蒎烯变得越来越有吸引力。然而，由于缺乏内源性蒎烯合酶，蓝藻无法直接将香叶基焦磷酸转化为蒎烯。在此，我们通过同源重组将编码蒎烯合酶的基因整合到模式蓝藻集胞藻PCC 7002中。在实验室规模的管式光生物反应器中通入CO进行通气培养，基因改造后的蓝藻实现了1.525±0.145 mg/L的蒎烯滴度。具体而言，结果显示产物为α-蒎烯和β-蒎烯的混合物（比例约为33:67）。与之前在工程化蓝藻中报道的相比，产物中β-蒎烯的比例显著增加。此外，我们研究了覆盖不同浓度十二烷的集胞藻的光合自养生长性能。这项工作表明，工程化的集胞藻是生产β-蒎烯的合适潜在平台。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/d793/8718756/33e0e3343ef9/fbioe-09-779437-g001.jpg

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Biotechnol Bioeng. 2019 Aug;116(8):2041-2051. doi: 10.1002/bit.26988. Epub 2019 Apr 20.

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Biotechnol J. 2019 Jun;14(6):e1800496. doi: 10.1002/biot.201800496. Epub 2019 May 17.

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利用工程化的嗜盐栖热放线菌PCC 7002将CO光合转化为蒎烯

Photosynthetic Conversion of CO Into Pinene Using Engineered sp. PCC 7002.

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