Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design

Xiaoyun Lu; Yuwan Liu; Yiqun Yang; Shanshan Wang; Qian Wang; Xiya Wang; Zhihui Yan; Jian Cheng; Cui Liu; Xue Yang; Hao Luo; Sheng Yang; Junran Gou; Luzhen Ye; Lina Lu; Zhidan Zhang; Yu Guo; Yan Nie; Jianping Lin; Sheng Li; Chaoguang Tian; Tao Cai; Bingzhao Zhuo; Hongwu Ma; Wen Wang; Yanhe Ma; Yongjun Liu; Yin Li; Huifeng Jiang

doi:10.1038/s41467-019-09095-z

Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design

Xiaoyun Lu, Yuwan Liu, Yiqun Yang, Shanshan Wang, Qian Wang, Xiya Wang, Zhihui Yan, Jian Cheng, Cui Liu, Xue Yang, Hao Luo, Sheng Yang, Junran Gou, Luzhen Ye, Lina Lu, Zhidan Zhang, Yu Guo, Yan Nie, Jianping Lin, Sheng LiChaoguang Tian, Tao Cai, Bingzhao Zhuo, Hongwu Ma, Wen Wang, Yanhe Ma, Yongjun Liu, Yin Li, Huifeng Jiang

School of Ecology and Environment

Research output: Contribution to journal › Article › peer-review

204 Scopus citations

Abstract

Acetyl-CoA is a fundamental metabolite for all life on Earth, and is also a key starting point for the biosynthesis of a variety of industrial chemicals and natural products. Here we design and construct a Synthetic Acetyl-CoA (SACA) pathway by repurposing glycolaldehyde synthase and acetyl-phosphate synthase. First, we design and engineer glycolaldehyde synthase to improve catalytic activity more than 70-fold, to condense two molecules of formaldehyde into one glycolaldehyde. Second, we repurpose a phosphoketolase to convert glycolaldehyde into acetyl-phosphate. We demonstrated the feasibility of the SACA pathway in vitro, achieving a carbon yield ~50%, and confirmed the SACA pathway by ¹³ C-labeled metabolites. Finally, the SACA pathway was verified by cell growth using glycolaldehyde, formaldehyde and methanol as supplemental carbon source. The SACA pathway is proved to be the shortest, ATP-independent, carbon-conserving and oxygen-insensitive pathway for acetyl-CoA biosynthesis, opening possibilities for producing acetyl-CoA-derived chemicals from one-carbon resources in the future.

Original language	English
Article number	1378
Journal	Nature Communications
Volume	10
Issue number	1
DOIs	https://doi.org/10.1038/s41467-019-09095-z
State	Published - 1 Dec 2019

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Lu, X., Liu, Y., Yang, Y., Wang, S., Wang, Q., Wang, X., Yan, Z., Cheng, J., Liu, C., Yang, X., Luo, H., Yang, S., Gou, J., Ye, L., Lu, L., Zhang, Z., Guo, Y., Nie, Y., Lin, J., ... Jiang, H. (2019). Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design. Nature Communications, 10(1), Article 1378. https://doi.org/10.1038/s41467-019-09095-z

@article{efa5ab01d3e34c5bb4c1ec41bf2d6075,

title = "Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design",

abstract = " Acetyl-CoA is a fundamental metabolite for all life on Earth, and is also a key starting point for the biosynthesis of a variety of industrial chemicals and natural products. Here we design and construct a Synthetic Acetyl-CoA (SACA) pathway by repurposing glycolaldehyde synthase and acetyl-phosphate synthase. First, we design and engineer glycolaldehyde synthase to improve catalytic activity more than 70-fold, to condense two molecules of formaldehyde into one glycolaldehyde. Second, we repurpose a phosphoketolase to convert glycolaldehyde into acetyl-phosphate. We demonstrated the feasibility of the SACA pathway in vitro, achieving a carbon yield ~50%, and confirmed the SACA pathway by 13 C-labeled metabolites. Finally, the SACA pathway was verified by cell growth using glycolaldehyde, formaldehyde and methanol as supplemental carbon source. The SACA pathway is proved to be the shortest, ATP-independent, carbon-conserving and oxygen-insensitive pathway for acetyl-CoA biosynthesis, opening possibilities for producing acetyl-CoA-derived chemicals from one-carbon resources in the future.",

author = "Xiaoyun Lu and Yuwan Liu and Yiqun Yang and Shanshan Wang and Qian Wang and Xiya Wang and Zhihui Yan and Jian Cheng and Cui Liu and Xue Yang and Hao Luo and Sheng Yang and Junran Gou and Luzhen Ye and Lina Lu and Zhidan Zhang and Yu Guo and Yan Nie and Jianping Lin and Sheng Li and Chaoguang Tian and Tao Cai and Bingzhao Zhuo and Hongwu Ma and Wen Wang and Yanhe Ma and Yongjun Liu and Yin Li and Huifeng Jiang",

note = "Publisher Copyright: {\textcopyright} 2019, The Author(s).",

year = "2019",

month = dec,

day = "1",

doi = "10.1038/s41467-019-09095-z",

language = "英语",

volume = "10",

journal = "Nature Communications",

issn = "2041-1723",

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Lu, X, Liu, Y, Yang, Y, Wang, S, Wang, Q, Wang, X, Yan, Z, Cheng, J, Liu, C, Yang, X, Luo, H, Yang, S, Gou, J, Ye, L, Lu, L, Zhang, Z, Guo, Y, Nie, Y, Lin, J, Li, S, Tian, C, Cai, T, Zhuo, B, Ma, H, Wang, W, Ma, Y, Liu, Y, Li, Y & Jiang, H 2019, 'Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design', Nature Communications, vol. 10, no. 1, 1378. https://doi.org/10.1038/s41467-019-09095-z

TY - JOUR

T1 - Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design

AU - Lu, Xiaoyun

AU - Liu, Yuwan

AU - Yang, Yiqun

AU - Wang, Shanshan

AU - Wang, Qian

AU - Wang, Xiya

AU - Yan, Zhihui

AU - Cheng, Jian

AU - Liu, Cui

AU - Yang, Xue

AU - Luo, Hao

AU - Yang, Sheng

AU - Gou, Junran

AU - Ye, Luzhen

AU - Lu, Lina

AU - Zhang, Zhidan

AU - Guo, Yu

AU - Nie, Yan

AU - Lin, Jianping

AU - Li, Sheng

AU - Tian, Chaoguang

AU - Cai, Tao

AU - Zhuo, Bingzhao

AU - Ma, Hongwu

AU - Wang, Wen

AU - Ma, Yanhe

AU - Liu, Yongjun

AU - Li, Yin

AU - Jiang, Huifeng

PY - 2019/12/1

Y1 - 2019/12/1

N2 - Acetyl-CoA is a fundamental metabolite for all life on Earth, and is also a key starting point for the biosynthesis of a variety of industrial chemicals and natural products. Here we design and construct a Synthetic Acetyl-CoA (SACA) pathway by repurposing glycolaldehyde synthase and acetyl-phosphate synthase. First, we design and engineer glycolaldehyde synthase to improve catalytic activity more than 70-fold, to condense two molecules of formaldehyde into one glycolaldehyde. Second, we repurpose a phosphoketolase to convert glycolaldehyde into acetyl-phosphate. We demonstrated the feasibility of the SACA pathway in vitro, achieving a carbon yield ~50%, and confirmed the SACA pathway by 13 C-labeled metabolites. Finally, the SACA pathway was verified by cell growth using glycolaldehyde, formaldehyde and methanol as supplemental carbon source. The SACA pathway is proved to be the shortest, ATP-independent, carbon-conserving and oxygen-insensitive pathway for acetyl-CoA biosynthesis, opening possibilities for producing acetyl-CoA-derived chemicals from one-carbon resources in the future.

AB - Acetyl-CoA is a fundamental metabolite for all life on Earth, and is also a key starting point for the biosynthesis of a variety of industrial chemicals and natural products. Here we design and construct a Synthetic Acetyl-CoA (SACA) pathway by repurposing glycolaldehyde synthase and acetyl-phosphate synthase. First, we design and engineer glycolaldehyde synthase to improve catalytic activity more than 70-fold, to condense two molecules of formaldehyde into one glycolaldehyde. Second, we repurpose a phosphoketolase to convert glycolaldehyde into acetyl-phosphate. We demonstrated the feasibility of the SACA pathway in vitro, achieving a carbon yield ~50%, and confirmed the SACA pathway by 13 C-labeled metabolites. Finally, the SACA pathway was verified by cell growth using glycolaldehyde, formaldehyde and methanol as supplemental carbon source. The SACA pathway is proved to be the shortest, ATP-independent, carbon-conserving and oxygen-insensitive pathway for acetyl-CoA biosynthesis, opening possibilities for producing acetyl-CoA-derived chemicals from one-carbon resources in the future.

UR - http://www.scopus.com/inward/record.url?scp=85063511403&partnerID=8YFLogxK

U2 - 10.1038/s41467-019-09095-z

DO - 10.1038/s41467-019-09095-z

M3 - 文章

C2 - 30914637

AN - SCOPUS:85063511403

SN - 2041-1723

VL - 10

JO - Nature Communications

JF - Nature Communications

IS - 1

M1 - 1378

ER -

Constructing a synthetic pathway for acetyl-coenzyme A from one-carbon through enzyme design

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