Cell-free chemoenzymatic starch synthesis from carbon dioxide

Cell-free chemoenzymatic starch synthesis from carbon dioxide

Starches, a storage form of carbohydrates, are a major source of calories in the human diet and a primary feedstock for bioindustry. We report a chemical-biochemical hybrid pathway for starch synthesis from carbon dioxide (CO ) and hydrogen in a cell-free system. The artificial starch anabolic pathw...

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Veröffentlicht in:Science (American Association for the Advancement of Science) 2021-09, Vol.373 (6562), p.1523-1527
Hauptverfasser: Cai, Tao, Sun, Hongbing, Qiao, Jing, Zhu, Leilei, Zhang, Fan, Zhang, Jie, Tang, Zijing, Wei, Xinlei, Yang, Jiangang, Yuan, Qianqian, Wang, Wangyin, Yang, Xue, Chu, Huanyu, Wang, Qian, You, Chun, Ma, Hongwu, Sun, Yuanxia, Li, Yin, Li, Can, Jiang, Huifeng, Wang, Qinhong, Ma, Yanhe
Format: Artikel
Sprache:eng
Schlagworte:
Amylopectin
Amylose
Calories
Carbohydrates
Carbon dioxide
Carbon fixation
Catalysts
Cell-free system
Chemical synthesis
Computer applications
Energy storage
Enzymes
Hybrid systems
Modular design
Modular engineering
Photosynthesis
Polymers
Protein engineering
Seeds
Starch
Starches
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Zusammenfassung:Starches, a storage form of carbohydrates, are a major source of calories in the human diet and a primary feedstock for bioindustry. We report a chemical-biochemical hybrid pathway for starch synthesis from carbon dioxide (CO ) and hydrogen in a cell-free system. The artificial starch anabolic pathway (ASAP), consisting of 11 core reactions, was drafted by computational pathway design, established through modular assembly and substitution, and optimized by protein engineering of three bottleneck-associated enzymes. In a chemoenzymatic system with spatial and temporal segregation, ASAP, driven by hydrogen, converts CO to starch at a rate of 22 nanomoles of CO per minute per milligram of total catalyst, an ~8.5-fold higher rate than starch synthesis in maize. This approach opens the way toward future chemo-biohybrid starch synthesis from CO .
ISSN:0036-8075
1095-9203
DOI:10.1126/science.abh4049