PLoS Biology (Sep 2023)

Construction of an artificial phosphoketolase pathway that efficiently catabolizes multiple carbon sources to acetyl-CoA.

  • Yiqun Yang,
  • Yuwan Liu,
  • Haodong Zhao,
  • Dingyu Liu,
  • Jie Zhang,
  • Jian Cheng,
  • Qiaoyu Yang,
  • Huanyu Chu,
  • Xiaoyun Lu,
  • Mengting Luo,
  • Xiang Sheng,
  • Yi-Heng P J Zhang,
  • Huifeng Jiang,
  • Yanhe Ma

DOI
https://doi.org/10.1371/journal.pbio.3002285
Journal volume & issue
Vol. 21, no. 9
p. e3002285

Abstract

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The canonical glycolysis pathway is responsible for converting glucose into 2 molecules of acetyl-coenzyme A (acetyl-CoA) through a cascade of 11 biochemical reactions. Here, we have designed and constructed an artificial phosphoketolase (APK) pathway, which consists of only 3 types of biochemical reactions. The core enzyme in this pathway is phosphoketolase, while phosphatase and isomerase act as auxiliary enzymes. The APK pathway has the potential to achieve a 100% carbon yield to acetyl-CoA from any monosaccharide by integrating a one-carbon condensation reaction. We tested the APK pathway in vitro, demonstrating that it could efficiently catabolize typical C1-C6 carbohydrates to acetyl-CoA with yields ranging from 83% to 95%. Furthermore, we engineered Escherichia coli stain capable of growth utilizing APK pathway when glycerol act as a carbon source. This novel catabolic pathway holds promising route for future biomanufacturing and offering a stoichiometric production platform using multiple carbon sources.