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Computational redesign of a hydrolase for nearly complete PET depolymerization at industrially relevant high-solids loading.

Ying-Lu CuiYanchun ChenJinyuan SunTong ZhuHua PangChunli LiWen-Chao GengBian Wu
Published in: Nature communications (2024)
Biotechnological plastic recycling has emerged as a suitable option for addressing the pollution crisis. A major breakthrough in the biodegradation of poly(ethylene terephthalate) (PET) is achieved by using a LCC variant, which permits 90% conversion at an industrial level. Despite the achievements, its applications have been hampered by the remaining 10% of nonbiodegradable PET. Herein, we address current challenges by employing a computational strategy to engineer a hydrolase from the bacterium HR29. The redesigned variant, TurboPETase, outperforms other well-known PET hydrolases. Nearly complete depolymerization is accomplished in 8 h at a solids loading of 200 g kg -1 . Kinetic and structural analysis suggest that the improved performance may be attributed to a more flexible PET-binding groove that facilitates the targeting of more specific attack sites. Collectively, our results constitute a significant advance in understanding and engineering of industrially applicable polyester hydrolases, and provide guidance for further efforts on other polymer types.
Keyphrases
  • pet ct
  • positron emission tomography
  • computed tomography
  • pet imaging
  • heavy metals
  • public health
  • wastewater treatment
  • air pollution
  • drinking water