Enzymatic Degradation of Polyethylene Terephthalate Plastics by Bacterial Curli Display PETase

The extensive production and use of polyethylene terephthalate (PET) have generated an enormous amount of plastic waste, which potentially threatens the environment and humans. Enzyme biocatalysis is a promising green chemistry alternative, relative to the conventional fossil-derived production process, to achieve plastic waste treatment and recycling. In this work, we created a biocatalyst, BIND-PETase, by genetically engineering the curli of an Escherichia coli cell with a functional PETase enzyme for biocatalytic degradation of PET plastics. BIND-PETase could degrade PET to generate degradation products at the concentration level of greater than 3000 mu M under various reaction conditions. The effects of key reaction parameters, including pH, temperature, plastic substrate mass load, and surfactant addition were characterized. BIND-PETase was reusable for PET degradation and remained stable with no significant enzyme activity loss when stored at both 4 degrees C and room temperature for 30 days (Student's t test, p > 0.05). Notably, BIND-PETase could enable the degradation of PET microplastics in wastewater effluent matrix. Moreover, BIND-PETase could depolymerize highly crystalline postconsumer PET waste materials under ambient conditions with degradation efficiency of 9.1% in 7 days. This study provides a new horizon for developing environmentally friendly biocatalytic approaches to solve the plastic degradation and recycling challenge.

Automated summary

The extensive production of polyethylene terephthalate (PET) has led to a significant amount of plastic waste, posing potential threats to the environment and humans. This study presents a promising green chemistry alternative, enzyme biocatalysis, for the treatment and recycling of PET plastics. The researchers engineered a biocatalyst called BIND-PETase, which successfully degraded PET under various conditions. BIND-PETase demonstrated stability and reusability, and could effectively degrade PET microplastics in wastewater effluent matrix and highly crystalline postconsumer PET waste. This study provides a new approach to environmentally friendly plastic degradation and recycling.