A synthetic bacterium that degrades and assimilates poly(ethylene terephthalate)

Polyethylene terephthalate (PET) is the fourth most commonly used plastic worldwide. Like all plastics, post-consumer PET is poorly managed and accumulates in the environment, posing significant ecological threats. After 70 years of accumulation, microorganisms capable of degrading and assimilating PET have been isolated, demonstrating that PET can be broken down and converted into valuable cellular biomass or metabolic products. These natural isolates, however, are poorly characterized and challenging to genetically manipulate, which limits their further optimization and applicability. Here, we engineer a well-established synthetic biology chassis for the biodegradation and assimilation of PET. We modified the bacterium Pseudomonas putida KT2440 to heterologously express an active PET-hydrolytic enzyme extracellularly and to metabolize PET biodegradation products. The resulting strain, named PETBuster, was capable of growing on PET as the sole carbon source on solid and liquid media. We achieved 91% PET degradation after 21 days of culture, with a doubling time of 3.6 days, under mesophilic conditions. In this way, we demonstrate that PET fermentation is feasible, opening the door to the production of valuable chemicals from waste.