Microbial Upcycling of Waste PET to Adipic Acid.

Microorganisms can be genetically engineered to transform abundant waste feedstocks into value-added small molecules that would otherwise be manufactured from diminishing fossil resources. Herein, we report the first one-pot bio-upcycling of PET plastic waste into the prolific platform petrochemical and nylon precursor adipic acid in the bacterium . Optimizing heterologous gene expression and enzyme activity enabled increased flux through the pathway, and immobilization of whole cells in alginate hydrogels increased the stability of the rate-limiting enoate reductase BcER.

One-Pot Synthesis of Adipic Acid from Guaiacol in .

Adipic acid is one of the most important small molecules in the modern chemical industry. However, the damaging environmental impact of the current industrial synthesis of adipic acid has necessitated the development of greener, biobased approaches to its manufacture. Herein we report the first one-pot synthesis of adipic acid from guaiacol, a lignin-derived feedstock, using genetically engineered whole-cells of .

Transition Metal-Free Reduction of Activated Alkenes Using a Living Microorganism.

Microorganisms can be programmed to perform chemical synthesis via metabolic engineering. However, despite an increasing interest in the use of de novo metabolic pathways and designer whole-cells for small molecule synthesis, the inherent synthetic capabilities of native microorganisms remain underexplored. Herein, we report the use of unmodified E.