Upon the development of traditional plastics their high stability was a very desirable feature, little though was given to their end-of-life fate. Now, half a century later, plastic pollution is everywhere. Amazingly, nature is already starting to adapt even after this very short evolutionary timespan. We are finding microbes that can degrade recalcitrant plastics like PET or PU. These microbes have enzymes that can break down the polymer to its monomeric constituent, and sometime they even have the metabolic pathways to then consume these plastic monomers.
We are discovering plastic-degrading enzymes in diverse natural habitats such as our oceans, but also in places with very high microbial activity like composting facilities. Given the incredibly short time these enzymes had to evolve on plastics, they will usually only have a minor, moonlighting activity on man-made polymers. We accelerate this evolution in the laboratory, creating specialized variants with greatly increased plastic-degrading activity. These enhanced enzymes enable the depolymerization of plastic waste. The resulting monomers can be purified and recycled into new polymers, or they can be fed to microbes in fermentation processes.
Unlike typical biotechnology substrates such as sugars, many plastic monomers are not common in nature. As a result, their biodegradation is often limited to a few organisms in specific environmental niches. We therefore engineer microbial biotechnology workhorses such as Pseudomonas putida and Corynebacterium glutamicum to metabolize plastic monomers. This engineering then allows for the conversion of plastic hydrolysates into value-added chemicals and biopolymers, leveraging the decades of experience we have with bio-based microbial catalysis to enable plastic-based microbial conversions.
UPLIFT sUstainable PLastIcs for the Food and drink packaging industry
Glaukos Circular solution for the textile industry
MIX-UP MIXed plastics biodegradation and UPcycling using microbial communities