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Polybutylene adipate terephthalate (PBAT) is a biodegradable alternative to polyethylene and can be broadly used in various applications. These polymers can be degraded by hydrolases of terrestrial and aquatic origin. In a previous study, we identified tandem PETase-like hydrolases (Ples) from the marine microbial consortium I1 that were highly expressed when a PBAT blend was supplied as the only carbon source. In this study, the tandem Ples, Ple628 and Ple629, were recombinantly expressed and characterized. Both enzymes are mesophilic and active on a wide range of oligomers. The activities of the Ples differed greatly when model substrates, PBAT-modified polymers or PET nanoparticles were supplied. Ple629 was always more active than Ple628. Crystal structures of Ple628 and Ple629 revealed a structural similarity to other PETases and can be classified as member of the PETases IIa subclass, α/β hydrolase superfamily. Our results show that the predicted functions of Ple628 and Ple629 agree with the bioinformatic predictions, and these enzymes play a significant role in the plastic degradation by the consortium.
This thesis deals with the characterisation and engineering of new thermophilic PET hydrolases as potential candidates for an eco-friendly biocatalytic recycling approach for the upcycling or downcycling of polyethylene terephthalate (PET) on industrial scale. Furthermore, high-throughput screening methods are described that detect the products of PET hydrolysis. The high demand of PET in the packaging and textile industries with a global production of 82 million metric tons per year has significantly contributed to the global solid waste stream and environmental plastic pollution after its end-of-life. Although PET hydrolases have been identified in various microorganisms, only a handful of benchmark enzymes have been engineered for industrial applications. Therefore, the identification of new PET hydrolases from metagenomes or via protein engineering approaches, especially thermophilic PET hydrolases with optimal operating temperatures (i.e., increased thermostability and activity) near the glass transition temperature of the polymer PET, is a crucial step towards a bio-based circular plastic economy. Article I demonstrates that metagenome-derived thermophilic PET hydrolases can be significantly improved using different engineering approaches to achieve a similar activity level as the well-established leaf-branch-compost cutinase (LCC) F243I/D238C/S283C/Y127G variant (LCC ICCG). In Article II, thermostable variants of a mesophilic enzyme (PETase from Ideonella sakaiensis) were identified from a mutant library and characterised against PET substrates in various forms. Articles III and IV describe the application of high-throughput methods for the identification of novel PET hydrolases by directly assaying terephthalic acid (TPA), one of the monomeric building blocks of PET. Furthermore, Article IV describes the possibility of a one-pot conversion of the TPA-based aldehydes produced to their diamines as example for an open-loop upcycling method.