Alessandro Satta, Guido Zampieri, Giovanni Loprete, Stefano Campanaro, Laura Treu, Elisabetta Bergantino
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引用次数: 0
Abstract
Polyethylene terephthalate (PET) is one of the most marketed aromatic polyesters in the world with an annual demand in 2022 of approximately 29 million metric tons, expected to increase by 40% by 2030. The escalating volume of PET waste and the current inadequacy of recycling methods have led to an accumulation of PET in the terrestrial ecosystem, thereby posing significant global health risks. The pressing global energy and environmental issues associated with PET underscore the urgent need for “upcycling” technologies. These technologies aim to transform reclaimed PET into higher-value products, addressing both energy concerns and environmental sustainability. Enzyme-mediated biocatalytic depolymerization has emerged as a potentially bio-sustainable method for treating and recycling plastics. Numerous plastic-degrading enzymes have been identified from microbial origins, and advancements in protein engineering have been employed to modify and enhance these enzymes. Microbial metabolic engineering allows for the development of modified microbial chassis capable of degrading PET substrates and converting their derived monomers into industrial relevant products. In this review, we describe several engineering approaches aiming at enhancing the performances of PET-degrading enzymes and we present the current metabolic engineering strategies adopted to bio-upcycle PET into high-value molecules.
聚对苯二甲酸乙二醇酯(PET)是世界上销售量最大的芳香族聚酯之一,2022 年的年需求量约为 2900 万公吨,预计到 2030 年将增加 40%。PET 废弃物数量的不断攀升以及目前回收方法的不足,导致 PET 在陆地生态系统中不断积累,从而对全球健康造成重大威胁。与 PET 有关的紧迫的全球能源和环境问题凸显了对 "升级再循环 "技术的迫切需求。这些技术旨在将回收的 PET 转变为价值更高的产品,同时解决能源问题和环境可持续性问题。酶介导的生物催化解聚法已成为处理和回收塑料的一种潜在的生物可持续方法。从微生物中发现了许多塑料降解酶,蛋白质工程学的进步也被用来改造和增强这些酶。微生物代谢工程允许开发能够降解 PET 底物并将其衍生单体转化为工业相关产品的改良微生物底盘。在这篇综述中,我们介绍了几种旨在提高 PET 降解酶性能的工程方法,并介绍了当前为将 PET 生物升级循环为高价值分子而采用的代谢工程策略。
期刊介绍:
Reviews in Environmental Science and Bio/Technology is a publication that offers easily comprehensible, reliable, and well-rounded perspectives and evaluations in the realm of environmental science and (bio)technology. It disseminates the most recent progressions and timely compilations of groundbreaking scientific discoveries, technological advancements, practical applications, policy developments, and societal concerns encompassing all facets of environmental science and (bio)technology. Furthermore, it tackles broader aspects beyond the natural sciences, incorporating subjects such as education, funding, policy-making, intellectual property, and societal influence.