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角质酶样酶对聚对苯二甲酸乙二酯生物降解的最新进展

Recent advances in the biodegradation of polyethylene terephthalate with cutinase-like enzymes.

作者信息

Sui Beibei, Wang Tao, Fang Jingxiang, Hou Zuoxuan, Shu Ting, Lu Zhenhua, Liu Fei, Zhu Youshuang

机构信息

School of Biological Science, Jining Medical University, Jining, Shandong, China.

Rizhao Administration for Market Regulation, Rizhao, Shandong, China.

出版信息

Front Microbiol. 2023 Oct 2;14:1265139. doi: 10.3389/fmicb.2023.1265139. eCollection 2023.

DOI:10.3389/fmicb.2023.1265139
PMID:37849919
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10577388/
Abstract

Polyethylene terephthalate (PET) is a synthetic polymer in the polyester family. It is widely found in objects used daily, including packaging materials (such as bottles and containers), textiles (such as fibers), and even in the automotive and electronics industries. PET is known for its excellent mechanical properties, chemical resistance, and transparency. However, these features (e.g., high hydrophobicity and high molecular weight) also make PET highly resistant to degradation by wild-type microorganisms or physicochemical methods in nature, contributing to the accumulation of plastic waste in the environment. Therefore, accelerated PET recycling is becoming increasingly urgent to address the global environmental problem caused by plastic wastes and prevent plastic pollution. In addition to traditional physical cycling (e.g., pyrolysis, gasification) and chemical cycling (e.g., chemical depolymerization), biodegradation can be used, which involves breaking down organic materials into simpler compounds by microorganisms or PET-degrading enzymes. Lipases and cutinases are the two classes of enzymes that have been studied extensively for this purpose. Biodegradation of PET is an attractive approach for managing PET waste, as it can help reduce environmental pollution and promote a circular economy. During the past few years, great advances have been accomplished in PET biodegradation. In this review, current knowledge on cutinase-like PET hydrolases (such as TfCut2, Cut190, HiC, and LCC) was described in detail, including the structures, ligand-protein interactions, and rational protein engineering for improved PET-degrading performance. In particular, applications of the engineered catalysts were highlighted, such as improving the PET hydrolytic activity by constructing fusion proteins. The review is expected to provide novel insights for the biodegradation of complex polymers.

摘要

聚对苯二甲酸乙二酯(PET)是聚酯家族中的一种合成聚合物。它广泛存在于日常使用的物品中,包括包装材料(如瓶子和容器)、纺织品(如纤维),甚至在汽车和电子行业中也有应用。PET以其优异的机械性能、耐化学性和透明度而闻名。然而,这些特性(例如高疏水性和高分子量)也使得PET在自然界中对野生型微生物或物理化学方法的降解具有高度抗性,导致环境中塑料废物的积累。因此,加速PET回收对于解决塑料废物造成的全球环境问题和防止塑料污染变得越来越紧迫。除了传统的物理循环(如热解、气化)和化学循环(如化学解聚)外,还可以采用生物降解,即通过微生物或PET降解酶将有机材料分解为更简单的化合物。脂肪酶和角质酶是为此目的而被广泛研究的两类酶。PET的生物降解是处理PET废物的一种有吸引力的方法,因为它有助于减少环境污染并促进循环经济。在过去几年中,PET生物降解取得了重大进展。在这篇综述中,详细描述了关于角质酶样PET水解酶(如TfCut2、Cut190、HiC和LCC)的当前知识,包括其结构、配体 - 蛋白质相互作用以及用于提高PET降解性能的合理蛋白质工程。特别强调了工程催化剂的应用,例如通过构建融合蛋白来提高PET水解活性。这篇综述有望为复杂聚合物的生物降解提供新的见解。

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4
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