细菌促进塑料生物降解的研究进展及机理:塑料垃圾可持续修复的关键

K. Kaur, Samiksha Sharma, Nidhi Shree, Rekha Mehrotra
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引用次数: 2

摘要

摘要:塑料已经成为我们生活中不可缺少的一部分,完全减少塑料的消耗是很难实现的。塑料的难降解性和不可生物降解性导致大量塑料堆积在垃圾填埋场和水体中,进一步危及海洋生物和人类生命,造成严重的健康问题。近年来,人们发现了几种具有降解塑料能力的微生物酶。目前的综述重点介绍了最近发现的塑料食性细菌,酒井Ideonella sakaiensis的特性,它具有用于塑料降解和回收的潜力。这种细菌拥有独特的酶,使其能够利用聚对苯二甲酸乙二醇酯(PET)塑料,从而将其降解成相对安全的单体形式,可以进一步降解和纯化以制造可回收塑料。综述了PET水解机理、提高酶解效率的研究进展以及利用基因工程技术开发新的酶解细菌和酶解菌株,以提高其催化能力,使酶解过程更省时、更经济。因此,塑料代谢细菌可以成为一种潜在的、有效的生物替代品,以生物和可持续的方式降解塑料,从而帮助扩大否则无法克服的塑料污染危机。
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Recent Advancements and Mechanism of Plastics Biodegradation Promoted by Bacteria: A Key for Sustainable Remediation for Plastic Wastes
ABSTRACT: Plastic has become an indispensable part of our lives and cutting down plastic consumption entirely is difficult to achieve. The recalcitrant and non-biodegradable nature of plastic leads to accumulation of tons of plastic in landfills and water bodies which further risks marine life and human life too causing serious health issues. In recent years, several microbial enzymes have been discovered that have the ability to degrade plastic. The present review highlights the recent discovery and properties of the plastic-eating bacteria, Ideonella sakaiensis, that has potential to be used for plastic degradation and recycling. The bacteria possess unique enzymes that allow it to utilise Polyethylene terephthalate (PET) plastic, thereby degrading it to relatively safer monomeric forms that can be further degraded and purified to manufacture recycled plastics. The review focuses on the mechanism of PET hydrolysis, recent advances in the field to escalate enzymatic efficiency and development of new bacterial and enzymatic strains through genetic engineering which can enhance its catalytic competence and make the process time and cost-effective. The plastic metabolising bacteria can thus be a potential and efficient bio-alternative to degrade plastic in a biological and sustainable manner thereby helping scale the otherwise insurmountable plastic pollution crisis.
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