Strategies for biofilm optimization of plastic-degrading microorganisms and isolating biofilm formers from plastic-contaminated environments

Sustainable microbiology Pub Date : 2024-05-17 DOI:10.1093/sumbio/qvae012

Adam McFall, Scott A Coughlin, Gary Hardiman, J. Megaw

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Abstract

The perpetual disposal of plastic waste, combined with ineffective waste management strategies, has resulted in widespread environmental plastic pollution. Microbial plastic biodegradation represents an emerging solution to this problem. However, biodegradation studies tend to overlook the fundamental prerequisite of initial surface colonization via biofilm formation. This study had two independent but connected aims relating to plastic surface colonization by microorganisms: to enhance biofilm formation by known plastic degraders, with translational potential for improved plastic degradation, and to isolate microorganisms from microplastic contaminated environments with the ability to colonize plastic surfaces. Planktonic and biofilm responses to diverse carbon and energy sources were investigated over seven days, using Bacillus subtilis 168, Fusarium solani (Martius) Saccardo, Ideonella sakaiensis 201-F6, Pseudomonas putida KT2440 and Rhodococcus ruber C208. This enabled optimal conditions for biofilm formation by each strain to be determined. In parallel, environmental samples containing synthetic or natural polymeric substances (anaerobic digestate, landfill leachate, and microplastic contaminated compost) were incubated with polyethylene and polyethylene terephthalate films, to isolate microorganisms capable of colonizing their surfaces. This yielded eight bacterial isolates from three genera: Bacillus, Lysinibacillus, and Proteus. These genera contain species that have been shown to degrade plastics and other recalcitrant synthetic polymers, demonstrating the success of our approach. This study also suggests that discrete plastic types may create different ecological niches which can be exploited by unique bacterial colonizers. Our findings underscore the importance of considering plastic colonization by microbial biofilms in the context of their biodegradation.

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优化塑料降解微生物生物膜的策略以及从塑料污染环境中分离生物膜形成者

塑料废弃物的长期弃置，加上无效的废物管理策略，造成了广泛的环境塑料污染。微生物塑料生物降解是解决这一问题的新兴方法。然而，生物降解研究往往忽略了通过生物膜形成初步表面定殖这一基本前提。这项研究有两个独立但相互关联的目的：一是增强已知塑料降解菌的生物膜形成，从而提高塑料降解的转化潜力；二是从微塑料污染环境中分离出具有塑料表面定殖能力的微生物。研究人员使用枯草芽孢杆菌 168、Fusarium solani (Martius) Saccardo、Ideonella sakaiensis 201-F6、Pseudomonas putida KT2440 和 Rhodococcus ruber C208，对浮游生物和生物膜对不同碳源和能源的反应进行了为期七天的研究。这样就能确定每种菌株形成生物膜的最佳条件。同时，将含有合成或天然高分子物质的环境样本（厌氧消化液、垃圾填埋场渗滤液和受微塑料污染的堆肥）与聚乙烯和聚对苯二甲酸乙二醇酯薄膜一起培养，以分离出能够在其表面定殖的微生物。结果从三个属中分离出八种细菌：分别是芽孢杆菌属、赖氨巴氏杆菌属和变形杆菌属。这些菌属中的物种已被证明可以降解塑料和其他难降解的合成聚合物，这证明我们的方法是成功的。这项研究还表明，不同类型的塑料可能会产生不同的生态位，而独特的细菌定殖者可以利用这些生态位。我们的研究结果强调了在生物降解过程中考虑微生物生物膜定殖塑料的重要性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Sustainable microbiology

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