生物膜
生物
斯氏假单胞菌
微生物种群生物学
微生物生态学
胞外聚合物
环境生物技术
生物降解
细菌
微生物学
降级(电信)
微生物代谢
聚乙烯
微生物降解
实验进化
生态学
利基
极端环境
微生物
生物污染
殖民地化
细胞外
抗性(生态学)
选择(遗传算法)
假单胞菌
作者
Shan Li,Jiajia Liu,Lei Su,Jingwen Qiu,Lian‐Bing Lin,Ákos T. Kovács,Yicen Lin
标识
DOI:10.1093/ismejo/wraf223
摘要
Polyethylene (PE), one of the most widely used synthetic polymers, presents significant environmental challenges due to its resistance to biodegradation. Its surface offers a unique ecological niche for microbial colonization and serves as a primary habitat for degrading microorganisms. Despite the pivotal role microbial communities play in plastic degradation, there has been limited research on constructing stable, interacting microbial consortia. In this study, we explored the potential of evolving bacterial biofilm communities to enhance PE degradation. Through long-term experimental evolution, six microbial populations underwent 40 selection cycles using PE as their sole carbon source. The resulting evolved communities formed robust, multi-species biofilms with enhanced degradation capabilities, outperforming their ancestral populations in biofilm production. Stutzerimonas stutzeri emerged as the dominant species, orchestrating a synergistic interaction with two other isolates through metabolic division of labor. (Meta)-transcriptomics analysis revealed that Stutzerimonas primarily contributed to the expression of enzymes involved in microbe-mediated degradation of PE, whereas the other community members were responsible for secreting extracellular polysaccharides, improving biofilm formation. This study highlights the potential of experimentally evolved microbial consortia to synergistically accelerate plastic biodegradation, offering promising strategies for environmental bioremediation.
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