• 关键词：持久性有机污染物  生物修复  生物可利用性  未培养微生物  基因工程菌

• 基金项目：国家自然科学基金项目(No.40576054,40476047,40206015);"长江学者和创新团队发展计划"项目.

• 黄栩
• 厦门大学生命科学学院应用与环境微生物研究所, 厦门 361005

• 骆苑蓉
• 厦门大学生命科学学院应用与环境微生物研究所, 厦门 361005

• 胡忠
• 1. 厦门大学生命科学学院应用与环境微生物研究所, 厦门 361005; 2. 近海海洋环境科学国家重点实验室(厦门大学), 厦门 361005

• 田蕴
• 厦门大学生命科学学院应用与环境微生物研究所, 厦门 361005

• 郑天凌
• 1. 厦门大学生命科学学院应用与环境微生物研究所, 厦门 361005; 2. 近海海洋环境科学国家重点实验室(厦门大学), 厦门 361005

• 摘要：持久性有机污染物(POPs)具有高毒性和低可降解性的特征,通过先进的生物修复技术来治理POPs污染正受到公众普遍的关注.而提高生物可利用性则可以突破原位生物修复的瓶颈;宏基因组技术可以获得大量的降解基因资源;利用生物工程手段,可以大幅度提高降解菌的能力.这3个方面是目前POPs生物修复领域的研究热点.

• Abstract：Due to the potential toxicity and poor degradation of POPs, advanced bioremediation, a novel effectively removing technique to POPs in various contaminated environmental media including water, sediments and soils, was more and more concerned by public.. With recent advances in the field of biomolecular engineering, the capability of microorganisms to bioremediate POPs could be greatly improved. Low bioavailability, the bottleneck of in situ bioremediation, would be broken through by the study of biosurfactant and chemtaxis; Metagenome could provide us with a large amount of useful genes involved in POPs degradation which traditional culture technique couldn't do. Recently, elevation of POPs bioavailabiliity, exploration of degradation gene from non-cultured microorganism, and construction of Genomic Engineering microorganism(GEM), are three hotspots in research of POPs bioremediation.

• Key words：POPs  bioremediation  bioavailability  non-cultured microorganism  GEMs

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