Recent advancements and applications of soil bioremediation techniques

doi:10.16085/j.issn.1000-6613.2023-0046

Abstract

Abstract:

Soil contamination is often caused by the inappropriate treatment of industrial wastes and municipal sewage threatening the safety of environment, food and ecology as well as the sustainability of society. Bioremediation refers to the application of microorganisms to dissociate organic compounds, detoxifying heavy metal ions or reducing their bioavailability. The advancement of biotechnology has empowered technical innovation of bioremediation methods and their applications in the treatment of contaminated farmland and wasted plant site. This review starts with a brief introduction to bioremediation techniques and their applications to three major types of soil contaminants. The applicability of these methods was discussed from the viewpoint of contaminates transformation and utilization. The technical advancement in the selection and screening of degradation microorganisms, molecular biology methods for assessing microbiological ecology as well as novel bioaugmentation principles were detailed. The applications of bioremediation techniques in the treatment of gas stations, abandoned plants and straw mulching were described. The problems in the development of soil bioremediation techniques such as the assessment of soil remediation outcome, formation of high performance degrading microbial consortia were outlined, as well as the prospects of soil remediation techniques.

Key words: contaminated soil, soil bioremediation, straw

摘要：

人类生产和生活中对于污染物的不当处理会导致土壤污染，威胁生态安全、粮食安全和可持续发展。土壤生物修复利用微生物来降解土壤中的有机污染物、转化重金属污染物价态或者降低其生物可利用度而降低其危害。伴随现代生物技术的发展，土壤生物修复技术被日益广泛地应用于污染耕地和污染工业场地的修复。本文从污染物质的转化与利用角度，概述了土壤污染物的主要类型及其所适用的生物修复技术及其进展。重点综述了生物修复菌株的筛选、土壤微生态分析、生物修复过程强化三方面的最新进展，介绍了生物修复技术在加油站、废弃化工厂的生物修复及秸秆还田中的工程实施案例，分析了土壤生物修复技术应用中存在的问题，如土壤修复效果评估和降解菌剂性能强化等，讨论了土壤生物修复技术的研究方向和应用前景。

关键词: 污染土壤, 土壤生物修复, 废弃秸秆

CLC Number:

TQ033

FANG Xiaoyu, LU Diannan, LIU Zheng. Recent advancements and applications of soil bioremediation techniques[J]. Chemical Industry and Engineering Progress, 2023, 42(12): 6498-6506.

房晓宇, 卢滇楠, 刘铮. 污染土壤生物修复技术的进展与工程应用现状[J]. 化工进展, 2023, 42(12): 6498-6506.

Figures/Tables 8

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污染物类型	典型污染物	特点	生物修复技术
无机污染物	重金属、微量元素、放射性核素、石棉等	不可降解，可溶，生物利用度低	生物钝化、植物挥发、生物浸出
有机污染物	农药、酚类化合物、药物和个人护理品等	可降解，可溶，有生物毒性，需筛选生物	微生物降解、生物通风、根际降解
有机污染物	石油烃、多环芳烃、硝基苯类、有机卤化物等	可降解，不可溶	微生物降解、生物通风、生物堆
废弃生物质	农作物秸秆、林产废弃物、畜禽粪便等	可降解	微生物降解、生物堆、生物通风、根际降解

污染物类型	典型污染物	特点	生物修复技术
无机污染物	重金属、微量元素、放射性核素、石棉等	不可降解，可溶，生物利用度低	生物钝化、植物挥发、生物浸出
有机污染物	农药、酚类化合物、药物和个人护理品等	可降解，可溶，有生物毒性，需筛选生物	微生物降解、生物通风、根际降解
有机污染物	石油烃、多环芳烃、硝基苯类、有机卤化物等	可降解，不可溶	微生物降解、生物通风、生物堆
废弃生物质	农作物秸秆、林产废弃物、畜禽粪便等	可降解	微生物降解、生物堆、生物通风、根际降解

功能微生物	处理污染物	作用机制	参考文献
HB-4	镉	表面分泌EPS吸附钝化重金属	[13]
E. cloacae TU	镉	表面化学基团钝化重金属	[14]
硝基还原假单胞菌	镉	菌体表面生物矿化重金属	[15]
R. sphaeroids SC01	铬	将硫酸盐转化为硫化物，形成硫化铬等复合物钝化金属	[16]
Citrobacer	镉	分解2-磷酸甘油，形成CdHPO₄沉淀钝化金属	[17]
P. fluorescens Q2-87	锌、镉	合成金属硫蛋白在细胞内部钝化重金属	[18-19]
CRB5	铬	分泌铬酸还原酶降低重金属毒性	[19]
R. metallidurans CH34	硒	周质或细胞质还原亚硒酸盐并在胞内沉积	[20]

功能微生物	处理污染物	作用机制	参考文献
HB-4	镉	表面分泌EPS吸附钝化重金属	[13]
E. cloacae TU	镉	表面化学基团钝化重金属	[14]
硝基还原假单胞菌	镉	菌体表面生物矿化重金属	[15]
R. sphaeroids SC01	铬	将硫酸盐转化为硫化物，形成硫化铬等复合物钝化金属	[16]
Citrobacer	镉	分解2-磷酸甘油，形成CdHPO₄沉淀钝化金属	[17]
P. fluorescens Q2-87	锌、镉	合成金属硫蛋白在细胞内部钝化重金属	[18-19]
CRB5	铬	分泌铬酸还原酶降低重金属毒性	[19]
R. metallidurans CH34	硒	周质或细胞质还原亚硒酸盐并在胞内沉积	[20]

处理污染物	功能微生物	功能酶系	作用机制	参考文献
石油烃	假单胞菌、阴沟肠杆菌、银汉小克霉菌	单/双加氧酶、脱氢酶	单/双加氧酶和脱氢酶通过单末端氧化、双末端氧化、次末端氧化、ω-氧化和β-氧化降解链烷烃，不同加氧酶将环烷烃依次氧化为环醇、环酮，开环后再进入三羧酸循环	[26-27]
多环芳烃	假单胞菌、芽孢杆菌、白腐真菌	单/双加氧酶、细胞色素P450酶、木质素降解酶系	单/双加氧酶和细胞色素P450酶将多环芳烃氧化为二氢二醇化合物、木质素降解酶系将多环芳烃氧化为醌类物质	[28-29]
炸药（硝基苯类化合物）	假单胞菌、红平红球菌、黄孢原毛平革菌	硝基还原酶、加氧酶	硝基还原酶将苯环上硝基还原为氨基或对苯环加氢还原，直接脱去硝基，释放亚硝酸根离子	[30]
多氯联苯	产碱杆菌、无色杆菌、红球菌	联苯双加氧酶、脱卤酶	联苯双加氧酶氧化多氯联苯的苯环上的2,3位生成顺二氢二醇产物，脱卤酶在厌氧条件下对多氯联苯进行还原脱氯	[31]
有机氯农药	克雷白氏杆菌菌、芽孢杆菌、白腐真菌	脱卤酶、脱氯化氢酶、谷胱甘肽转移酶	脱卤酶结合有机氯农药催化C—Cl键水解，脱氯化氢酶从底物上脱去氯化氢并生成碳碳双键，谷胱甘肽转移酶催化有机氯农药与谷胱甘肽结合脱氯	[32]
有机磷农药	芽孢杆菌、黄杆菌曲霉、放线菌	有机磷水解酶、细胞色素P450酶、糖基转移酶	有机磷水解酶裂解P—O键、P—C键、P—S键，细胞色素P450酶对有机磷农药进行羟基化或N-脱烷基化反应，糖基转移酶将有机物与糖氨基酸或谷胱甘肽结合	[33-34]