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Project 5: Phytoremediation to Degrade Airborne PCB Congeners from Soil and

项目 5：通过植物修复来降解土壤和土壤中空气中的多氯联苯同系物

基本信息

批准号：
7599047
负责人：
Jerald Lee Schnoor
金额：
$ 20.34万
依托单位：
UNIVERSITY OF IOWA
依托单位国家：
美国
项目类别：
财政年份：
资助国家：
美国
起止时间：
至
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/7599047
关键词：
Aerobic Age Agriculture Air Area Bacteria Bioreactors Bioremediations Biota Breathing CAT development factor Chemicals Complex Condition Cytochrome P450 Decontamination Depth Detection Drug Metabolic Detoxication Ecosystem Ensure Environment Environmental Hazards Enzymes Evaluation Exposure to Food Chain Gases Genes Glucuronosyltransferase Glutathione S-Transferase Goals Hand Health Horseradish Peroxidase Human Hydroponics Inhalation Toxicology Intervention Investigation Irrigation Kinetics LIF gene Label Laboratories Lead Left Light Link Literature Liver Mammals Metabolic Activation Metabolic Biotransformation Metabolic Pathway Molecular Biology Mono-S Mutagenicity Tests Organism Oxidation-Reduction Oxygenases Parents Pathway interactions Pesticides Pheretima sieboldi Plant Extracts Plant Leaves Plant Model Plant Roots Plants Play Polychlorinated Biphenyls Polymerase Chain Reaction Populus Process Quinones Radio Reactive Oxygen Species Refuse Disposal Research Residual state Reverse Transcriptase Polymerase Chain Reaction Role Route Site Soil Solutions Source Staging Surface Sustainable Development System Testing Time Tissues Toxic effect Toxicity Tests Vascular Plant Volatilization Water Work Xenobiotic Metabolism Xenobiotics base benzoquinone concept cyclophosphamide/doxorubicin/fluorouracil protocol dehalogenation engineering design exposed human population falls improved innovation insight microbial microbial community mineralization planetary Atmosphere pollutant research study soil sampling stable isotope tool uptake volatile organic compound wasting

项目摘要

This proposal investigates the working hypothesis that phytoremediation can be used to degrade airborne PCB congeners from soil and groundwater sources. Plants stimulate the microbial community in the root zone and contribute to microbial degradation of RGBs (rhizodegradation). Higher-chlorinated PCBs are dechlorinated under reducing (anaerobic) conditions; resulting lesser-chlorinated congeners can undergo oxidative mineralization under aerobic conditions. Alternating reducing and oxidizing conditions in the rhizosphere makes the plant-soil system a natural two-stage bioreactor for initial PCB transformation. Lesser-chlorinated PCBs can also be taken-up and transformed inside plan tissues. The specific aims of the project are (1) to test the hypothesis that poplar plants can take up and detoxify lesser-chlorinated PCB congeners by identifying metabolic pathways of PCBs and genes that encode for catabolic enzymes, (2) to test the hypothesis that bacteria in the rhizosphere can reductively dechlorinate higher-chlorinated PCBs and can mineralize resulting lesser-chlorinated congeners under oxidizing conditions; this will be tested using anaerobic and aerobic batch bioreactors with rhizosphere soils contaminated with PCBs, (3) to test the hypothesis that phytoremediation will allow for significant reductions in the airborne transfer of PCBs from waste disposal sites and mitigate exposure to humans and ecosystems; this innovative cleaning up strategy (based on hypotheses 1 and 2) will be tested at the bench scale and by pot-studies in the greenhouse, (4) to test the hypothesis that residues of PCBs in plant tissues are non-toxic or of greatly reduced toxicity to biota by conducting an eco-toxicological evaluation of the phytoremediation process using a battery of toxicity tests, and (5) to test the hypothesis that higher plants play a significant role in the environmental cycling of airborne PCBs by field analyses of PCB accumulation on vegetation. The significance of this project is that it provides an intervention and remedy for contaminated waste sites that will help to break the continuous cycling of PCBs in the atmosphere and the subsequent exposure to humans.

这项提案调查了植物修复可用于退化的工作假说。空气中来自土壤和地下水来源的多氯联苯同系物。植物刺激微生物群落在根区，并有助于微生物降解RGB(根部降解)。高氯化多氯联苯在还原(厌氧)条件下脱氯；导致氯化程度较低的同系物可以在好氧条件下进行氧化矿化。氧化还原交替进行根际条件使植物-土壤系统成为初始印刷电路板的天然两级生物反应器转型。氯化程度较低的多氯联苯也可以被吸收，并在计划组织内转化。这个该项目的具体目标是(1)检验杨树植物可以吸收和解毒的假设通过确定多氯联苯和编码多氯联苯的基因的代谢途径，减少氯化多氯联苯的同系物对于分解代谢酶，(2)检验根际细菌可以还原的假设脱氯高氯化多氯联苯，并可矿化产生的低氯化同系物氧化条件；这将使用具有根际的厌氧和好氧间歇生物反应器进行测试被多氯联苯污染的土壤，(3)测试植物修复将允许显著减少废物处置场的多氯联苯空中转移并减少对人类的暴露和生态系统；这一创新的清理战略(基于假设1和2)将在试验台规模和温室盆栽研究，(4)检验多氯联苯残留假设在植物组织中对生物群无毒或极大地降低毒性，通过进行生态毒理学使用一组毒性测试对植物修复过程进行评估，以及(5)测试高等植物在空气中多氯联苯的环境循环中起重要作用的假说多氯联苯在植被上积累的田间分析。这个项目的意义在于它提供了一个对受污染的废物场地进行干预和补救，有助于打破环境污染的持续循环大气中的多氯联苯和随后对人类的暴露。