小分子有机碳源对滴滴涕污染沉积物生物修复作用的基础研究

考察了辽河沉积物p,p'-DDT在无外加碳源和外加乳酸钠或丙酸钠情况下的缺氧生的降解行为，降解过程中体系的pH变化，并测定了p,p'-DDT的主要缺氧降解产物及其浓度变化，结果表现，p,p'-DDT的缺氧脱氯行为符合准一级反应动力学，无外加碳源，DDT的缺氧脱氯降解有近一个月的滞后期，降解速率为k（无碳源）＝0.0082d^-1，而外加碳源物质，大大缩短了DDT缺氧脱氯降解的滞后，降解速率分别为k(乳酸钠）＝0.0917d^-1,k(丙酸钠）＝0.1023d^-1，而且，p,p'-DDT的缺氧还原脱氯行为主要发生在体系中pH上升的阶段，p-p'-DDT缺氧生物降解的主要产物是p,p'-DDD，并有少量的p,p'-DDE产生；p,p'-DDD主要发生在体系中pH上升的阶段，p,p'-DDT缺氧生物降解的主要产物是p,p'-DDD，并有少量的p,p'-DDE产生，p,p'-DDD在后期有降解。     

污染水体的生物修复技术进展

随着全球范围内水体污染的加剧,近年来水体修复技术不断取得新的进展。根据国内外有关水体生物修复的文献,对水体生物修复的最新进展作了综述,并提出水体修复技术的研究与应用方向。     

高效石油降解菌的筛选及石油污染土壤生物修复特性的研究

从陕北石油污染土壤中富集分离、优选出7株菌株,并进一步研究了7株菌的生理生化特性.菌株鉴定结果表明,SY21为不动细菌属,SY22为奈瑟氏球菌属,SY23为邻单胞菌属、SY24为黄单胞菌属、SY42为动胶菌属、SY43为黄杆菌属、SY44为假单胞菌属.7株菌的降油试验结果表明,降解8d后,加菌试样的石油烃降解率均达到80%左右,7株菌的石油烃降解速率高于目前已有的报道.接种量越大,石油菌数量越多,石油烃降解率随接种量的增加而提高.采用SY43和SY23菌株对土壤进行生物修复,试验结果表明,投加高效菌株SY43和SY23均可在较短的时间内将土壤中的石油污染物去除,去除率可达88.4%和73.4%,其中菌株SY43的修复效果优于SY23.     

环境生物技术的研究现状及发展趋势

进入21世纪以来,减轻环境污染和遏制生态恶化趋势已成为人们关注的焦点.为了满足人们对清洁的土壤、空气和水环境的需要,当今世界各国无不大力发展环境生物技术.介绍了环境生物技术的形成发展,着重分析了环境生物技术的研究现状及其发展趋势.     

细菌还原U(VI)分子生物学机理的研究进展

铀（U）污染对生态环境和人类健康的潜在危害受到越来越多的关注.U（VI）还原细菌可将U（VI）还原至U（IV）,从而降低铀在水中的溶解性和移动性,达到污染修复的目的.目前发现的U（VI）还原细菌主要包括但不限于铁还原菌和硫酸盐还原菌.本文综述了细菌还原U（VI）的分子生物学机理,重点阐述了U（VI）还原细菌的胞外电子转移方式,包括希瓦氏菌的金属还原方式、土杆菌的孔蛋白介导方式和微生物纳米线方式.竞争性电子受体和共存离子对细菌还原U（VI）有重要影响.目前细菌还原U（VI）过程中胞外电子转移的机理仍需更多实证,土杆菌利用微生物纳米线和细胞色素协作调控电子转移的机制尚不明确.今后可将研究聚焦于细菌还原U（VI）机理的验证和完善,并开发和优化基于微生物还原的铀污染修复技术,进而提高铀污染生物修复效率和稳定性.     

氯嘧磺隆降解菌的筛选及对污染土壤的生物修复

采用富集培养方法从江苏某激素研究所污水处理池排污口污泥中分离得到1株氯嘧磺隆降解菌,经菌株形态学特征和26S rDNA序列分析,鉴定为胶红酵母菌（Rhodotorula mucilaginosa ）.经降解条件优化,菌株对含100mg/L氯嘧磺隆的无机盐培养基中氯嘧磺隆的最佳降解条件为：接种量2.5%,培养温度28℃,pH 6.0,培养5d后降解率为87.33%;在氯嘧磺隆初始浓度为10mg/kg（干土）的模拟污染土壤中,菌株最佳降解条件为：接种量2.5%,温度25℃,pH 6.0,土壤含水量30%,静息培养30d后降解率为90.74%.土壤修复实验结果表明,施加胶红酵母菌后减轻了氯嘧磺隆对小麦幼苗的药害,在氯嘧磺隆浓度为10mg/kg的土壤中投加降解菌后,小麦的出苗率、株高、根长及鲜重均明显高于未投加降解菌的对照组（P < 0.05）.     

Potential and Limitations of Microbial Reductive Dechlorination for Bioremediation Applications

Current knowledge and recent advances in the area of microbial reductive dechlorination of polychlorinated organic compounds are summarized. Factors which may limit the efficacy of the dechlorination process for the in situ bioremediation of contaminated soil and sediment systems are identified. Results of recent studies on the anaerobic biotransformation of soil-sorbed chlorinated ethenes and sediment-sorbed chlorinated benzenes are provided to illustrate how low contaminant bioavailability may control the rate and extent of dechlorination in subsurface systems, especially those with long-term contamination. Use of nonionic, polysorbate surfactants as the sole electron donors of a mixed, methanogenic culture supported the microbial sequential reductive dechlorination of either free or sediment-bound hexachlorobenzene (HCB) to primarily 1,3-dichlorobenzene, but did not enhance the bioavailability of sediment-bound HCB as compared to microcosms, which used glucose. Because current knowledge on the interactions of dechlorinating populations with other microbial populations in the presence of alternative terminal electron acceptors (e.g., nitrate, Fe³⁺ , Mn⁴⁺) is limited, such interactions and their effect on the dechlorination process in subsurface systems need to be further explored to improve our understanding of the reductive dechlorination process in complex environmental systems and lead to the development of more efficient in situ bioremediation technologies and strategies.     

The Potential Use of Chicken-Drop Micro-Organisms for Oil Spill Remediation

An examination of chicken-drop micro-organisms for oil spill remediation is presented in this work. The chicken droppings contained aerobic heterotrophs (1.2×10⁸ CFU g^–1), total fungi (3.4×10⁴ CFU g^–1) and crude oil (transniger pipeline crude, TNP) degrading bacteria (1.5×10⁶ CFU g^–1). The crude oil degraders were identified as species of Micrococcus, Bacillus, Pseudomonas, Enterobacter, Proteus, Klebsiella, Aspergillus, Rhizopus, and Penicillium. Pseudomonas aeruginosa CDB-06 and species of Bacillus CDB-08 and Penicillium CDF-10 degraded the crude oil at exceedingly high rates. Pseuedomonas aeruginosa CDB-06 degraded 65.5 percent of the crude oil after 16 days, while Bacillus sp. CDB-08, and Penicillium sp. CDF-10 degraded 65.3 percent, and 53.3 percent, respectively of the crude oil over the same period. The chicken droppings also had a pH 7.3, 18.5 percent moisture content, 2.3 percent total nitrogen, and 0.5 percent available phosphorus. Addition of oil polluted soil (10 percent (v/w) pollution level) with chicken droppings enhanced degradation of the crude oil in the soil. 68.2 percent of the crude oil was degraded in the soil amended with chicken droppings, whereas only 50.7 percent of the crude oil was degraded in the unamended soil after 16 days. The amendment raised the acidic reaction (pH 5.7) of the oil-polluted soil to alkaline (pH 7.2) within 16 days. Chicken droppings could, therefore, be used in an integrated oil pollution abatement program.     

春冬季节对堆肥修复多环芳烃（PAHs）污染土壤的影响

采用强制通风堆肥法修复多环芳烃PAHs(16种)污染土壤,比较了春季和冬季时堆肥法对PAHs污染土壤的修复效果.结果表明,冬季时受污染土壤中PAHs降解率高于春季,1号堆料[m(土壤)∶ m(猪粪)∶ m(锯末)=1∶ 1∶ 1(干重)]和2号堆料[m(土壤)∶ m(猪粪)∶ m(锯末)=1∶3∶1(干重)]的总PAHs降解率>70%,但1号堆料的总PAHs降解率(74.61%)高于2号堆料,低、中和高环三类PAHs的降解率分别为66.46%、 79.12%和75.88%;堆肥过程结束后,受污染土壤(干重)中大部分PAHs残留量均≤1000 μg/kg,但苯并[b]荧蒽在春季试验的残留量较高,它在1号和2号堆料的残留量分别为25000 μg/kg和20000 μg/kg,而它在冬季2个堆体的残留量均低于5000 μg/kg;堆肥修复污染土壤过程中总PAHs降解的一级反应动力学拟合结果表明,冬季拟合程度高于春季,R2>0.6,半衰期约为13 d.     

Arsenic removal from contaminated soil via biovolatilization by genetically engineered bacteria under laboratory conditions

In Rhodopseudomonas palustris, an arsM gene, encoding bacterial and archaeal homologues of the mammalian Cyt19 As(III) S-adenosylmethionine methytransferase, was regulated by arsenicals. An expression of arsM was introduced into strains for the methylation of arsenic. When arsM was expressed in Sphingomonas desiccabilis and Bacillus idriensis, it had 10 folds increase of methyled arsenic gas compared to wild type in aqueous system. In soil system, about 2.2%–4.5% of arsenic was removed by biovolatilization during 30 days. This study demonstrated that arsenic could be removed through volatilization from the contaminated soil by bacteria which have arsM gene expressed. These results showed that it is possible to use microorganisms expressing arsM as an inexpensive, efficient strategy for arsenic bioremediation from contaminated water and soil.