多环芳烃污染对桑园土壤微生物结构及种群多样性的影响

采用磷脂脂肪酸(PLFAs)分析法和变性梯度凝胶电泳(DGGE)考察了受多环芳烃(PAHs)污染的桑园3个区域的土壤微生物群落结构及种群多样性的变化.PLFAs分析结果表明,区域2中微生物PLFA总量最高,主要为细菌和真菌;聚类分析揭示,土壤中微生物的PLFAs主要分为3大类群;冗余分析表明,土壤PAHs污染程度对土壤微生物群落结构有一定的影响.DGGE指纹图谱分析结果显示,在PAHs污染较高区域,其电泳条带较多,且3个区域中Shannon指数和Simpson优势度差异达显著水平,区域2种群优势度较高;主成分分析表明,不同区域微生物的种群结构存在显著性差异.     

反硝化微生物燃料电池的基础研究

在启动双室型反硝化微生物燃料电池的基础上,研究了阴极溶解氧及外电阻对其产电性能和污染物去除效果的影响.结果表明,以乙酸钠为阳极电子供体,硝酸钠为阴极电子受体,在25℃的环境温度下,采用先间歇后连续培养的方式,42d内成功启动了反硝化微生物燃料电池.在阴极进水含氧的情况下,氧和硝酸盐可共同用作阴极电子受体.在较小电流密度区域内,氧是阴极的主要电子受体,相应的最大功率密度为26.0W/m3NC;电流密度增加到一定程度后,硝酸盐逐步变为阴极的主要电子受体,相应的最大功率密度为20.9W/m3NC.外阻变化对COD去除及反硝化程度影响较小,阳极COD去除负荷维持在1.2kg/(m3NC·d)左右,出水NO-2-N保持在0.05mg/L以下;但外阻减小有利于提高阴极脱氮效果,外阻为5 Ω时NO-3-N去除负荷达0.111kg/(m3NC·d).     

污泥为燃料的微生物燃料电池运行特性研究

实验采用单室无膜悬浮阴极微生物燃料电池(MFC),考察了运行特性对污泥为燃料的MFC(SMFC)的影响.研究表明,相对于未搅拌情况,搅拌时SMFC最大输出功率由45.94mW/m2分别增加到124.03mW/m2(1300r/min)和136.5mW/m2(2600 r/min),主要是由于搅拌有利于改善SMFC内物质的传递. 温度对SMFC的产电特性影响较明显,但在一定区间内(如20~25℃;30~40℃;45~50℃)变化不明显,说明产电微生物有一定的温度适应范围,这也可能是在不同温度下产电微生物不同导致.相对于采用未经处理的剩余污泥为燃料,微波处理后的污泥和微波处理过滤后的上清液做燃料时SMFC输出功率迅速增加,这主要是由于污泥中的微生物竞争作用引起.阴极面积的增加有利于降低阴极电势,降低SMFC内阻,从而促进功率密度的增加.     

Oxidative and genotoxic effects of bisphenol A on primary gill cell culture of Lake Van Fish (Alburnus tarichi Güldenstädt, 1814)

Lake Van is the largest lake in Turkey. The lake limits lifespan due to its high pH and brackish water. For this reason, only a single species of fish (Van Fish) is living in the lake that has been adapted to these conditions. In the present study, we investigated the total oxidant status (TOS), total antioxidant status (TAS), malondialdehyde (MDA) level and DNA damage effect of bisphenol A (BPA) (10^?7, 10^?6 and 10^?5?M) on primary gill cell culture of Van Fish for 24 and 48?h of incubation periods. TAS levels were not changed when compared to those of the control group, but TOS levels were decreased in both 24 and 48?h. The MDA level increased only at the highest concentration (10^?5) at the end of 12 and 24?h (p?.05). DNA damage increased only at the 10^?5?M concentration after 48?h. At the end of the experiment, BPA exposure caused lipid peroxidation and genotoxic effect. These results indicate that high levels of BPA exposure induced oxidative stress and DNA damage by time- and concentration-dependent fashion in the gill cell culture of Van Fish. Gill cell culture is a useful model for the rapid identification of the harmful effects of chemicals in the aquatic environment.     

Epigenetic effect of long-term bisphenol A exposure on human breast adenocarcinoma cells

In this research, epigenetic effects of bisphenol A (BPA) on human breast cancer MCF-7 cells were analyzed. Genome-wide DNA methylation and gene expression were analyzed in MCF-7 cells exposed to BPA (10^?5 and 10^?6 mol/L for 5 weeks). No significant changes in the global level of 5-methyl-2′-deoxycytidine and 5-hydroxymethyl-2′-deoxycytidine were observed. DNA methylation profiling analysis indicated that BPA exposure resulted in the hypermethylation of FOXK2, LKB1, LMX1A and CUGBP2 and the hypomethylation of PTPRN2, TRIM27, BCAS3 and ZNF423. Decreased expression of apoptosis genes (P38 and BCL2L1) and increased expression of chemokine (Cxcl2 and ccl20) were detected. Changes of these genes were speculated to affect the ERα-related cell growth as well as cell apoptosis.     

Recent advances in three typical configurations and applications of bioelectrochemical systems北大核心CSCD

As the world's freshwater resources and available energy are alarmingly decreasing, the bioelectrochemical system (BES) is a cutting-edge technology for the resolution of the resource and energy issue. Researchers have paid much attention to t he application of t he BES configuration. Based on t he brief i ntroduction of m icrobial f uel cell a nd m icrobial electrolytic cell structure, principles, and domestic and foreign research, the BES and its influencing factors are introduced, specifically including: microbial activity, electrode materials, and configuration. Three important aspects (i.e., the electrode chamber, the reaction chamber, and micro-sensor) are summarized, and the advantages and disadvantages of single-electrode and multi-electrode chambers are compared, based on the microbial desalination cell. Microbial electrolysis desalination cell: Microbial electrolysis desalination and chemical-production cell have been discussed to introduce increasing reaction chamber configuration; this review focuses on the research of BES monitoring with regards to biochemical oxygen demand. The potential applications of the research progress are explored. The results show that the configuration of multi-chamber microbial fuel cell is complex and its efficiency is low, while the single chamber configuration is advantageous. The reaction chamber added is mainly aimed at desalination, and the study of the desalination pool still needs to be focused on optimizing the cation exchange membrane to maintain the anode pH balance and reduce the air cathode dissolved oxygen. Microbial electrode sensor can be applied in more areas, and its sensitivity and long-term stability need to be further improved. However, there is relatively less research on the abundance and activity of electricigen communities; the configurations and scopes of application of BES are still the research priority. © 2018 Science Press. All rights reserved.     

Efficient photoelectrochemical oxidation of rhodamine B on metal electrodes without photocatalyst or supporting electrolyte

We designed photoelectrochemical cells to achieve efficient oxidation of rhodamine B (RhB) without the need for photocatalyst or supporting electrolyte. RhB, the metal anode/cathode, and O₂ formed an energy-relay structure, enabling the efficient formation of O ₂ ^– species under ultraviolet illumination. In a single-compartment cell (S cell) containing a titanium (Ti) anode, Ti cathode, and 10 mg·mL^–1 RhB in water, the zero-order rate constant of the photoelectrochemical oxidation (k_PEC) of RhB was 0.049 mg·L^–1·min^–1, while those of the photochemical and electrochemical oxidations of RhB were nearly zero. k_PEC remained almost the same when 0.5 mol·L^–1 Na₂SO₄ was included in the reactive solution, regardless of the increase in the photocurrent of the S cell. The k_PEC of the illuminated anode compartment in the two-compartment cell, including a Ti anode, Ti cathode, and 10 mg·mL^–1 RhB in water, was higher than that of the S cell. These results support a simple, eco-friendly, and energysaving method to realize the efficient degradation of RhB.

Open image in new window

     

潮汐-复合流人工湿地系统优化及对抗生素抗性基因的去除效果

抗生素抗性基因随废水排放传播扩散,对环境生物和民众健康构成严重威胁.针对废水中抗性基因的深度去除值得重点关注.在前期研究中发现潮汐流人工湿地能有效去除废水中多种氮素.本研究通过增加隔板和种植植物等方式进一步优化潮汐流人工湿地系统,并考察了工艺优化对抗性基因去除和脱氮功能微生物的影响机制.结果表明,同时增加隔板和种植植物后的潮汐-复合流人工湿地系统能有效提高抗性基因的去除效率,在增加隔板和种植植物组对7类21种抗性基因去除率最高达到83.82%~100.0%,显著高于单一增加隔板或种植植物组.从湿地基质和植物中的抗性基因绝对丰度对比可以看出,增加隔板能促进湿地基质中抗性基因量积累,而植物对抗性基因吸附也是其去除途径之一.同时,结合氮循环功能基因测序结果显示,湿地系统优化能提高基质中硝化和反硝化功能微生物物种多样性和丰富度,这与优化系统对废水中硝化量、反硝化量和总氮的去除率相对更高结果一致.     

溶解氧对低碳源城市污水处理系统脱氮性能与微生物群落的影响

为了阐明溶解氧对低碳源城市污水处理系统脱氮除磷性能的影响,研究了供氧区溶解氧浓度分别为2~3、1~2和低于1mg·L^-1的运行条件下微生物应对低碳源环境生长与代谢特性的差异.随着供氧区溶解氧浓度的降低利用外碳源和内碳源脱氮量分别升高了20.23%和80.54%,内碳源的除磷利用效率升高了13.89%,进而使低碳源城市污水的脱氮除磷效果得到强化.高通量测序和RDA分析结果表明,降低供氧区溶解氧浓度驱动微生物群落结构的调整,促使脱氮除磷功能微生物（如：Dechloromonas菌属）的丰度显著增加.基于PICRUSt预测分析可知,在低溶解氧浓度的运行环境中微生物与基质利用、能量合成和代谢调控功能相关的基因活性更高,保证了功能微生物在低碳源条件下稳定生长并维持较高的脱氮除磷效率.本研究为提升低碳源城市污水处理系统中脱氮除磷功能微生物的生长提供理论依据.     

个人乘用车用可替代燃料与我国未来的选择

个人乘用车排放量占道路交通运输二氧化碳(CO2)排放量的三分之一。因此,逐步实现其燃料由传统石化燃料汽柴油向新能源转变是交通运输行业低碳减排和绿色发展的重要抓手之一。本文对当前可供个人乘用车使用的4大类新能源即生物燃油、燃料乙醇、氢和电的属性,特别是其CO2减排效果和使用成本进行了分析和对比,并对新能源加注(充电)设施在欧盟和美国的布局战略和实施成果进行了介绍。结合欧美的实践和中国的实际,本文提出了未来个人乘用车用可替代燃油布局的建设,建议我国直接从传统石化汽油跨越至氢和/或电,并将其作为未来个人乘用车的燃料。