杀虫单降解菌的筛选分离与降解特性研究

从农药厂废水排放沟污泥中分离到一株对杀虫单有较强降解能力的菌株LY－4,经鉴定为巨大芽孢杆菌（Bacillus megaterium)。其生长的最适pH为7,最适温度为30℃。该菌对杀虫单有很强的耐受性,在杀虫单浓度ρ＝5000mg/L时,仍能较好地生长并发挥降解作用。当杀虫单初始浓度高于一定值时,一定量的菌剂对杀虫单的降解率随底物浓度的提高而降低,而绝对去除量则随底物浓度的提高而提高。与不加菌的对照相比,加入LY－4后,可使杀虫单浓度在很短的时间内降到很低的水平。图5表1参6     

青海湖几种主要湿地植物的种群分布格局及动态

应用种群生态空间分布的分析方法,研究了青海湖四种主要湿地植物：杉叶藻（Hippuris vulgaris)、槽杆荸荠（Eleocharis valleculosa)、华扁穗莞（Blysmus sinocompresus)、碱蓬（Suaeda glauca)的空间分布格局及其动态,研究表明：杉叶藻、槽杆荸荠、华扁穗莞三种群由侵入期、定期初期到种群发育盛期的过程中,其集群程度先增大后减小,总体呈扩散的趋势;碱蓬种群,从幼苗到繁殖期,集群程度增大,呈聚集的趋势,说明前三种植物的克隆繁殖方式于滨湖湿地生境具有更好的生态适应性,图2表3参11     

铝铁锡共聚物的合成及其特性研究

合成制备了铝铁锡共聚物,测定分析了其水解共聚合和熟化过程中的pH变化,并通过扫描电镜和混凝实验对共聚物的晶形貌像和絮凝作用进行了研究。结果表明：Sn^4 具有比Fe^3 ,Al^3 更强的水解活性,它有使共聚物的分子趋于均一的作用;铝铁锡共聚物的最佳配比为：NAl∶NFe∶NSn=5∶5∶3,最佳水解度B^*＝2．0,此共聚物具有比CPAFC更优良的絮凝性能。     

缺氧对贝类的胁迫效应及对其免疫系统的影响

基于缺氧对贝类养殖的危害,从贝类免疫系统角度总结了近年来围绕缺氧胁迫对其细胞免疫和体液免疫系统的相关因子影响的研究。从缺氧对与细胞免疫功能相关的血细胞总数(THC)、吞噬活性和细胞活性氧(ROS)含量、以及参与体液免疫的溶酶体酶、抗氧化物酶、抗氧化因子、酚氧化酶等多种免疫因子的影响,概括了缺氧对贝类免疫系统影响的一般规律。本文不仅能为衡量贝类所在水域的环境变化提供科学依据,还能为围绕贝类在缺氧胁迫下生理适应性机制的相关研究奠定基础。     

Biocompatible self-healing hydrogels based on boronic acid-functionalized polymer and laponite nanocomposite for water pollutant removal

Environmental Chemistry Letters - Global water pollution by organic dyes and metals may be solved by adsorption. In particular, hydrogel adsorbents display unique...     

绍兴茶园小流域的3种农药生态风险评价

虫螨腈、联苯菊酯和溴氰菊酯是茶叶生产中较为常见的3种杀虫剂,但其对茶园小流域内生态环境影响的相关研究较少。为评价其生态风险,选取我国浙江绍兴茶园小流域内主要溪流及湖库采集水体样品,采用气相色谱-质谱法对样品中3种农药进行残留检测;基于美国生态毒理数据库(ECOTOX)收集了3种农药对我国常见水生生物的毒性数据,利用BITSSD软件平台构建了物种敏感度分布(species sensitivity distribution, SSD)曲线,结合研究区实测数据开展3种农药对绍兴茶园小流域的生态风险评价研究。结果表明：(1)无脊椎动物和节肢动物对3种农药的敏感度高于鱼类,营养级越高其敏感度越低;(2)根据SSD模拟结果,为保护该流域95%的物种,联苯菊酯和溴氰菊酯浓度需<0.001μg·L^(-1),虫螨腈为0.4μg·L(-1),虫螨腈为0.4μg·L^(-1);(3)农药喷施后,虫螨腈、溴氰菊酯和联苯菊酯在茶园溪流中的残留浓度最高分别影响22%、50%和66%的物种,联苯菊酯是生态风险的主要贡献者,但在喷施1个月后,茶园流域水溪及河湖水环境中的农药残留基本均未检出。这说明3种农药施用对茶园小流域物种的影响较小,所带来的生态风险尚在可控范围之内。     

双酚A促进粪肠球菌中信息素调控质粒pCF10介导的耐药基因接合转移

粪肠球菌是一种在自然水体中广泛存在的革兰氏阳性细菌。信息素调控质粒介导的接合转移是造成粪肠球菌耐药基因快速扩散的重要方式。双酚A是一种内分泌干扰物,因其在工业中大量应用造成其在水环境中的广泛分布。本文以信息素调控质粒中比较有代表性的pCF10质粒作为研究对象,研究了双酚A对粪肠球菌中耐药基因接合转移的影响,证实了双酚A可以促进pCF10质粒介导的耐药基因接合转移,且这一结果同双酚A作用浓度和作用时间相关。双酚A影响耐药基因的扩散,是通过促进编码正调控信息素的ccfA基因表达实现的。本文旨在深入理解双酚A影响抗生素抗性基因扩散的环境行为,为耐药基因控制及双酚A环境效应的评估提供理论支持。     

Sulfur cycle as an electron mediator between carbon and nitrate in a constructed wetland microcosm

• Fe(III) accepted the most electrons from organics, followed by NO₃^‒, SO₄^2‒, and O₂. • The electrons accepted by SO₄^2‒ could be stored in the solid AVS, FeS₂-S, and S⁰. • The autotrophic denitrification driven by solid S had two-phase characteristics. • A conceptual model involving electron acceptance, storage, and donation was built. • S cycle transferred electrons between organics and NO₃^‒ with an efficiency of 15%. A constructed wetland microcosm was employed to investigate the sulfur cycle-mediated electron transfer between carbon and nitrate. Sulfate accepted electrons from organics at the average rate of 0.84 mol/(m³·d) through sulfate reduction, which accounted for 20.0% of the electron input rate. The remainder of the electrons derived from organics were accepted by dissolved oxygen (2.6%), nitrate (26.8%), and iron(III) (39.9%). The sulfide produced from sulfate reduction was transformed into acid-volatile sulfide, pyrite, and elemental sulfur, which were deposited in the substratum, storing electrons in the microcosm at the average rate of 0.52 mol/(m³·d). In the presence of nitrate, the acid-volatile and elemental sulfur were oxidized to sulfate, donating electrons at the average rate of 0.14 mol/(m³·d) and driving autotrophic denitrification at the average rate of 0.30 g N/(m³·d). The overall electron transfer efficiency of the sulfur cycle for autotrophic denitrification was 15.3%. A mass balance assessment indicated that approximately 50% of the input sulfur was discharged from the microcosm, and the remainder was removed through deposition (49%) and plant uptake (1%). Dominant sulfate-reducing (i.e., Desulfovirga, Desulforhopalus, Desulfatitalea, and Desulfatirhabdium) and sulfur-oxidizing bacteria (i.e., Thiohalobacter, Thiobacillus, Sulfuritalea, and Sulfurisoma), which jointly fulfilled a sustainable sulfur cycle, were identified. These results improved understanding of electron transfers among carbon, nitrogen, and sulfur cycles in constructed wetlands, and are of engineering significance.     

Locally enhanced electric field treatment (LEEFT) for water disinfection

• Nanowire-assisted LEEFT is applied for water disinfection with low voltages. • LEEFT inactivates bacteria by disrupting cell membrane through electroporation. • Multiple electrodes and device configurations have been developed for LEEFT. • The LEEFT is low-cost, highly efficient, and produces no DBPs. • The LEEFT can potentially be applicable for water disinfection at all scales. Water disinfection is a critical step in water and wastewater treatment. The most widely used chlorination suffers from the formation of carcinogenic disinfection by-products (DBPs) while alternative methods (e.g., UV, O₃, and membrane filtration) are limited by microbial regrowth, no residual disinfectant, and high operation cost. Here, a nanowire-enabled disinfection method, locally enhanced electric field treatment (LEEFT), is introduced with advantages of no chemical addition, no DBP formation, low energy consumption, and efficient microbial inactivation. Attributed to the lightning rod effect, the electric field near the tip area of the nanowires on the electrode is significantly enhanced to inactivate microbes, even though a small external voltage (usually<5 V) is applied. In this review, after emphasizing the significance of water disinfection, the theory of the LEEFT is explained. Subsequently, the recent development of the LEEFT technology on electrode materials and device configurations are summarized. The disinfection performance is analyzed, with respect to the operating parameters, universality against different microorganisms, electrode durability, and energy consumption. The studies on the inactivation mechanisms during the LEEFT are also reviewed. Lastly, the challenges and future research of LEEFT disinfection are discussed.