Azo dyes degradation by microorganisms – An efficient and sustainable approach

Synthetic aromatic compounds consisting of various functional groups are known as dyes. These colored compounds are often discharged in effluents, and they are very dangerous to aquatic life. Basically, the dye industry started by using natural plant and insect sources, and then suddenly turned into artificial manufacturing. Natural equilibrium of our environment gets changed by the reduction in photosynthetic activity due to the dyes. In China 900,000 tons of all kinds of dyes are usually produced, which are used in many industries like food, textile, food, paper and leather. Untreated wastewater contaminates aquatic bodies by causing eutrophication, change in water color, oxygen depletion which affect aquatic organisms to a great extent. Dye wastewater is now the key environmental pollution form. In recent eras an extensive study line has been developed to explore the dye decolorization and biodegradation under both aerobic as well as anaerobic conditions. In this review, the chemistry, toxicity and microbial biodegradation/decolorization are presented. Some recent studies along with the new techniques and methodologies of remediating the dye pollution are also discussed to provide the bases of their handling. Overall, efficient and high biodegradation potential make microbes an impending foundation for green chemistry to eradicate toxic dyes from industrial wastewater.     

Gas chromatographic detection of anaerobic bacteria from environment.

A rapid method of detection of anaerobic bacteria in environment using gas chromatograph is described. Metabolically produced volatile and non-volatile fatty acid by the anaerobic bacteria are detected gas-chromatographically. Using this technique anaerobic bacteria are detected from soil, air, laboratory and operation theatre environments and drinking water samples. In the polluted drinking water apart from drug resistant E. coli, Clostridium difficile is isolated indicating faecal pollution of drinking water from cases of antibiotic associated pseudomembraneous colitis. The method has great significance in detection of anaerobic bacteria in environment especially in the management of war wounds.     

大气污染对大鼠呼吸道微生态的影响研究

探讨了大气污染引起呼吸道症状和机体健康效应的作用机理,为防治大气污染及其对机体的损害提供理论依据。采用模拟现实大气污染的方法,分高、中、低浓度用Wistar大鼠制备大气污染动物模型,对大鼠口咽部菌群进行定性、定量、定位检测,动态研究。大气污染大鼠模型口咽部微生态发生改变。与污染前比,肺炎克雷伯杆菌等致病菌检出率明显增加(P<0.05),厌氧菌含量明显减少(P<0.05),并且随着染毒时间厌氧菌和细菌总量都呈明显下降趋势(P<0.05);口咽部菌群含量在一定范围内波动,没有随着染毒浓度改变而呈明显改变。大气污染对呼吸道正常菌群有毒害作用,对微环境有破坏作用,导致微环境改变,正常菌群含量减少,致病菌定植,是呼吸道疾病发病率升高的重要因素之一。     

石油中长链烷烃微生物降解及分子机制研究进展

中长链烷烃是石油烃中的重要组成部分,由于其疏水性强、黏度大、化学活性低、难降解,是地下原油黏度大、石油采收率低、泄漏后长期污染生态环境的重要原因,因此成为提高石油采收率和石油污染环境治理中的重要降解目标。微生物降解中长链烷烃作为一种新型高效的绿色技术日益受到重视。本文总结了微生物降解中长链烷烃的间期适应与转运过程,与转运过程相关的膜蛋白,微生物好氧与厌氧降解的代谢途径,以及好氧降解过程中的基因调控机制,并对微生物降解中长链烷烃的研究方向提出了展望,以期为后续的相关研究工作提供参考。     

Flow cytometric analysis of bacterial respiratory and enzymatic activity in the natural aquatic environment

The respiratory and enzymatic activity of bacteria in polluted and unpolluted river water was investigated by flow cytometry. Double staining with 6CFDA (6-carboxy fluorescein diacetate) and PI (propidium iodide) was used to examine bacterial esterase activity. CTC (5-cyano-2,3-ditolyl tetrazolium chloride) was employed as the indicator of bacterial respiration. The ratios of colony-forming units to total bacterial number were less than 2%, except highly polluted sites. The number of respiring bacteria determined by flow cytometry amounted to 10–15% of the total bacterial number at both unpolluted and polluted sampling stations, while it was 30% at the highly polluted station. Almost 50% of total bacteria demonstrated esterase activity in the unpolluted areas, whereas 70–90% of total bacteria retained this enzymatic activity in the polluted areas. Thus, many of the non-culturable bacteria in the natural aquatic environment have enzymatic activity regardless of the pollution level, and 6CFDA was more superior in the sensitivity for the evaluation of physiological activity of bacteria in the natural environment. The ratio of bacteria with esterase activity increased in direct proportion to the pollution level of river water and suggested that this ratio would be a useful indicator in evaluating the pollution levels in an aquatic environment.     

细菌产黄素类化合物介导的电子传递及对环境污染物的厌氧生物转化研究进展

氧化还原介体能够加速有毒环境污染物的厌氧生物转化。黄素类化合物是一类微生物自身合成分泌的氧化还原介体,其应用可有效地避免外源性介体带来的成本较高及造成二次污染的问题,因此引起了广泛的关注。研究表明,细菌合成的微量黄素类化合物不仅能够作为黄素蛋白的辅酶因子参与偶氮染料、铬酸盐和硝基芳烃等污染物的厌氧生物转化,并且还可以分泌到胞外将电子传递给固态电子受体如含铁矿物和电极等来参与生物修复过程。根据黄素类化合物的功能,本文综述了黄素类化合物的合成与分泌,及其介导的胞内外电子传递和对环境污染物厌氧生物转化的影响,以促进其在实际环境污染物处理中的应用。     

Pollution and parasitism in the aquatic environment

The studies of aquatic parasitology and of aquatic pollution effects both have experienced increasing interest during the recent fifteen years. Although considerable effort has been spent on studying the role of pollution as a cause or a trigger of anomalies, tumors and infectious diseases in aquatic organisms, the interactions between pollution and parasitism have been largely neglected by scientists.Pollution and other man-made alterations of the aquatic environment may affect a parasite community directly by acting on free-living parasite stages or on ectoparasites, or indirectly by acting on the intermediate or the definitive host population. Certain pollution conditions favour the propagation of parasites by excluding their natural predators, by reducing the resistance of their hosts or by providing improved living conditions for their intermediate hosts. In a number of experimental studies parasitized organisms have been shown to suffer from greater mortalities when exposed to high temperature, to low oxygen stress or to high levels of dissolved heavy metal salts, when compared to nonparasitized control animals. Unfortunately, field studies on synergistic effects of pollution and parasites on host populations are still scarce and seldom offer more than qualitative observations and theoretical evaluations.The complexity of the pollution-parasite-host system complicates the use of parasites as indicators of pollution effects. However, experience from aquaculture practice teaches that a number of (mostly ecto-) parasites are more susceptible to certain chemicals (used as parasiticides) and to artificial alterations of salinity, temperature or oxygen content of the water than their hosts. Accordingly, it is postulated that during future studies the composition of ectoparasitic faunas of aquatic organisms might turn out to become a useful and quickly reacting indicator for effects of certain pollution conditions, such as anthropogene oxygen deficiency, salt introduction from salines into freshwater ecosystems, and introduction of certain heavy metal salts.     

水生生态系统中金属依赖型甲烷厌氧氧化过程的研究进展

甲烷是一种比CO_2更活跃的温室气体,微生物驱动的甲烷厌氧氧化(anaerobicoxidationof methane,AOM)过程对于降低全球甲烷的排放有着重要意义。参与AOM反应的最终电子受体主要分为三类,即硫酸盐、亚硝酸盐/硝酸盐以及以Fe(III)、Mn(IV)等为代表的金属离子。可溶性金属物质和不溶性金属矿物都可以被用作AOM的电子受体,这大大提高了参与金属依赖型甲烷厌氧氧化(metal-dependent anaerobic oxidation of methane,Metal-AOM)微生物的生态价值。目前研究聚焦在功能菌群、生态分布等方面。部分甲烷厌氧氧化古菌(anaerobic methanotrophic archaea,ANME)具有直接或间接参与Metal-AOM过程的能力。但由于功能菌群纯化富集和分离具有一定难度,有关其生理生化和生态学等特征的研究受到限制。同时,随着Metal-AOM被发现存在于不同水生生境中,其在污染治理领域的应用也被广泛讨论,但是河口生境尚缺乏深入研究。本文从Metal-AOM的发现入手,阐述了参与该过程的主要微生物及其在水域环境下的生态分布,并介绍了Metal-AOM的反应机制和在实际应用中的机遇与挑战。最后,根据现有研究结果,提出对功能菌群、机制及环保应用的研究展望,包括微生物分离纯化和影响因素、菌群代谢活性和作用机制的解析以及新型生产工艺的设计和发展应用,以期为今后的环境污染治理和工业应用提供借鉴意义。     

水环境中药物和个人护理品(PPCPs)的污染现状及对藻类的毒性研究进展

药物和个人护理品(PPCPs)因持续排放到水环境且对水生态环境和人类健康造成潜在威胁而受到广泛关注.藻类作为水体重要的初级生产者,对水体的生态平衡和稳定起着重要的作用.本文围绕地表水PPCPs污染,介绍了不同国家和地区地表水体中PPCPs的浓度分布和污染特征,并从毒性效应、生物累积及潜在的生态风险等方面,综述了PPCPs对藻类的污染生态学研究进展,阐述PPCPs对藻类的毒性效应及机制,PPCPs在藻类中的生物累积,以及地表水体PPCPs的生态风险,为地表水体PPCPs的相关标准制定和修订,以及水体生态环境健康风险评价提供参考.     

A Novel Bio-Controller for Localizing Pollution Sources in a Medium Peclet Environment

##正## Nature inspired solutions enable biological systems to adapt and accomplish their tasks in very noisy and uncertain environments.Taking inspiration from nature,a novel bacteria controller capable of finding the source of pollution in an underwatermedium turbulent environment is presented in this paper.Experiments prove that the controller is capable of performing pollutionsource exploration,pollution plume transverse and source declaration in a medium Peclet environment without distinctivelyseparating these three components as most researchers did.The results obtained from these experiments are considered asa step towards the deployment of robotic fish in a highly turbulent marine environment.Finally,a brief conclusion and futureextension are presented.     

湖泊氮素氧化及脱氮过程研究进展

自然界中氮的生物地球化学循环主要由微生物驱动,由固氮作用、硝化作用、反硝化作用和氨化作用来完成。过去数十年间,随着异养硝化、厌氧氨氧化和古菌氨氧化作用的发现,人们对环境中氮素循环认识逐步深入,提出了多种脱氮途径新假说。对湖泊生态系统中氮素的输入、输出及其在水体、沉积物和水土界面的迁移转化过程进行了概括,对湖泊生态系统中反硝化和厌氧氨氧化脱氮机理及脱氮效率的最新研究进展进行了探讨,并对以后的氮素循环研究进行了展望。     

Degradation of Microbicides under Different Environmental Conditions

To determine the biodegradability of some widely used microbicides, these products were dissolved in a mineral solution and synthetic sewage and their breakdown was followed under aerobic and anaerobic conditions. The results indicated that most biocides will not raise pollution problems provided they are discharged into domestic sewage and subsequently treated by aerobic water purification systems. However, all but a few of the biocides tested failed to be degraded in tests simulating conditions prevailing in oligotrophic aquatic systems or in anaerobic ecosystems.     

微生物厌氧呼吸与有机污染水体沉积物修复

水体沉积物有机污染是当前全球关注的重要环境问题。微生物具有呼吸和代谢多样性,能以多种污染物作为厌氧呼吸的电子供体或受体,与周围环境中的生物和非生物因素组成代谢网络耦合有机污染物降解转化,是有机污染水体沉积物修复的重要驱动者。本文重点综述了微生物厌氧呼吸、电子传递网络及其对有机污染水体沉积物的修复机制研究进展,并对有机污染水体沉积物微生物修复理论和技术研究的问题和挑战进行了探讨。     

Microbial transformation of chlorinated benzoates

Chlorinated benzoates enter the environment through their use as herbicides or as metabolites of other halogenated compounds. Ample evidence is available indicating biodegradation of chlorinated benzoates to CO₂ and chloride in the environment under aerobic as well as anaerobic conditions. Under aerobic conditions, lower chlorinated benzoates can serve as sole electron and carbon sources supporting growth of a large list of taxonomically diverse bacterial strains. These bacteria utilize a variety of pathways ranging from those involving an initial degradative attack by dioxygenases to those initiated by hydrolytic dehalogenases. In addition to monochlorinated benzoates, several bacterial strains have been isolated that can grow on dichloro-, and trichloro- isomers of chlorobenzoates. Some aerobic bacteria are capable of cometabolizing chlorinated benzoates with simple primary substrates such as benzoate. Under anaerobic conditions, chlorinated benzoates are subject to reductive dechlorination when suitable electron-donating substrates are available. Several halorespiring bacteria are known which can use chlorobenzoates as electron acceptors to support growth. For example, Desulfomonile tiedjei catalyzes the reductive dechlorination of 3-chlorobenzoate to benzoate. The benzoate skeleton is mineralized by other microorganisms in the anaerobic environment. Various dichloro- and trichlorobenzoates are also known to be dechlorinated in anaerobic sediments.     

Reduction of azo dyes by anaerobic bacteria: microbiological and biochemical aspects

Azo dyes are recalcitrant pollutants commonly found in several industrial wastewaters, such as those originated from textile factories, which generally persist to biological transformation. Discharge of these effluents in open water bodies not only represents an aesthetic problem, but also may limit photosynthesis in aquatic plants. Furthermore, many azo dyes and products derived from their partial transformation in the environment (e.g. aromatic amines) may be toxic or carcinogenic. Biological wastewater treatment processes have emerged as promising technologies to remove azo dyes from industrial effluents and intensive research has been conducted during the last two decades in order to elucidate the mechanisms involved in the reductive decolourisation of azo dyes. The present work describes the main biochemical and microbiological aspects involved in the reductive decolourisation of azo dyes by anaerobic bacteria.     

Fate of linear alkylbenzene sulfonates in the environment: A review

The fate and risk of linear alkylbenzene sulfonates (LAS) in various compartments of the environment have been reviewed. Under aerobic conditions LAS degrade rapidly and concentration of LAS has been found very low in effluents from aerobic sewage treatment plants (STP). On the contrary, in anaerobic STPs effluents, LAS concentrations have been found very high. Anaerobic effluents containing high LAS concentrations have been found to pose risk to aquatic environment. Similarly, LAS concentrations have been found high in anaerobically treated sewage sludge's. LAS enter the soil as a result of sludge application to the land. Risk to aquatic and terrestrial ecosystems is increased when wastewaters and sludge's are treated anaerobically.     

Bacterial anaerobic respiration and electron transfer relevant to the biotransformation of pollutants

Bacterial anaerobic respiration is one of the most ancient and essential metabolism processes, possessing the characteristics of both flexibility and high diversity, and a very close relationship with the physiological function in the ecological environment. Under anaerobic conditions, bacteria and anthropogenic substances can form coupling process facilitating terminal electron transfer. Several forms of bacterial anaerobic respiration and electron transfer related to the biotransformation of pollutants, including respiration with humics, sulfonates, halogenated chemicals, azo compounds, TNTs, metallic and non-metallic elements, are reviewed in this paper. These respirations and electron transfers on diverse electron acceptors in the environment have important biotechnological implications because these biochemical reactions have their roles on the transformation/degradation of toxic substances and the cycling of organic carbon as well as many inorganic elements. Furthermore, remediation of sites contaminated with toxic pollutants based on bacterial anaerobic respirations is being recognized widely.     

苎麻酶法脱胶的研究进展*

苎麻酶脱胶法是一种高效能、优质量、无污染的脱胶方法,它是直接利用微生物发酵后期产生的胞外酶或酶制剂降解苎麻的胶质,使得苎麻纤维释放出来。到目前为止,国内外的科研人员在这方面已经进行了大量的研究,筛选了许多不同的脱胶菌,包括需氧菌和厌氧菌等用于苎麻的脱胶。相比化学脱胶,苎麻的酶脱胶具有提高精干麻的质量、大幅度降低环境污染等显的优点,是苎麻脱胶未来的主要发展方向,有着不可估量的前途。同时,随着酶脱胶技术在工业化生产中的推广应用,酶的使用量势必大幅度增加,从而将带动酶工业的发展。     

微塑料附着微生物研究进展

近年来,微塑料引起的环境污染已经成为一个全球性的问题,在海洋环境中,微生物可以附着于微塑料表面形成生物被膜。已有研究表明生物被膜可以为生活在其内部的细菌提供保护,被膜中可能富集了对人体或者水生生物有害的致病菌,且频繁的基因交流可能产生更多耐药菌。微塑料表面附着的微生物,能借助大洋环流随微塑料在海洋中迁徙,进而可能引起微生物入侵事件的发生。主要对微塑料与生物被膜之间的相互作用、微塑料与附着在其表面的塑料降解菌、微塑料与致病菌、微塑料对微生物迁徙的影响,以及微塑料表面生物被膜中耐药基因的扩散进行综述,对微塑料附着微生物未来研究方向进行了展望,为更好地了解海洋微塑料污染提供参考。     

Contribution of molecular microbiology to the study in water pollution removal of microbial community dynamics

Molecular tools based on 16S rRNA geneidentification are revolutioning microbialecology. After a short presentation of theadvantages and drawbacks of these new tools,the paper gives a succinct review of theirpossibilities as they have been applied to themicrobial ecology of water pollution removal.Examples of applications are presented in thefields of anaerobic digestion, nitrogen andphosphorus removal, filamentous bacteria andbioaugmentation. The data provided give someinsights about microbial diversity, populationdynamics, ecosystems stability and specificmicrobial population activity.