基于周丛藻类的雅鲁藏布江流域水生态系统健康评价

为评估雅鲁藏布江流域水生态系统的健康状态, 研究于2013年10月、2014年4月和2014年7月, 在雅鲁藏布江流域干流及其4大支流上设置了26个采样点, 先对河流每个点位的海拔、坐标、河道底质类型及构成比例、河岸植被类型、水电工程等环境数据进行收集, 随后采集周丛藻类群落数据, 并在此基础上构建了周丛藻类生物完整性指数(P-IBI)评价指标体系, 结果显示: 调查期间, 雅鲁藏布江流域干支流共观察到周丛藻类7门10纲23目34科70属(种), 硅藻门(35.71%)、绿藻门(32.86%)和蓝藻门(20.00%)为前3个优势门类, 周丛藻类的优势种均属于硅藻门, 该水域属硅藻-绿藻-蓝藻型水体。周丛藻类Shannon-Wiener多样性指数的变幅为4.84—9.41, Pielou均匀度指数的变幅为2.41—4.80, 则表明雅鲁藏布江流域整体为轻污型-清洁型水体。周丛藻类的Shannon-Wiener多样性指数、Pielou均匀度指数与P-IBI评价指标体系共同说明: 雅鲁藏布江流域干流上下游及其4大支流水生态系统的健康状态优于雅鲁藏布江流域干流中游的健康状态。研究雅鲁藏布江流域水生态系统周丛藻类的群落特征和水环境的健康状态, 一方面能为西藏土著鱼类食性、摄食机制等的研究提供饵料数据基础, 另一方面能对河流水生态系统的健康状况进行科学评价, 从而保障西藏水生态安全。     

汾河源头周丛藻类植物群落结构特征

基于对汾河源头流域周丛藻类植物群落进行的生态调查,共鉴定出周丛藻类植物24属47种,分别隶属于蓝藻(Cyanophyta)、红藻(Rhodophyta)、黄藻(Xanthophyta)、硅藻(Bacillariophyta)和绿藻(Chlorophyta)5个门。汾河源头流域的周丛藻类群落主要有5类,即颤藻群落(Oscillatoria community)、刚毛藻群落(Cladophora community)、无隔藻群落(Vaucheria community)、水绵-双星藻群落(Spirogyra-Zygnema community)和串珠藻群落(Batrachospermum community)。文章还对该地区的周丛藻类群落的种类组成、结构特征等进行了研究,分析了该流域中不同海拔梯度的变化对周丛藻类群落种类数的影响。结果表明海拔对周丛藻类植物的生长影响不明显,周丛藻类植物种数与水流速度之间存在负相关性。通过对周丛藻类植物种类组成、群落结构特征的研究,为汾河源头流域的环境保护和生物资源保护提供基础资料。     

基于周丛藻类群落结构的新疆额尔齐斯河生态健康评价

周丛藻类对水环境变化较为敏感,可迅速而灵敏的反映水质健康状况。本研究于2019年对额尔齐斯河周丛藻类群落结构和水环境特征进行了系统调查,并运用周丛藻类生物完整性指数(Periphytic algae index of biotic integrity, P-IBI)对生态健康进行了评价。结果表明:额尔齐斯河周丛藻类有6门41属102种,以硅藻门为主。周丛藻类密度和生物量的时间变化趋势为:9月>7月>5月,空间分布趋势为中下游>上游、支流>干流。主成分分析(PCA)与典范对应分析(CCA)显示,影响周丛藻类群落结构的主要环境因子有水温、溶解氧、高锰酸盐指数、氨氮、硝酸盐氮、pH、悬浮物,不同月份的环境影响因素有所差异。额尔齐斯河周丛藻类多样性指数(H′)、丰富度指数(D)、Pielou均匀度指数(J)的平均值分别为3.52、3.02、0.75,显示额尔齐斯河流域整体水质为寡污或无污。P-IBI分析结果显示:5个采样点为健康状态,1个采样点为亚健康状态,3个采样点为一般状况,1个采样点极差,表明额尔齐斯河整体生态健康状况趋于良好。本研究可为额尔齐斯河的水环境监测提供...     

淡水藻类在监测水质和净化污水中的应用

淡水藻类作为水体中的初级生产者,分布广泛,适应性强,在水生生态系统食物链中占据着十分重要的地位,在水质监测中起着关键的作用。通过对藻类生长与水环境之间的相互关系进行简要的概述,探讨了pH值和氮磷对淡水藻类的生长的影响,以及淡水藻类的生长对外界环境的影响。藻类不但应用于水质监测,而且还能去除水体中的氮、磷等营养物质和其它有机物,对自然水域中的污水有良好的净化作用。重点论述淡水藻类在水质监测和污水净化中的作用以及利用淡水藻类来处理污水的方法。并提出了保护水资源的相关建议,为综合监测和治理水环境提供一定的理论依据和支持。     

拉萨河下游周丛藻类群落结构特征及其与环境因子的关系

为探究西藏拉萨河下游周丛藻类群落结构时空特征及其驱动因子分析,研究于2018年2月(枯水期)、6月(平水期)、9月(丰水期)采用人工基质法对拉萨河下游进行3次周丛藻类群落结构调查。调查结果显示拉萨河下游共有周丛藻类7门53属104种,优势度≥0.02的藻类有28种,全部隶属于硅藻门。其中肘状针杆藻(Synedra ulna)、长等片藻(Diatom aelongatum)和中型脆杆藻(Fragilaria intermedia)为前三优势种。拉萨河下游周丛藻类年平均生物量为0.047 mg/cm²,其中曲水县平均生物量最高(0.121 mg/cm²),其次为尼玛江热乡(0.052 mg/cm²)和拉萨市(0.04 mg/cm²),墨竹工卡县平均生物量最低(0.015 mg/cm²)。拉萨河下游周丛藻类生物量空间分布为:曲水县>尼玛江热乡>拉萨市>阿朗乡>扎雪乡>达孜县>墨竹工卡县;拉萨河下游周丛藻类丰度时间分布为:平水期>丰水期>...     

安康水库表层浮游藻类群落结构及其与环境因子的关系

为了解安康水库表层水质与浮游藻类群落现状以及浮游藻类群落结构与环境因子之间的关系,于2012年1—12月对水库表层水进行每月一次的采样,分别对浮游藻类分布状况和理化因子进行分析.利用Shannon指数(H)和Pielou均匀度指数(J)分析浮游藻类群落特征,根据理化指标和综合营养状态指数(TSI)评价水体营养状态.共检测到浮游藻类7门110属,丰度为0.11×10⁴～2.08×10⁴ cells·L^-1.藻类组成、污染指示种分布情况、多样性分析和TSI显示安康水库表层属于中污染水质,处于中营养状态.此外,高密度投饵水产养殖及生活污水直接排放入库对水质产生负面影响,支流岚河的水质状况也较差.典范对应分析(CCA)结果显示,测定的8个环境因子中,不同季节影响浮游藻类群落组成及分布的环境因子不同,且氮是影响浮游藻类组成的主要营养盐因子.理化指标分析显示,安康水库表层水大体满足Ⅱ类水标准,水质良好.但部分采样点的总氮出现差于Ⅱ类水标准的现象,表明安康水库水质有变差的趋势.     

环境汞污染对藻类的毒性效应及其影响因素

综述了汞污染对藻类的毒性效应及影响因素。水环境中汞主要以元素汞、无机汞和有机汞3种形式存在。藻类吸附汞主要分为胞外的快速吸附和胞内的缓慢富集,在安全浓度内,金属汞对藻生长有一定的促进作用,随着浓度增大,抑制藻生长或致死。汞进入藻体细胞后,藻类为了存活会产生一系列保护机制。藻类对汞的排斥和排出作用可能就是对汞耐性的一种重要机制。藻类也可以通过多种方式减少汞进入藻类细胞,以及通过与其他物质结合汞使其排出胞外。温度、pH、生物学因素等影响重金属对藻类的毒性作用。并就藻类对汞耐性和适应机理、利用藻类修复和监测重金属污染、藻类响应汞胁迫的信号转导途径及其保护机制等未来研究领域进行了展望。     

藻类中添加剂的应用研究进展

藻类富含多种营养元素和活性物质,具有重要的经济价值和广阔的应用前景。现阶段藻类培养多采用露天跑道池,成本低,但易受环境影响。不适宜的环境条件(温度、酸性、重金属、紫外、盐度和光强胁迫等)会造成藻类生产成本上升、产品产量及品质下降等后果,严重制约藻类养殖业及相关产业的发展。添加剂不仅能有效促进藻类生长,还能缓解环境胁迫对其带来的逆境伤害。将近年来添加剂在藻类生长及抗逆方面的应用进行系统汇总,并对已阐明的几种添加剂的作用机理进行分析整理。添加剂在藻类中的应用研究大多停留在生长及生理指标的测定,如藻细胞密度、光系统活性、渗透调节物质含量、脂质含量、过氧化氢酶和硝酸还原酶活力等,仅有少部分研究是利用分子技术测定防御基因的表达情况,尝试进一步探究藻类抗逆性分子机制。旨在为研究者进一步明确常用添加剂在藻类中的信号传导机制及改善非生物胁迫造成的产品产量及品质的问题提供理论依据,具有重要现实意义。     

杭州西湖浮游藻类变化规律与水质的关系

于2006～2007年对杭州西湖浮游藻类的种类及个体丰度进行初步研究,并依据<水和废水监测分析方法>对其水质现状进行了生物学评价.综合生物和理化指标数据,对杭州西湖的水质作一总体评估,并对西湖水中的物种多样性保护及水质的可持续利用提出了建议.共鉴定浮游藻类179种,其中蓝藻25种,隐藻1种,金藻3种,甲藻3种,黄藻5种,裸藻23种,硅藻41种和绿藻78种.分析了杭州西湖浮游藻类的组成和分布的特点,揭示出西湖浮游藻类的种类组成与西湖水质变化之间的关系.结果表明:藻类的组成和分布与水质变化规律基本吻合,西湖水质较整治前有明显的改善,一些清水藻类的物种逐步增多.     

人工湿地生态系统的除藻研究

由于水体污染的日益加剧 ,水生态环境破坏严重 ,可利用的水资源不断减少 ,导致水资源供需矛盾日显突出。国内外学者在寻求多元化污水处理新技术方面进行了许多有意义的探索 ,人工湿地系统即是本世纪七十年代发展起来的污水处理新技术之一 ,由于具有高效的去除水体中的氮磷营养及有机物的能力 ,出水水质可达到或超过常规二级处理水平 ,且基建投资及日常运行费用却比常规二级处理厂低得多 ,因而被广泛应用于城镇污水、畜牧业、食品业和矿山等工农业废水的处理[1— 3] 。因藻类过量繁殖引起的富营养化问题在我国日趋突出 ,众多水厂也因水源中藻…     

Littoral macrophyte–periphyton complexes in two Hungarian shallow waters

Periphyton developing on the surfaces of emergent and submerged aquatic plants has a significant influence on water quality. The periphyton types that form on various plant species can be characterized by their mass values, the proportion of the present organic and inorganic fractions, as well as their chlorophyll-a contents. Studies on periphyton complexes constituting integrated biomonitoring systems are useful to gain essential long-term information about the performance of shallow water bodies. The filtering and settling effect of Phragmites and other aquatic plants, as well as their periphyton was examined and clearly observable in the water areas and non-flooded aquatic habitats belonging to the second phase of Kis-Balaton Protection System, as it was indicated by the mass values and ash contents. The periphyton forming on the aquatic vegetation that annually develops in Kisköre Reservoir and yields a considerable biomass has a critical part in influencing water quality. The only difference (p<0.05) was found in the ash content of the periphyton, being lower in Kis-Balaton (48.64 ± 2.29 S.E., %) and higher in Kisköre Reservoir (57.42 ± 2.54 S.E., %). This paper presents the dry mass of the periphyton, as well as its ash and chlorophyll-a content, and the results obtained on the composition of the alga species of the periphyton.

     

水产养殖水体附着生物对磺胺甲恶唑胁迫响应及其降解效应

研究通过模拟养殖水体,探究附着生物对磺胺甲恶唑(SMX)的胁迫响应及其对SMX的降解途径。结果表明,在5和10 mg/L SMX胁迫下,附着生物胞外聚合物(EPS)分泌较对照组增加31.3%和21.5%,抗氧化能力降低20.6%和31.8%,但生物量的积累没有显著差异。SMX使附着生物抗氧化系统受到损伤,并刺激其分泌更多胞外聚合物以提高耐受性。去除实验结果表明,附着生物会促进SMX的消减, 1 g/L附着生物在第14天对SMX的去除率为25.10%。主要降解中间产物有N4-乙酰基-磺胺甲恶唑(TP295)、对苯醌亚胺(TP107)、去砜基磺胺甲恶唑(TP189)和去氨基磺胺甲恶唑(TP238),键的断裂和苯环上氨基反应是SMX降解的两种主要途径。研究结果对评估SMX在养殖水体中的生态风险和利用附着生物去除SMX提供技术支撑。     

水生植物-微生物联合去除水体有机污染物的研究进展

近年来,随着经济的快速发展,大量有机化合物随着工业废水和生活污水排放进入水体,严重破坏了水环境的生态平衡,威胁着水生生物及人类健康。植物-微生物联合修复技术因具有修复效率高、持续时间长、投入成本低,而且不会产生二次污染等特点,在水体有机污染治理中受到了人们的广泛关注。本文综述了近年来水生植物-微生物联合去除水体有机污染物的应用现状,详细阐述了水生植物-微生物联合修复过程中的研究方法、作用机制及影响因素。以期不断完善和优化水生植物-微生物联合修复技术,为实现水环境有机物污染的统筹高效治理提供参考。     

Periphyton response to simulated nonpoint source pollution: local over regional control

We investigated functional and structural responses of periphyton communities to simulated nonpoint source (NPS) pollution over a 2-year period. Periphyton communities were examined in three unique but hydrologically connected habitats in the lower Muskegon River: river, wetland, and lake. Our study addressed several major questions: (1) what are the effects of nonpoint source pollutants on periphyton structure and function, (2) to what degree do environmental conditions, including the pollutant delivery system and hydrologic conditions, affect periphyton response, and (3) do periphyton communities show synchronous responses to nonpoint source pollution? Nutrients were added over a 21-day period in each of the four seasons over 2 years. The effect of road salt on metabolism was evaluated in the winter and spring seasons in the river habitat only. In general, the periphyton community showed complex responses to the NPS amendments, but there was little evidence of nutrient limitation in this system based on community structure, biomass accrual, metabolism, or alkaline phosphatase activity. This result was unexpected given the relatively low ambient concentrations of phosphorus. We discuss the possibilities that nutrient delivery was ineffective or that herbivory and/or irradiance might have constrained periphyton growth, but ultimately conclude that our results suggest that periphyton communities in the lower Muskegon River watershed were (1) nutrient-replete, (2) tolerant of short-term salt additions, and (3) influenced more by local conditions (habitat) than by regional (watershed) factors. In systems where nonpoint source pollutant delivery is diffuse and hydrologic residence time is short, the influence of nonpoint source pollutants on periphyton may be either modest or too difficult to detect using traditional endpoints.     

Effects of nutrients and grazers on periphyton phosphorus in lake enclosures

SUMMARY. 1. Periphyton. measured as particulate phosphorus (PP) and expressed as periphyton PP, growing on vertically oriented substrata (polyvinyl impregnated nylon) under different nutrient loadings, light intensities (exposures), and grazer communities was examined in eight large enclosures (750 m3) where nutrients (N and P) and planktivorous fish (1+yellow perch) were added in a 2x2 factorial design.
2. During the first 3 weeks of the experiment (25 June to 15 July), there was a significantly higher accumulation of phosphorus into periphyton (periphyton PP) with fertilization, but fish addition had no effect. During the fourth to seventh weeks (16 July to 12 August), addition of fish was associated with lower abundance of amphipods and chironomids and higher concentration of periphyton PP. In the enclosures without fish, these invertebrates were over 25 times more abundant, and periphyton PP decreased substantially compared to the June-July period. Fertilization increased periphyton PP only at high exposures in the enclosures with fish.
3. Exposure had a significant effect on periphyton PP. In the enclosures with fish, high abundance of nanoplankton reduced water transparency, and periphyton PP was lower in the deeper waters which may have been due to limitation by low light. Lower periphyton PP was also observed at the surface on sunny sides of enclosures without fish, and therefore with high water transparency. This pattern may have been due to inhibitory effects of high light intensity.
4. Periphyton communities in the enclosures with fish had higher uptake rates for planktonic phosphorus, and lower rates of phosphorus release, suggesting that periphyton with high phosphorus demand may have high internal cycling of assimilated phosphorus.     

THE ROLE OF PERIPHYTON IN PHOSPHORUS RETENTION IN SHALLOW FRESHWATER AQUATIC SYSTEMS

Eutrophication caused by phosphorus (P) leads to water quality problems in aquatic systems, particularly freshwaters, worldwide. Processing of nutrients in shallow habitats removes P from water naturally and periphyton influences P removal from the water column in flowing waters and wetlands. Periphyton plays several roles in removing P from the water column, including P uptake and deposition, filtering particulate P from the water, and attenuating flow, which decreases advective transport of particulate and dissolved P from sediments. Furthermore, periphyton photosynthesis locally increases pH by up to 1 unit, which can lead to increased precipitation of calcium phosphate, concurrent deposition of carbonate-phosphate complexes, and long-term burial of P. Actively photosynthesizing periphyton can cause super-saturated O₂ concentrations near the sediment surface encouraging deposition of metal phosphates. However, anoxia associated with periphyton respiration at night may offset this effect. Linking the small-scale functional role of periphyton to ecosystem-level P retention will require more detailed studies in a variety of ecosystems or large mesocosms. A case study from the Everglades illustrates the importance of considering the role of periphyton in P removal from wetlands. In general, periphyton tends to increase P retention and deposition. In pilot-scale constructed periphyton-dominated wetlands in South Florida, about half of the inflowing total P was removed.     

How light and nutrients affect the relationship between autotrophic and heterotrophic biomass in a tropical black water periphyton community

This study examines how nutrients and light affect the relationship between autotrophic biomass and non-autotrophic periphyton organic matter in a tropical black water lake biofilm community. We hypothesized that there is no positive correlation between autotrophic and non-autotrophic organic matter in the periphytic community of a black water humic lake, where non-algal components of periphyton can rely on carbon sources external to the periphyton matrix and where nutrient availability is low. Second, we sought to test our hypothesis that non-autotrophic periphyton organic matter will benefit from nutrient enhancement in a lake where the availability of DOC is high. We performed a field experiment using in situ lake mesocosms to manipulate nutrient concentrations and light availability in a 2 × 2 factorial design. Control treatments (no nutrient added) and nutrient treatments (N + P) were compared in different light conditions: high light (near surface water) and low light (near bottom). No positive correlation was found between autotrophic biomass and non-autotrophic periphyton organic matter, but a negative correlation was observed in high nutrient and light conditions. The low C:P and N:P ratios revealed that the non-autotrophic organic matter mostly comprised a heterotrophic microbial biofilm. High levels of light and nutrients together caused significant changes in periphyton community properties. The non-autotrophic periphyton organic matter was negatively affected by nutrient addition, whereas autotrophic biomass was positively affected, especially in high light conditions. Our results strongly suggest that non-autotrophic periphyton organic matter in a humic lake is primarily comprised of a bacterial biofilm that directly competes for nutrients with autotrophs in the periphytic community. We also observed no effect of nutrient addition on periphyton growing in light-limited conditions. These results suggest that heterotrophic periphytic organisms might experience carbon limitation despite the high availability, but usually low quality, of dissolved carbon in the water column of humic lakes.     

The effect of periphyton stoichiometry and light on biological phosphorus immobilization and release in streams

Periphyton stoichiometry can vary substantially as a result of differences in stream nutrient availability. A decrease in the periphyton carbon to phosphorus (C:P) ratio should decrease the demand for new P to be immobilized from stream water, but no studies to our knowledge have explored the relationship between periphyton stoichiometry and net P immobilization and release by periphyton. We sought to model biological P immobilization and release (flux) in streams by measuring periphyton stoichiometry and light availability. We measured P flux to and from intact periphyton on stream cobbles (20–100 mm diameter) in 1 L microcosms incubated with streamwater under variable light conditions. Net P immobilization occurred in 75% of microcosms, net P release occurred in only 5% of microcosms, and 20% of microcosms had neither net immobilization nor net release. When normalized to stream conditions, net P immobilization was highest when light availability was high (<60% canopy attenuation) and the periphyton C:P ratio was also high. In contrast, net P release occurred only when light availability was low (>60% canopy attenuation) and the periphyton C:P ratio was also low. A multiple regression model that included both periphyton stoichiometry and light availability from the growing season only, and the interaction term of these two variables, explained 99% of the variation in daily periphyton P flux observed in the study. These results indicate that in order to predict periphyton P immobilization, periphyton stoichiometry and light availability should be considered together. Furthermore, the results indicate that net P immobilization occurs even in very P-rich periphyton, which can act as a P sink when light availability is high.     

Effect of periphyton biomass on hydraulic characteristics and nutrient cycling in streams

The effect of periphyton biomass on hydraulic characteristics and nutrient cycling was studied in laboratory streams with and without snail herbivores. Hydraulic characteristics, such as average water velocity, dispersion coefficients, and relative volume of transient storage zones (zones of stationary water), were quantified by performing short-term injections of a conservative tracer and fitting an advection-dispersion model to the conservative tracer concentration profile downstream from the injection site. Nutrient cycling was quantified by measuring two indices: (1) uptake rate of phosphorus from stream water normalized to gross primary production (GPP), a surrogate measure of total P demand, and (2) turnover rate of phosphorus in the periphyton matrix. These measures indicate the importance of internal cycling (within the periphyton matrix) in meeting the P demands of periphyton. Dense growths of filamentous diatoms and blue-green algae accumulated in the streams with no snails (high-biomass streams), whereas the periphyton communities in streams with snails consisted almost entirely of a thin layer of basal cells of Stigeoclonium sp. (low-biomass streams). Dispersion coefficients were significantly greater and transient storage zones were significantly larger in the high-biomass streams compared to the low-biomass streams. Rates of GPP-normalized P uptake from water and rates of P turnover in periphyton were significantly lower in high biomass than in low biomass periphyton communities, suggesting that a greater fraction of the P demand was met by recycling in the high biomass communities. Increases in streamwater P concentration significantly increased GPP-normalized P uptake in high biomass communities, suggesting diffusion limitation of nutrient transfer from stream water to algal cells in these communities. Our results demonstrate that accumulations of periphyton biomass can alter the hydraulic characteristics of streams, particularly by increasing transient storage zones, and can increase internal nutrient cycling. They suggest a close coupling of hydraulic characteristics and nutrient cycling processes in stream ecosystems.