采用倒置显微镜法定量浮游植物的数据稳定性

浮游植物种类组成细胞密度或生物量的现存量反映其在水生生态系统的结构与功能,准确地对水体中浮游植物进行定量是水质评价和生态功能分析的基础.针对目前国际上推荐使用的倒置显微镜法(即Utermhl计数法),通过采集处于不同营养状态和水体条件(水库和实验围隔)中的浮游植物,分析样品的显微计数量、水体营养状态对浮游植物密度和多样性等指标稳定性的影响,同时比较了多个水体中同一采样点的重复(或平行)样品之间浮游植物定量数据的差别,从而对倒置显微镜法进行较为系统的评估.结果表明,基于浮游植物的显微镜计数效率与定量数据稳定性的综合考虑,选择计数400个个体即可基本保证定量数据的稳定性;在依赖生物量或稀有种进行水质评价时,处于不同营养水平的水体均需要增加样品的平行数来提高定量数据的可靠性,贫营养型水体中单个采样的重复或平行样品更为必要;两种定量方法所得群落数据计算的辛普森指数无显著差异,说明两种方法所获得结果均能反映浮游植多样性;通过样品浓缩法和倒置显微镜法所获得的浮游植物生物量和细胞密度均具有显著差异,因样品浓缩法在样品处理过程中造成浮游植物损失,使通过样品浓缩法所得的浮游植物群落生物量及细胞密度偏小;相比浓缩法,倒置显微镜法沉淀浓缩的水样体积小,样品处理和计数耗时短,更适宜用于应急监测.     

贵州百花湖麦西河河口浮游植物群落结构及与环境因子关系

2009年7月至2010年6月,以每月一次的频率对百花湖(水库)麦西河河口浮游植物群落结构和环境因子进行调查.监测到浮游植物66种(属),浮游植物主要由绿藻、硅藻和蓝藻组成,夏秋季湖泊假鱼腥藻(Pseudanabaena limnetica)为优势浮游植物,而冬春季梅尼小环藻(Cyclotella meneghinia...     

黑龙江扎龙湿地不同功能区浮游植物群落与环境因子的关系

为研究黑龙江扎龙湿地不同功能区浮游植物群落结构分布及其与环境因子的关系,于2010年7—8月在扎龙湿地4个功能区340个研究点进行水环境样品采集分析.样品共鉴定出浮游植物6门80属354种,各门类细胞密度变化范围为0.06×10~6~37.82×10~6cells/L.主要优势种为普通小球藻(Chlorella vulgaris)、梅尼小环藻(Cyclotella meneghiniana)、旋转囊裸藻(Trachelomonas volvocina)等.各功能区浮游植物优势种差异较大,核心区中放射舟形藻(Navicula radiosa)、弯棒杆藻(Rhopalodia gibba)、扁圆卵形藻(Cocconeis placentula)等为优势种类,而排污区中梅尼小环藻、普通小球藻、巨颤藻(Oscillatoria princes)、固氮鱼腥藻(Anabaena azotica)等处于优势地位.主成分分析表明在扎龙湿地水环境中浊度和总磷浓度是影响浮游植物生长的主要因素,典范对应分析结果表明总氮浓度、总磷浓度、电导率、浊度对浮游植物属种分布影响较大,梅尼小环藻、箱形桥弯藻(Cymbella cistula)、美丽星杆藻(Asterionella formosa)、普通小球藻、旋转囊裸藻等受环境因子的影响较为明显.     

太湖梅梁湾与五里湖浮游植物群落的比较

富营养化和风浪是影响大型浅水湖泊浮游植物群落的重要因素,本文于2003年10月至2004年9月对太湖梅梁湾和五里湖理化环境因子(水温、透明度值、悬浮质浓度和氮、磷营养盐浓度)和浮游植物群落进行了逐月监测,通过对两个湖区理化因子和浮游植物群落结构在周年内季节变化的比较研究,探讨富营养化程度以及风浪对浮游植物群落结构的影响,结果为:(1)梅梁湾由于受风浪影响悬浮物含量较高,五里湖则富营养化水平更高.(2)周年内五里湖浮游植物平均生物量(6.85 mg/L)高于梅梁湾的平均生物量(4.99 mg/L),两个湖区都呈现夏秋高峰、冬季低谷的变化特征.梅梁湾浮游植物群落季节演替的模式基本为:冬季硅藻(小环藻属Cyclotella spp.)和隐藻(隐藻属Cryptomonas spp.)-春季绿藻(细丝藻属Planctonema sp.)-夏季绿藻(绿球藻目Chlorococcales种类)和蓝藻(微囊藻属Microcystis spp.和浮游蓝丝藻属Planktothrix spp.)-初秋蓝藻(微囊藻属)和硅藻(浮游直链硅藻Aulacoseira spp.)-秋季隐藻(隐藻属).五里湖的季节演替模式没有梅梁湾明显,全年隐藻(隐藻属)都占优势,在此基础上,秋冬季硅藻(小环藻属和浮游直链硅藻属)占优势,裸藻(裸藻属Euglena spp.)在冬春季占优势,绿藻(绿球藻目种类和团藻目衣藻属Chlamydomonas spp.)在整个春季和初夏的优势地位在夏季被蓝藻(微囊藻属和浮游蓝丝藻属)所取代.群落构成的差异是浮游植物对两个湖区不同风浪条件和富营养化水平的响应结果.(3)通过与PEG(Plankton Ecology Group)模式的比较,梅梁湾和五里湖浮游植物群落的季节演替主要受水温、光照、营养盐(氮、磷)浓度和浮游动物牧食等因子的影响,因此,大型富营养化浅水湖泊浮游植物群落演替规律需要进一步的研究.     

热带富营养化湖泊中浮游植物的脂肪酸组成与分布

星湖位于广东省．是一个热带地区的湖泊．本文测定和分析了该湖的两个子湖仙女湖和中心湖浮游植物群落的脂肪酸组成,探讨了浮游植物群落特征与脂肪酸组成之间的关系．两个子湖的富营养化程度较高,其中中心湖更严重．仙女湖的浮游植物群落以蓝藻为主导,而在中心湖则蓝藻或金藻占优势．浮游植物样品中检测到的脂肪酸碳链长为16碳到22碳．其中饱和脂肪酸和单不饱和脂肪酸种类较少,均有3种;而高不饱和脂肪酸的种类相对较多．两个子湖的脂肪酸均以饱和脂肪酸为主,高不饱和脂肪酸浓度相对较低．对于单一的脂肪酸种类来说,C16：0浓度最高,其浓度与蓝藻数量有很高的相关性(R^2=0．955,P=0．001),表明样品中的C16：0主要来源于蓝藻．而富含EPA(二十碳五烯酸)的硅藻和隐藻生物量高时其浮游植物的EPA浓度也较高;在中心湖中高浓度的DHA(二十二碳六烯酸)主要来源于金藻总之．两个子湖泊的脂肪酸组成与浮游植物群落结构特征基本一致．     

2002-2017年千岛湖浮游植物群落结构变化及其影响因素

为认识大型水库中浮游植物群落结构的演替特征及其驱动机制,以钱塘江流域新安江水库（下称"千岛湖"）为例,基于2002-2017年16年的水库浮游植物数据,结合同期千岛湖水质与水文气象资料,分析了千岛湖浮游植物结构及优势属的长期变化特征,探讨了影响浮游植物群落结构变化的主要因素.结果表明：2002-2017年千岛湖共鉴定出浮游植物7门93属,主要由硅藻门、绿藻门、蓝藻门及隐藻门种类组成.16年间,浮游植物年均丰度和群落结构经历了4个阶段：2008年前丰度持续低值且蓝藻不是主要类群,2009-2012年丰度较高且蓝藻成为主要类群,及2013-2015丰度降低且蓝藻占比降低,2016-2017年丰度增加且蓝藻再次成为主要类群.浮游植物门类变化的同时伴随着优势属的变化：浮游植物年优势属从2002-2008年的小环藻属（Cyclotella）、隐藻属（Cryptomonas）和蓝隐藻属（Chroomonas）转变为2009-2012年的颤藻属（Oscillatoria）、小球藻属（Chlorella）、小环藻属和蓝隐藻属,2013-2017年又转变为鱼腥藻属（Anabaena）、束丝藻属（Aphanizomenon）、小环藻属、针杆藻属（Synedra）、直链藻属（Melosira）、栅藻属（Scenedesmus）和蓝隐藻属.冗余分析表明,气温、风速、水位、入库流量等气象水文因子和总氮浓度、电导率、氮磷比、透明度等水质因子与浮游植物群落结构变化关系密切.研究结果表明,在千岛湖这种大型贫-中营养水库,浮游植物群落结构不仅受来水营养盐负荷的影响,还在很大程度上受水文、气象条件的影响,给水库藻类水华等生态风险的预测以及水库水质管理带来了挑战.     

冻融期包头南海湖浮游植物群落及优势种生态特征

为了探究包头南海湖浮游植物群落特征和物种与生境之间的关系,于2018年11月和2019年1月、3月分别对南海湖浮游植物群落结构进行调查分析,得出南海湖冻融期浮游植物群落结构为绿藻硅藻蓝藻型使用改进的Levins公式和Petraitis指数测定了南海湖冻融期优势种的生态位量度结果显示:在不同生境条件下,物种生态位宽度存在季节性变化,同样,生态位重叠也随季节变化而变化随着湖面冰冻,多数浮游植物生态位宽度有所下降;结冰期生态位重叠程度最高,融冰期生态位重叠程度最低综合冻融过程优势藻种生态特征,绿藻门的四尾栅藻(Scenedesmus quadricauda)是冻融过程中最主要优势种,优势度、密度、生态位量度均优于其他优势藻种,能充分利用环境资源,更具竞争力优势种与环境因子的灰关联分析显示,p H是影响浮游植物优势种数量的主要相关因子.     

新安江水库(千岛湖)湖泊区夏季热分层期间垂向理化及浮游植物特征

2010年7月对亚热带特大型水库——新安江水库湖泊区水体的垂向物理、化学参数以及浮游植物群落进行了观测研究,并应用Water-PAM对水体浮游植物垂向光合作用参数进行了测定.研究结果表明:夏季该水库湖泊区在水下10～20 m处形成明显的温跃层,垂向pH值、溶解氧及浊度的变化同叶绿素a浓度呈现高度一致;夏季浮游植物群落以硅藻占绝对优势,水体表层以梅尼小环藻(Cyclotella meneghiniana)为主,表层以下其它各层均以巴豆叶脆杆藻(Fragilaria cro-tonensis)为绝对优势种,垂向分布表现为5～10 m区间为浮游植物高密度区域,温跃层以下浮游植物密度显著下降,水温分层可能是决定浮游植物垂向分布的重要因素之一.浮游植物最大光合效率从表层向下层逐步降低,实际光合效率最大值出现在垂向10 m区域.     

洪湖浮游植物群落结构及其与环境因子的关系

为研究洪湖浮游植物群落结构及其与环境因子的关系,于2008年3月(枯水期)及7月(丰水期)在洪湖进行采样分析。两次采样共鉴定有浮游植物6门46属95种,细胞丰度变化范围为2.00×10~5-284×10~5 cells/L。硅藻为两个季节绝对优势门类,其次为绿藻及蓝藻;主要种属为直链藻、脆杆藻、栅藻等.丰水期与枯水期浮游植物群落结构季节差异较大;在枯水期由于硅藻对水温和光照较好的适应能力使其处于优势门类;丰水期由于其他藻类对营养盐的竞争及水体中硅含量充足使得绿藻等生长同时硅藻能继续保持优势地位。主成分分析表明在洪湖富营养化水平及水体中离子类型、水体中物质组成和污染程度是影响浮游植物生长的三类主要因素;典范对应分析结果表明浮游植物群落结构与水温、溶解氧及悬浮物浓度相关。     

江苏滆湖北部区整治后浮游植物时空分布及环境因子变化规律

滆湖是我国长江中下游典型的浅水型湖泊,为了解其治理后浮游植物群落时空分布规律,2013年1 12月对其北部区浮游植物及环境因子进行调查.调查期间共检出浮游植物7门43属61种,春、冬季以栅藻(Scenedesmus)和小环藻(Cyclotella)为主要优势种属,夏、秋季以微囊藻(Microcystis)和颗粒直链藻(Melosira granulata)为主要优势种属,采样期间浮游植物生物量最高值为90.6 mg/L,出现在8月份,铜绿微囊藻(Microcystis aeruginosa)占绝对优势.浮游植物平均密度呈现由西向东递减的趋势,植被覆盖区低于敞水区.环境因子分析表明:总氮浓度、总磷浓度、水温是影响滆湖北部区浮游植物密度和生物量的主要因子.比较相同月份湖区内部菱角芦苇区和未治理的敞水区的平均生物量,菱角区生物量较敞水区低约72.7%~91.1%,芦苇区生物量较敞水区低约63.9%~83.7%.在8、9月湖区内敞水区暴发水华时菱角区浮游植物生物量仅为敞水区的14.6%,芦苇区为敞水区的30.3%.     

淡水浮游植物计数与定量方法

显微镜计数法是淡水浮游植物计数最常用的经典方法,是浮游植物生物量测定的基本方法,也是衡量其他测定方法准确性的依据.随着科技的发展,可见分光光度法、荧光分光光度法、流式细胞显微镜计数法、库尔特计数法等新型细胞计数法相继问世.对各种方法的特点进行比较,结果表明:光密度法、流式摄像机计数法、流式细胞仪法、叶绿素a法等仅能够分析测定浮游植物生物量,而显微镜法是测量浮游植物粒径的经典方法,不仅可以测定浮游植物生物量,还可以进行浮游植物的种类及群落结构分析.以上这些方法都可以用于浮游植物的计数与定量,可以根据不同的需求来选择最佳的浮游植物计数方法,如分析方便性、样本处理速率、样本大小等.但显微镜计数法在淡水生态学中具有不可替代的作用.     

Phytoplankton pigments and epifluorescence microscopy as tools for ecological status assessment in coastal and estuarine waters, within the Water Framework Directive

Inverted microscopy is widespread employed for the analysis of phytoplankton composition within water quality monitoring networks. However, the analysis at the lowest taxonomical level is not always required for ecological status assessment. In addition, inverted microscopy can underestimate the small phytoplankton, and not always distinguish photoautotrophic from heterotrophic cells. In this study, as alternative tools, epifluorescence microscopy and High Performance Liquid Chromatography (HPLC) were employed to characterize phytoplankton communities within waters of different trophic condition. Epifluorescence microscopy confirmed its effectiveness to count the small phytoplankton. Furthermore, significant correlations between nutrients of anthropogenic origin and nanoplankton abundances were found. However, this technique resulted very time-consuming. HPLC together with the CHEMTAX program was more appropriate than inverted microscopy, in terms of cost-effectiveness. Also, the main variability patterns observed in the phytoplankton community structure by HPLC coincided with previous findings in the study area. Nevertheless, a rapid screening at the inverted microscope is recommended.     

基于浓缩法的浮游植物定量数据稳定性与可靠性分析

浮游植物是水生生态系统中重要的初级生产者,相对准确地定量它们的数量是进一步进行水质评价和生态功能分析的基础.通过采集处于不同营养状态的水库和不同处理的围隔中的浮游植物,研究影响浓缩法定量浮游植物的因素,了解如何通过浓缩法来合理地定量浮游植物.分析浓缩倍数、样品的显微镜计数量、水体营养状态对浮游植物丰度、生物量及群落多样性等定量参数稳定性的影响,同时比较单个不同水体中重复(或平行)样品之间浮游植物丰度的差别.结果表明,基于浮游植物的显微镜计数效率与定量数据稳定性的综合考虑,选择计数4片×10格/片即可基本保证定量数据的稳定性;在保证正常镜检的基础上,考虑水体营养状态适当增加浓缩倍数能够提高定量数据的可靠性;在特别依赖生物量或稀有种进行水质评价时,处于不同营养水平的水体均需要增加样品的平行数来提高定量数据的可靠性.     

Mikroskopische und elektronische Zählung von Sestonpartikeln im Wasser der Warnow — ein Vergleich

In 37 samples from the river Warnow in the course of one annual variation the seston particles were counted in the inverted microscope in three size classes: A <8 μm, B 8 … 25 μm C>25μm. Parallel to that, counting was performed with the electronic particle counting device Picoscale 4, which is used for the counting of blood cells, in the setting WBC for leucocytes with a nozzle 200 μm in diameter, so that the setting approximately corresponded to the size range B of the microscopic count. The microscopic particle numbers per ml were 800,000 … 5,200,000 for A, 10,000 … 96,000 for B and 2,000 … 21,000 for C. In principle, there is a correlation between microscopic and electronic results for the particles B and C. The regression analysis, however, produces a considerable residual scattering because of the morphological variety of the particles and its changes in the course of the seasonal change of mass. Therefore, the conclusion of the particle density from results of electronic counting is connected with considerable indistinctness, so that the electronic counting can be used only as a supplementary method for the estimation of the density of suspended matter.     

北京城区河湖水质分析

调研结果显示,2003年北京城区河湖(11个监测水体)总磷、总氮含量分别为0．142mg/L、1．481mg/L,已达到比较 严重的富营养状态．北京城市河湖属于藻型水体,初级生产力主要决定于浮游藻类的群落结构与密度．河湖水体中浮游 藻类密度为37867．82×10~4cells/L,其群落由蓝藻(Cyanophyta)、绿藻(Chlorophyta)、硅藻(Bcillariophyta)、甲藻(Pyrrophy— ta)、隐藻(Cryptophyta)、黄藻(Xanthophyta)、金藻(Chrysophyta)和裸藻(Eugleniphyta)构成．群落中蓝藻占绝对优势 (89．54%)．在近几年的夏秋季连续发生程度不同的微囊藻(microcystis)水华,对水体功能和城市景观造成了不良影响． 主要原因是：(1)氮磷和有机物的污染,(2)给城市河湖补给的水量少,(3)河湖生态系统被损害,水体自净能力差．本文 对如何改善北京城市河湖水质提出了建议．     

Determinations of particle size distributions in natural waters use of Zeiss Micro-Videomat image analyzer

Use of a Zeiss Micro-Videomat electronic image analyzer for routine measurements of size distributions of particles found in natural waters greater than 0.3 μm has been investigated. Staining of particles with a solution of Gentiana-violet eliminated the multiple-count problem which has frustrated earlier attempts to use image analyzers for quantitative phytoplankton work. Concentration of samples from the lake water column was successfully achieved with an impact centrifuge. Losses of inorganic particles indicate that the centrifuge method must be evaluated on an individual case basis. Precision and accuracy of the Zeiss Micro-Videomat using either sedimentation (Utermöhl) or centrifugation for sample concentration were satisfactory for particles larger than 1 μm. The system appears promising for routine surveillance of raw water quality at water treatment plants, and performance of unit processes used for particulate removal, as well as for specific investigations of ecological phenomena in natural waters.     

Effects of nitrogen and phosphorus on phytoplankton composition and biomass in 15 subtropical, urban shallow lakes in Wuhan, China

This study aims at investigating the composition and biomass of the phytoplankton community in 15 urban shallow eutrophic lakes as well as the effects of main environmental factors, including nutrient concentrations and the ratio of nitrogen to phosphorus, temperature, COD, BOD, water depth, etc. on the phytoplankton community structure. Lake water samples were taken and analyzed on a bimonthly basis during the period from March 2004 to March 2006. The redundancy analysis (RDA) and regression analysis (RA) were performed to identify the effects of nutrients on the phytoplankton community and biomass in these typical urban lakes. The results indicate that most of these urban lakes were hypertrophic due to high concentrations of total phosphorus (TP) and total nitrogen (TN), with mean levels of 490 and 5380 mg m⁻³, respectively. The phytoplankton community was dominated by Microcystis aeruginosa and Euglena caudate in summer and Cryptomonas ovata and Cyclotella meneghiniana in winter. The mean biomass of the phytoplankton reached 456.87 mg L⁻¹ in summer months and the annual level was 189.24 mg L⁻¹. Temperature and TP content were found to be the principal limiting factors for phytoplankton growth on an annual basis. On the other hand, the results of RDA and RA demonstrate that the dominant phytoplankton species were not nutrient-limited during summer months. Low TN:TP ratios (<10) were detected accompanied with fewer occurrences of N-fixing cyanobacteria and other filamentous algae in most lakes in summer, which implies that low N:P ratio does not always shifts the dominance of phytoplankton community to the N-fixing cyanobacteria. Moreover, TP always had higher correlation with chlorophyll a (Chl-a) than TN, even when the TN:TP ratios of most samples were lower than 10. Therefore, it is concluded that the TN:TP ratio is not always a suitable index to determine whether nitrogen or phosphorus limits the phytoplankton biomass in urban shallow eutrophic lakes.     

Do benthic algae provide important information over and above that provided by macrophytes and phytoplankton in lake status assessment? – Results from a case study in Norway

To test if phytobenthic algae provide additional important information to macrophytes and phytoplankton for lake monitoring, we sampled two large lakes in Norway. In each lake, we analyzed water chemistry and phytoplankton above the deepest site, recorded macrophytes and non-diatom phytobenthic algae at 20 sites around the shoreline and estimated site-specific nutrient input from land cover. Since no ready-to-use phytobenthos index exists for lakes in Norway, we tested the PIT index developed for rivers, commonly perceived signs of disturbance such as high algal cover, and taxon richness as well as similarity patterns. Both lakes were nutrient poor, but had potential local nutrient inputs (villages, agriculture). In neither of the lakes did phytobenthos indicate a worse overall ecological status than macrophytes and phytoplankton. Our data therefore, did not suggest that it would be useful to add phytobenthos into surveillance monitoring of lakes in Norway. There was a loose correlation between macrophyte and phytobenthic site-specific taxon richness and similarities. This means that macrophytes and phytobenthos do indeed give partly redundant information. High algal cover was found at sites with both high and low phosphorus input. Using algal cover as indicator of site-specific nutrient input is therefore overly simplistic. Urban and cultivated areas were associated with a more eutrophic PIT. This indicates that the PIT, despite being developed for lotic waters, may be used to detect site specific nutrient input in lakes.