莱州湾大型砂壳纤毛虫群落季节变化

为揭示莱州湾砂壳纤毛虫群落季节变化规律, 在莱州湾设置8个站位, 于2011年5-11月及2012年3-4月进行了9个航次的调查, 用浅海III型浮游生物网由底至表垂直拖网采集砂壳纤毛虫。结果表明, 莱州湾3-11月砂壳纤毛虫物种丰富度的变化范围为5-19, 周年变化呈现一峰两谷的趋势。丰度的范围为0-318 ind./L, 丰度较大(> 50 ind./L)的种类有运动类铃虫(Codonellopsis mobilis)和清兰拟铃虫(Tintinnopsis chinglanensis)。各月平均丰度随时间的变化趋势为双峰型, 最大值出现在7月(63 ind./L), 次峰值出现在5月(48 ind./L), 最小值出现在3月(2 ind./L)。黏着壳种类在3-11月均有出现, 透明壳种类仅在温度较高(> 15°C)的6-9月出现。各月的优势种数目为1种(5月)到8种(8月), 其中运动类铃虫在所有月中都是优势种, 对砂壳纤毛虫丰度周年的变化规律产生较大影响。使用各月所有种类的平均丰度对各月砂壳纤毛虫群落进行聚类分析, 得到两个群落(相似度30%): 群落I(7-9月)和群落II(3-6月、10-11月), 说明砂壳纤毛虫群落发生了明显的季节变化。砂壳纤毛虫的物种丰富度、丰度与环境因子(温度、盐度)均没有明显的相关性。     

春季和秋季东海陆架区浮游纤毛虫的丰度和生物量

于2011年春季(5月)和秋季(11月)在东海陆架区进行浮游纤毛虫丰度和生物量的调查.春季和秋季纤毛虫的平均丰度分别为(614±861)和(934±809) ind·L^-1,平均生物量分别为(1.70±3.91)和(0.93±0.99) μg C·L^-1.表层纤毛虫丰度和生物量的高值区春季主要分布在近岸及远岸海区,秋季主要分布在远岸海区.春季纤毛虫的丰度和生物量在水体上层较高;秋季纤毛虫主要分布在水体上层,有时在水体底层也会出现丰度和生物量的高值.春季无壳纤毛虫群落的粒级较大,秋季较小.砂壳纤毛虫占纤毛虫丰度的平均比例春季和秋季分别为(26.9±34.3)%和(44.9±25.2)%.两个季节共鉴定出砂壳纤毛虫27属52种,春季丰度较大的种为原始筒壳虫、橄榄领细壳虫及筒状拟铃虫,秋季丰度较大的种为原始筒壳虫、小领细壳虫及矮小拟铃虫.纤毛虫丰度与温度、叶绿素a(Chl a)浓度呈显著正相关.砂壳纤毛虫丰度与盐度呈显著负相关,群落结构变化与温度显著相关.     

2010年两个航次獐子岛海域浮游纤毛虫丰度和生物量

2010年7、8月在北黄海獐子岛海域进行了浮游纤毛虫丰度和生物量的调查。7月浮游纤毛虫的平均丰度为(5107±4451) 个/L,平均生物量为(10.17±9.06) μg C/L。8月浮游纤毛虫的平均丰度为(7894±7212) 个/L,平均生物量为(15.24±18.49) μg C/L。7月表层浮游纤毛虫丰度和生物量均呈现近岸多、远岸少的趋势。8月Y1-3、Y2-5两个站表层纤毛虫丰度较高,Y2-5、Y1-1两个站表层纤毛虫生物量较高。7月STA断面浮游纤毛虫丰度呈现表层或次表层高、底层低的特点。8月STA、Y1断面纤毛虫丰度在表层或次表层高、底层低,而Y2断面纤毛虫垂直分布较一致。7月纤毛虫水体丰度及生物量在近岸较远岸高, 8月纤毛虫水体丰度及生物量在离岛较近的Y2-5、Y1-1两站较高。7、8月航次中分别鉴定出砂壳纤毛虫17和21种,其中拟铃虫属(Tintinnopsis)种数最多,Tintinnopsis corniger Hada, 1964为中国海区的新记录种。7、8月砂壳纤毛虫丰度占纤毛虫总丰度的平均比例分别为(19.0±21.6)%和(13.0±16.1)%;7、8月砂壳纤毛虫生物量占纤毛虫总生物量的平均比例分别为(58.2±33.0)%和(42.6±33.2)%。7、8月两个航次中小型无壳纤毛虫在无壳纤毛虫丰度中均占绝对优势。     

渤海湾浮游纤毛虫丰度和生物量的周年变化

为了解渤海湾浮游纤毛虫丰度、生物量和种类组成的周年变化,于2019年7月-2020年6月在渤海湾一个站位进行每月1次共12个航次浮游纤毛虫样品的采集。样品按照Utermöhl方法进行分析,通过倒置显微镜镜检,计算纤毛虫的丰度和生物量。无壳纤毛虫和砂壳纤毛虫出现峰值的时间不同,无壳纤毛虫丰度和生物量均在4月和8月呈现双峰值,砂壳纤毛虫丰度和生物量均在7月出现单峰值。周年砂壳纤毛虫丰度占纤毛虫总丰度的比例平均为(28.6±32.6)%,5-7月较高,均超过50%。共鉴定砂壳纤毛虫6属21种,其中拟铃虫属(Tintinnopsis)种类最多,6-8月砂壳纤毛虫种类数最高。砂壳纤毛虫种类组成呈现明显的周年变化,温度是驱动砂壳纤毛虫群落周年变化的主要环境因子。砂壳纤毛虫群落Shannon指数的平均值为0.95±0.78,Pielou指数的平均值为0.52±0.34,均在6-8月较高。除无壳纤毛虫外,砂壳纤毛虫丰度、纤毛虫总丰度和砂壳纤毛虫丰度占纤毛虫总丰度的比例均与温度、Chl a浓度呈显著的正相关,与盐度呈显著的负相关。     

2013年夏威夷东南部海区表层砂壳纤毛虫的群落结构和分布特征

鉴于东太平洋热带海区表层砂壳纤毛虫和其他微型浮游动物的群落结构资料几乎空白, 我们于2013年8月14日至9月18日在夏威夷东南部海区的23个站位采样调查了表层砂壳纤毛虫群落。23个站位共采集到砂壳纤毛虫22属36种, 均为透明壳种类。各站砂壳纤毛虫种丰富度范围为15-21种, 总丰度范围为4,730-23,693个/m³, 生物量范围为9.60-88.61 μg C/m³。本海区主要优势种为镯形囊坎虫(Ascampbelliella armilla)、斯廷细瓮虫(Steenstrupiella steenstrupii)、薄壳真铃虫(Eutintinnus tenuis)和纤弱细瓮虫(Steenstrupiella gracilis), 这4种主要优势种的口径范围不同。     

福建北部近海浮游动物数量分布与水团季节变化的关系

根据2015—2016年在福建北部近海水域(120.10°E—120.65°E, 26.35°N—27.07°N)夏、秋、冬、春4个季节的海洋生态调查资料, 探讨了该水域浮游动物的数量分布、季节变化及其与水团变化的关系。结果表明, 调查水域浮游动物的平均生物量依次是: 夏季(479.51 mg/m3)>秋季(257.37 mg/m3)>春季(241.86 mg/m3)>冬季(84.05 mg/m3), 平均丰度依次是: 夏季(156.36 ind./m3)>春季(91.57 ind./m3)>秋季(40.34 ind./m3)>冬季(21.82 ind./m3), 生物量和丰度均值都呈现出夏季、秋季到冬季依次减少, 春季增多的趋势, 不同的是秋季生物量均值高于春季, 而丰度均值低于春季。在夏、冬和春三季, 浮游动物的总生物量和总丰度的分布总体较为一致; 而在秋季, 浮游动物的总生物量和总丰度的分布几乎相反。百陶箭虫(Sagitta bedoti)和微剌哲水蚤(Canthocalanus pauper)是影响夏季总丰度分布最主要的种类; 链钟水母(Desmophyes annectens)是影响秋季总丰度分布最主要的种类; 驼背隆哲水蚤(Acrocalanus gibber)、亚强真哲水蚤(Eucalanus subcrassus)和百陶箭虫对冬季总丰度的分布起到了重要影响; 五角水母(Muggiaea atlantica)和微剌哲水蚤是春季占总丰度比例较高的种类。浮游动物数量各季不同分布模式的根本原因是台湾暖流和浙闽沿岸流水团的季节性变化所致。研究结果不仅对了解与评价区域海洋生态系统动态和生物多样性变化具有重要的理论意义, 而且还可以丰富我国近海水域浮游动物的生态特征与水团变化之间的关系。     

长江口及东海春季底栖硅藻、原生动物和小型底栖生物的生态特点

利用Ludox-QPS方法并结合沉积环境因子的综合分析,研究了2011年4月采自长江口及东海10个站位以底栖硅藻、纤毛虫和异养小鞭毛虫为代表的微型底栖生物及小型底栖生物的组成、丰度和生物量、分布及生态特点。结果表明,底栖硅藻的丰度 (5.92 ? 104 ind/10 cm2) 和生物量 (83.29 ?g C/10 cm2) 远高于纤毛虫 (丰度为1036 ind/10 cm2,生物量为3.33 ?g C/10 cm2)、异养小鞭毛虫 (丰度为4451 ind/10 cm2,生物量为2.51 ?g C/10 cm2) 和小型底栖生物 (丰度为1947 ? 849 ind/10 cm2,生物量为49.01? 22.05 ?g C/10 cm2)。在鉴定出的11个小型底栖生物类群中,线虫占小型底栖生物总丰度的90%和总生物量的37%。底栖硅藻生物量在长江口及东海海域呈由近岸向外海逐渐降低的分布特点,而底栖纤毛虫、异养小鞭毛虫及小型底栖生物的分布则正相反。在垂直分布上,76%的硅藻和80%的线虫分布在0–2 cm沉积物表层,仅1%的硅藻和6%的线虫分布在5–8 cm分层。统计分析表明,底栖硅藻的现存量与沉积物中叶绿素a含量呈极显著的正相关,与底层水温度呈弱的正相关;该海域底栖原生动物和小型底栖生物的分布受多个因子而非单一环境因子的共同作用。对比分析表明,长江口及东海单位体积沉积物中的硅藻丰度较水体中的硅藻丰度高2个数量级,沉积物中相当部分的叶绿素a含量可能系底栖硅藻所贡献;表层8 cm沉积物中纤毛虫的丰度约是上层30 m水柱中纤毛虫丰度的30倍,生物量约是后者的40倍。尽管纤毛虫在生物量上远小于小型底栖生物,但其估算的生产力约是后者的3倍;而异养小鞭毛虫由于个体更小,其周转率可能较纤毛虫更高。长江口及东海陆架区原生动物和小型底栖生物的高现存量及生产力预示着其在该海域生态系统中的重要作用。     

夏季南海北部纤毛虫群落组成及其水平分布

在2007年中国科学院南海海洋研究所南海北部开放航次期间,设计了两条纤毛虫采样断面(X断面、Y断面),共13个站位,涵盖了珠江冲淡水区、粤东上升流区和陆坡开阔海区,旨在对纤毛虫的种类组成和空间分布及其影响因素进行探讨。共检出4纲8目22属38种纤毛虫,其中种类数最多的属是砂壳目拟铃虫属(9种),其次是急游目急游属(5种)。本航次中纤毛虫主要是砂壳目纤毛虫(27种),共鉴定出砂壳虫15属27种。纤毛虫优势种为蚤状中缢虫Mesodinium pulex(18.1%),其次是丁丁急游虫Strombidium tintinnodes(9.7%),盾形拟铃虫Tintinnopsis urula(5.8%)。纤毛虫种类数和丰度从近岸向外海逐渐减少,纤毛虫种类数与温度(R2=0.53,P0.05)和盐度(R2=0.43,P0.05)呈负相关,随着温度的升高,纤毛虫种类数逐渐降低。纤毛虫丰度与温度和盐度相关性并不明显,这可能由于受上升流的影响,近岸上升流高盐区存在着纤毛虫丰度较为丰富的情况。叶绿素a浓度与纤毛虫种类数(R2=0.36,P0.05)和纤毛虫丰度(R2=0.36,P0.05)呈正相关,近岸浮游植物生物量高,纤毛虫种类丰富,丰度大,叶绿素a沿纵断面降低,纤毛虫种类数和丰度也降低。     

东、黄海春秋季小型底栖生物丰度和生物量研究

《北斗号》调查船分别于 2 0 0 0年 10月和 2 0 0 1年 4月在 2 6°N至 36°N,12 0°E至 12 6°30′E东、黄海陆架浅水区调查中进行了小型底栖生物的取样。研究表明 ,两个航次 (秋季、春季 )小型底栖生物的平均丰度分别为 6 5 4 .2 5± 4 4 1.72 ind/10 cm2 和342 .0 0± 2 5 2 .0 0 ind/10 cm- 2 ,平均生物量分别为 80 7.0 6± 5 17.89μg dwt/10 cm2 和 2 85 .2 5± 173.72μg dwt/10 cm2 ;平均生产量分别为 72 6 3.5 8± 4 6 6 4 .18μg dwt/(10 cm2· a)和 2 5 6 7.2 8± 15 6 3.5 0 μg dwt/(10 m2· a)。两个航次小型生物的平面分布类似 ,即高密度和高生物量区分布在水深等深浅 5 0 m左右的站位上 ,特别是在长江口以南的浙江沿海。共鉴定出 14个小型生物类群 ,按丰度自由生活海洋线虫是最优势的类群 ,秋、春季两个航次的优势度分别为 87.2 %和 91.2 %。其他优势类群依次为底栖桡足类、多毛类和动吻类 ;按生物量优势依次为多毛类 38.1%～ 5 4 .0 % ,线虫 2 8.3%～ 38.1%和桡足类 9.0 %～ 9.4 %。垂直分布的研究表明 ,91%的小型生物分布在 0～ 5 cm的表层内 ,线虫和桡足类分布在 0～ 2 cm的比例分别为 6 3%和 86 %。相关分析表明 ,小型底栖生物的数量分布与粘土含量 (% )、粉砂粘土含量 (% )和中值粒     

三亚珊瑚礁水域纤毛虫种类组成和数量分布及与环境因子的关系

2004年8月通过对三亚珊瑚礁水域纤毛虫进行表、底层采集分析,共鉴定6纲14目33属58种浮游纤毛虫,其中旋毛纲41种,叶口纲6种,寡膜纲5种,叶咽纲4种,前口纲和伪纤毛纲各1种。在14个目中,以旋毛纲环毛亚纲砂壳目纤毛虫种类最多,达到31种。主要优势种为布氏拟铃虫 Tintinnopsis bütschlii、小拟铃虫 Tintinnopsis minuta、丁丁急游虫Strombidium tintinnodes和具沟急游虫Strombidium sulcatum等,底层纤毛虫数量和种类都较表层高,底、表层平均丰度分别为375个/L和346 个/L,表、底层纤毛虫种类差异明显,表层主要由浮游纤毛虫组成,以旋毛纲环毛亚纲砂壳目纤毛虫为主,急游目纤毛虫次之;而底层主要由缘毛目组成,如长圆靴纤虫 Cothurnia oblonga、透明鞘居虫Vaginicola crystalline、钟虫Vorticella sp.以及吸管目的壳吸管虫 Acineta sp. 等。结果显示,在活珊瑚覆盖率高的站位（S4,S7和S9）纤毛虫数量明显低于珊瑚覆盖率低或没有珊瑚覆盖的站位,这暗示了珊瑚对纤毛虫的摄食作用。典型对应分析结果表明,影响三亚湾海域纤毛虫分布的主要因素有Chla、颗粒悬浮物SS和活性磷,以及水体溶解有机碳含量。通过对纤毛虫数量与环境因子关系的分析表明,三亚湾珊瑚礁水域纤毛虫的数量与叶绿素呈明显的正相关性。     

Abundance and biomass of planktonic ciliates in the sea area around Zhangzi Island,Northern Yellow Sea

We investigated the abundance and biomass of planktonic ciliates in the sea area around Zhangzi Island, Northern Yellow Sea, from July 2009 to June 2010. Ciliates were sampled monthly from surface to bottom with a 10 m depth interval at 13 sample stations along three transects. A 1 L sample of water from each depth was collected with a 2.5 L Niskin water sampler and fixed in 1% acid Lugol’s iodine solution. Water samples were pre-concentrated using the Utermöhl method and observed using an Olympus IX51 inverted microscope at 100× or 200x. The dimensions of the ciliates were measured and the cell volume of each species was estimated using appropriate geometric shapes. The carbon:volume ratio used to calculate biomass was 0.19 pg C/μm³. Abundance and biomass of the ciliate in water column were calculated as the integral of the abundance and biomass from bottom to surface, respectively. The classification of tintinnids was based on taxonomic literature. The average abundance of non-loricate ciliates was 3066 ± 2805 ind/L, ranging from 165 ind/L (50 m depth of St. B6 in July) to 26,595 ind/L (surface of St. C1 in September). The average biomass of non-loricate ciliates was 2.88 ± 2.68 μg C/L, ranging from 0.05 μg C/L (10 m depth of St. A6 in July) to 20.51 μg C/L (surface of St. A5 in August). The average tintinnid abundance was 142 ± 273 ind/L, ranging from 0 ind/L (monthly) to 2756 ind/L (surface of St. A1 in July). The average tintinnid biomass was 0.84 ± 2.19 μg C/L, ranging from 0.00 μg C/L (every month) to 37.64 μg C/L (20 m depth of St. C5 in July). The results showed that the average abundance of total ciliates was 3208 ± 2828 ind/L, ranging from 166 ind/L (10 m depth of St. A6 in July) to 26,625 ind/L (surface of St. C1 in September); the average biomass of total ciliates was 3.73 ± 3.55 μg C/L, ranging from 0.05 μg C/L (10 m depth of St. A6 in July) to 38.29 μg C/L (20 m depth of St. C5 in July). Abundance and biomass were vertically homogeneous in February, November and December, but decreased dramatically from the surface down to the bottom in other months. 23 tintinnid species were identified, 12 of which were in genus Tintinnopsis. Tintinnid species were more abundant in February, July and August. Tintinnids occupied 6.6 ± 10.2% and 19.7 ± 23.3% of the total ciliate abundance and biomass, respectively, which increased during the warm season and at coastal stations, and decreased during the cold season and at offshore stations. Large non-loricate ciliate species were prevalent in spring, while smaller species dominated in summer and autumn. The average abundance of total ciliates in water column was 132 ± 72 × 10⁶ ind/m², with increases during spring and autumn. The average biomass of total ciliates in water column was 152.57 ± 93.10 mg C/m², with increases during spring and summer. The average abundance and biomass of total ciliates in water column were greater at offshore stations than at coastal stations during spring and autumn, and were lower during summer and winter. Non-loricate ciliates, tintinnids and total ciliates showed significant positive correlation with temperature and significant negative correlation with salinity (p < 0.01). Non-loricate ciliates and total ciliates showed significant positive correlation with Chl a concentration (p < 0.01); however, relationship between Chl a concentration and tintinnids was not significant.     

大熊猫胃内纤毛虫检测初报

Twenty three captive giant pandas, fecal specimens and stomach juice from five captive giant pandas(Ailuropoda melanoleuca)were tested for ciliate in 2004. Of them, ciliates of Epdinium spp.and Entodinium spp.were found in the stomach of five giant panda. Density of ciliates in each stomach of giant pandas were 4.21×10 4 ind./ml, 6.98×10 4 ind./ml, 3.05×10 4 ind./ml, 4.46×10 4 ind./ml and 4.38×10 4 ind./ml respectively. But all the fecal specimens were negative.     

The annual cycle of planktonic ciliates in nearshore waters at Signy Island, Antarctica

The abundance and biomass of marine planktonic ciliates in BorgeBay, Signy Island, were determined at monthly intervals betweenApril 1990 and June 1991. At least 24 different ciliate taxawere recorded from samples preserved in Lugol's iodine, includingthe tintinnids Codonellopsis balechi, Cymalocylis convallaria,Laackmaniella naviculaefera and Salpingella sp., and the aloricatetaxa Didinium sp. and Mesodinium rubrum. Ciliate abundance andbiomass exhibited a clear seasonal cycle with high values duringthe austral summer and low values in the austral winter. Abundanceranged from 0.3 10³l^–1 in September to 2.3 10³l^–1in January, while biomass ranged from 0.5 µg C l^–1in October to 12.6 µg C l^–1 in December. Small ciliatesdominated abundance throughout the year, and biomass duringwinter. Larger ciliates contributed most to biomass during summer.Aloricate ciliates were common throughout the year, while tintinnidscontributed substantially to abundance and biomass only duringsummer. Salpingella sp. was the commonest tintinnid, but C.convallariacontributed most to tintinnid biomass. The seasonal patternof ciliate abundance and biomass matched that of chlorophylla concentration and bacterial biomass, suggesting tight trophiccoupling between ciliates and other components of the pelagicmicrobial community. ¹Present address: Scott Polar Research Institute, Universityof Cambridge, Lensfield Road, Cambridge CB2 1ER, UK     

Ciliate community structure, diversity and trophic role in offshore sediments from the Yellow Sea

We investigated the community structure, diversity and trophic role of ciliates in the sediments from 48 stations in the Yellow Sea using Ludox density centrifugation and quantitative protargol stain. The ciliate abundance ranged from 1 to 221cellscm(-3) and biomass from 0.0001 to 0.47μgCcm(-3) in the upper 8cm of the sediments. On average, 77% of ciliate abundance and 81% of biomass were distributed in the 0-2cm sediment layers, while the respective proportions were only about 6% and 3% in the 5-8-cm layers. Among the 198 morphospecies, Prostomatea was the most dominant group accounting for 45% of the total abundance and 58% of the total biomass. Carnivorous ciliates constituted the primary feeding type, occupying about 64% of the total biomass, followed by bacterivores (21%), algivores (12%) and omnivores (3%). The ciliate abundance and biomass in the upper 5cm of sediments were two orders of magnitude higher than those in the upper 10m of the Yellow Sea water column. The estimated ciliate bacterivory and herbivory indicate that ciliate ingestion had little direct influence on bacterial standing stock but possibly had an important impact on diatoms in the sediments from the Yellow Sea.     

舟山渔场及邻近海域浮游动物数量分布特征

依据2006年8月(夏)、2007年1月(冬)、5月(春)和11月(秋)在舟山渔场及其邻近海域(29°30′-31°30′N,124°30′E以西)开展海洋生态系统综合调查时,用浅水Ⅰ型浮游生物网采集的浮游动物样本资料,分析了浮游动物总丰度及中华哲水蚤(Calanus sinicus)、精致真刺水蚤(Euchaeta concinna)、百陶箭虫(Sagitta bedoti)、肥胖箭虫(Sagitta enflata)等主要种类的数量分布和季节变化特征。结果表明:调查海域浮游动物平均丰度季节变化明显,春季(555.87ind./m3)夏季(270.87ind./m3)秋季(138.39ind./m3)冬季(127.70ind./m3);其水平分布呈现南部高、北部低的特点。中华哲水蚤为广温广盐种,春季数量最大且分布均匀,大部分海域丰度≥100.00ind./m3;夏季丰度急剧下降,主要分布在30°00′N以南海域;秋、冬季丰度较低,无明显高密集区。精致真刺水蚤为热带种,以夏、冬季丰度较高,主要分布在沿岸水与外海高盐水交汇区和调查海域的南北两端;春、秋季丰度较低且分布均匀。百陶箭虫、肥胖箭虫分别属于暖水种和热带大洋性种,冬、春季丰度都很低,无明显密集区,夏、秋季丰度较大。百陶箭虫主要分布在盐度梯度较大、外海高盐水与沿岸水的交汇区,肥胖箭虫则主要分布在外海高盐水与沿岸水交汇区的靠高温高盐水一侧,其分布与外海高温高盐水的消长有密切关系,可作为暖流指示种。温盐和水系消长变化是影响舟山渔场及邻近海域浮游动物丰度水平分布的重要因素。