The biology and ecology of lotic nematodes

• 1 Morphological structures for identifying freshwater nematodes, e.g. buccal cavity, sensory receptors, oesophagus, reproductive organs and tail are described.
• 2 Most freshwater nematodes belong to the Adenophorea and are characterised by the presence of setae, adhesive glands and conspicuous amphids.
• 3 Methods for collecting nematodes from the sediments of running water (e.g. corer, pumps), within plants and aufwuchs are listed. Methods for fixation, extracting and preparing nematodes for identification are described.
• 4 Life history parameters (e.g. generation time, eggs per female) are not available for lotic nematodes but are summarised for free‐living nematodes in soil, lakes and seas. Field studies indicate that, in contrast to laboratory experiments with nematode cultures, many species will have a generation time of several months.
• 5 Abundance and species diversity of nematodes of lotic habitats are provided; more than 100 nematode species inhabit lotic habitats and densities can reach 230 individuals per ml.
• 6 Links between meiobenthic nematodes and the micro‐ and macrobenthos are unclear at present. Evidence such as the increased bacterial activity due to nematode grazing suggests that such interactions may be significant.

     

Production of C2 toxin by Alexandrium tamarense CI01 using different culture methods

The dinoflagellate Alexandrium tamarense CI01 wasgrown in three types of cultures: batch culture, semi-continuous culture andtemporary culture, to investigate the effects of different culture methods oncell growth and the productivity of C2 toxin (C2, a paralytic shellfish toxin).In the batch cultures, cells grew in three phases: a short lag phase, anexponential phase with a specific growth rate () of 0.78day^–1 and a relatively long stationary phase. Themaximum toxin productivity was 1.2 mol L^–1 or77 fmol cell^–1 in 9 days. In the semi-continuouscultures, cells grewin response to the dilution cycles, with values being 0.64, 0.32 and 0.35day^–1 for one-day, two-day and three-day cycles,respectively. The toxin yield was about one half of that of the batch cultures.A "temporary" culture method was used to maintain the metabolically activecellsremoved from the semi-continuous cultures, in a nutrient-depleted condition, toachieve a high toxin productivity of 1.0 molL^–1 in 4 days. Thus,the semi-continuous culture method provided an efficient means to generateamounts of metabolically active algal cells. The temporary culture offered aneffective way to produce C2. The highest yields of C2 were obtained in3–4days when the temporary cultures were aerated.     

夏季南黄海冷水团及其周边海域小型底栖动物类群组成与分布

对2011年6月南黄海冷水团及其周边海域23个站位的小型底栖动物类群组成、丰度、生物量和空间分布及其与环境因子的关系进行了研究。结果表明,调查海域共鉴定出小型底栖动物20个类群,平均丰度为(1194±873)个/10 cm~2,平均生物量为(881±669)μg干重/10 cm~2,其中自由生活海洋线虫是绝对优势类群,占小型底栖动物总丰度的89.7%,其次为底栖桡足类(5.5%)、甲壳类幼体(1.8%)、多毛类(1.2%);对生物量的贡献上依次为海洋线虫(49.0%)、多毛类(22.9%)、桡足类(13.9%)、介形类(7.8%)、涡虫(2.0%)。在垂直分布上,79.1%的小型底栖动物分布在沉积物0—2 cm的表层,16.4%分布在2—5 cm的次表层,4.5%的小型底栖动物分布在5—8 cm的下层。与环境因子的相关性分析表明,小型底栖动物的总丰度和总生物量与沉积物叶绿素a含量显著正相关;小型底栖动物的生物量和沉积物中部分重金属(Pb、Cu、Fe、Ni、Co)含量呈显著负相关,但与Cd含量呈极显著正相关。BIOENV分析结果表明,沉积物含水量、有机质含量和分选系数组合最能解释小型底栖动物类群组成分布差异。根据小型底栖动物的类群组成可将研究海域划分为3个区域,包括:冷水团中央区域,冷水团边缘区和近岸区,其中冷水团边缘区丰度和生物量最高,冷水团区域次之,近岸区最低;整个冷水团海域小型底栖动物丰度和生物量分别是非冷水团海域的2.3倍和2.1倍。     

First records of Gastrotricha from South Africa, with description of a new species of Halichaetonotus (Chaetonotida, Chaetonotidae)

During a survey of the biota of the St. Lucia Estuary in the iSimangaliso Wetland Park, South Africa, a number of Gastrotricha were found among samples of meiofauna. Fresh, marine sediment yielded several specimens belonging to a total of seven species. Of these, two are already known from other regions (i.e., Dactylopodola australiensis and Heteroxenotrichula squamosa), one is described as new to science (Halichaetonotus sanctaeluciae sp. n.), while the remaining four (Pseudostomella sp., Halichaetonotus sp.1, Halichaetonotus sp. 2, Xenotrichula sp.) require further collections and analysis, in order to establish the extent of their affiliation to species already described. General appearance, shape of hydrofoil scale and the occurrence of three long spines on the dorsal side make the new species most closely related to Halichaetonotus australis and Halichaetonotus marivagus. The key differences from these taxa and between Halichaetonotus sanctaeluciae sp. n. and Halichaetonotus aculifer are discussed.     

Feeding response of a benthic copepod to ciliate prey type,prey concentration and habitat complexity

1. Protozoans are important consumers within microbial food webs and, in turn, they represent potential prey for small metazoans. However, feeding interactions within these food webs are rarely characterised and this is especially true for freshwater sediments. 2. We aimed to quantify the feeding links between a freshwater meiofaunal copepod and ciliates in two laboratory experiments. The first experiment addressed the response of Eucyclops serrulatus towards ciliate density and type (two ciliate species of the same genus differing in terms of body size). A second experiment assessed the effect of habitat structure on feeding rates by introducing different structural complexity into the feeding arena. In contrast to the first experiment, which was run only for one time period, this experiment also tested three different total feeding times (4, 7 and 9 h). 3. Eucyclops serrulatus exhibited high ingestion rates, with 3–69 ciliates copepod^?1 h^?1 consumed depending on food concentration, food type and habitat complexity. Copepods exhibited a preference for the smaller ciliate when total ciliate concentration was low, but selected both ciliates equally when food concentrations were medium or high. However, at very high food concentration, Eucyclops preferred the larger ciliate (which was 1/3 of its own body size), suggesting that the longer handling times of the larger prey are rewarding when the large prey is present in high numbers. In terms of total numbers consumed, copepods fed on more small ciliates, but in terms of carbon units both ciliates were selected equally when total prey concentration was low or medium. However, copepods derived more carbon from the larger prey at high and very high prey concentrations (up to 0.7 μgC out of a maximum of 1.1 μgC copepod^?1 h^?1). Habitat complexity influenced the feeding of copepods when it was observed over time. 4. The copepod–ciliate link is well known from the pelagic zone of both marine and freshwater habitats. We have shown its potential importance within the benthos, where it can be influenced by food identity, food quantity and possibly by habitat complexity.     

Future ocean climate homogenizes communities across habitats through diversity loss and rise of generalist species

Predictions of the effects of global change on ecological communities are largely based on single habitats. Yet in nature, habitats are interconnected through the exchange of energy and organisms, and the responses of local communities may not extend to emerging community networks (i.e., metacommunities). Using large mesocosms and meiofauna communities as a model system, we investigated the interactive effects of ocean warming and acidification on the structure of marine metacommunities from three shallow‐water habitats: sandy soft‐bottoms, marine vegetation, and rocky reef substrates. Primary producers and detritus—key food sources for meiofauna—increased in biomass under the combined effect of temperature and acidification. The enhanced bottom‐up forcing boosted nematode densities but impoverished the functional and trophic diversity of nematode metacommunities. The combined climate stressors further homogenized meiofauna communities across habitats. Under present‐day conditions metacommunities were structured by habitat type, but under future conditions they showed an unstructured random pattern with fast‐growing generalist species dominating the communities of all habitats. Homogenization was likely driven by local species extinctions, reducing interspecific competition that otherwise could have prevented single species from dominating multiple niches. Our findings reveal that climate change may simplify metacommunity structure and prompt biodiversity loss, which may affect the biological organization and resilience of marine communities.