Isolation of polyhydroxyalkanoate-producing bacteria from an integrated-farming pond and palm-oil mill effluent ponds

Bacterial isolates from two environments, an integrated-farming pond in the university and palm-oil mill effluent (POME) ponds at a local palm-oil-processing factory, were screened for polyhydroxyalkanoates (PHAs). Initially Sudan Black B staining was performed to detect lipid cellular inclusions. Lipid-positive isolates were then grown in a nitrogen-limiting medium containing 2% (w/v) glucose to promote accumulation of PHA before the subsequent Nile Blue A staining. The PHA extracted from positive isolates was confirmed by nuclear magnetic resonance (NMR) spectroscopy. The proportion of PHA-positive bacterial isolates was higher in the POME ponds compared to the integrated-farming pond.     

海蜇-对虾-蛤仔综合养殖池塘的食物网

为了研究海蜇-对虾(中国明对虾、斑节对虾)-菲律宾蛤仔海水综合养殖池塘养殖生物的食性、营养级和池塘食物网结构,在2017年5—9月的养殖周期内,采集并检测池塘内各种饵料和4种养殖生物的碳、氮稳定同位素比值(δ¹³C、δ¹⁵N),并运用IsoSource线性混合模型分析了海蜇、中国明对虾、斑节对虾和菲律宾蛤仔的食物来源。结果表明: 海蜇的主要食物来源为浮游动物;中国明对虾和斑节对虾的主要食物来源为投喂的鯷鱼;菲律宾蛤仔的主要食物来源为浮游植物、底栖硅藻和对虾粪便。综合养殖池塘中菲律宾蛤仔的营养级范围为2.64～2.95,平均值为2.84;海蜇的营养级范围为2.78～3.27,平均值为3.06;斑节对虾的营养级范围为3.03～3.54,平均值为3.25;中国明对虾的营养级范围为3.76～4.40,平均值为3.95。在综合养殖池塘中,菲律宾蛤仔为初级消费者,海蜇为次级消费者,中国明对虾和斑节对虾为捕食者;菲律宾蛤仔在滤食两种对虾粪便的同时一定程度上改善了养殖池塘的水质。     

Temporal variations and pond age effect on plankton communities in semi-intensive freshwater marron (Cherax cainii,Austin and Ryan, 2002) earthen aquaculture ponds in Western Australia

The abundance and diversity of the plankton community represents the health of the aquatic ecosystem, and plays an important role in the growth of cultured animals under aquaculture conditions. The temporal variations of plankton abundance, taxonomic composition, diversity, evenness and species richness were studied in three old and three new semi-intensive marron (Cherax cainii, Austin and Ryan, 2002) ponds. Water parameters such as temperature, dissolved oxygen, pH, turbidity, TAN, nitrite, nitrate and reactive phosphate were recorded, and plankton samples were collected every two months, for one year of juvenile production cycle. A total of twenty-six phytoplankton and seven zooplankton genera were recorded. Chlorophyceae was the dominant class of phytoplankton throughout the year, followed by Trebouxiophyceae. Rotifera comprised 49.8% of the total zooplankton community (individuals L^?1), the largest proportion of any group. Temporal variations impacted the plankton abundance and community structure, and plankton abundance were more abundant during summer. The pond age did not influence the phytoplankton abundance, whereas zooplankton abundance was higher in older ponds.     

Fluctuating water levels control water chemistry and metabolism of a charophyte‐dominated pond

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The contrasting effects of short‐ and long‐term habitat drainage on the population dynamics of freshwater turtles in a human‐dominated landscape

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An effective method for ecosystem‐scale manipulation of bird abundance and species richness

Manipulation experiments are a cornerstone of ecological research, but can be logistically challenging to execute—particularly when they are intended to isolate the ecological role of large, vagile species, like birds. Despite indirect evidence that birds are influential in many ecosystems, large‐scale, multi‐year bird manipulation experiments are rare. When these studies are conducted, they are typically realized with caged or netted exclosures, an approach that can be expensive, risky for wildlife, and difficult to maintain. In cases where caged exclosures are not appropriate, alternate approaches are needed to allow rigorous empirical studies on the ecological role of birds. Here, we present and validate a method for experimentally increasing the abundance and richness of birds at the scale of entire aquatic ecosystems. Unlike bird exclusion, this approach is experimentally tractable, appealing to land managers, and possible to deploy over large spatial scales. We tested the efficacy of our approach for increasing bird abundance and species richness at 16 central California ponds. Based on bird visitation data obtained by summer camera trapping, our approach significantly increased bird species richness and abundance at manipulated ponds compared to control ponds. Attractant treatments mitigated the negative effects of a major drought on bird species richness and generated a near doubling of bird abundance in the presence of attractants. Treatments had no effect on most mammal species, with the exception of ground squirrels, which increased in abundance in the presence of attractants. These results suggest that attractants are effective in increasing bird abundance and richness. We encourage researchers to consider this approach for experimentally isolating the ecological role of birds in aquatic and open terrestrial ecosystems, especially in cases where cost or logistical constraints preclude the use of caged or netted exclosures.     

莲虾共作池塘夏季浮游植物群落及其与环境因子关系

为研究莲虾共作生态系统夏季浮游植物的群落结构特征,于2018年6月至8月对洪湖莲虾共作池塘的浮游植物和水质进行了定量调查监测,并探讨了浮游植物群落结构变化与环境因子之间的关系。结果显示,共鉴定有浮游植物7门71种属,其中绿藻门种类最多,蓝藻门和硅藻门种类次之,三者共占浮游植物总种类数的83.1%。浮游植物优势种有8种,以蓝藻门和绿藻门为主。莲虾共作池塘夏季浮游植物密度和生物量分别变化在2.50×10⁶~6.20×10⁷ cells/L和0.93~24.36 mg/L之间,浮游植物密度总体表现为逐渐升高的趋势,而浮游植物生物量为先升高后降低的趋势,且浮游植物各门的密度、生物量月份间差异不显著(P>0.05)。浮游植物Shannon-Wiener指数和Pielou均匀度指数均以7月最高出现峰值,不具有明显的月份差异(P>0.05);夏季各月的浮游植物多样性指数均较好,表明莲虾共作池塘浮游植物群落结构处于较稳定的状态。冗余分析（RDA）显示养殖期间的浮游植物物种密度受水温（WT）、总氮（TN）、氨氮（NH₄ ⁺—N）、高锰酸钾指数（COD_Mn）等多种环境因子的影响,而影响莲虾共作池塘各月浮游植物分布的关键环境因子是WT、NH₄ ⁺—N、TN。     

亚热带河口养殖塘沉积物有机碳矿化及其影响因子

亚热带河口的养殖塘是温室气体二氧化碳(CO2)的重要排放源,但其沉积物有机碳矿化动力学特征目前尚未厘清.以我国东南沿海亚热带闽江、木兰溪以及九龙江河口区的6个凡纳滨对虾(Penaeus vannamei)养殖塘为研究对象,对沉积物取样,并进行为期60 d的室内厌氧培养,对养殖塘沉积物CO2累积产量曲线利用一阶动力学模型...     

Species diversity in native fish community in Japan: comparison between non-invaded and invaded ponds by exotic fish

The relationship between invasions by two exotic fishes (Micropterus salmoides and Lepomis macrochirus) and species diversity in native fish communities was studied in 14 Japanese farm ponds. We found that mean number of species in native fish communities was three times higher in the ponds without the exotic fish than in the ponds with them. Further, negative relationships were observed between abundance of the two exotic fish and the total abundance of native fish communities. Our results suggest that invasions by the two exotic fish caused serious depletion of native fish communities, although another process can also be considered , that is, that ponds with poor native fish communities were prone to colonization by these exotic fish.