凡纳滨对虾健康状态分化前后养殖水体浮游细菌群落的比较

养殖水体浮游细菌群落与对虾健康状态息息相关.本研究基于16S rRNA高通量测序技术手段比较了凡纳滨对虾病害发生前后病害趋向塘与健康塘的浮游细菌群落多样性、组成及关键类群互作关系的动态变化.结果表明:对虾发病前,病害趋向养殖水体浮游细菌群落Shannon指数显著低于健康养殖水体,且呈现持续下降的趋势;伴随疾病爆发,病害趋向养殖水体浮游细菌群落结构离散程度显著增大,群落稳定性较差;发病前,病害趋向塘养殖水体中绿弯菌门、δ-变形菌纲和Saccharibacteria平均相对丰度均显著高于健康水体,而拟杆菌门显著低于健康水体;部分病害指示OTU隶属于弧菌科及黄杆菌科,隶属于红杆菌科的OTU1是发病前健康塘的健康指示OTU.网络分析表明,大多数与OTU1存在相互作用的指示OTUs属于黄杆菌科,说明黄杆菌科在对虾养殖水体浮游细菌群落中扮演重要角色.鉴于以上结果,对虾发病可能与多种浮游细菌群落相关,当出现“生态位机会”时,条件致病菌快速繁殖进而导致对虾发病,而保持和恢复细菌群落平衡可以成为预防对虾发病的有效策略.     

对虾养殖围隔生态系统浮游细菌的呼吸与生产

The study on the respiration and production of bacterioplankton in five shrimp cultural enclosure ecosystems showed that the production and respiration fluctuated from 90 to 909 and 248 to 1785 μgC· L^-1. d^-l, respec-tively. There existed a significant positive relationship between production and respiration. The daily P/B ratio of bacterioplancton averaged 0.93 d^-l, and its production efficiency averaged 0.34.     

浙江近海海域浮游病毒和异养细菌的时空分布

为了解浙江近海海域浮游病毒和异养细菌的时空生态分布, 于2014 年11 月(秋)、2015 年1 月(冬)、2015 年5 月(春)和2015 年7 月(夏)连续4 个季节采集了浙江近海海域表层海水样品, 采用流式细胞仪技术对样品浮游病毒和异养细菌丰度进行了检测, 对其时空分布特征及与环境因子的相关性做了分析。从水平分布来看, 在4 个季节中浮游病毒、异养细菌丰度均为宁波、沈家门、岱山等沿岸海域站位的丰度低, 远陆海域东极和枸杞站位的丰度高。从季节变化来看, 浮游病毒、异养细菌丰度的季节分布特征同为夏>春>秋>冬, 相关性分析结果表明, 春、夏、秋、冬4 个季节, 浮游病毒丰度与异养细菌丰度均为显著正相关。浮游病毒丰度在春、秋、冬季节均与病毒/细菌比值(VBR)显著正相关; 夏、秋季节均与盐度显著正相关; 春、夏季节均与总磷显著负相关; 春季分别于与溶解氧、pH、化学耗氧量(COD)显著正相关。异养细菌在春、秋、冬季节均与VBR 显著正相关; 春、夏季节与溶解氧显著正相关, 冬季与溶解氧显著负相关; 春、夏季节与总磷显著负相关; 秋、冬季节均与温度、盐度显著正相关; 春、冬季节均与COD 显著正相关。     

凡纳滨对虾低盐度高产虾池环境微生物生态研究

对广东珠三角地区,凡纳滨对虾低盐度高产虾池环境微生物调查结果,养殖水体异养菌平均数量为5.15×10⁴cfu·mL^-1,致病性弧菌为5.00×10³cfu·mL^-1,池底泥浆中异养细菌平均数量为2.41×10⁶cfu·mL^-1,致病性弧菌为1.45×10⁵cfu·mL^-1。不同虾池异养细菌的数量差别小而稳定,致病性弧菌的数量差别及波动大。淤泥较深的老化虾池,水体和泥浆中异养细菌平均分别为6.10×10⁴cfu·mL^-1和2.89×10⁶cfu·mL^-1,致病性弧菌为6.00×10³cfu·mL^-1和2.14×10⁵cfu·mL^-1;无淤泥虾池水体和泥浆中异养细菌平均分别为4.53×10⁴cfu·mL^-1和2.08×10⁶cfu·mL^-1,致病性弧菌为4.34×10³cfu·mL^-1和9.86×10⁴cfu·mL^-1。老化虾池底泥致病性弧菌明显偏高,成为老化虾池易爆发虾病的重要原因。低盐度虾池水体异养菌和致病性弧菌的数量变化,表现为养殖前期高,中后期低而稳定;池底泥浆中异养菌和致病性弧菌的数量变化,呈不规则波动。高的养殖水温对养殖环境异养菌和致病性弧菌表现抑制作用,养殖环境微生物与水体浮游藻类也有一定的关系。     

池塘分区养殖系统对水质和浮游植物群落结构的影响

通过对虾池塘内浮游植物群落结构的生态学特征指标进行连续采样监测, 研究分区养殖系统对于虾塘水质和浮游植物群落组成的影响。采用进排水管和水泵将虾塘和鱼塘相连, 通过泵出虾塘底层水和回流鱼塘上层水实现水体流动。分区组(R)由对虾单养塘和鱼类混养塘组成, 对照组(C)为对虾单养塘, 监测时间为30 天。结果显示: 通过定期循环处理可使对虾养殖池塘内总悬浮颗粒物(TPM)、颗粒有机物(POM)含量分别降低36%-45% 和15%-20%。R 组虾塘水质改善, 溶解态活性磷含量(PO₄–P)增加, 显著高于C 组(P<0.05); 实验结束时R 组虾塘NH4⁺–N 含量显著低于C 组(P<0.05)。实验期间, R 组浮游植物种类多于C 组, 均表现为绿藻门>蓝藻门>硅藻门>裸藻门; R 组蓝藻生物量低于C 组, 尤其C 组具有较高比例的颤藻。实验结束时, R 组绿藻门的优势度明显高于C 组(P<0.05); R 组浮游植物的香农多样性指数(2.91)略高于C 组(2.62)(P>0.05)。实验期间, 2个处理组浮游植物群落的Margale 丰富度指数均逐渐升高, 并且R 组在第20、30 d 高于C 组(P<0.05)。结果表明: 分区养殖可以通过减少颗粒物而改善水质, 水体流动可以加速含磷物质释放。水体流动和较低的N/P 可能有助于提高虾塘内绿藻种类优势度而减少蓝藻发生, 并且在提高浮游植物种类多样性以及丰富度方面具有积极作用。     

海水和淡化水养殖凡纳滨对虾饲料蛋白需求量的比较研究

本研究从生长、饲料利用和体成分等指标综合评价饲料蛋白质含量对凡纳滨对虾的影响。研究发现,在海水养殖环境下,饲料蛋白水平对凡纳滨对虾的存活率、增重率、特定生长率、饵料系数、蛋白效率和虾体粗蛋白含量均有显著性影响(p<0.05)。摄食饲料蛋白含量38%的海养凡纳滨对虾有较高的存活率、增重率以及最高的特定生长率。饵料系数随蛋白含量的增加而减小,虾体粗蛋白含量随饲料蛋白水平升高而增加,而蛋白含量38%和41%实验组饵料系数和虾体粗蛋白含量均没有显著性差异(p>0.05)。淡化水养殖条件下,凡纳滨对虾的存活率随饲料蛋白水平的增加而提高,而增重率和特定生长率均在饲料蛋白含量35%实验组最高,饵料系数随蛋白含量的增加先减小后增大,蛋白含量35%实验组饵料系数显著小于其他实验组。海水养殖条件下,凡纳滨对虾的存活率、末体重、增重率、特定生长率和蛋白质效率均高于淡水养殖的对虾。对虾虾体粗蛋白、粗脂肪和粗灰分含量均随盐度升高而升高,而虾体水分随着盐度的升高而降低。     

水下LED 光照对凡纳滨对虾养殖水体环境因子和浮游植物群落变化的影响

为了研究水下LED 光照对凡纳滨对虾养殖环境的影响, 从2013 年5 月到12 月对架设水下LED 光源和未加光源的养殖池塘进行水质和浮游植物样品的分析。结果显示, 在有水下LED(LED 组)和未装光源(对照组)的养殖池塘内温度、碱度、pH、透明度、总悬浮物、溶解氧、硅酸盐和磷酸盐变化趋势均相似。养殖前期LED 组和对照组各项指标变化相似。在养殖中期LED 组的叶绿素a 含量高于对照组, 说明水下LED 有助于提高微藻生物量的积累。同时养殖中期LED 组的浮游植物群落的多样性指数和均匀度指数高于对照组, 说明水下LED 光照有助于提高浮游植物群落稳定性。而在养殖后期LED 组的硝酸盐和亚硝酸盐的含量低于对照组, 说明水下LED 光照有助于水质的稳定。养殖周期内LED 组和对照组优势种变化趋势体现为前期蓝藻-绿藻-硅藻, 中期蓝藻-绿藻(少量)和后期蓝藻-绿藻。     

施用生石灰对精养池塘浮游细菌群落结构和多样性的影响

为研究施用生石灰对池塘浮游细菌群落结构和多样性的影响,采用基于16S rRNA的高通量测序技术比较分析了施用生石灰前后精养池塘浮游细菌群落结构和多样性差异。研究结果显示,施用生石灰进行处理1d后,池塘优势浮游细菌在门和属水平上均与施用前相同,但相对丰度产生变化。在门水平上,蓝细菌门（Cyanobacteria）的相对丰度由53.80%显著降低至47.57%,拟杆菌门（Bacteroidetes）的相对丰度由7.00%显著降低至5.24%,变形菌门（Proteobacteria）的相对丰度由19.72%显著降低至17.60%,而放线菌门（Actinobacteria）的相对丰度由6.76%显著上升至13.47%,浮霉菌门（Planctomycetes）的相对丰度由8.24%显著上升至11.10%。另外,在属水平上,分枝杆菌属（Mycobacterium）的相对丰度由0.73%显著降低至0.49%,浮丝藻属（Planktothrix）的相对丰度由0.041%显著降低至0.0074%。施用生石灰后池塘浮游细菌群落的物种丰富度指数（ACE和Chao 1）和Shannon多样性指数均显著提高,且Simpon指数显著降低（P < 0.05）。研究结果可为施用生石灰管理池塘水质和进行疾病预防提供理论解释,并可为更加科学合理地利用生石灰管理池塘提供科学指导。     

环境、病原、免疫因子三要素与池塘养殖对虾AHPND发生的关联性

为研究虾急性肝胰腺坏死病(Acute Hepatopancreas Necrosis Disease,AHPND)的发生与环境、病原和虾体免疫间的相互关系,文章对池塘养殖凡纳滨对虾(Litopenaeus vannamei)AHPND发生及其环境、病原、虾体免疫因子进行持续性跟踪监测。结果表明,试验点的气温、水温、溶解氧(DO)、pH、盐度、氨氮(NH₄-N)和亚硝态氮(NO₂-N)波动范围为21—29℃、24.8—31℃、1.4—8.32 mg/L、8—8.91、34—50、0.01—0.26 mg/L和0.005—0.212 mg/L;水体可培养细菌和弧菌数量变化范围为3×10³—2.4×10⁵和2×10²—1.8×104 CFU/mL,虾体肝胰腺内可培养细菌和弧菌数量变化范围为9.8×10⁴—8.8×10⁶和3.9×10³—3.61×10⁶ CFU/g;16S rDNA鉴定结果显示,在...     

凡纳滨对虾生物絮团养殖系统中不同生境细菌群落特征

【目的】凡纳滨对虾生物絮团养殖系统(biofloc-based culture system, BFS)是一种基于培育和调控微生物群落的新型生态养殖模式。然而,目前对于BFS在不同生境中的微生物群落特征及其构建过程还不清楚。【方法】采用16S rRNA基因测序技术探究BFS在3种不同生境(水体、絮团和对虾肠道)的细菌群落组成;通过溯源分析和中性模型等方法,探究不同生境细菌群落的特征及其构建过程。【结果】3种生境的微生物群落多样性和组成具有显著性差异,絮团和对虾肠道的群落结构和组成最为相似,溯源结果显示对虾肠道有98.76%的细菌类群来自絮团,仅有0.83%的细菌类群来自水体;3种生境共有的细菌主要为鲁杰氏菌(Ruegeria),在水体、絮团和对虾肠道中的丰度分别为1.72%、7.34%和6.00%,水体中特有的扩增子变异序列(amplicon sequence variants, ASV)数量为89个,主要属于海茎状菌(Maricaulis)和欧文威克斯菌(Owenweeksia),絮团中有56个,主要为莱茵海默氏菌(Rheinheimera),而对虾肠道中仅有10个,主要属于玫瑰杆菌(Roseobacter);中性模型结果表明,水体、絮团和对虾肠道细菌群落构建均符合中性模型,表明3种生境中细菌群落构建均受中性过程主导。【结论】在BFS系统中,不同生境的微生物群落具有显著差异,对虾肠道细菌主要来自生物絮团,而3种生境的细菌群落构建过程由中性过程主导。这些结果为调控生物絮团养殖系统中微生物群落提供了理论依据。     

高位虾池养殖过程浮游植物群落的演替

通过对湛江东海岛北寮村和庵里村各2个高位虾池养殖过程的浮游植物演替和主要理化因子进行调查,研究浮游植物群落的演替过程对高位虾池的健康养殖的影响.结果表明:4池共检出浮游植物7门76属140种;对虾生长正常的北寮高位虾池演替优势种主要有螺旋环沟藻、椭圆扁胞藻、海链藻、湖泊束球藻密胞变种、裸甲藻、卵囊藻、微囊藻、锥形斯克里普藻、色球藻和尖尾蓝隐藻等,而对虾发病的庵里高位虾池演替优势种主要有铜绿微囊藻、柔弱布纹藻、咖啡形双眉藻、小席藻、卷曲鱼腥藻、水生集胞藻、衣藻、尖尾蓝隐藻和螺旋环沟藻等,北寮正常虾池浮游植物种类(包括优势种)较对虾发病的庵里虾池多而复杂;对虾生长正常池优势种的演替快而门类交替,而对虾发病池呈现硅藻到蓝藻优势的演替;对虾生长正常池浮游植物密度随养殖过程延伸呈上升态势,而对虾发病池浮游植物密度初期增加病害后下降;养殖过程浮游植物密度与主要理化因子的相关关系不显著;对虾生长正常的北寮高位池多样性指数与均匀度高于对虾发病的庵里高位池,而优势度却较低.水体理化因子变化平缓,浮游植物有较高的多样性指数和均匀度、较低的优势度对于稳定虾池养殖水环境有重要作用.     

微生物制剂对斑节对虾亲虾池异养细菌的影响

研究了施用10 mg·kg-1光合细菌以及1、2和3 mg·kg-1芽孢杆菌制剂对斑节对虾亲虾培育池水体异养细菌和弧菌数量的影响.结果表明:在试验初期,试验组和对照组水体总异养细菌和弧菌数量都明显上升;试验后期,试验池水体异养细菌和弧菌数量均明显下降,明显低于对照池;施用10 mg·kg-1光合细菌能显著抑制亲虾池水体异养细菌的生长(P＜0.01);施用3 mg·kg-1芽孢杆菌对亲虾池水体弧菌数量的抑制效果最好(P＜0.01).     

Changes in cell volume of bacteria and heterotrophic nanoflagellates in a hypereutrophic pond

Changes in cell volume of planktonic bacteria and heterotrophic nanoflagellates (HNF) were examined in a hypereutrophic pond from April to October, 1997. There were marked changes in the abundance of bacteria, HNF and ciliates and in protistan bacterivory during this period. The cell volume of free-living bacteria (0.121 ± 0.031 m³, mean ± SD) was large relative to that reported in the literature. The cell volumes of HNF was 71.1 ± 24.8 m³. Both cell volumes did not follow a seasonal trend. The dominant size class of bacteria was seasonally variable, whereas density of filamentous bacteria was relatively high between August and September. Biomass of filamentous bacteria accounted for up to 33.6% of total bacterial biomass. A correlation analysis for cell volume of bacteria and HNF, density of filamentous bacteria and some microbial variates was performed. The positive correlations detected (p<0.05) were between density of bacteria and cell volume of HNF, and between density of filamentous bacteria and cell volume of HNF.     

Seasonality of phytoplankton in northern tundra ponds

Thermokarst ponds are the most abundant type of water body in the arctic tundra, with millions occurring in the coastal plains of Alaska, Northwest Territories and Siberia. Because ice covers of at least 2 m in thickness are formed at these latitudes, tundra ponds freeze solid every winter As a result, the growing season is shortened to a range of 60 to 100 days, during which time the photoperiod is altered to a prolonged light phase. Tundra ponds are generally close to neutral in pH and low in ions, contain dissolved gases near saturation and are nutrient poor. In low arctic ponds there are two phytoplankton biomass and primary production peaks, whereas they may be only one in the high arctic. Nanoplanktonic flagellates of the Chrysophyceae and Cryptophyceae dominate the maxima. The mid-summer decline in phytoplankton in the low arctic can be attributed to a combination of phosphorus limitation and heavy grazing pressure. The cryptomonad Rhodomonas minuta Skuja is one of the most widespread phytoplankters in tundra ponds. Because of the altered photoperiods, many species do not form resting spores prior to ice formation but survive freezing in the vegetative state.     

不同类型虾池的理化因子及浮游植物群落的调查

于2001年10月和2002年4月两次调查分析了高位池、低位池两种类型的南美白对虾养殖池的理化因子及浮游植物群落的特征.结果表明:低位池的营养盐浓度普遍高于高位池,而高位虾池的盐度则高于低位.盐度是影响两类虾池浮游植物群落特征的主要因素.盐度较小(<5)的养殖池中,蓝藻占优势,主要为微囊藻、平裂藻、水花束丝藻、色球藻等;盐度介于10～30的池中,硅藻占优势,主要为舟形藻、桥弯藻等.     

Dynamics of bacterial communities and qualitative evolution of heterotrophic bacteria during the growth and decomposition processes of phytoplankton in an experimental marine ecosystem

The fluctuations of the bacterial number and the qualitative composition of heterotrophic bacteria were investigated using an experimental marine ecosystem (AME) of 7001, attempting to produce Euterpina acutifrons (Dana) from a monoxenic culture of Phaeodactylum tricorntum Bohlin. During the complete cycle of the system, installation phase, algae growth phase, algae decomposition phase, the bacterial communities homeostasis was tested using aliquots of the AME, severely disturbed via amino acids enrichment. In three identical batches, the bacterial populations showed similar quantitative and qualitative evolutions which all depended on the nature (phytoplanktonic exudates or dead cells) of the carbonaceous compounds from photosynthetic origin. If bacterial communities stayed in a diversified state of organization, considering the physiological and nutritional diversity, quick evolutions were demonstrated.     

Response of bacteria and phytoplankton to contaminated sediments from Trenton Channel,Detroit River

Several types of bioassays were used in 1986 and 1987 to investigate the effect of contaminated sediments on natural populations of bacteria and phytoplankton from the Trenton Channel, Detroit River. The approach included the measurement of uptake of ³H-glucose or ³H-adenine by bacteria and ¹⁴C-bicarbonate by phytoplankton in the presence of different amounts of Trenton Channel and Lake Michigan (control) sediments. Trenton Channel sediments are contaminated by high levels of toxic organic compounds and metals, especially zinc, lead, and copper. Because levels of biomass of bacteria and phytoplankton varied widely among the different bioassays, it was necessary to adjust uptake rates for biomass. Biomass adjustments were made using acridine orange counts for bacteria and chlorophyll measurements for phytoplankton. The results show a statistically significant suppression of uptake of substrates for both bacteria and phytoplankton with increasing amounts of sediment. Uptake was suppressed as much as 90 percent for bacteria and 93 percent for phytoplankton at 1200 mg l^-1 of Trenton Channel sediments compared to bioassays without sediment. Uncontaminated Lake Michigan sediment suppressed uptake much less than Detroit River sediment; the difference in suppression of uptake between the two types of sediment was statistically significant for both bacteria and phytoplankton.Contribution No. 518 of the Center for Great Lakes and Aquatic Sciences of the University of Michigan.     

Mutualistic relationships between phytoplankton and bacteria caused by carbon excretion from phytoplankton

For the competition system of phytoplankton and bacteria through inorganic phosphorus, our mathematical model showed that mutualistic relationships between them could occur due to production and consumption of extracellular organic carbon by phytoplankton and bacteria. In our model, phytoplankton are limited in their growth by light and phosphorus, and bacteria are limited in their growth by phosphorus and carbon released from phytoplankton. We adopted permanence as a criterion of the coexistence in mathematical analysis, and led necessary conditions of permanence in the model. Under these coexistence conditions, we estimated the strength of total effects of interactions between phytoplankton and bacteria at the steady state by press perturbation method. The results of this estimation indicated the mutualistic interactions between phytoplankton and bacteria. This suggests that mutualistic situation could occur due to the introduction of carbon flow from phytoplankton to bacteria, even if phytoplankton and bacteria compete with each other through common resource, inorganic phosphorus.     

Grazing of bacteria and phytoplankton by heterotrophic nanoflagellates in a Baltic Sea sample

Grazing by heterotrophic nanoflagellates on bacteria and phytoplankton was studied in a laboratory experiment, using a natural pelagic community originating from the Tvärminne sea area off the southern coast of Finland. Water was prescreened to remove larger grazers. Four experimental treatments were used: light and dark, with and without added nutrients. The growth of the large heterotrophic flagellates was stimulated by increased production of < 3 m phytoplankton. Clearance rates for heterotrophic nanoflagellates were estimated and were found to be within the range of previously reported values.