光合细菌菌剂和沼泽红假单胞菌对实验水体氮磷营养盐和微生物群落的影响

为比较光合细菌菌剂与沼泽红假单胞菌(Rhodopseudomonas palustris)的生理生态特性,分析了不同初始菌量的菌剂PG和菌株PSB-1对实验水体氨氮(NH_4~+-N)、亚硝氮(NO_2~--N)、硝氮(NO_3~--N)和活性磷(PO_4~(3-)-P)的降解效果,通过高通量测序分析了菌剂PG的优势菌组成及实验结束时水体细菌数量和微生物群落组成。结果显示,菌剂PG组对实验水体的PO_4~(3-)-P、NO_3~--N和NO_2~--N有一定的降解作用,其最大降解率分别为40.98%、28.28%和20.12%。菌株PSB-1组仅对实验水体的NO_2~--N和PO_4~(3-)-P有一定的降解效果,其最大降解率分别为14.19%和9.88%。菌剂PG的主要优势菌为红假单胞菌属(Rhodopseudomonas sp.)。实验7 d后实验组水体细菌数量和微生物群落结构发生变化,水体细菌数量增长,形成以异养细菌为优势菌的菌群结构。结果表明光合细菌菌剂PG对水质因子的降解效果优于沼泽红假单胞菌PSB-1,但与报道的高效光合细菌菌株的降解能力存在一定差距。     

球形红假单胞菌对三角帆蚌养殖水体水质的影响

将红螺菌科的红假单胞菌应用于三角帆蚌养殖水体,测定水化学环境因子变化情况。结果表明,光合细菌可稳定养殖水体pH,去除氨氮、亚硝酸盐氮、总氮,降低COD,促进水体氮循环,改善养殖水体水质。按水体体积计算,红假单胞菌密度109/mL的菌液合理施用量为0.1%。     

光合细菌的计数方法--半固体试管法

光合细菌是一大类能在厌氧条件下进行不产氧光合作用的细菌的总称,包括红螺菌科、着色菌科、绿硫菌科和绿色丝状菌科,由于它有能利用硫化氢、氨氮、有机酸等小分子有机物快速生长且菌体本身具有营养丰富、无毒无害等特点,因而在水产养殖上得到了广泛应用。目前水产养殖中用的光合细菌主要是红螺菌科的光合细菌,如沼泽红假单胞菌、荚膜红假单胞菌、球形红菌等,常用来净化水质、防治疾病和促进水产动物的生长,效果比较明显。然而长期以来,光合细菌水产制剂却没有一个统一的质量标准,造成产品质量参差不齐,甚至时有掺假使杂现象发生,严重危害到…     

洛河水域光合细菌的分离鉴定及体外抑菌作用研究

光合细菌作为重要的微生物资源,对它进行研究开发应用具有重要的意义。本试验从光合细菌的分离鉴定及抑菌作用出发,以期得到较好的菌株用于水产养殖中。试验通过选择性富集培养的方式从洛阳市洛河分离得到光合细菌,通过形态学观察,以伯杰氏细菌鉴定手册为依据进行鉴定,鉴定结果为：污水中培养物为沼泽红假单胞菌,清水中培养物为万尼氏红微菌。体外抑菌试验表明分离得到的光合细菌对G+ 、G- 模式菌种大肠杆菌和金黄色葡萄球菌都有较强的抑菌活性。     

一种培养光合细菌的方法

<正>目前市场上有很多的光合细菌产品,尤其是淘宝网上都能便捷地购买到高浓度的光合细菌。但这些光合细菌产品是浮游态生长的,并且这些培养基的配方均是商业机密。而公开的光合细菌的培养液中需要添加多种成分,尤其是营养物质丰富的酵母膏或牛肉膏等,配置过程相对繁琐。本文介绍一种便捷的、原料来源丰富的光合细菌培养方法,其原料是渔用配合饲料,并且可生长出附着态的光合细菌。养殖户可自行在养殖过程中培养光合细菌并应用到养殖水体中。     

光合细菌对三角帆蚌养殖水体水质的影响

将红螺菌科的红假单胞菌应用于三角帆蚌(Hyriopsis cum ingii)养殖水体,测定水化学环境因子和微生态群变化情况。结果表明,光合细菌可稳定养殖水体pH,去除氨氮、亚硝基氮、总氮,降低COD,改变水体氮磷比;光合细菌能有效控制异养细菌、弧菌、气单胞菌数量,对真菌的增殖也有一定抑制作用,避免养殖水体水质恶化。     

对虾养殖中盐度对光合细菌生长影响的研究

锦州是辽西地区海水养殖规模最大最集中的区域,主导养殖品种是海参和中国对虾。在参、虾混养过程中多使用微生态制剂对池塘进行改善水质、调节微生态平衡、抑制病原微生物生长等。光合细菌简称PSB,是优质的水质改良剂和饲料添加剂。在水产养殖过程中,多使用红色假单胞菌属的混合菌株[1],它能够降解水体中的亚硝酸盐、硫化物等有毒物质,中国水产科学研究院将PSB应用于池水净化,对虾养殖池塘应用PSB后,氨态氮下降58%,硫化氢下降50%,溶氧增加13.6%[2],邢华3利用PSB对虾池进行净化.     

滇池平水期紫色非硫细菌的生态分布特征

为得到高原深水湖泊中的微生物生态分布信息，运用统计学软件，在2002年平水期对滇池中的紫色非硫光合细菌的数量进行了数学分析。影响湖泊中PNSB数量分布的主要因子是地点和深度，SD、TN、TP、COD、BOD和Chl-a等环境因子对PNSB数量也有影响。各环境因子间也有相关性，对其进行了分析并计算出环境因子之间关系的一元回归方程，且通过逐步回归得出了一个模型。对滇池平水期PNSB的种群结构作了初步分析，优势种群为红假单胞菌属和红微菌属。     

育肥饲料中虾青素含量对雄性中华绒螯蟹肠道和鳃部可培养优势细菌数量和组成的影响

在育肥饲料中添加虾青素会影响中华绒螫蟹肠道及鳃内的可培养优势菌群以及机体的免疫力,本实验旨在探讨饲料中虾青素含量及养殖水体对其肠道和鳃部菌群的影响。采用不同虾青素含量的饲料(0.00、26.60、41.62、81.37和75.35 mg/kg,分别对应饲料1#~5#)对雄性中华绒螫蟹进行育肥70 d后,利用基础培养基和选择性培养基对其肠道、鳃及养殖水体中的细菌进行传统分离和纯化,所得菌株进行16S rRNA测序,再进行同源性分析后做系统进化树。结果发现,在分离获得的106株细菌(登录号:KU570293~KU570368,KU570370,KU570372~KU570383,KU601302~KU6013 16,KU720553)中,92株为优势菌株,其中,肠道、鳃部和水体各29、32和31株。肠道中的可培养优势细菌属于柠檬酸杆菌属、假单胞菌属和气单胞菌属;而鳃中可培养优势细菌属于柠檬酸杆菌属、芽孢杆菌属、假单胞菌属和气单胞菌属;养殖水体中可培养优势细菌属于芽孢杆菌属、气单胞菌属、柠檬酸杆菌属、假单胞菌属和黄杆菌属。饲料2#组肠道中可培养细菌总数最高(1.06×10~8cfu/g);饲料5#肠道中的潜在致病菌数量最低,但其可培养细菌总数显著高于其他饲料组;饲料3#组肠道和鳃中潜在致病菌数量相对较高。研究表明,饲料中添加不同含量的虾青素能够显著影响雄性中华绒螫蟹肠道和鳃中的菌群构成,但对水体中可培养细菌数量无显著影响。本研究首次对投喂不同含量虾青素饲料的育肥期雄性中华绒螫蟹肠道、鳃及养殖水体可培养的优势细菌数量和组成进行分析,探究了饲料中虾青素含量以及养殖水体与蟹肠道内可培养细菌之间的联系,为中华绒螫蟹营养免疫和菌群调控提供了理论基础。     

华北地区水产用光合细菌液体制剂的优势菌属分析

正为了解目前水产用光合细菌液体制剂优势菌属的实际情况,从华北地区养殖户和水产动保产品销售商处采集了12种典型菌剂,运用16S高通量测序分析菌群组成,去除非光合细菌数据,进而统计光合细菌的百分构成比。结果显示,水产用光合细菌液体制剂中最常见的菌属是紫硫细菌的外硫红螺菌,而不是紫非硫细菌的红假单胞菌。生产厂家、管理机构和研究人员应根据光合细菌制剂菌种的实际情况开展相应的工作。     

室内集约化养虾池以低频率运转水处理系统调控水质效果及氮磷收支

采用低频率运转循环水处理系统(含粗滤器、臭氧仪、气液混合器,蛋白分离器、暗沉淀池等)联用池内设施(微泡曝气增氧机与净水网)开展凡纳滨对虾室内集约化养殖实验。研究了养虾池以水处理系统调控水质效果及氮磷收支。结果表明,养虾水经系统处理后,NO₂-N(53.4%～64.5%)、COD_Mn(53.4%～94.4%)与TAN(31.6%～40.4%)被显著去除,有效改进虾池水质;养殖周期内未换水与用药,虾池主要水化指标均控制在对虾生长安全范围,7号实验池(100 d)与8号对照池(80 d)主要水化指标变化范围:DO分别为 5.07～6.70 mg/L和4.38～6.94 mg/L,TAN 0.248～0.561 mg/L和0.301～0.794 mg/L,NO₂-N 0.019～0.311 mg/L和0.012～0.210 mg/L,COD_Mn 10.88～21.22 mg/L和11.65～23.34 mg/L。7号池对虾生长指数优于8号池(80 d虾病暴发终止),单位水体产量分别为1.398 kg/m²与0.803 kg/m²。氮磷收支估算结果:7号与8号池饲料氮磷分别占总收入:氮93.70%与92.37%,磷98.77%与99.09%;初始水层与虾苗含氮共占总收入6.30%与7.63%,磷共占1.23%与0.91%。总水层(含排污水)氮磷分别占总输出:氮56.45%与59.86%,磷53.26%与55.79%;收获虾体氮磷分别占总输出:氮37.07%与31.94%,磷21.37%与13.11%。7号池饲料转化率较高;池水渗漏与吸附等共损失氮磷分别占总输出:氮7.00%与9.34%,磷25.37%与31.10%。实验结果表明,虾池以低频率运转循环水处理系统联用池内设施可有效控制水质与虾病,具较高饲料转化率。     

草鱼养殖水体中参与氮转化途径的异养菌分析

为分析草鱼池塘中参与氮代谢的异养细菌比例及其代谢途径,从杭州郊区取得4个草鱼池塘的水样,每个水样通过涂布随即挑选100株菌株进行定性显色试验,并据此选取11株异养菌进行16S rRNA序列分析。结果表明,4个草鱼养殖池塘中NH4+-N和NO2--N的平均水平分别为5.597 mg/L和0.135 mg/L。池塘中可培养的异养菌平均为3.26×105cfu/mL,其中的89.75%参与了氮的不同代谢途径,其中31.25%的氨化菌和33.50%NO3--N(NO2--N)还原菌参与了NH4+-N的生成,32.45%的氨氧化菌参与了NH4+-N的降低;NO2--N生成途径主要包括蛋白质直接转化(11.26%)、氨氧化(4.25%)和硝酸盐氮还原(10.75%),而NO2--N降低主要通过15.50%的亚硝酸氧化菌、8.75%的NO2--N还原菌和10.75%的反硝化菌实现。结果提示,草鱼养殖水体中存在大量的异养硝化菌参与不同的氮代谢途径,且产生氨氮的异养菌比例远高于去除氨氮的菌,这是草鱼养殖水体中氨氮含量易偏高的原因。同时,11株不同功能的异养菌16SrRNA鉴定结果为寡养食单胞菌(Stenotrophomonas)6株、假单胞菌(Pseudomonas)3株、克雷伯氏菌(Klebsiella)和肠杆菌(Enterobacter)各1株,而且细菌对氮源的利用具有菌株特异性。     

Effects of adding sucrose on Penaeus monodon (Fabricius, 1798) growth performance and water quality in a biofloc system

A 60‐day indoor growth trial was conducted to study the effects of biofloc on the growth performance of a Penaeus monodon (Fabricius, 1798), water quality and biological indicators including biofloc volume, chlorophyll‐a, heterotrophic bacteria and Bacillus quantity. Two concentrations of sucrose (0 and 75%) were added daily to the P. monodon culture systems (2.94 ± 0.11 g), which were conducted indoors in fibre‐glass tanks (500 L). Results showed that the final body weight and weight gain of the adding 75% sucrose group were significantly higher (P < 0.05) than that of the control, as well as significantly (P < 0.05) improved specific growth rates and survival rates, and reduced feed coefficient. Adding 75% sucrose promoted heterotrophic bacteria, Bacillus and phytoplankton reproduction, and significantly (P < 0.05) reduced the concentration of ammonia‐N (NH₄‐N), nitrite‐N (NO₂‐N) and nitrate‐N (NO₃‐N). The changes of water quality indicators in the two groups showed the similar trend at the end of the experiment, and the ammonia‐N, nitrite‐N, nitrate‐N and phosphate‐P concentrations in the 75% sucrose group were significantly (P < 0.05) lower than those of the control group, Chlorophyll‐a concentrations peaked at 389.12 μg/L in the biofloc sucrose group at 18:00 h, and heterotrophic bacteria peaked 8 h after sucrose was added. The addition of sucrose also reduced the pH of the water. Our research showed that adding sucrose promoted biofloc formation and shortened the formation time; increased the number of heterotrophic bacteria and algae which might play a role in improving water quality by assimilating ammonia‐N and other harmful substances in the water; supplemented food for P monodon growth; and reduced the feed coefficient.     

生物絮团养殖模式下益生菌添加对异育银鲫生长、消化酶活性及肠道组织结构的影响

前期研究表明,生物絮团技术(biofloc technology,BFT)适于异育银鲫(Carassius auratus gibelio)养殖。为进一步优化BFT养殖模式,本研究设置3个实验组:BFT模式下EM菌添加组(BB组)、枯草芽孢杆菌(Bacillus subtilis)添加组(BI组)和BFT对照组(B组),以均体重(1.60±0.50)g的异育银鲫为研究对象,探讨BFT模式下外源添加益生菌对养殖动物生长、消化酶活性及肠道组织结构的影响。结果表明:(1)益生菌添加组异育银鲫增重率和特定生长率显著高于对照组(P0.05),BB和BI组的增重率分别提高了216.70%和184.04%,特定生长率分别提高了141.18%和125.49%,BB和BI组间差异不显著(P0.05);(2)益生菌添加组(BB组和BI组)的消化酶(淀粉酶、脂肪酶和胃蛋白酶)活性均显著高于对照组(B组)(P0.05)。益生菌添加组间,BB组淀粉酶活性显著高于BI组(P0.05),脂肪酶和胃蛋白酶活性亦高于BI组,但差异不显著(P0.05);(3)益生菌添加组肠道肌层厚度和黏膜下层厚度显著高于对照组(B组)(P0.05),BB组异育银鲫肠道黏膜皱襞高度和皱襞间质宽度与BI和对照组相比,均无显著差异(P0.05)。研究表明,BFT养殖模式下外源添加益生菌可以更好地促进异育银鲫生长。     

Effects of tank colour and feed colour on growth and feed utilization of thinlip mullet (Liza ramada) larvae

The effects of aquarium background colour and feed colour on survival, growth rates and feed utilization efficiency of thinlip mullet (Liza ramada) larvae (0.035 g) were investigated in two experiments. In the aquarium background colour trial, 50 larvae were stocked in duplicates in 120 L glass aquaria filled with dechlorinated tap water. The outside walls and bottoms of each pair of the aquaria were covered with coloured paper sheets to achieve one of six colours (white, black, red, green, yellow and blue), while noncoloured aquaria served as a control. The fish were fed an experimental diet (35% crude protein) at a daily rate of 5% of their body weight (BW), twice a day for 8 weeks. The best growth rates, feed efficiency and survival were achieved in larvae reared in light‐coloured aquaria (white, noncoloured and yellow). Fish performance was significantly retarded in larvae reared in dark‐coloured aquaria (red, green, black and blue). Body composition was not significantly affected by aquarium colour. In a feed colour trial, duplicate groups of larvae (0.035 g) were stocked at 50 fish per 120 L aquarium and fed a test diet (35% crude protein) with six different colours [dark blue, red, yellow, light brown (control), light green and dark brown] at a daily rate of 5% BW, twice a day for 8 weeks. The best performance and survival were achieved in fish fed on dark‐coloured diets (red, dark blue and dark brown). Light‐coloured diets (yellow, light green and light brown) resulted in inferior performance. Body composition was not significantly affected by feed colour. These results suggest that light‐coloured tanks should be used for rearing thinlip mullet, L. ramada larvae, while dark‐coloured diets are more preferable to light‐coloured diets.     

Diet supplemented with probiotic for Nile tilapia in polyculture system with marine shrimp

The aim of this study was to assess the effect of a probiotic (Lactobacillus plantarum) supplemented diet on Nile tilapia (Oreochromis niloticus) in a polyculture system with marine shrimp (Litopenaeus vannamei) as regards culture performance, hematology, and gut bacterial microbiota. Ten 20-m2 pens were arranged in one earthen pond and stocked with 2 fish (41.9 g) m⁻² and 10 shrimp (2.3 g) m⁻², in total of 40 Nile tilapias and 200 shrimp per experimental unit. Tilapia groups in five of the experimental units were fed a commercial diet supplemented with L. plantarum and the other five with an unsupplemented commercial diet (control). After 12 weeks of culture, the tilapia groups fed the probiotic-supplemented diet presented values 13.6, 7.5, and 7.1% higher for feed efficiency, yield, and final weight, respectively. Viable culturable heterotrophic bacteria counts were reduced, and the number of lactic acid bacteria was increased in the gut of fish and shrimp fed the probiotic-supplemented diet. Hematological analyses showed higher number of thrombocytes and leukocytes in tilapia fed the supplemented diet. L. plantarum utilized in this study colonized the gut of tilapia and shrimp and resulted in reduced number of total bacteria and increased tilapia final weight and feed efficiency.     

Artificial substrates in zero‐water‐exchange culture system regulate the rearing performance of Pacific white shrimp Litopenaeus vannamei (Boone, 1931) under the winter indoor condition

Effects of artificial substrates in zero‐water‐exchange culture system on the rearing performance of Litopenaeus vannamei under winter indoor condition were investigated in this study. Growth, survival, feed conversion rate (FCR), production rate of L. vannamei and water quality were compared between artificial substrate‐treated group (AST) and control group (without artificial substrates presented in the rearing environment). Artificial substrates can significantly improve the water quality, the ammonia and nitrite‐N concentrations in the AST group were significantly lower than in the control group (P < 0.05), and the total heterotrophic bacteria and Vibrio spp. were also significantly lower in the AST group (P < 0.05). The survival, growth and production rate of L. vannamei in the AST group were significantly higher than in the control group (P < 0.05). Significantly lower FCR was observed in the AST group (P < 0.05). Results from this study indicate that the utilization of artificial substrates in the indoor shrimp culture system could effectively control the water quality, improve the survival and growth of shrimp and significantly reduce the FCR. This study provides a guideline for employing artificial substrates in rearing of shrimp in the zero‐water‐exchange culture system under lower temperature, which could be applicable to other similar species.     

牙鲆自净式养殖槽中异养细菌和硝化细菌数量及硝化速率

对牙鲆(Paralichthys olivaceus)自净式养殖槽水层和过滤沙层的异养细菌和硝化细菌数量及硝化速率进行了研究，测得装有循环过滤装置的水槽水中和沙粒上异养细菌平均数量分别为2.32×10     

配合饲料和活饵料对刀鲚幼鱼生长、存活和消化酶、非特异性免疫酶、代谢酶及抗氧化酶活性的影响

为了解配合饲料和活饵料对刀鲚幼鱼生长、存活和几种酶活性的影响,对用配合饲料和活饵料喂养178 d的刀鲚幼鱼的生长、存活和消化酶、非特异性免疫酶、代谢酶以及抗氧化酶活性进行分析与比较。结果显示,配合饲料组的最终体长、体质量、成活率、鱼体肥满度和肝指数(分别为125.17 mm、6.27 g、65.73%、0.31 g/cm3和1.4%)显著低于活饵料组(分别为150.66 mm、12.39 g、85.59%、0.36 g/cm3和1.9%),两组鱼的肠长和体长比无显著差异(分别为25.3%和23.6%);两组鱼的肝脏中均未检测出蛋白酶,配合饲料组的幽门盲囊中碱性蛋白酶的活性(43.49 U/mg prot)显著低于活饵料组(86.37 U/mg prot),但两处理组鱼胃中酸性蛋白酶和肠道中碱性蛋白酶的活性均没有显著差异;配合饲料组肠道和幽门盲囊中的淀粉酶活性(分别为196.63和575.93 U/g prot)显著低于活饵料组(分别为928.91和1 755.90U/g prot),但两处理组鱼肝脏和胃中的淀粉酶活性没有显著差异;两处理组鱼的肝脏和胃中均未检测出脂肪酶,配合饲料组的肠道脂肪酶活性(23.55 U/g prot)显著高于活饵料组(14.39 U/g prot),但两处理组幽门盲囊中脂肪酶活性(分别为17.90和13.23 U/g prot)没有显著差异;配合饲料组的肝脏碱性磷酸酶(AKP)活性(103.44 U/g prot)显著高于活饵料组(58.20 U/g prot),而配合饲料组的肝脏谷草转氨酶(AST/GOT)活性(20.38 U/g prot)显著低于活饵料组(32.51 U/g prot);肝脏中其余被检测的5种酶活性(ACP、ALT/GPT、SOD、GSH-PX和CAT)和血清中被检测的代谢酶(ALT/GPT和AST/GOT)及抗氧化酶(SOD和GSH-PX)活性在两处理组之间均没有显著差异。研究表明,刀鲚能摄食配合饲料,配合饲料组和活饵料组的大多数消化酶、非特异性免疫酶、代谢酶及抗氧化酶活性,没有显著性差异,但配合饲料组的刀鲚生长和成活率远低于活饵料组,建议今后研发和改进刀鲚配合饲料,逐步替代活饵料。     

Effects of fish farming on microbial planktonic communities in the middle Adriatic sea

The effects of farming on planktonic microbial communities were investigated at the coastal sea bass/sea bream farm in the oligotrophic middle Adriatic Sea. Analyses of nutrients, chlorophyll a, cyanobacteria (Prochlorococcus), heterotrophic bacteria and nanoflagellates (both pigmented and heterotrophic) were carried out on samples taken during six seasonal cruises at different water depths. Farming activity increased the natural concentrations of some nutrients (ammonium, nitrite, phosphate, dissolved inorganic nitrogen) and changed their seasonal pattern. The values still remained typical for oligotrophic environ‐ments demonstrating no risk for eutrophication. Enhanced nutrient supply provoked an immediate increase in abundances of both autotrophic and heterotrophic microbial groups (except pigmented nanoflagellates) and chlorophyll a. The effect of farming was more visible for the heterotrophic microbial component. Results from this study reveal a potential common pattern of microbial response to farming in the oligotrophic environments. It also suggests the importance of heterotrophic microbial web in transferring the matter and energy released from the fish farms in nutrient poor environments.