九孔鲍养殖水体中产酶菌群的研究

为了解九孔鲍养殖环境中细菌生理菌群的生态作用，对分离自养殖水体的33株菌株的产酶能力和种类进行了研究。结果表明，具有分泌胞外蛋白酶、脂肪酶和纤维素酶能力的菌株分别为39．4％、57．6％和30．3％；在这33株菌中，产至少一种胞外酶的菌株比例高达63．6％。API鉴定结果表明，在有能力分泌胞外蛋白酶、脂肪酶和纤维素酶的菌株中，弧菌菌群所占的比例分别为46％、42％和40％，而其中河流弧菌又占各弧菌菌群比例的83．3％、62.5％和100％。充分阐明弧菌，尤其是河流弧菌为优势菌，在鲍鱼养殖微生物态中起的重要作用。     

近江牡蛎肠道细菌及其产酶能力

从近江牡蛎肠道中分离出21株菌,其中, 9株为革兰阳性菌, 12株革兰阴性菌。为寻找能分泌多种酶的有益微生物,研究了它们蛋白酶、脂肪酶、淀粉酶、纤维素酶的产酶能力。结果表明,有61 .9%的菌株能分泌蛋白酶或淀粉酶(各有13株菌);有52. 4%的菌株能分泌脂肪酶(11株菌);有33. 3%的菌株能产纤维素酶(7株菌)。在这21株菌中,产4种酶的有5株菌,产3种酶的3株菌,产两种酶的5株菌,产1种酶的3株菌,不产酶的仅有5株菌。不产酶的菌株仅占细菌总数的23. 8%,而各种产酶菌则高达76. 2%,由此表明细菌在近江牡蛎对食饵消化过程的重要性。     

近江牡蛎肠道细菌及其产酶能力

从近江牡蛎肠道中分离出21株菌，其中，9株为革兰阳性菌，12株革兰阴性菌。为寻找能分泌多种酶的有益微生物，研究了它们蛋白酶、脂肪酶、淀粉酶、纤维素酶的产酶能力。结果表明，有61．9％的菌株能分泌蛋白酶或淀粉酶(各有13株菌)；有52．4％的菌株能分泌脂肪酶(11株菌)；有33．3％的菌株能产纤维素酶(7株菌)。在这21株菌中，产4种酶的有5株菌，产3种酶的3株菌，产两种酶的5株菌，产1种酶的3株菌，不产酶的仅有5株菌。不产酶的菌株仅占细菌总数的23．8％，而各种产酶菌则高达76．2％，由此表明细菌在近江牡蛎对食饵消化过程的重要性。     

溶藻弧菌gr基因缺失株构建及其生物学特性

【目的】研究敲除谷胱甘肽还原酶(GR)基因gr对溶藻弧菌HY9901生物学特性的影响。【方法】通过同源重组技术和Overlap PCR等分子生物学手段构建溶藻弧菌HY9901的gr基因缺失株,通过反转录验证并检测其遗传稳定性,绘制该菌的野生株和缺失株的生长曲线,测定该菌野生株和缺失株的生物膜形成能力、抗生素敏感性、胞外蛋白酶活性和泳动能力等生物学特性。【结果】gr基因的缺失几乎不影响溶藻弧菌的生长趋势,但敲除gr基因后溶藻弧菌对呋喃唑酮、头孢唑林、四环素等敏感性增强,该菌的生物膜形成能力增强显著提高。缺失株△gr的胞外蛋白酶活性和泳动能力均低于野生株。【结论】谷胱甘肽还原酶在溶藻弧菌的毒力、生物膜形成、药物敏感性、泳动等方面有重要作用。     

具有多种胞外酶的对虾肠道黏附菌的分离和鉴定

用对虾饲料培养基从健康凡纳滨对虾肠道分离出500株黏附细菌,以产淀粉酶、脂肪酶和蛋白酶能力为指标,筛选出产该3种消化酶的细菌90株,占总菌株的18%.对其中生长较快的69株进行16S rDNA 基因测序,确定其分类地位.结果显示,69株菌分别属于不动杆菌属(Acinetobacter)、芽孢杆菌属(Bacillus)、葡萄球菌属(Staphylococcus)、假交替单胞菌属(Pseudoalteromonas)、气单胞菌属(Aeromonas)、嗜盐单胞菌属(Halomonas)、利斯顿氏菌属(Listonella)、莫拉氏菌属(Moraxella)等,其中数量最多是芽胞杆菌属,占鉴定细菌总数的53.62%,数量最少是气单胞菌属和嗜盐单胞菌属,均占鉴定细菌总数的2.90%.表明对虾肠道黏附菌群中具有较多能分泌多种消化酶的细菌,可进一步开发为促进对虾消化功能的益生菌     

马氏珠母贝肠道及其养殖水体可培养细菌群落结构

【目的】了解马氏珠母贝(Pinctada fucata martensii)肠道及其养殖水体可培养细菌的群落组成。【方法】采用2216E平板涂布法研究海区养殖马氏珠母贝肠道与养殖水体的可培养菌群种类及丰度。【结果与结论】马氏珠母贝肠道及其养殖水体的可培养细菌归属于2门(变形菌门和厚壁菌门)3纲7目10科23属56种。属水平上,肠道中以弧菌属(74.7%)和假交替单胞菌属(18.7%)为主;养殖水体中α-变形菌纲的FJ943236_g属(40.7%)丰度最大,弧菌属(16.7%)相对肠道丰度较低。样品共有菌属为弧菌属、假交替单胞菌属、发光杆菌属和芽孢杆菌属;肠道特有菌属为希瓦氏菌属和盐单胞菌属;养殖水体特有菌属主要为FJ943236_g、鲁杰氏菌属和Nautella。在种水平上,7个种为二者共有;马氏珠母贝肠道和养殖水体特异性菌种分别为18个和31个。虽然门水平上马氏珠母贝肠道中可培养细菌群落与其养殖水体中的细菌群落大致相似,但在属、种水平上二者差异明显。     

眼斑拟石首鱼烂尾病病原菌的分离鉴定及灭活疫苗的免疫效果

从患烂尾病眼斑拟石首鱼(Sciaenops ocellatus)的溃疡处分离到一株优势菌So GZ1401,回归感染试验证实该菌是引起烂尾病的病原菌,对眼斑拟石首鱼的半致死量(LD50)为8.6×103 CFU·g~(-1);结合其形态学和生理生化特征及HSP60测序分析,鉴定为哈维氏弧菌(Vibrio harveyi);利用杯碟法研究其胞外产物性质,结果表明:其胞外产物具有淀粉酶、明胶酶、酪蛋白酶、卵磷脂酶、脂酶活性以及溶血活性,但无脲酶活性。药敏试验表明,该菌株对氟哌酸、恩诺沙星、氟苯尼考和复方新诺明等抗菌药有较高的敏感性。制备哈维氏弧菌灭活疫苗,采用注射和浸泡2种途径免疫眼斑拟石首鱼,测定受免疫鱼的血清抗体效价和疫苗对眼斑拟石首鱼的免疫保护率。结果显示,免疫组血清中的抗体效价水平均高于对照组,差异有统计学意义(P0.05),注射组和浸泡组的抗体效价最高值分别达718.4和128,哈维氏弧菌攻毒后免疫保护率分别为75.0%~86.7%和46.4%~56.7%。哈维氏弧菌灭活疫苗对眼斑拟石首鱼具有较好的免疫保护性。     

芽孢杆菌胞外产物的研究进展

芽孢杆菌大多能分泌高活性的胞外产物(extracellular products),如蛋白酶、淀粉酶、脂肪酶等水解酶和果胶酶、葡聚糖酶、纤维素酶等分解植物性饵料中非淀粉多糖的酶类[1].     

海洋动物肠道中抗氧化活性乳酸菌的分离及多样性分析

【目的】分析海洋动物肠道中抗氧化活性乳酸菌的多样性,并对活性菌株胞外与胞内代谢物清除1,1-二苯基-2-三硝基苯肼(DPPH)自由基能力进行测定。【方法】采用溶钙圈分离培养技术和DPPH自由基清除法,从湛江海域6种海洋动物肠道中分离活性乳酸;通过构建16S rDNA基因序列系统发育树,分析其多样性;利用DPPH自由基清除法,测定其抗氧化活性。【结果】共分离得到16株抗氧化活性乳酸菌,分属于细菌域厚壁菌门(Firmicutes)的4个科(Leuconostocaceae,Streptococcaceae,Lactobacillaceae,Enterococcaceae)、6个属(Weissella,Pediococcus,Leuconostoc,Lactococcus,Lactobacillus,Enterococcus),其中除菌株zy-3、LY-87、ZH-54的16S r DNA基因序列与数据库EzBioCloud中的模式菌相似性100%外,其余13株活性菌株与模式菌存在一定的遗传差异(97.42%～99.93%),菌株zy-I与模式菌株Weissella cibaria(KACC11862T)的相似性仅为97.42%,推测为Weissella cibaria属中的潜在新种;16株活性菌株胞外代谢物对DPPH的抗氧化活性均大于胞内代谢物,且5株乳酸菌株(zy-4、zy-s6、YM-49、ZH-53、ZH-54)的胞外的DPPH清除能力均在45%以上,高于其它11株菌株。【结论】湛江海域动物肠道中存在较为丰富的抗氧化活性乳酸菌,并蕴藏潜在乳酸菌新种。     

噬菌弧菌N1对淡水和海水养殖水体细菌群落影响PCR-DGGE分析

【目的】研究噬菌弧菌Bacteriovorax sp. N1在一个投放周期内对淡水和海水养殖环境中细菌、弧菌总数及细菌群落结构的影响。【方法】自市售微生态制剂分离蛭弧菌N1并进行分子鉴定,测定其裂解效果,制备高浓度N1菌液分别投放至淡水红鲤鱼(red carp)和海水仿刺参(Apostichopus japonicus)养殖水体,采用细菌平板计数法及PCR-变性梯度凝胶电泳(PCR-DGGE)技术分析48 h内水体环境中细菌、弧菌总数及细菌群落结构变化。【结果】经鉴定蛭弧菌N1为噬菌弧菌,其对大肠杆菌(Escherichia coli)、溶藻弧菌(Vibrio alginolyticus)、黄海希瓦氏菌(Shewanella smarisflavi)、灿烂弧菌(Vibrio splendidus)、哈氏弧菌(Vibrio harveyi)和金黄色葡萄球菌(Staphylococcus aureus)均有裂解效果。将噬菌弧菌N1投放进淡水和海水养殖环境的12～24 h,其能显著降低两种环境中弧菌含量(P 0.05)。DGGE分析显示添加噬菌弧菌N1后淡水组优势菌群弧菌属(Vibrio,a1)和不可培养杆菌属(Uncultured bacterium, a5)在12 h以后含量有明显的减少,假单胞菌属(Pseudomonas, a3)和红杆菌科Shimia属(Shimia, a6)菌含量增加。海水组优势菌群不可培养杆菌属(c2)菌在12 h时变成非优势菌群,而白杆菌属(Albirhodobacter,c1)增加成为优势菌群。噬菌弧菌N1在水中含量在24 h时降至最低。【结论】噬菌弧菌N1对海水和淡水环境中的弧菌属和不可培养杆菌属菌群有明显的裂解作用导致其含量下降,但也使假单胞菌属(Pseudomonas),红杆菌科Shimia属和白杆菌属(Albirhodobacter)菌群含量增加,但生物效应不明。为维持噬菌弧菌N1对弧菌的控制,需要24 h左右重新补充投放。     

Extracellular enzymatic activities of cold-adapted bacteria from polar oceans and effect of temperature and salinity on cell growth

The potential of 324 bacteria isolated from different habitats in polar oceans to produce a variety of extracellular enzymatic activities at low temperature was investigated. By plate assay, lipase, protease, amylase, gelatinase, agarase, chitinase or cellulase were detected. Lipases were generally present by bacteria living in polar oceans. Protease-producing bacteria held the second highest proportion in culturable isolates. Strains producing amylase kept a relative stable proportion of around 30% in different polar marine habitats. All 50 Arctic sea-ice bacteria producing proteases were cold-adapted strains, however, only 20% were psychrophilic. 98% of them could grow at 3% NaCl, and 56% could grow without NaCl. On the other hand, 98% of these sea-ice bacteria produced extracellular proteases with optimum temperature at or higher than 35℃, well above the upper temperature limit of cell growth. Extracellular enzymes including amylase, agarase, cellulase and lipase released by bacteria from seawater or sediment in polar oceans, most expressed maximum activities between 25 and 35℃. Among extracellular enzymes released by bacterial strain BSw20308, protease expressed maximum activity at 40℃, higher than 35℃ of polysaccharide hydrolases and 25℃ of lipase.     

Studies on culture condition and extracellular hydrolase of psychrophilic bacteria from Arctic sea ice

Arctic sea ice in the polar region provides a cold habitat for microbial community. Arctic sea ice microorganisms are revealed to be of considerable importance in basic research and potential in biotechnological application. This paper investigated the culture condition and extraceIlular hydrolase of 14 strains of different Arctic sea ice bacteria. The results showed that optimal growth temperature of strains is 15 ℃ or 20 ℃. The optimal pH is about 8.0. They hardly grow at acid condition. 3 % NaCl is necessary for better growth. These strains have different abilities in producing amylase, protease, eellulase and lipase. Pseudoalteronomas sp. Bsi429 and Pseudoalteronomas sp. Bsi539 produced both cellulose, protease and lipase. These results provide a basis for further developing and exploiting the cold adapted marine enzyme resources.     

Intraspecific Diversity of Aureobasidium pullulans Strains from Different Marine Environments

Totally more than 500 yeast strains were isolated from seawater, sea sediments, mud of sea salterns, marine fish guts and marine algae. The results of routine and molecular biology identification methods show that nine strains among these marine yeasts belong to Aureobasidium pullulans, although the morphologies of their colonies are very different. The marine yeasts isolated from different marine environments indicate that A. pullulans is widely distributed in different environmental conditions. These Aureobasidium pullulans strains include A. pullulans 4#2, A. pullulans N13d, A. pullulans HN3-11, A. pullulans HN2-3, A. pullulans JHSc,A. pullulans HN4.7, A. pullulans HN5.3, A. pullulans HN6.2 and A. pullulans W13a. A. pullulans 4#2 could produce cellulase and single cell protein. A. pullulans N13d could produce protease, lipase, amylase and cellulase. Both A. pullulans HN3-11 and A. pullulans HN2-3 were able to produce protease, lipase and cellulase. A. pullulans JHSc could secrete cellulase and killer toxin. Both A.pullulans HN4.7 and A. pullulans HN5.3 could yield lipase and cellulase. A. pullulans W13a was able to secrete extracellular amylase and cellulase while A. pullulans HN4.7 and A. pullulans N13d could produce siderophores. This means that different A. pullulans strains from different marine environments have different physiological characteristics, which may be applied in many different biotechnological industries.     

生物采油解堵剂中产蛋白酶菌株的筛选及培养条件优化

为研究生物酶采油解堵剂中产蛋白酶菌株的初、复筛选及培养条件优化,从大庆原油样品中筛选菌种,通过水解酪素的透明圈实验及福林酚测蛋白酶酶活的方法进行菌株的初、复筛选;以蛋白酶酶活为优化指标,采用单因素实验对筛选的产蛋白酶菌株的培养基及培养条件进行优化,优化最适培养基:可溶性淀粉为15g/L,蛋白胨为20g/L,酵母膏为20g/L,NaCl为1.0g/L,CaCl2为0.02g/L,Na2HPO4为0.2g/L,NaH2PO4为0.1g/L;在初始pH为6.0、接种量为5%(体积分数)、温度为31℃、摇床转速为160r/min的条件下,培养72h后,菌株的蛋白酶酶活为551.0U/mL,为复筛选菌株的蛋白酶酶活的22.92倍,即为菌株生长繁殖及代谢的最佳条件,能够获得更高的蛋白酶酶活,有利于后续实验的进行.结果表明:菌株产蛋白酶对原油作用效果为发酵液表面张力从作用前的56.2mN/m降低到作用后的30.5mN/m,表面张力显著降低,还有降解降黏原油等效果,具有一定的研究价值.     

不同养殖模式虾池弧菌对抗菌药物的耐药性与虾池水质评价

研究了湛江东海岛3种不同养殖模式虾池弧菌对抗菌药物的耐药性,并对虾池水域环境的水温、盐度、DO、pH、叶绿素a、DOC、无机氮、无机磷、硅酸盐、细菌总数和弧菌数量变化进行了监测和评价。结果表明,调查的三个虾池的弧菌对万古霉素产生耐药性,高位新池和传统精养池的弧菌对利福平产生耐药性,对其他抗菌药尚未形成耐性,3个虾池的弧菌对恩诺沙星和氯霉素高度敏感,传统精养池和天然虾池的弧菌对复方新诺明、庆大霉素、TMP和环丙沙星高度敏感;在水平差异上,高位新池的弧菌比传统精养池和天然虾池对12种抗菌药更具耐药性,同时多重耐药菌株在高位新池中出现,可能与虾苗来源和配合饲料中添加了抗菌药物有关。水质监测结果表明,养殖过程中,虾池水域环境逐渐富营养化,无机氮和Chla超过富营养化阈值,细菌总数增加;两个精养池的水体富营养化程度高于天然虾池;调查期间的弧菌数量在对虾发病的感染剂量阈值范围之内,尚无弧菌病害发生的潜在危险。     

Intraspecific diversity of Aureobasidium pullulans strains from different marine environments

Totally more than 500 yeast strains were isolated from seawater, sea sediments, mud of sea salterns, marine fish guts and marine algae. The results of routine and molecular biology identification methods show that nine strains among these marine yeasts belong to Aureobasidium pullulans, although the morphologies of their colonies are very different. The marine yeasts isolated from different marine environments indicate that A. pullulans is widely distributed in different environmental conditions. These Aureobasidium pullulans strains include A. pullulans 4#2, A. pullulans N13d, A. pullulans HN3-11, A. pullulans HN2-3, A. pullulans JHSc, A. pullulans HN4.7, A. pullulans HN5.3, A. pullulans HN6.2 and A. pullulans W13a. A. pullulans 4#2 could produce cellulase and single cell protein. A. pullulans N13d could produce protease, lipase, amylase and cellulase. Both A. pullulans HN3-11 and A. pullulans HN2-3 were able to produce protease, lipase and cellulase. A. pullulans JHSc could secrete cellulase and killer toxin. Both A. pullulans HN4.7 and A. pullulans HN5.3 could yield lipase and cellulase. A. pullulans W13a was able to secrete extracellular amylase and cellulase while A. pullulans HN4.7 and A. pullulans N13d could produce siderophores. This means that different A. pullulans strains from different marine environments have different physiological characteristics, which may be applied in many different biotechnological industries.     

大亚湾网箱养殖水体弧菌种类组成及变化

研究了海水网箱养殖海域弧菌数量变化、种类组成及其相关因素,探讨弧菌数量的变化与鱼病的关系。结果表明:网箱内水体弧菌数量为390~230 mL-1,平均为20.6×102mL-1,网箱外水体为130~1450 mL-1,平均为530 mL-1,非养殖对照海区为10~390 mL-1,平均为190 mL-1。养殖海区弧菌数量呈现明显的季节性变化,尤其是网箱水体,对照海区只在9月数量较高,其他时间变化不大。平均数量网箱内大于网箱外,网箱外大于对照海区。水体中出现的弧菌种类有河流弧菌Vibrio fluvialis,创伤弧菌Vibrio vulnifgicus,霍乱弧菌Vibrio cholerae,副溶血弧菌Vibrio parahaemolyticus,溶藻弧菌Vibrio alginolyticus,美人鱼弧菌Vibrio damsela,拟态弧菌Vibriomimicus和好利斯弧菌Vibrio hollisae,美人鱼弧菌、溶藻弧菌和霍乱弧菌占有较大优势。弧种数量与海水温度、盐度及营养盐有相关性,但其相关性因不同种和不同点而不同。检测期间,网箱养殖鱼类无明显流行病发生,但弧菌的高峰期明显与报道的鱼病高峰期相吻合。