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自北冰洋楚科奇海、加拿大海盆、格陵兰海和中国南极中山站近岸的海水、海冰和沉积物样品中分离的322株低温细菌中筛选出73株低温β-半乳糖苷酶产生菌,并对其中1株BCw006进行了研究。通过16S rDNA序列同源性分析表明,该菌株属于交替单胞菌属,定名为Alteromonas sp.BCw006。对该菌株研究表明:该菌最适生长和产酶温度为24℃;在pH6.0—8.0、含0%—6.O% NaCl的培养基条件下菌株能够较好地生长与产酶,其最适生长和产酶NaCl浓度分别为3%和1%,乳糖对β-半乳糖苷酶合成具有明显诱导作用,酵母粉和蛋白胨是菌株生长和产酶较适宜的氮源,酶的最适作用温度为35℃,0℃时能保持35℃下酶活的25%左右,表明其具有较好的适应低温特性。酶对热敏感,60℃时作用30min后酶活力下降了41%。 相似文献
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覆盖在北极海洋上的广阔海冰为其内部生存的微生物群落提供了一个独特的生境。研究表明 ,大量海冰细菌能够分泌产生胞外酶 ,其中产蛋白或脂质水解酶细菌的比例远高于产多糖水解酶的细菌。温度、盐度是直接影响海冰细菌生存与活力的 2个主要环境因子。 76%的产酪蛋白酶海冰细菌为低温菌 ,菌株只能在 <35°C条件下生长 ;而 98%的酪蛋白酶最适作用温度≥ 35°C ,其中 62 %的酶最适作用温度≥ 45°C。几乎所有的产酪蛋白酶海冰细菌都耐盐或嗜盐 相似文献
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从北极楚科奇海水中分离到一株产蛋白酶耐冷河豚毒素假交替单胞菌BSw20353。该菌可合成多种胞外蛋白酶,而培养温度影响蛋白酶的合成。分离纯化出其中一种在15℃、25℃培养时均有生成的酶:该酶最适作用温度55℃;最适pH8;金属离子Hg2+、Sr2+抑制酶活,Fe2+、Mn2+则具有激活作用;该酶属于金属蛋白酶,受螯合剂邻二氮杂菲、EDTA及EGTA抑制,基本不受丝氨酸蛋白酶抑制剂PMSF、TPCK及TLCK抑制,半胱氨酸蛋白酶抑制剂E-64对该酶无抑制作用,天冬氨酸蛋白酶抑制剂pepstatin则具有一定抑制作用;SDS、二硫苏糖醇、碘乙酸可抑制酶活;而在变性剂尿素、盐酸胍作用下,酶活反而有所增高。 相似文献
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本研究对产虾青素的南极菌株NJ298进行了鉴定,同时对影响虾青素产量的主要环境因子进行了测试。形态特征、生理生化特征及ITS序列的系统发育分析表明,南极菌株NJ298属于红酵母属(Rhodotorula);虾青素积累主要在NJ298生长的对数期和稳定期;乙酸钠、蛋白胨是合成虾青素的最佳碳、氮源;在0-15℃之间,南极酵母NJ298均可以生长,但是低温更有利于虾青素的积累;pH值在6-8范围内NJ298均可生长,最适pH值为7.5;该菌对盐度要求不严格。 相似文献
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《极地研究》2021,33(2)
二甲基巯基丙酸内盐(DMSP)是一种主要由海洋浮游植物生成的含硫化合物,在海洋中含量丰富,同时也是海洋细菌的重要营养物之一。采用生长选择性培养基从北极王湾海水中分离到一株细菌DMSP-1。基于16S rRNA基因序列及基因组平均核苷酸一致性(Average Nucleotide Identity, ANI)分析,将该菌鉴定为乳酸假单胞菌。该菌细胞呈杆状,有极生鞭毛;具有耐冷(可在5℃较快生长,适宜生长温度范围为22~29℃,最高生长温度为38℃)、耐盐(适宜生长盐度范围为0~4%NaCl、最高生长盐度为8%NaCl)等特性,表明该菌能较好地适应其所处的北极近岸环境。碳源生长实验证实该菌能以DMSP为唯一碳源进行生长。该菌具有乳酸假单胞菌的许多生理生化特征,但也存在差异,如色氨酸脱氨酶与脲酶为阳性、不能利用鼠李糖产酸等。对假单胞菌DMSP-1开展进一步的研究,将推动人们对于海洋细菌降解DMSP的代谢机制及其在北极海洋环境中生态功能的深入认识。 相似文献
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本文对影响南极细菌S-15-13生长和胞外多糖产量的主要环境因子进行了研究,同时采用16S rDNA序列分析及系统发育分析方法对其进行了分子鉴定。结果表明:菌株S-15-13最佳产糖条件为:培养时间,56h;培养温度,8℃;碳源,1.0%葡萄糖;NaCl浓度,3.0%;pH,6.0-7.0。16S rDNA序列分析和系统发育分析表明,菌株S-15-13属于假交替单胞菌属(Pseudoaltero- monas)。 相似文献
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红球菌(Rhodococcus sp.)B7740分离自北冰洋海水样品,前期实验表明其能产生大量黄色素,但是该菌生物量很低。本实验通过碳源、氮源、培养温度、发酵液起始pH值、菌种接种量等单因素和正交实验优化了该菌株的培养条件,在此基础上,通过对提取剂种类及pH、提取时间、料液比等的研究,优化了色素的提取条件。实验结果表明,1L陈海水中,添加5g酵母粉,5g葡萄糖,3g乳糖,7g牛肉膏;起始pH7,培养温度25℃,菌种接种量1.0%,160r/min摇床培养7d时,生物量从6.1mg/mL上升到23.08mg/mL,提高了278.4%。以上述培养条件下得到的干菌体为材料,采用pH7的无水乙醇,当料液比1:30,浸提温度75℃,浸提1h重复提取2次时,色素含量为1160.625μg/g干菌体。对色素的分析表明,该色素为类胡萝卜素,实验结果为进一步研究极地微生物红球菌(Rhodococcus sp.)B7740产类胡萝卜素的提取工艺提供了基础。 相似文献
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从421株南极细菌中筛选出产超氧化物歧化酶南极细菌NJ062、NJ379、NJ522和NJ548。它们的最适生长温度在10-15℃之间,在0℃均能生长,属于嗜冷菌。4株南极嗜冷菌均含有一种类型的SOD同工酶。菌株NJ062的超氧化物歧化酶为Mn-SOD;菌株NJ379,NJ522和NJ548的超氧化物歧化酶均为Fe-SOD。它们所产的超氧化物歧化酶最适酶活温度大约在40-50℃,在0℃仍有较高的活性,为最高活性的20%-35%,热稳定性较差,属低温酶。通过16S rDNA序列对4株产低温超氧化物歧化酶的南极嗜冷菌NJ062、NJ379、NJ522和NJ548进行鉴定。结果表明,它们均属于细菌域(Bacteria)中的紫细菌类群(Proteobacteria)中的γ-亚群。其中菌株NJ062属于假交替单胞菌属(Pseudoalteromonassp.);NJ379属于希瓦氏菌属(Shewanellasp.);NJ522和NJ548属于海单胞菌属(Marinomonassp.)。 相似文献
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《湿地科学》2017,(1)
原位筛选石油烃降解菌可以用于修复被石油污染的湿地土壤。从莫莫格湿地被石油污染的土壤中分离筛选烷烃降解菌,研究其降解特性,为湿地石油污染治理提供修复材料。以十六烷(C16)为唯一碳源,对采集自莫莫格湿地东部、嫩江西岸的哈尔挠区(45°50′N~46°18′N,123°55′E~124°4′E)的表层石油污染土壤中的烷烃降解菌进行富集,并筛选分离出一株对C16具有高效降解能力的细菌。通过形态学和16S r RNA基因序列分析,明确其系统发育进化地位;同时,利用气相色谱—质谱仪(GC-MS),测定培养物中C16的含量,研究不同温度、时间、培养基初始p H、C16初始浓度对菌株降解C16的影响。研究结果表明,成功筛选、分离得到一株能够降解C16的细菌菌株JLC1,该菌株属于铜绿假单胞菌,命名为Pseudomonas aeruginosa JLC1;Pseudomonas aeruginosa JLC1降解C16的适宜温度为35℃,适宜p H为6.5。此外,随着C16初始浓度升高;菌株JLC1对C16的降解率逐渐降低。对温度、p H、C16浓度适应范围较广的C16降解菌——Pseudomonas aeruginosa JLC1菌在油田污染湿地的生物修复中具有潜在的应用前景。 相似文献
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Isolation and characterization of a marine bacterium producing protease from Chukchi Sea, Arctic 
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下载免费PDF全文 A Gram negative bacterium Ar/W/b/75°25′N/1 producing extracellular alkaline protease was isolated from surface water of latitude 75°25′N, and longitude 162°25′W in Chukchi sea, Arctic. The strain can grow at the temperature range from 7℃ to 30℃, and grow better at 30℃. It can not grow at 40℃. Keeping certain salinity concentration in medium is necessary for cell growth. It grows well in medium containing salinity concentration from 0.5% to 10% sodium chloride. Glucose, sucrose and soluble starch can be utilized by the strain, among which glucose is the optimal carbon source. Peptone is the optimal organic nitrogen source for cell growth and protease producing, and ammonium nitrate is the optimal inorganic nitrogen source. About 75 7% of total protease of the strain are extracellular enzyme. Optimal temperature for proteolytic activity is at 40℃. Protease of the strain keeps stable below 40℃, and shows high proteolytic activity within the pH range from 7 to 11. 相似文献
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Isolation and characteristics of one marine psychrotrophic cellulase-generating bacterium Ar/w/b/75°/10/5 from Chuckchi Sea,Arctic 下载免费PDF全文
下载免费PDF全文 Microorganisms living in polar zones play an important part as the potential source of organic activity materials with low temperature characteristics in the bio-technological applications. A psychrotrophic bacterium (strain Ar/w/b/75°/10/5) , producing cellulose at low temperatures during late-exponential and early-stationary phases of cell growth, was isolated from sea ice-covered surface water in Chuckchi Sea, Arctic. This bacterium, with rod cells, was Gram-negative, slightly halophilic. Colony growing on agar plate was in black. Optimum growth temperature was 15℃. No cell growth was observed at 351 or above. Optimum salt concentration for cell growth was between 2 and 3 % of sodium chloride in media. Maximal cellulase activity was detected at a temperature of 35℃ and pH8. Cellulase was irreversibly inactivated when incubated at 55℃ within 30 min. Enzyme can be kept stable at the temperature no higher than 25℃. Of special interest was that this bacterium produced various extracellular enzymes i 相似文献
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Screening and molecular classification of low-temperature protease from Antarctic microorganism and its characterization 下载免费PDF全文
下载免费PDF全文 <正> 107 strains producing protease were screened from 260 strains of Ant-arctic psychrophilic bacteria,among which proteolytic activity of five strains wasmore than 45 U ml~(-1).The 16S rRNA gene sequences homology and phylogenet-ic analysis of five Antarctic psychrophilic bacteria showed that NJ276、NJ5-9、NJ16-70、NJ345 belonged to the described genus Pseudoalteromonas and NJ341belonged to the genus Colwellia.The growth and the protease characteristic offour Antarctic psychrophilic bacteria had been studied,and the result showedthat the optimal temperature for growth and protease-producing of four strainswas about 10℃.Their growth and protease-producing were still high during in-cubating 2-5 days.The maximum proteolytic activity occurred at pH 9 for fourAntarctic psychrophilic bacteria.The optimal temperature of protease action ofboth strains NJ276 and NJ5-9 was about 50℃,however,the optimal temperatureof protease action of both strains NJ341 and NJ345 was about 40℃,and theirproteolytic activity under 0℃ exhibited nearly 30% of the maximum activity,but their thermal stabilities were weaker.These results indicated that proteasesfrom NJ341 and NJ345 were low-temperature proteases. 相似文献
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Extracellular enzymatic activities of cold-adapted bacteria from polar oceans and effect of temperature and salinity on cell growth 下载免费PDF全文
下载免费PDF全文 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. 相似文献
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Studies on culture condition and extracellular hydrolase of psychrophilic bacteria from Arctic sea ice 下载免费PDF全文
下载免费PDF全文 Arctic sea ice in the polar region provides a cold habitat for microbial community.Arctic sea ice microorganisms are revealed to be of considerable impor- tance in basic research and potential in biotechnological application.This paper in- vestigated the culture condition and extracellular 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 pro- ducing amylase,protcase,cellulase 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. 相似文献
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试验选用一株高产低温蛋白酶的南极细菌菌株Pseudoalteromonas sp. AN64,从溶解氧、化学需氧量、氨氮、亚硝态氮、pH值5个方面研究了南极细菌对养殖水体的影响。结果显示,随着饲料中蛋白质的散失,水体中蛋白质的含量在第7天达到高峰,溶解氧下降,化学需氧量持续上升,在第11天达最大值9.88 mg/L,并且维持在较高的水平。缺氧条件下,有害物质氨氮和亚硝态氮含量逐渐增加,在第9天和第11天分别达最大值0.65 mg/L和0.352 mg/L,而pH值持续下降,在第9天达最低值5.95。当水体中加入高产蛋白酶的南极菌株AN64后,蛋白质含量在第5天即达高峰,溶解氧无明显变化,化学需氧量在第7天达最高峰,比对照组提前4天,但含量仅约为后者的一半。同时,氨氮和亚硝态氮含量远低于对照组,分别仅为对照的47.7 %和26.5 %,而pH值有小幅下降,维持在6.85到7.52之间。由此可以看出,南极菌株产生的低温蛋白酶可以有效分解海水中的蛋白质,降低水体中的氨氮和亚硝态氮等有害物质,维持pH值的稳定性,为健康养殖提供了有效途径。 相似文献
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Effect of isolation temperature on the characteristics of extracellular proteases produced by Antarctic bacteria 总被引:1,自引:0,他引:1
Protease-producing psychrotolerant bacteria were isolated from Antarctic biotopes on casein agar plates using different incubation temperatures. Most of the isolates were non-spore-forming Gram-negative motile rods with catalase activity, 30% were pigmented and none of them were glucose fermenters. All the strains were grown in liquid cultures at 20°C and protease secretion was tested using the azocasein method. Despite their capacity for production of a clear zone of hydrolysis in agar plates, some strains did not produce detectable levels of proteolytic activity in liquid cultures. The lowest apparent optimum temperature for protease activity found in culture supernatants was 40°C. Almost all the strains showed activation energy values about 10-20 kJ-mol−1 lower than that observed for a mesophilic Subtilisin. Most of the proteases showed optimal activity at neutral or alkaline pH values and developed a multiple-band profile on gelatine-SDS-PAGE. It was observed that the lower the strain isolation temperature was, the more stongly cold-adapted–in terms of optimal temperature and activation energy–were the proteases produced by them. This dependence of the characteristics of the proteases on the isolation temperature is an important factor to take into account in the design of screening programmes directed towards the isolation of psychrotolerant bacteria able to produce proteases strongly or weakly adapted to work in the cold. The Antarctic area explored proved to be a promising source of proteolytic bacteria with potential use in industrial processes to be carried out at low or moderate temperatures. 相似文献