嗜水气单胞菌气溶素基因的克隆与序列分析

以嗜水气单胞菌BZ和NK分离株的DNA为模板, 采用PCR技术, 扩增气溶素基因(aerA)的DNA片段, 将其克隆到pMD18-T载体上。通过序列测定, 分析结果表明：所克隆的1393 bp片段为aerA部分序列, 编码产生464个氨基酸。BZ与NK之间aerA核苷酸同源性为97.6%, 氨基酸同源性为98.3%, 与其它分离物核苷酸同源性为71.6%~97.5%, 氨基酸同源性为68.0%~98.9%。利用邻接法构建了aerA分子树状图, 树状图分析表明：气单胞菌属各分离物聚为三支, 其中嗜水气单胞菌各菌株之间关系密切, 被聚类为同一支。     

嗜水气单胞菌国内分离株的毒力因子分布与致病性相关性分析

为了研究分析国内致病性嗜水气单胞菌的毒力因子的分布及与致病性的相关性及其防治,选取5种主要毒力因子气溶素(aerA)、溶血素(hlyA)、丝氨酸蛋白酶(ahpA)、抗金属蛋白酶(ast)、肠毒素(altA)设计5对特异性引物,用PCR方法进行检测,采用急性毒性实验方法测定菌株对异育银鲫的半数致死量(50%lethal dose,LD50),细菌药物敏感试验纸片扩散(K-B)法检测对抗生素的敏感性,结果显示:除菌株Hong12的LD50约为109 cfu,毒力弱外,其他毒力均较强,LD50均在106 cfu左右。aerA、ahpA、hlyA、altA、ast 5种毒力基因的携带率分别为77.8%、88.9%、100%、100%、77.8%。通过比较嗜水气单胞菌毒力基因的分布情况与其对鲫鱼致病性试验结果可以发现,aerA、ahpA为嗜水气单胞菌致病的主要毒力因子,与致病性存在相关性,ast与致病力存在一定相关性,但不是主要毒力因子,hlyA、altA与致病性不存在相关性。9株嗜水气单胞菌对青霉素、羧苄青霉素、万古霉素不敏感,对复合磺胺、头孢噻肟、利福平中毒敏感,对呋喃妥因、氯霉素、四环素、氧氟沙星高度敏感。     

嗜水气单胞菌菌落多重PCR方法的建立及应用

[背景]嗜水气单胞菌(Aeromonas hydrophila)对水产动物、畜禽和人类均有致病性.基因表达的溶血素、气溶素和肠毒素是重要毒力因子,在致病性嗜水气单胞菌早期检测及防治中尤为重要.目前采用菌落直接提取DNA用于多重PCR研究的相关报道较少.[目的]基于菌落PCR方法建立针对嗜水气单胞菌溶血性基因、肠毒素基因...     

嗜水气单胞菌气溶素基因的克隆与序列分析

以嗜水气单胞菌BZ和NK分离株的DNA为模板,采用PCR技术,扩增气溶素基因(aerA)的DNA片段,将其克隆到pMDl8-T载体上.通过序列测定,分析结果表明:所克隆的1393 bp片段为aerA部分序列,编码产生464个氨基酸.BZ与NK之间aerA核苷酸同源性为97.6%.氨基酸同源性为98.3%,与其它分离物核苷酸同源性为71.6%～97.5%,氨基酸同源性为68.0%～98.9%.利用邻接法构建了aerA分子树状图,树状图分析表明:气单胞菌属各分离物聚为三支,其中嗜水气单胞菌各菌株之间关系密切,被聚类为同一支.     

翘嘴鳜病原嗜水气单胞菌分子特征及LAMP检测方法的建立

嗜水气单胞菌(Aeromonas hydrophila)是一种危害鳜鱼养殖生产的重要病原细菌, 为进一步明确该病原菌的分子特征及建立快速检测技术, 实验对引起翘嘴鳜(Siniperca chuatsi)暴发性死亡的病原嗜水气单胞菌进行了致病性、菌株毒力特征研究, 同时以嗜水气单胞菌气溶素基因aerA为分子靶标设计引物, 利用环介导等温扩增技术(Loop-mediated isothermal amplification, LAMP)建立了病原嗜水气单胞菌的快速检测方法。结果表明, 本次引起翘嘴鳜暴发性死亡的病原嗜水气单胞菌半致死浓度为1.6×106 CFU/mL, 携带aerA等14种毒力基因, 此14种毒力基因可用于其致病性分析及分子检测。以气溶素基因aerA设计引物进行的环介导恒温扩增, 结果显示可扩增出阶梯状条带, 加入SYBR Green I染色后呈现绿色的阳性反应, 而对照组均未出现任何扩增条带且反应体系呈现橙色, 表明LAMP检测方法对于嗜水气单胞菌检测具有很好的特异性; 灵敏度检测的最低检测限为4.6×101 CFU/mL; 10种经人工感染的淡水养殖鱼虾组织匀浆增菌液, 提取DNA后进行LAMP方法检测, 结果均可获得阳性扩增结果, 而对照未染菌组呈阴性, 表明该方法具有较好的应用性, 可应用于嗜水气单胞菌引起的水生动物疾病的检测。     

白藜芦醇抑制嗜水气单胞菌毒力作用研究

为探索白藜芦醇(Resveratrol, Res)在水产动物细菌病防控中的应用价值, 实验以淡水养殖中重要的细菌病原嗜水气单胞菌(Aeromonas hydrophila)为研究对象, 通过设置药物浓度梯度, 检测其对嗜水气单胞菌生长、生物膜形成和溶血活性的抑制作用, 和对毒力及群感调控系统相关基因表达的影响; 同时通过人工感染异育银鲫(Carassius auratus gibelio)试验检测其对鱼体保护作用和对鱼体炎症相关因子基因表达的影响。结果显示: 白藜芦醇对嗜水气单胞菌的最小抑菌浓度(MIC)>1024 μg/mL; 浓度低于64 μg/mL时, 对菌株生长影响不显著; 浓度≥32 μg/mL时, 对病原菌株生物膜形成和溶血活性具有显著抑制作用(P<0.05), 且随剂量增加而增强。荧光定量RT-PCR结果分析发现白藜芦醇能引起嗜水气单胞菌群感调控系统中luxR和luxS基因分别显著上调和下调表达; 外膜蛋白基因omp表达显著下降。人工感染试验发现攻毒前两小时腹腔注射25、50和100 mg/kg白藜芦醇处理组的异育银鲫死亡率显著下降, 鱼体炎症相关的肿瘤坏死因子(TNF-α)和Ⅱ型干扰素(IFN-γ)的mRNA表达量也显著下降。研究表明药用植物大黄、虎杖等所含白藜芦醇成分能有效抑制嗜水气单胞菌毒力, 降低鱼体炎症反应的功效; 腹腔注射25—100 mg/kg白藜芦醇对感染病原菌的异育银鲫有一定保护作用。     

一种检测大鲵致病性嗜水气单胞菌的四重PCR法

建立一种快速诊断致病性嗜水气单胞菌的PCR法。根据嗜水气单胞菌的16S rDNA、外膜蛋白、溶血素及丝氨酸蛋白酶基因设计4对引物,经PCR反应条件优化后进行检测。结果表明,仅嗜水气单胞菌呈阳性,其检测敏感性高,可检测100 fg的DNA模板。20株大鲵源嗜水气单胞菌经四重PCR法检测时,有18株呈阳性。其中,毒力基因种类较多的阳性菌株经人工感染试验和胞外产物活性检测时显示出较高的致病性。利用该PCR法进行的其他检测中,还发现33份人工感染样本全部呈阳性,34份疑似样本有21份呈阳性,说明四重PCR法可应用于临床检测。本研究建立的四重PCR法具有高度敏感性和特异性,可用于嗜水气单胞菌快速诊断。     

多个环境因素对嗜水气单胞菌感染团头鲂致病力的影响

采用正交试验L16(4×213)设计检验了养殖环境中多种理化因子(温度、p H、分子氨、亚硝酸盐)对嗜水气单胞菌感染团头鲂致病力的影响。试验设立温度(A)4个水平(20、24、28、32℃);p H(B)2个水平(6.5、8.0);分子氨(C)2个水平(0.02、0.04 mg·L-1)和亚硝酸盐(D)2个水平(0.1、0.3 mg·L-1),每组试验鱼分别注射嗜水气单胞菌106CFU·m L-1;以试验鱼存活时间的长短判断嗜水气单胞菌对团头鲂致病力的大小。结果表明:分子氨与p H的交互作用(B×C)和温度(A)因素分别对嗜水气单胞菌致病力影响极其显著(FF0.01),p H(B)对嗜水气单胞菌致病力影响显著(FF0.05),而亚硝酸盐(D)和分子氨(C)对嗜水气单胞菌致病力的影响不显著;团头鲂存活时间y(单位为h)与环境因子间的多元线性回归方程为y=164.713-6.399A+14.367B-11.914(B×C);根据该线性回归方程,当温度为20℃、p H=8.0、分子氨浓度为0.02 mg·L-1时,嗜水气单胞菌对团头鲂的致病力最弱,鱼体的存活时间最长(149.76 h)。本实验结果可为团头鲂养殖中的嗜水气单胞菌出血病防控预警提供一定的参考。     

嗜水气单胞菌毒力基因的研究进展

嗜水气单胞菌(Aeromonas hydrophila)隶属于气单胞菌科(Aermonadaceae)气单胞菌属(Aeromonas),为人、畜及水生动物共患的条件致病菌。该菌广泛存在于水环境中,是多种水产动物的主要致病菌。国内外学者对其进行了许多研究,现普遍认为嗜水气单胞菌的致病性与其产生的毒素密切相关。随着分子生物技术的发展,已有许多学者从分子水平上对嗜水气单胞菌进行了研究,为阐明嗜水气单胞菌的致病机理提供了一些理论依据,并建立起针对几种主要毒力因子的检测手段。本文将嗜水气单胞菌目前的研究策略、部分主要毒力因子及其检测手段作一综述,以期为嗜水气单胞菌致病机理的研究及嗜水气单胞菌病的防治提供参考和借鉴。       

聚合酶链反应(PCR)法检测产β-溶血素嗜水气单胞菌

嗜水气单胞菌(A.hydrophila Stanier下略为Ah)隶属弧菌科气单胞菌属,分布广泛,是鱼类、两栖类、爬行类和哺乳类的致病菌。一般认为Ah的致病机理与其产生的毒素密切相关,尤其是溶血素1-5。作者推测采用PCR法检测β-溶血素基因也能用于确认鱼类的致病菌株。本文根据鱼源Ah卜溶血素基因序列设计了两对引物,用Nested-PCR法证实了我国鱼源Ah流行株亦存在卜溶血素的基因后,探讨了应用PCR法检测产卜溶血素Ah的方法及其灵敏度。       

Correlation between the distribution pattern of virulence genes and virulence of Aeromonas hydrophila strains

Nine strains of Aeromonas hydrophila isolated from diseased fish or soft-shelled tortoise were tested for the presence of three virulence genes including the genes encoding aerolysin,hemolysin,and extracellular serine protease (i.e.,aerA,hlyA,and ahpA,respectively).These genes were investigated using polymerase chain reaction (PCR)with specific primers for each gene.And the pathogenicities to Carrassius auratus ibebio of these strains were also assayed.PCR results demonstrated that the distribution patterns of aerA,hlyA,and ahpA were different in these strains.6/9 of A.hydrophila strains were aer A positive,8/9 of strains hly A positive,7/9 of strains ahp A positive,respectively.However,the assay for pathogenesis showed that two strains (A.hydrophila XS91-4-1 and C2)were strong virulent,two strains (A.hydrophila ST78-3-3 and 58-20-9)avirulent and the rest middle virulent was to the fish.In conclusion,there are significant correlation between the distribution pattern of the three virulence genes and the pathogenicity to Carrassius auratus ibebio.All strong virulent A.hydrophila strains were aerA+hlyA+ahpA+genotype,and all aerA+hlyA+ahpA+strains were virulent.Strains with the genotype of aerA-hlyA-ahpA+have middle pathogenicity.In the present study,we found for the first time that all A.hydrophila isolated from the ahpA positive were virulent to Carrassius auratus ibebio.Additionally,there was a positive correlation between the virulence of A.hydrophila and the presence of aerA and ahpA.     

Rapid Aeromonas hydrophila identification by TaqMan PCR assay: comparison with a phenotypic method

Aims:  Aeromonas hydrophila is recognized as a human pathogen following wound exposure or ingestion of contaminated water and food. For rapid identification of this bacterium, a TaqMan-based real-time PCR assay has been developed.
Methods and Results:  Primers and probes that target specific sequences of the 16S rRNA gene and cytolytic enterotoxin gene ( aerA ) were combined in a duplex assay. Presence and size of PCR products were confirmed with microchannel fluidics electrophoresis analysis. After validation, using type strain CIP7614T DNA, the PCR assay was tested on 12 positive and negative controls. Twenty-one Aeromonas strains were isolated from environmental samples and were identified with biochemical tests as Aer. sobria , Aer. caviae and Aer. hydrophila . Only Aer. hydrophila strains tested positive by PCR assay.
Conclusions:  The PCR developed here was successfully applied for the identification of Aer. hydrophila from reference, clinical and environmental samples and showed a high discrimination between Aer. hydrophila and other Aeromonas species.
Significance and Impact of the Study:  This molecular method is convenient, rapid (2·5 h vs 24 h), specific to identify Aer. hydrophila and usable for diagnosis in medical and veterinary laboratories.     

Distribution of two hemolytic toxin genes in clinical and environmental isolates of Aeromonas spp.: correlation with virulence in a suckling mouse model

Previous studies have shown that two hemolytic toxins, HlyA and AerA, contribute to the virulence of Aeromonas hydrophila. A survey was performed to gauge the distribution of hlyA and aerA genes in clinical and environmental Aeromonas isolates. For A. hydrophila, A. veronii biotype sobria and A caviae, 96%, 12% and 35% of strains, respectively, were hlyA positive, whereas, 78%, 97%, 41%, respectively, were aerA positive. All virulent A. hydrophila isolates were hlyA+ aerA+. This genotype was most common in A. hydrophila (75.4%) followed by A. caviae (29.4%) and A. veronii biotype sobria (9.6%). For A. hydrophila, a two-hemolytic toxin model of virulence provides the best prediction of virulence in an animal model.     

Cloning, expression, and mapping of the Aeromonas hydrophila aerolysin gene determinant in Escherichia coli K-12.

DNA sequences corresponding to the aerolysin gene (aer) of Aeromonas hydrophila AH2 DNA were identified by screening a cosmid gene library for hemolytic and cytotoxic activities. A plasmid containing a 5.8-kilobase EcoRI fragment of A. hydrophila DNA was required for full expression of the hemolytic and cytotoxic phenotype in Escherichia coli K-12. Deletion analysis and transposon mutagenesis allowed us to localize the gene product to 1.4 kilobases of Aeromonas DNA and define flanking DNA regions affecting aerolysin production. The reduced hemolytic activity with plasmids lacking these flanking regions is associated with a temporal delay in the appearance of hemolytic activity and is not a result of a loss of transport functions. The aerolysin gene product was detected as a 54,000-dalton protein in E. coli maxicells harboring aer plasmids and by immunoblotting E. coli whole cells carrying aer plasmids. We suggest that the gene coding aerolysin be designated aerA and that regions downstream and upstream of aerA which modulate its expression and activity be designated aerB and aerC, respectively.     

Cloned aerolysin of Aeromonas hydrophila is exported by a wild-type marine Vibrio strain but remains periplasmic in pleiotropic export mutants.

With a wide host range vector, the structural gene aerA for the hole-forming extracellular protein aerolysin of Aeromonas hydrophila was cloned into the marine Vibrio sp. strain 60 and into three pleiotropic export mutants (epr mutants). The parent strain and all of the mutants were able to express the protein with the aerA promoter in the plasmid. The parent strain exported proaerolysin into the medium, while all of the mutants accumulated the protoxin in their periplasms. Two of the mutants also accumulated protease; however, as we have found earlier with A. hydrophila, the periplasmic form of proaerolysin in the Vibrio sp. must somehow be protected from proteolysis because it was not converted to active toxin until the cells were shocked. Conversion could be prevented by adding o-phenanthroline to the solutions used in shocking. These results show that the export pathway in the marine Vibrio sp. is very similar to the pathway in A. hydrophila.     

Virulence markers in Aeromonas hydrophila and Aeromonas veronii biovar sobria isolates from freshwater fish and from a diarrhoea case

AIMS: To evaluate the public health significance of representative strains of two Aeromonas spp., mainly from freshwater fish, on the basis of production of virulence-associated factors and presence of the haemolytic genes aerA and hlyA. METHODS AND RESULTS: Eleven strains of Aer. hydrophila, three strains of Aer. veronii biovar sobria (all from freshwater fish) and one strain of Aer. hydrophila from human diarrhoea were tested for potential virulence traits and for the presence of the haemolytic genes aerA and hlyA. Ten Aer. hydrophila isolates were aerA(+)hlyA(+) and two aerA(+)hlyA(-). Aeromonas veronii biovar sobria isolates were aerA(-)hlyA(-). Strains from the three genotypes showed enterotoxic activity in the suckling mouse assay. At 28 degrees C, four Aer. hydrophila fish strains could be considered as potentially virulent (possessing at least two of these characteristics: haemolytic, cytotoxic and enterotoxic). One Aer. veronii biovar sobria strain and the clinical isolate were cytotoxic on Vero cells. When grown at 4 degrees C, these six isolates fulfilled virulence criterion, but at 37 degrees C, only one fish strain, an Aer. hydrophila, did. CONCLUSIONS: The potential health risk derived from the presence of Aer. hydrophila and Aer. veronii biovar sobria in ice-stored freshwater fish should not be underestimated. SIGNIFICANCE AND IMPACT OF THE STUDY: Expression of virulence factors is affected by temperature incubation and not always related to the presence of haemolytic genes.