37 resultados para Enteric viruses
Resumo:
硫化叶菌病毒表现出了极为独特、多样的形态学和基因组学特征,它们为研究硫化叶菌提供了很好的模型,同时也为构建可在硫化叶菌中进行分子操作的分子工具提供了有用的材料。 本研究从西藏热泉中分离出一株嗜酸热菌S3-3,S3-3的16S rDNA序列和腾冲硫化叶菌同源性最高,为96%,而和其它硫化叶菌同源性相对较低。基于16S rDNA序列进行的系统发育学分析同样证实了,S3-3和腾冲硫化叶菌亲缘关系最近,推测S3-3是硫化叶菌属的一新种。 从S3-3a中分离出一株硫化叶菌病毒,命名为西藏硫化叶菌丝状病毒(Sulfolobus Tibet Filamentous Virus, STFV)。STFV呈丝状,外面有一层脂膜包裹,病毒长约1.4 μm,病毒直径约20 nm,两端各有一约60 nm长的小尾巴。病毒的复制抑制宿主细胞生长,但并不引起宿主细胞的裂解。STFV的DNA为线性双链DNA,推测其DNA末端含共价闭合的发夹结构。已经完成了除病毒末端以外的基因组序列的测定,共测得序列29 568 bp。病毒基因组DNA的GC含量为32.70%,编码49个阅读框,其中包括四个解旋酶基因,四个糖基转移酶基因,一个核苷酸转移酶基因和一个磷酸转移酶基因。其中35个阅读框在已知硫化叶菌病毒中有同源基因。病毒含有两个主要的结构蛋白,分别由ORF162 和 ORF219所编码,这两个结构蛋白在Betalipothrixvirus中非常保守。基因组比对发现,STFV和Betalipothrixvirus的同源性很高。所有的证据表明,STFV为一新的病毒,属于硫化叶菌病毒Lipothrixviridae病毒科,Betalipothrixvirus病毒属。 腾冲硫化叶菌纺锤型病毒STSV1由向小宇博士分离。该病毒编码一个整合酶基因。但通过Southern杂交分析,未检测到病毒基因组整合至宿主基因组中。STSV1病毒颗粒的蛋白由5个阅读框所编码,而其主要的结构蛋白由ORF40编码。
Resumo:
A method of loop-mediated isothermal amplification (LAMP) was employed to develop a rapid and simple detection system for porcine circovirus type 2 (PCV2). The amplification could be finished in 60 min under isothermal condition at 64 degrees C by employing a set of four primers targeting the cap gene of PCV2. The LAMP assay showed higher sensitivity than the conventional PCR, with a detection limit of five copies per tube of purified PCV2 genomic DNA. No cross-reactivity was observed from the samples of other related viruses including porcine circovirus type 1 (PCV1), porcine parvovirus (PPV), porcine pseudorabies virus (PRV) and porcine reproductive and respiratory syndrome virus (PRRSV). The detection rate of PCV2 LAMP for 86 clinical samples was 96.5% and appeared greater than that of the PCR method. The LAMP assay reported can provide a rapid yet simple test of PCV2 suitable for laboratory diagnosis and pen-side detection due to ease of operation and the requirement of only a regular water bath or heat block for the reaction. (c) 2008 Elsevier B.V. All rights reserved.
Resumo:
Edwardsiella tarda is an important Gram-negative enteric pathogen affecting both animals and humans. It possesses a type III secretion system (T3SS) essential for pathogenesis. EseB, EseC and EseD have been shown to form a translocon complex after secretion, while EscC functions as a T3SS chaperone for EseB and EseD. In this paper we identify EscA, a protein required for accumulation and proper secretion of another translocon component, EseC. The escA gene is located upstream of eseC and the EscA protein has the characteristics of T3SS chaperones. Cell fractionation experiments indicated that EscA is located in the cytoplasm and on the cytoplasmic membrane. Mutation with in-frame deletion of escA greatly decreased the secretion of EseC, while complementation of escA restored the wild-type secretion phenotype. The stabilization and accumulation of EseC in the cytoplasm were also affected in the absence of EscA. Mutation of escA did not affect the transcription of eseC but reduced the accumulation level of EseC as measured by using an EseC-LacZ fusion protein in Ed. tarda. Co-purification and co-immunoprecipitation studies demonstrated a specific interaction between EscA and EseC. Further analysis showed that residues 31-137 of EseC are required for EseC-EscA interaction, Mutation of EseC residues 31-137 reduced the secretion and accumulation of EseC in Ed. tarda. Finally, infection experiments showed that mutations of EscA and residues 31-137 of EseC increased the LD50 by approximately 10-fold in blue gourami fish. These results indicated that EscA functions as a specific chaperone for EseC and contributes to the virulence of Ed. tarda.
Resumo:
Edwardsiella tarda is a Gram-negative enteric pathogen that causes disease in both humans and animals. Recently, a type III secretion system (T3SS) has been found to contribute to Ed. tarda pathogenesis. EseB, EseC and EseD were shown to be secreted by the T3SS and to be the major components of the extracellular proteins (ECPs). Based on sequence similarity, they have been proposed to function as the 'translocon' of the T3SS needle structure. In this study, it was shown that EseB, EseC and EseD formed a protein complex after secretion, which is consistent with their possible roles as translocon components. The secretion of EseB and EseD was dependent on EscC (previously named Orf2). EscC has the characteristics of a chaperone; it is a small protein (13 kDa), located next to the translocators in the T3SS gene cluster, and has a coiled-coil structure at the N-terminal region as predicted by COILS. An in-frame deletion of escC abolished the secretion of EseB and EseD, and complementation of Delta escC restored the export of EseB and EseD into the culture supernatant. Further studies showed that EscC is not a secreted protein and is located on the membrane and in the cytoplasm. Mutation of escC did not affect the transcription of eseB but reduced the amount of EseB as measured by using an EseB-LacZ fusion protein in Ed. tarda. Co-purification studies demonstrated that EscC formed complexes with EseB and EseD. The results suggest that EscC functions as a T3SS chaperone for the putative translocon components EseB and EseD in Ed. tarda.
Resumo:
Viperin is an antiviral protein that has been found to exist in diverse vertebrate organisms and is involved in innate immunity against the infection of a wide range of viruses. However, it is largely unclear as to the potential role played by viperin in bacterial infection. In this study, we identified the red drum Sciaenops ocellatus viperin gene (SoVip) and analyzed its expression in relation to bacterial challenge. The complete gene of SoVip is 2570 bp in length and contains six exons and five introns. The open reading frame of SoVip is 1065 bp, which is flanked by a 5'-untranslated region (UTR) of 34 bp and a 3'-UTR of 350 bp. The deduced amino acid sequence of SoVip shares extensive identities with the viperins of several fish species and possesses the conserved domain of the radical S-adenosylmethionine superfamily proteins. Expressional analysis showed that constitutive expression of SoVip was relatively high in blood, muscle, brain, spleen, and liver, and low in kidney, gill, and heart. Experimental challenges with poly(I:C) and bacterial pathogens indicated that SoVip expression in liver was significantly upregulated by poly(I:C) and the fish pathogen Edwardsiella tarda but down-regulated by the fish pathogens Listonella anguillarum and Streptococcus iniae. Similar differential induction patterns were also observed at cellular level with primary hepatocytes challenged with E. tarda, L anguillarum, and S. iniae. Infection study showed that all three bacterial pathogens could attach to cultured primary hepatocytes but only E. tarda was able to invade into and survive in hepatocytes. Together these results indicate that SoVip is involved in host immune response during bacterial infection and is differentially regulated at transcription level by different bacterial pathogens. (C) 2010 Elsevier Ltd. All rights reserved.
Resumo:
对虾病害在世界范围内的广泛传播,给水产养殖和沿海农村经济造成了重大损失。深入开展对虾免疫机制研究并在此基础上寻找对虾疾病防治的有效方法已成为当务之急。研究表明,当对虾等甲壳动物受到外界病原刺激时,其体内的吞噬细胞在吞噬活动中会激活磷酸己糖支路的代谢,引起呼吸爆发,产生多种活性氧分子。另外,受到病原侵染的对虾还会产生其他多种免疫反应,这些免疫反应将消耗大量的能量(ATP),产能的呼吸链会加速运转,由此也会引发大量活性氧的产生。这些活性氧分子可以杀灭入侵的病原微生物,但同时由于活性氧分子反应的非特异性,它们也会对宿主的细胞、组织和器官造成严重伤害,进而导致对虾生理机能的损伤和免疫系统的破坏。所以,消除对虾体内因过度免疫反应产生的过量氧自由基将能够增强其抵御病原侵染的能力,提高免疫力。本论文从中国明对虾体内克隆了线粒体型超氧化物歧化酶(mMnSOD)、胞质型超氧化物歧化酶(cMnSOD)、过氧化氢酶(Catalase)和过氧化物还原酶(Peroxiredoxin)等四种与免疫系统相关的抗氧化酶基因,分析了它们的分子结构特征,组织分布及应答不同病原刺激的表达变化模式,并对其中的mMnSOD基因和Peroxiredoxin基因进行了体外重组表达、分离纯化和酶活性分析。 采用RACE技术从中国明对虾血细胞中克隆了两个超氧化物歧化酶(SOD)基因,通过序列比对分析发现,其中一个为mMnSOD基因,另一个为cMnSOD基因。mMnSOD基因的cDNA全长为1185个碱基,其中开放阅读框为660个碱基,编码220个氨基酸,其中推测的信号肽为20个氨基酸。多序列比对结果显示中国明对虾mMnSOD基因的推导氨基酸序列与罗氏沼虾、蓝蟹的推导氨基酸序列同源性分别为88%和82%。Northern blot结果表明,该基因在对虾的肝胰脏、血细胞、淋巴器官、肠、卵巢、肌肉和鳃等组织中均有表达。半定量RT-PCR结果显示,对虾感染病毒3 h时,该基因在血细胞和肝胰脏中的转录水平显著升高。此外,通过构建原核表达载体,本研究对该基因进行了体外重组表达,并对纯化的重组蛋白进行了质谱鉴定和酶活分析。cMnSOD基因的cDNA全长为1284个碱基,其中开放阅读框为861个碱基,编码287个氨基酸。多序列比对结果显示中国明对虾cMnSOD基因的推导氨基酸序列与斑节对虾和凡纳滨对虾的同源性高达98%和94%。组织半定量结果显示,cMnSOD基因在对虾被检测的各个组织中均有表达。 另外,半定量RT-PCR结果表明,对虾感染病毒23h时,该基因在肝胰脏中的转录上升到正常水平的3.5倍;而感染后59 h时,该基因在血细胞中的转录上升到正常水平的2.5倍。 利用根据其他生物过氧化氢酶保守氨基酸序列设计的简并引物,结合RACE技术,从中国明对虾肝胰脏中克隆到了过氧化氢酶基因的部分片段,片段长1725个碱基。多序列比对结果发现目前所得中国明对虾Catalase基因部分片段的推导氨基酸序列与罗氏沼虾和皱纹盘鲍Catalase氨基酸序列的同源性分别达到95%和73%。通过实时荧光定量PCR技术对中国明对虾Catalase基因在各个组织中的分布情况及病毒感染后该基因在血细胞和肝胰脏中的转录变化进行了研究。结果发现,该基因在肝胰脏、鳃、肠和血细胞中表达水平较高,在卵巢、淋巴器官和肌肉中的表达水平相对较弱;感染病毒23 h和37 h时,对虾血细胞和肝胰脏中该基因mRNA的表达量分别出现显著性上升。 依据中国明对虾头胸部cDNA文库提供的部分片段信息,结合SMART-RACE技术,从中国明对虾肝胰脏中克隆到了过氧化物还原酶基因(Peroxiredoxin), 该基因的cDNA全长为942个碱基,其中开放阅读框为594个碱基,编码198个氨基酸。中国明对虾Peroxiredoxin基因的推断氨基酸序列与伊蚊、文昌鱼和果蝇等Peroxiredoxin基因的推断氨基酸序列同源性分别为77%、76%和73%。其蛋白理论分子量为22041.17 Da,pI为5.17。Northern blot结果表明,Peroxiredoxin基因在对虾的肝胰脏、血细胞、淋巴器官、肠、卵巢、肌肉和鳃等组织中均有表达。实时荧光定量PCR结果显示,弧菌感染后,该基因在对虾血细胞和肝胰脏中的转录水平都有明显变化并且表达模式不同。另外,对该基因进行了体外重组表达,并对纯化的重组蛋白进行了质谱鉴定和酶活性分析。酶活性分析表明,复性后的重组蛋白能在DTT存在的条件下还原H2O2。
Resumo:
Acute peristome edema disease (APED) is a new disease that broke out in cultured sea cucumber along the Shangdong and Liaoning province coasts in China, PR, and has caused a great deal of death in Apostichopus japonicus (Selenka) since 2004. Here we report virus-like particles found in intestine epithelium of sea cucumbers reared in North China. It is the first time that sea cucumbers are reported to be infected by virus. Histological examinations showed that the viral inclusion bodies existed in intestine epithelium cells. Electron microscopic examinations show that the virions were spherical, 80-100 nm in diameter, and composed of a helical nucleocapsid within an envelope with surface projections. Detailed studies on the morphogenesis of these viruses found many characteristics previously described for coronaviruses. Virus particles always congregated, and formed a virus vesicle with an encircling membrane. The most obvious cellular pathologic feature is large granular areas of cytoplasm, relatively devoid of organelles. Tubular structures within virus-containing vesicles, nucleocapsid inclusions, and double-membrane vesicles are also found in the cytopathic cells. No rickettsia, chlamydia, bacteria, or other parasitic organisms were found. (c) 2007 Elsevier Inc. All rights reserved.
