罗氏沼虾白斑综合症病毒WSSV ORF147片段的克隆、表达与序列分析

白斑综合症病毒WSSV(White Spot Syndrome Virus),是严重危害虾类养殖业的主要病原之一.本实验根据已知南美白对虾WSSV ORF147序列设计1对特异性引物,从患疑似白斑病毒病的罗氏沼虾中提取总DNA,用PCR法扩增得到1特异性片段.将该片段克隆进pET-28a( )载体,测序表明该片段全长1 475 bp,最大开放式阅读框为1 380 bp,编码459个氨基酸,预计其相对分子质量为51.9 kDa;与GenBank登录的WSSV ORF147序列(登录号AF369029)进行比对,核苷酸同源性为99%,证实为WSSV ORF147片段.将该片段在大肠杆菌E coli中进行表达,能获得相应的特异多肽条带.根据测序结果推导WSSV ORF147多肽在N端有信号肽序列,并且在氨基酸序列的122～144区间形成跨膜螺旋区.     

对虾白斑综合征病毒囊膜蛋白VP28研究进展

对虾白斑综合征病毒(white spot syndrome virus,WSSV)是在水产养殖中引起对虾等甲壳类动物发生严重病害的病原体。VP28是WSSV中最重要的囊膜蛋白之一,在WSSV感染对虾的初期起着至关重要的作用。文章从基因和蛋白质结构、VP28在病毒入侵中的作用及免疫应用等方面概述了VP28的研究进展,可为WSSV的防治研究提供参考。     

以 WWSV ORF234片段诊断罗氏沼虾白斑病毒病及片段分析

根据GenBank中登录的对虾白斑综合症病毒(WSSV )全基因组序列中和ORF234相应的序列来设计1对引物, 从疑似病例的罗氏沼虾中提取总DNA, 并以此为模板, 经PCR扩增出约885 bp的特异性片段, 克隆进质粒载体pET- 28a( + ), 进行序列测定和分析。结果显示: 扩增序列共编码294个氨基酸, 预测的相对分子质量为34kDa, 与G enBank中登录序列的对应区域同源性达99%, 由此确认该罗氏沼虾患有白斑综合病毒病。该序列所编码的蛋白在22~ 96氨基酸位置有一段球状结构, 在142~ 272 氨基酸位置有一个与DUF1335 蛋白同源的将近130个氨基酸残基的保守区, 其功能未知。同时还对克隆出的片段进行序列分析和蛋白预测, 以进一步深入开展蛋白的功能及对该病毒病的防治的研究。     

以WWSV ORF234片段诊断罗氏沼虾白斑病毒病及片段分析

根据GenBank中登录的对虾白斑综合症病毒(WSSV)全基因组序列中和ORF234.相应的序列来设计1对引物,从疑似病例的罗氏沼虾中提取总DNA,并以此为模板,经PCR扩增出约885 bp的特异性片段,克隆进质粒载体pET-28a(+),进行序列测定和分析.结果显示:扩增序列共编码294个氨基酸.预测的相对分子质量为34kDa,与GenBank中登录序列的对应区域同源性达99%,由此确认该罗氏沼虾患有白斑综合病毒病.该序列所编码的蛋白在22～96氨基酸位置有一段球状结构,在142～272氨基酸位置有一个与DUF1335蛋白同源的将近130个氨基酸残基的保守区,其功能未知.同时还对克隆出的片段进行序列分析和蛋白预测,以进一步深入开展蛋白的功能及对该病毒病的防治的研究.     

白斑综合征病毒囊膜蛋白VP19及VP28的研究进展

自二十世纪90年代,白斑综合征病毒(WSSV)就因其暴发范围广、致死率高得到了广泛的关注。研究主要集中在确定该病毒蛋白的结构及功能,以及利用其囊膜蛋白制备亚单位疫苗、研发DNA疫苗等来提高对虾抵抗白斑综合征病毒的能力,尽管免疫防治目前在实验室阶段已取得了显著的保护效果,但因其给药方式局限以及成本较高等因素一直没有应用于实际生产中。VP19和VP28是白斑综合征病毒主要的囊膜蛋白,在WSSV感染对虾的过程中起着非常重要的作用。本文从WSSV的基因组学、VP19和VP28的蛋白质结构及其在免疫防治中的应用等方面概述了VP19和VP28的研究进展,包括蛋白亚单位疫苗、DNA疫苗、RNA疫苗以及相关抗体的研究。在总结了不同类型疫苗的保护效果后发现,VP19和VP28的双价疫苗的保护率较高,为今后制定有效的WSSV控制方法提供了参考。     

凡纳滨对虾和罗氏沼虾肠道微生物及抗生素抗性基因多样性分析

探究凡纳滨对虾和罗氏沼虾肠道微生物及抗生素抗性基因(antibiotic resistance genes, ARGs)种类的差异。通过高通量测序和变性梯度凝胶电泳(denaturing gradient gel electrophoresis, DGGE)技术分析2种虾肠道微生物群落结构差异和微生物多样性,并运用PCR方法检测了2种虾肠道细菌常见38种ARGs的携带情况。结果显示,获得凡纳滨对虾和罗氏沼虾肠道细菌有效序列分别为42 795和40 713条,物种注释单元(operational taxonomic unit, OTU)数目分别为124和82,分类地位明确的细菌种类分别隶属5个门、17个属和5个门、16个属。凡纳滨对虾肠道细菌的优势类群为变形菌门,所占比例为75.45%,优势菌属为副球菌属(25.83%)和不动杆菌属(25.24%);罗氏沼虾肠道细菌的优势类群是厚壁菌门(49.74%),优势菌属为乳球菌属(49.01%)和弧菌属(29.98%)。凡纳滨对虾肠道细菌(2.19)Shannon指数高于罗氏沼虾肠道细菌(1.78),表明前者肠道细菌多样性大于后者。DGGE图谱的分析结果与高通量测序一致,2种虾肠道细菌种类差异很大。PCR结果显示,凡纳滨对虾肠道细菌携带15种ARGs,罗氏沼虾肠道细菌携带14种ARGs。本实验表明凡纳滨对虾肠道细菌的群落种类多样性、OTU丰富度、物种总数和ARGs种类均高于罗氏沼虾肠道细菌,为后续肠道微生物资源的挖掘提供了理论依据。     

南美白对虾亲虾暴发性传染病病原调查

对福建、广东沿海对虾育苗场的南美白对虾亲虾暴发性传染病进行病原学研究,结果表明大部分亲虾感染了白斑综合症病毒,还有一些亲虾同时感染桃拉综合症病毒。发病对虾体色发红,部分对虾体表可见大小不一的白色斑点。对这些病毒的PCR扩增产物进行测序,并进行同源性比较,结果表明导致本次对虾传染病的WSSV基因片段与基因库已报告的WSSV具有很高的同源性。结合流行病学特点,可确定这些亲虾主要因感染了WSSV和TSV而发病死亡。     

对虾白斑综合征病毒囊膜蛋白VP19的单克隆抗体制备及其定位

为了更好地研究对虾自斑综合征病毒(WSSV)蛋白VP19在WSSV感染过程巾的作用,利用VP 19的单克隆抗体直接对VP19进行了定位.从患白斑综合征的中国明对虾(Fenneropenaeus chinensis)鳃丝中提取WSSV,将提纯的WSSV经十二烷基磺酸钠-聚内烯酰胺凝胶电泳(SDS-PAGE)分离,然后洗脱提纯其病毒蛋白VP19并免疫Balb/c小鼠,取免疫小鼠脾细胞和骨髓瘤细胞融合,用间接免疫荧光技术(IFAT)和Western-Blot技术筛选出1株阳性杂交瘤细胞,将检测出的阳性杂交瘤细胞经有限稀释法克隆,研制出抗VP19的单抗,再利用免疫胶体金技术对病毒蛋白VP19进行定位,结果显示,胶体金粒子位于WSSV病毒的囊膜上,说明病毒篮白VP19位于WSSV囊膜上.[中国水产科学,2009,16(1):69-74]     

养殖对虾病毒病控制技术的创新与集成

<正>对虾白斑综合症病毒(WSSV)是全世界危害最严重的对虾病毒。目前对于该病毒尚没有特效药,最根本的办法就是预防感染,采取综合措施,实现健康养虾。笔者从1993-2003年在50亩虾池中连续做了11年的防病养虾试验,预防对虾白斑病(WSSV)取得了令人满意的试验成     

凡纳滨对虾RAS与WSSV-VP26的相互作用

白斑综合征病毒(WSSV)是对虾养殖中主要的病原之一,病原与宿主作用是介导病毒感染的重要过程。RAS蛋白是Ras基因分泌的保守蛋白,为小G蛋白家族的一员,普遍存在于从酵母菌到哺乳动物的真核细胞中,具有偶联受体和效应系统传递跨膜信号的功能,在细胞增殖和分化中起双重调节的作用,但关于RAS与WSSV的作用尚不明确。本研究将凡纳滨对虾(Litopenaeus vannamei) Ras基因克隆至pBAD/gⅢA表达载体上,以E. coli Top10为宿主菌,在L-阿拉伯糖的诱导下获得RAS重组蛋白。以Co~(2+)亲和层析方法,获得纯化的RAS蛋白,质谱分析显示,该蛋白为凡纳滨对虾RAS。采用Far-western和ELISA检测方法分析RAS与WSSV结构蛋白VP26、VP28N和VP37的相互作用。Far-western结果显示,RAS与VP26有明显的结合作用,ELISA实验结果显示,RAS与VP26蛋白的相互作用随RAS量的增加而增强。本研究表明,RAS参与WSSV侵染过程,为进一步研究WSSV侵染机制提供了理论基础。     

Nucleotide sequence variations of the major structural proteins (VP15, VP19, VP26 and VP28) of white spot syndrome virus (WSSV), a pathogen of cultured Litopenaeus vannamei in Mexico

White spot syndrome virus (WSSV) was first reported in farmed Litopenaeus vannamei stocks in Sinaloa and Sonora, Mexico during 1999 and continues to cause severe shrimp losses. WSSV genes encoding nucleocapsid (VP26 and VP15) and envelope proteins (VP19 and VP28) of a Mexican isolate were cloned in the pMosBlue vector. The nucleotide sequences of these genes were compared with WSSV isolates in GenBank. VP15 is highly conserved, and VP26 showed 99% homology to a Chinese isolate. The VP28 fragment demonstrated 100% homology to the majority of the isolates analysed (UniProt accession no. Q91CB7), differing from two Indian WSSV and one Chinese WSSV isolates by two non-conserved and one conserved replacements, respectively. Because of their highly conserved nature, these three structural proteins are good candidates for the development of antibody-based WSSV diagnostic tools or for the production of recombinant protein vaccines to stimulate the quasi-immune response of shrimp. In contrast, VP19 of the Mexican isolate was distinguishable from almost all isolates tested, including an American strain of WSSV (US98/South Carolina, GenBank accession no. AAP14086). Although homology was found with isolates from Taiwan (GenBank accession no. AAL89341) and India (GenBank accession no. AAW67477), VP19 may have application as a genetic marker.     

对虾白斑综合征病毒囊膜蛋白VP28和VP26的毕赤酵母组成型分泌表达

近年来,重组 VP28和 VP26蛋白作为蛋白亚单位疫苗,在增强对虾抗白斑综合征病毒(WSSV)感染的过程中具有重要作用。本研究根据GenBank中WSSV的基因序列设计引物,以WSSV粗提液为模板进行普通PCR扩增,得到VP28和VP26基因,再用引物悬挂法将EcoRⅠ和XbaⅠ酶切位点分别添加到 VP28和 VP26基因的5￠端和3￠端。目的基因经双酶切后插入到表达载体pGAPZαA,转化TOP10大肠杆菌,经博莱霉素(Zeocin)抗性筛选阳性重组酵母表达载体。AvrⅡ酶切线性化之后,电击转化 X-33毕赤酵母感受态细胞,经 Zeocin 抗性筛选得到阳性重组酵母。SDS-PAGE电泳分析重组酵母表达上清液的目的蛋白,没有检测到VP28和VP26重组蛋白。随后,采用蛋白质银染法,结果显示,与空载pGAPZαA组相比,VP28和VP26表达上清液组有明显的条带,证明VP28和VP26在毕赤酵母中成功表达,蛋白分子量大小约为32 kDa。     

Protection of crayfish, Cambarus clarkii, from white spot syndrome virus by polyclonal antibodies against a viral envelope fusion protein

White spot syndrome virus (WSSV) is a large double-stranded DNA virus, causing considerable mortality in penaeid shrimp and other crustaceans. WSSV produces five major structural proteins, including two major envelope proteins, VP28 and VP19. To produce VP28 and VP19 as a single protein for antibody production, DNA sequences encoding both open reading frames were fused together and cloned into pET-22b(+) expression vector. The fusion protein, VP(19+28), was expressed in Escherichia coli, purified using Ni2+ His affinity chromatography and injected into a rabbit. Antiserum collected from the immunized rabbit was tested in vivo for ability to protect crayfish, Cambarus clarkii, from disease caused by WSSV. Fifteen days after challenge with WSSV, treatment with VP(19+28) antiserum gave 100% protection against disease in the ambient temperature range of 15-22 degrees C and 65% protection at a constant temperature of 26 degrees C. These results demonstrated VP(19+28) antiserum is effective in protection of crayfish from WSSV and confirmed that VP19 and VP28 play an important role in WSSV host infection. Targeting both VP19 and VP28 may be effective for the design of both immunotherapeutic medicines and reagents to detect WSSV.     

Production of polyclonal antiserum against recombinant VP28 protein and its application for the detection of white spot syndrome virus in crustaceans

The VP28 gene of white spot syndrome virus (WSSV) was cloned into pRSET B expression vector. The VP28 protein was expressed as a protein with a 6-histidine taq in Escherichia coli GJ1158 with NaCl induction. Antiserum was raised against this recombinant-VP28 protein in rabbits and it recognized VP28 protein in naturally and experimentally WSSV-infected shrimp, marine crabs, freshwater prawns and freshwater crabs. The antiserum did not recognize any of the other known WSSV structural proteins. Various organs such as eyestalks, head muscle, gill tissue, heart tissue, haemolymph, tail tissue and appendages were found to be good materials for detection of WSSV using the antiserum and detection of WSSV was successful in experimentally infected Penaeus monodon and P. indicus at 12 and 24 h post-infection (p.i.), respectively. The antiserum was capable of detecting WSSV in 5 ng of total haemolymph protein from WSSV-infected shrimp.     

Development of monoclonal antibodies against VP28 of WSSV and its application to detect WSSV using immunocomb

White spot disease (WSD) is an important viral disease of penaeid shrimp caused by white spot syndrome virus (WSSV). WSSV isolated from WSD outbreaks in commercial shrimp (Penaeus monodon) farms in India were propagated in the laboratory in healthy shrimp. The virus was purified from the infected tissues by sucrose gradient centrifugation. The VP28 was electroeluted from SDS-PAGE gels and was used to immunize Balb/c mice to produce hybridomas secreting monoclonal antibodies (MAb) against WSSV. A total of five hybridoma clones secreting MAbs to VP28 were produced. The MAbs were of the isotypes IgG1, IgG2b and IgM. The MAbs reacted with VP28 of WSSV and not with any other viral or shrimp protein in western blot. The MAbs were used to develop dot immunoblot assay using an immunocomb to detect WSSV from field samples. The test developed had an analytical sensitivity of 625 pg and a diagnostic sensitivity of 100% compared to single step polymerase chain reaction (PCR). The test can be used as an alternate for first step PCR to detect WSSV from field samples.     

Characterization and application of monoclonal antibodies against white spot syndrome virus

Three hybridoma clones secreting monoclonal antibodies (MAbs) were produced from mouse myeloma and spleen cells immunized with white spot syndrome virus (WSSV) isolated and purified from Penaeus monodon (Fabricius), collected from north-eastern Taiwan. By sodium dodecyl sulphate–polyacrylamide gel electrophoresis (SDS–PAGE), the protein profile of this isolate contained four major proteins with sizes of approximately 35 (VP35), 28 (VP28), 24 (VP24), and 19 kDa (VP19). Western blot analysis revealed that two MAbs (1D7 and 6E1) recognized epitopes on VP28 and one MAb (3E8) recognized an epitope on VP19. The MAb 6E1 isotyped to the IgG₁ class was used in both an indirect immunofluorescence assay (IFA) and in an immunochemical staining protocol for successful identification and localization of WSSV in infected shrimp tissues. Antigenic similarity of isolates from Indonesia and Malaysia to the Taiwan isolate was illustrated by IFA with MAb 6E1. A MAb (2F6) which bound specifically to two shrimp proteins, 75 and 72 kDa, and reacted to the healthy and non-target tissues of WSSV in infected shrimp, such as hepatopancreas, is also described here and shows the necessity for specific identification of antibodies.     

Protection of Fenneropenaeus chinensis (Osbeck, 1765) against the white spot syndrome virus using specific chicken egg yolk immunoglobulins by oral delivery

Two kinds of specific chicken egg yolk immunoglobulins (IgYs), IgY‐WSSV and IgY‐VP28, were, respectively, raised against the 2 mM binary ethylenimine (BEI)‐inactivated white spot syndrome virus (WSSV) and a principal envelope protein VP28. The activity of purified specific IgYs was stable under the conditions of 20–70 °C, pH 3.0–10.0 and 0–700 g L^?1 sucrose solution. In the neutralization assay, these high‐affinity IgY antibodies can specifically bind with the virus particles to protect shrimp (Fenneropenaeus chinensis) against WSSV infection. After oral delivery for 20 days, the IgY‐WSSV exerted a higher protection effect (RPS: 71.5%) than IgY‐VP28 (RPS: 63.7%). Moreover, an increase in RPS (79.2%) was found on addition of IgY‐WSSV:VP28 (0.1% IgY‐VP28 plus 0.2% IgY‐WSSV). This may indicate that neutralization of WSSV refers to the multiple‐hit model. By time‐course study of the levels of the specific IgYs in vivo, the data showed that the titre was enhanced to a relatively high level (P/N=8.35±0.45) at 3 days post administration, declined slightly (P/N=7.13±1.01) at 7 days post administration and then remained stable for further investigation. The stable antibody level potentially contributes towards blocking a large number of WSSV particles from entering and infecting on the major tissues at the early and late stages after challenge in shrimp.     

Protection of Procambarus clarkii against white spot syndrome virus using recombinant subunit injection vaccine expressed in Pichia pastoris

ABSTRACT:   The potentiality of injection vaccine against white spot syndrome virus (WSSV) in crayfish Procambarus clarkii was investigated. WSSV envelope proteins VP19 and VP28 were expressed in yeast Pichia pastoris GS115. The purified recombinant proteins (2 µg/g of crayfish) were injected intramuscularly, and the same dose injected as a booster shot on fifth day after vaccination. The vaccinated crayfish were divided into two even groups and later challenged orally by WSSV-infected dead crayfish muscle (2 g/individual) on the third and 21st days after the booster shot. The relative percent survival (RPS) in the third-day group was the highest in VP28 (91%), followed by VP19 + VP28 (84%), and VP19 (45%). The RPS for the 21st-day group was the highest in VP28 (78%), followed by VP19 + VP28 (76%), and VP19 (17%). Development of vaccine by using recombinant proteins VP19 and VP28 expressed in yeast is feasible.