家蚕蛹表达的重组Vp28疫苗对克氏原螯虾的抗病毒保护效应

对虾白斑综合症病毒(WSSV)的致病性强、危害性大、地域分布和宿主范围广泛,目前还不能有效地控制疫情。将含有WSSV囊膜蛋白Vp28基因的重组杆状病毒HyNPV-Vp28感染家蚕(Bombyx mori)蛹,对发病蚕血淋巴进行SDS-PAGE和Western blotting分析,结果表明Vp28在家蚕体内得到了表达。将重组病毒囊膜蛋白rVp28疫苗配制成药饵,持续口服免疫75天,对克氏原螯虾进行预防WSSV,实验虾分为2%重组Vp28疫苗、2%普通蚕蛹组织匀浆(阳性对照)和普通饵料(阴性对照)3个处理组。免疫35天后进行口服攻毒,20天内rVp28疫苗组的累积存活率为63.33%,与阳性和阴性对照比差异显著(P<0.05),PRP分别达54.16%和59.26%;注射攻毒后20 天内rVp28疫苗组的累积存活率与阳性和阴性对照组比差异不显著(P>0.05),PRP分别为46.12% 和49.99%。第55天对存活虾再口服攻毒,20天内rVp28疫苗组与阳性和阴性对照组比累积存活率差异显著(P<0.05),PRP分别为55.80%和63.16%;二次注射攻毒后,rVp28疫苗组的PRP均为31.25%。对vVp28疫苗组存活虾的胃、肠和肝胰腺组织进行病毒的原位杂交检测均呈阴性反应,而对照组死亡虾组织都呈阳性反应。本研究表明,口服免疫家蚕蛹表达的病毒囊膜蛋白Vp28能诱导螯虾产生抗病毒保护作用,对应用疫苗预防对虾的病毒性疾病具有重要意义。     

对虾白斑综合征病毒囊膜蛋白VP53B原核表达及抗血清的制备

【目的】研究对虾白斑综合征病毒(White spot syndrome virus,WSSV)囊膜蛋白sVP53B克隆、表达、纯化及抗血清制备。【方法】根据WSSV囊膜蛋白基因序列,设计引物,PCR扩增出功能序列(Svp53B),构建到pET-16b载体后,转化至大肠杆菌Rosetta 2诱导表达,用SDS-PAGE、Western blotting检测优化表达。表达产物采用Ni-NTA琼脂糖磁珠进行纯化、割胶回收融合蛋白,以纯化的Svp53B-his为抗原,免疫兔子获得多克隆抗体,通过间接ELISA检测抗体的效价。【结果】构建重组质粒pET-16b-Svp53B,在大肠杆菌Rosetta 2中以1 mmol/L IPTG诱导表达量最高,主要以包涵体形式表达。纯化包涵体蛋白免疫兔子,获得多克隆血清,效价达到1:150 000。【结论】原核表达并纯化得到高纯度的WSSV囊膜蛋白sVP53B,制备的兔源多克隆血清亲和力高、特异性好,这对后期进一步研究VP53B与经口侵染相关功能奠定了基础。     

WSSV囊膜蛋白VP37和VP39基因酵母双杂交诱饵载体的构建及其激活作用检测

对虾暴发性流行病是近十年来危害对虾养殖业发展的重要病害之一,其主要病原为对虾白斑综合症病毒（WSSV）^[1]。近年来对WSSV的研究主要集中在其囊膜蛋白、黏附蛋白等结构蛋白方面^[2]。本实验室经病毒结合分析^[3]和病毒铺覆蛋白印迹技术（Virus overlay protein blot assay,VOPBA）初步研究,已证实WSSV存在4种病毒黏附蛋白（VAP）,其中VAP1已确定为WSSV囊膜蛋白VP37^[4],该蛋白存在有特征性的细胞结合域（RGD）。编码的蛋白包含281个碱基,与Huang C,et al.^[5]报道的VP37一致,     

一种抗对虾白斑综合症病毒(WSSV)线性抗原表位单链抗体的筛选

对虾白斑综合症病毒(WSSV)是全世界对虾养殖业最主要的病原体之一, 虽然对该病毒的研究已较为深入, 但目前仍无有效的防治方法。本研究应用噬菌体展示技术, 构建了抗变性WSSV的单链抗体噬菌体展示文库, 分别以WSSV病毒粒子和原核表达的囊膜蛋白VP28为靶分子对该文库进行淘选。经过数轮淘选后, 得到5个能特异识别WSSV的单链抗体, 且首次获得了能特异识别WSSV线性抗原表位的单链抗体P75E8。并通过免疫胶体金电镜分析, 对5种单链抗体对应在病毒粒子上的表位进行了定位。为获取识别多种WSSV抗原的抗体提供了新的方法路线, 也为获取特异性识别线性表位的单链抗体提供了一种新的淘选技巧。     

对虾白斑综合征杆状病毒体内增殖模型的建立

应用对虾白斑综合征杆状病毒（WSSV）,对淡水克氏螯虾、罗氏沼虾、日本沼虾和两种淡水蟹（中华绒螯蟹、长江华溪蟹）进行人工感染实验。结果除淡水克氏螯虾之外,其它受试的虾蟹均不能感染WSSV。克氏螯虾3个不同剂量级感染至12d平均死亡率为94％。从发病或死亡个体采集血淋巴,经电镜负染色可观察到完整的病毒粒子,其形态大小、靶细胞组织病理均与从中国对虾中分离的WSSV相似或相同。同时,通过原位杂交技术进一步证明该实验的可靠性。克氏螯虾重复感染效果良好,有可能成为研究WSSV的一种理想的病毒体内增殖模型。     

对虾白斑综合征杆状病毒体内增殖模型的建立

应用对虾白斑综合征杆状病毒(WSSV),对淡水克氏螯虾、罗氏沼虾、日本沼虾和两种淡水蟹(中华绒螯蟹、长江华溪蟹)进行人工感染实验.结果除淡水克氏螯虾之外,其它受试的虾蟹均不能感染WSSV.克氏螯虾3个不同剂量组感染至12 d,平均死亡率为94%.从发病或死亡个体采集血淋巴,经电镜负染色可观察到完整的病毒粒子,其形态大小、靶细胞组织病理均与从中国对虾中分离的WSSV相似或相同.同时,通过原位杂交技术进一步证明该实验的可靠性.克氏螯虾重复感染效果良好,有可能成为研究WSSV的一种理想的病毒体内增殖模型.     

以枯草芽孢杆菌递呈VP28对南美白对虾免疫相关基因表达和细胞特异性吞噬的影响

以枯草芽孢杆菌(Bacillus subtilis)为活载体口服递呈对虾白斑综合征病毒(WSSV)囊膜蛋白VP28, 评价其抗病毒感染能力、对南美白对虾免疫相关基因表达以及血淋巴细胞对病毒特异性吞噬的影响。经口服免疫枯草重组菌株B. subtilis-VP28攻毒后, 对虾的相对存活率达83.3%。为探讨重组菌株的抗病机理, 比较研究了免疫相关基因proPO(酚氧化酶原)、Peroxinectin(PE)和脂多糖--1, 3-葡聚糖结合蛋白(LGBP)基因的表达差异, 并进一步分析了血淋巴细胞吞噬活性和特异性。结果表明, B. subtilis-VP28菌液能显著提高(P 0.05)对虾proPO、PE和LGBP mRNA的表达水平和血细胞对WSSV的吞噬活性, B. subtilis组对免疫相关基因也有一定的激活作用, 而B. subtilis-VP28发酵上清液则能增加血细胞吞噬活性; 此外, B. subtilis-VP28菌液组血细胞对WSSV具有特异性吞噬作用。研究为枯草重组菌株B. subtilis-VP28抗WSSV感染作用及其作为特殊功能水产微生态制剂的应用提供了一定的科学依据。       

不同途径感染白斑综合征病毒 (WSSV) 对日本沼虾的致病性

日本沼虾肉质鲜美、经济价值高,但其对白斑综合征病毒(White spot syndrome virus,WSSV)的易感性尚不明确。采用流行病学调查、感染试验和荧光定量PCR(qPCR)等方法,研究了日本沼虾Macrobrachium nipponense对WSSV的易感性、感染发病率以及WSSV在其体内的增殖情况。结果表明:日本沼虾是WSSV的自然宿主,上海市附近省份地区120个样本的自然携带率为8.33%。日本沼虾可以通过注射、摄食、浸泡途径感染WSSV,10 d内累计感染率均为100%,累计死亡率分别为100%、75%和0%。其中注射途径感染日本沼虾,感染后5 d肌肉病毒含量达到感染后1 d的1 000倍,8 d死亡率达100%。用注射WSSV感染日本沼虾死亡率来测量病毒致死日本沼虾的半数致死剂量(LD_(50)),2.71×10~5病毒粒子/μL能使日本沼虾死亡率达到50%以上。在养殖生产中,日本沼虾可以通过摄食感染WSSV的病虾或死虾而感染WSSV,也能通过浸泡在含WSSV的水体中而感染,并因此成为一种传播媒介,从而影响了WSSV的迅速传播与致病。     

家蚕蛹表达的重组Vp28疫苗对克氏原螯虾免疫反应的影响

将含有对虾白斑综合征病毒囊膜蛋白Vp28基因的重组杆状病毒HyNPV-Vp28感染家蚕(Bombyx mori)蛹,配制成药饵持续口服免疫克氏原螯虾35天后,螯虾血细胞的吞噬百分比和吞噬指数比对照组显著提高(P＜0．05);血清中的抗菌活力、溶菌活力、酚氧化酶活性、超氧化物歧化酶活性以及血清和肝胰腺组织中的酸性磷酸酶、碱性磷酸酶活性均显著提高(P＜0．05)。免疫35天后进行口服攻毒,20天内rVp28疫苗组的累积存活率达66．67%,与对照组和对照蚕蛹组比差异显著(P＜0．05),PRP分别达64．29%和58．33%。rVp28疫苗组存活虾的胃、肠、鳃、甲壳下上皮和肝胰腺等病毒侵染的靶组织进行组织病理检测均无病毒感染,DIG标记核酸探针斑点杂交和PCR检测也呈阴性反应;而试验濒死虾的组织都呈现典型的病变特征,病毒DNA检测均为阳性反应。本研究表明,口服免疫家蚕蛹表达的囊膜蛋白Vp28具有增强螯虾机体免疫功能的作用,对应用免疫措施预防对虾的病毒性疾病具有重要意义。     

从噬菌体展示抗体文库筛选对虾白斑综合征病毒的单链抗体

对虾白斑综合征是一种严重危害对虾养殖业的病毒性疾病.由于目前对其病原体对虾白斑综合征病毒（WSSV）的研究不够深入,所以对WSSV的有效防治仍然是一大难题.为此,用完整的对虾白斑综合征病毒粒子作为靶抗原固相包被,淘选噬菌体展示单链抗体文库,得到两个能够与WSSV结合的单链抗体：E2和H4.单链抗体H4能够结合病毒并抑制病毒对原代培养的对虾淋巴细胞的感染,这些结果表明此单链抗体具有开发为诊断试剂盒和抗病毒药物的潜力.     

对虾白斑综合症病毒与虾鳃细胞膜特异性结合关系的确立

对虾白斑综合症病毒(White spot syndrome virus,WSSV)是养殖对虾的一个主要病原,也是目前发现的基因组最大的动物病毒(基因组约290kDa,双链环状)。WSSV病毒粒子为卵形杆状,外被囊膜,囊膜在尾部延伸成一长尾。它不仅能感染对虾,还能感染其它淡水及海水甲壳类。养殖对虾被感染后,3—10d内累积死亡率可达100％,给对虾养     

Four viral proteins of white spot syndrome virus (WSSV) that attach to shrimp cell membranes

White spot syndrome virus (WSSV) is a major shrimp pathogen that has a widespread negative affect on shrimp production in Asia and the Americas. It is known that WSSV infects shrimp cells through viral attachment proteins (VAP) that bind with shrimp cell receptors. However, the identity of both WSSV VAP and shrimp cell receptors remains unclear. We used digoxigenin (DIG)-labeled shrimp hemocyte and gill cell membranes to bind to WSSV proteins immobilized on nitrocellulose membranes, and 4 putative WSSV VAP (37 kDa, 39 kDa and 2 above 97 kDa) were identified. Mass spectrometric analysis identified the 37 kDa putative VAP as the product of WSSV gene VP281.     

VP37 of white spot syndrome virus interact with shrimp cells

Aims:  To investigate VP37 [WSV 254 of White spot syndrome virus (WSSV) genome] interacting with shrimp cells and protecting shrimp against WSSV infection.
Methods and Results:  VP37 was expressed in Escherichia coli and was confirmed by Western blotting. Virus overlay protein binding assay (VOPBA) technique was used to analyse the rVP37 interaction with shrimp and the results showed that rVP37 interacted with shrimp cell membrane. Binding assay of recombinant VP37 with shrimp cell membrane by ELISA confirmed that purified rVP37 had a high-binding activity with shrimp cell membrane. Binding of rVP37 to shrimp cell membrane was a dose-dependent. Competition ELISA result showed that the envelope protein VP37 could compete with WSSV to bind to shrimp cells. In vivo inhibition experiment showed that rVP37 provided 40% protection. Inhibition of virus infection by rVP37 in primary cell culture revealed that rVP37 counterparted virus infection within the experiment period.
Conclusions:  VP37 has been successfully expressed in E . coli . VP37 interacted with shrimp cells.
Significance and Impact of the Study:  The results suggest that rVP37 has a potential application in prevention of virus infection.     

Involvement of interaction between viral VP466 and host tropomyosin proteins in virus infection in shrimp

The accumulating evidence indicates that the viral structural proteins play critical roles in virus infection. However, the interaction between the viral structural protein and host cytoskeleton protein in virus infection remains to be addressed. In this study, the viral VP466 protein, one of the major structural proteins of shrimp white spot syndrome virus (WSSV), was characterized. The results showed that the suppression of VP466 gene expression led to the inhibition of WSSV infection in shrimp, indicating that the VP466 protein was required in virus invasion. It was found that the VP466 protein was interacted with the host cytoskeleton protein tropomyosin. As documented, the VP466–tropomyosin interaction facilitated the WSSV infection. Therefore our findings revealed a novel molecular mechanism in the virus invasion to its host, which would be helpful to better understand the molecular events in virus infection in invertebrate.     

A model for apoptotic interaction between white spot syndrome virus and shrimp

White spot syndrome virus (WSSV) is an enveloped, large dsDNA virus that mainly infects penaeid shrimp, causing serious damage to the shrimp aquaculture industry. Like other animal viruses, WSSV infection induces apoptosis. Although this occurs even in by-stander cells that are free of WSSV virions, apoptosis is generally regarded as a kind of antiviral immune response. To counter this response, WSSV has evolved several different strategies. From the presently available literature, we construct a model of how the host and virus both attempt to regulate apoptosis to their respective advantage. The basic sequence of events is as follows: first, when a WSSV infection occurs, cellular sensors detect the invading virus, and activate signaling pathways that lead to (1) the expression of pro-apoptosis proteins, including PmCasp (an effecter caspase), MjCaspase (an initiator caspase) and voltage-dependent anion channel (VDAC); and (2) mitochondrial changes, including the induction of mitochondrial membrane permeabilization and increased oxidative stress. These events initiate the apoptosis program. Meanwhile, WSSV begins to express its genes, including two anti-apoptosis proteins: AAP-1, which is a direct caspase inhibitor, and WSV222, which is an E3 ubiquitin ligase that blocks apoptosis through the ubiquitin-mediated degradation of shrimp TSL protein (an apoptosis inducer). WSSV also induces the expression of a shrimp anti-apoptosis protein, Pm-fortilin, which can act on Bax to inhibit mitochondria-triggered apoptosis. This is a life and death struggle because the virus needs to prevent apoptosis in order to replicate. If WSSV succeeds in replicating in sufficient numbers, this will result in the death of the infected penaeid shrimp host.     

白斑综合症病毒感染相关蛋白质相互作用的研究进展

白斑综合症病毒（white spot syndrome virus,WSSV）是危害对虾的主要病原,给全球水产养殖业带来了巨大经济损失,但至今仍未发现有效的防治方法。研究病毒与宿主的相互作用对于深入了解病毒的致病机理和宿主的免疫机制,从而寻找合适的抗病毒措施具有非常重要的理论意义和实际应用价值。该文主要介绍了蛋白质相互作用的研究方法,以及WSSV病毒蛋白之间、病毒—宿主蛋白之间和宿主蛋白之间相互作用的研究进展,为有效地防治WSSV及相关科研提供参考。     

Enzyme E2 from Chinese white shrimp inhibits replication of white spot syndrome virus and ubiquitinates its RING domain proteins

Recent studies have shown that the ubiquitin (Ub) proteasome pathway (UPP) is closely related to immune defense. We have identified a ubiquitin-conjugating enzyme, E2, from the Chinese white shrimp, Fenneropenaeus chinensis (FcUbc). Injection of recombinant FcUbc protein (rFcUbc) reduced the mortality of shrimp infected with white spot syndrome virus (WSSV) and inhibited replication of WSSV. rFcUbc, but not a mutant FcUbc (mFcUbc), bound to WSSV RING domains (WRDs) from four potential E3 ligase proteins of WSSV in vitro. Importantly, rFcUbc could ubiquitinate the RING domains (named WRD2 and WRD3) of WSSV277 and WSSV304 proteins in vitro and the two proteins in WSSV-infected Drosophila melanogaster Schneider 2 (S2) cells. Furthermore, overexpression of FcUbc increased ubiquitination of WSSV277 and WSSV304 during WSSV infection. In summary, our study demonstrates that FcUbc from Chinese white shrimp inhibited WSSV replication and could ubiquitinate WSSV RING domain-containing proteins. This is the first report about antiviral function of Ubc E2 in shrimp.     

Shrimp laminin receptor binds with capsid proteins of two additional shrimp RNA viruses YHV and IMNV

Laminin receptor (Lamr) in shrimp was previously proposed to be a potential receptor protein for Taura syndrome virus (TSV) based on yeast two-hybrid assays. Since shrimp Lamr bound to the VP1 capsid protein of TSV, we were interested to know whether capsid/envelope proteins from other shrimp viruses would also bind to Lamr. Thus, capsid/envelope encoding genes from 5 additional shrimp viruses were examined. These were Penaeus stylirostris densovirus (PstDNV), white spot syndrome virus (WSSV), infectious myonecrosis virus (IMNV), Macrobrachium rosenbergii nodavirus (MrNV), and yellow head virus (YHV). Protein interaction analysis using yeast two-hybrid assay revealed that Lamr specifically interacted with capsid/envelope proteins of RNA viruses IMNV and YHV but not MrNV and not with the capsid/envelope proteins of DNA viruses PstDNV and WSSV. In vitro pull-down assay also confirmed the interaction between Lamr and YHV gp116 envelope protein, and injection of recombinant Lamr (rLamr) protein produced in yeast cells protected shrimp against YHV in laboratory challenge tests.     

Vp28 of shrimp white spot syndrome virus is involved in the attachment and penetration into shrimp cells

White spot disease (WSD) is caused by the white spot syndrome virus (WSSV), which results in devastating losses to the shrimp farming industry around the world. However, the mechanism of virus entry and spread into the shrimp cells is unknown. A binding assay in vitro demonstrated VP28-EGFP (envelope protein VP28 fused with enhanced green fluorescence protein) binding to shrimp cells. This provides direct evidence that VP28-EGFP can bind to shrimp cells at pH 6.0 within 0.5 h. However, the protein was observed to enter the cytoplasm 3 h post-adsorption. Meanwhile, the plaque inhibition test showed that the polyclonal antibody against VP28 (a major envelope protein of WSSV) could neutralize the WSSV and block an infection with the virus. The result of competition ELISA further confirmed that the envelope protein VP28 could compete with WSSV to bind to shrimp cells. Overall, VP28 of the WSSV can bind to shrimp cells as an attachment protein, and can help the virus enter the cytoplasm.