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,     

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     

一种改良的对虾白斑综合征病毒的提纯技术

对虾白斑综合征病毒(White spot syndrome virus,WSSV)是对虾养殖业的主要病原,自1992年以来一直严重影响对虾的产量和质量,造成巨大的经济损失.     

对虾白斑综合症病毒极早期基因的研究进展

对虾白斑综合症病毒(white spot syndrome virus,WSSV)是危害对虾养殖业的主要病原之一。WSSV在侵染宿主细胞的过程中,极早期基因(immediate-early gene)对病毒复制增殖起着非常重要的作用。在这个过程中,一方面极早期基因编码的蛋白通过与细胞调控因子相互作用,调节细胞信号通路,为病毒的增殖提供更合适的环境;另一方面,极早期蛋白直接调控病毒基因的转录和表达。综述列举了WSSV的21个极早期基因,并将重点介绍其中5个研究比较深入的基因:ie1、wsv051、wsv083、wsv249和wsv403。     

中国对虾抗WSSV及其它经济性状的QTL定位初步研究

以中国对虾抗WSSV选育群体第四代雌虾和野生中国对虾雄虾为亲本,采用人工精荚移植方式产生F1代家系,家系内个体姊妹交获得R家系材料,42尾R家系个体采用口饲法进行WSSV（White Spot Syndrome Virus）攻毒实验,获得个体抗WSSV及其它相关数据。构建了中国对虾的AFLP（Amphfied Fragment Length Polymorphism）分子标记遗传连锁图谱。利用MAPMAKER／QTL1．1软件进行了中国对虾体长、全长、体重及抗WSSV性状的QTL（Quantitative TraitsLoci）定位分析,首次实现了中国对虾重要经济性状的QTL定位。在LOD值大于2．0的条件下,共检测到和体长相关的QTL位点1个,与全长相关的QTL位点2个,与体重相关的QTL位点2个,与抗WSSV性状相关的位点2个,分别位于3个连锁群上,位点变异解释率从26．6％-66．9％不等。在其中的1个连锁群上检测到了体重、全长和抗WSSV性状相关的三个QTL位点,1个连锁群上检测到了体重和抗WSSV性状相关的两个QTL位点,1个连锁群上检测到了全长和体长相关的两个QTL位点。表明在中国对虾在此生长阶段,抗WSSV性状和个体大小存在一定程度的正相关关系[动物学报54（6）：1075-1081,2008]。     

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.     

凡纳滨对虾白斑综合征病毒广西株变异区基因的比较分析

对凡纳滨对虾白斑综合征病毒(White spot syndrome virus,WSSV)广西株变异区ORF14/15基因序列进行比较分析,了解WSSV广西株遗传进化差异及其与各地WSSV毒株间的遗传进化关系。考虑地理和时间因素选取2010年5月至2013年7月采自广西凡纳滨对虾主要养殖地区北海、钦州和防城港的40份WSSV阳性的凡纳滨对虾样品,PCR扩增、克隆样品中WSSV的ORF14/15基因并对其进行序列测定与比较分析。40份样品中有25份的ORF14/15基因被成功克隆和测序,其中22株为619bp,3株为620bp;相对于此区域最为完整的TH-96-Ⅱ株,25株WSSV广西株的ORF14/15基因均在中间缺失了5 949bp,仅剩5′端的190bp和3′端的429bp(430bp),与印度株IN-05-Ⅰ缺失大小和位置相同;在变异区25株WSSV广西株中有16株核苷酸序列同源性为100%,其余毒株间的同源性也在97.9%以上,仅存在单个碱基的变异;基于变异区构建的系统进化树显示,WSSV广西地方株在遗传上相距较近,全部与印度株IN-05-Ⅰ聚在一个大的分支,而与目前发表的其他毒株均相距较远。广西养殖凡纳滨对虾中流行的WSSV毒株变异区ORF14/15基因的变异类型为中间大片段缺失,广西各地流行的WSSV毒株间无明显的地域和时间差异;WSSV广西株与印度株IN-05-Ⅰ的遗传进化关系最近。     

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

对虾白斑综合症病素养(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素养(基因组约290kDa,双链环状).     

注意杆状病毒科分类的变化

杆状病毒由于被广泛用作目的基因的表达载体倍受重视.近年来证实某些杆状病毒对虾具有致病性,从而成为研究热点之一.目前公认的最重要的对虾致病病毒是对虾白斑综合征病毒(white spot syndromviruS,WSSV),在我国养殖对虾中广为流行,引致重大经济损失.不少文献将WSSV称作对虾白斑病杆状病毒,其实并不准确.     

对虾白斑综合征病毒中国地方株变异区基因的比较

对虾白斑综合征病毒(White spot syndromevirus,WSSV)是对虾养殖的主要病原之一,它是目前发现的基因组最大的动物病毒,为环状双链DNA病毒[1,2],全基因组序列分析结果显示,对虾白斑综合征病毒和其他杆状病毒相差甚远,最新病毒分类报告已将该病毒划归新建立的线头病毒科(Nima-viridae)白斑病毒属(Whispovirus)[3,4]。目前Gen-Bank公布有3个版本的WSSV全序列[1,2],其基因组大小的测定结果相差较大。不同的WSSV毒株可能在形态结构、理化性质上无法区分,但病毒基因组限制酶切片段长度多态性(RFLP)可以将之区分开来,Marks等[6,7]通过计…     

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.     

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.     

Feeding hermit crabs to shrimp broodstock increases their risk of WSSV infection

White spot syndrome virus (WSSV) is a serious shrimp pathogen that has spread globally to all major shrimp farming areas, causing enormous economic losses. Here we investigate the role of hermit crabs in transmitting WSSV to Penaeus monodon brooders used in hatcheries in Vietnam. WSSV-free brooders became PCR-positive for WSSV within 2 to 14 d, and the source of infection was traced to hermit crabs being used as live feed. Challenging hermit crabs with WSSV confirmed their susceptibility to infection, but they remained tolerant to disease even at virus loads equivalent to those causing acute disease in shrimp. As PCR screening also suggests that WSSV infection occurs commonly in hermit crab populations in both Vietnam and Taiwan, their use as live feed for shrimp brooders is not recommended.     

Increasing production in Korean shrimp farms with white-spot syndrome virus PCR-negative brood stock

White-spot syndrome virus (WSSV) is a devastating, infectious virus affecting shrimp. Although sensitive techniques involving PCR have been developed to assist farmers in screening shrimp (brood stock) for WSSV prior to stocking ponds, such practices have not yet been applied in Korea. Despite the rationality of implementing screening, there has been some doubt as to whether the stocking of WSSV-PCR-negative fry epidemiologically decreases white-spot disease outbreaks. Here, we report a retrospective analysis of data from shrimp farms in the western coast of Korea where WSSV-PCR-negative brood stocks were used to stock rearing ponds. A total of 366 shrimp from Heuksan Island were sampled for WSSV with PCR. Of the tested shrimp, 7.2% (28 brood stocks) were identified as WSSV positive; only WSSV-PCR-negative shrimp were used for brood stocks. Total unit production (final shrimp production/ the area of the ponds) was higher, at 1.96, in ponds where WSSV-PCR-negative shrimp were used, as compared with 1.02 in other ponds in Korea in 2004. This retrospective analysis of WSSV in Korea may be useful to the shrimp aquaculture industry, suggesting a testable hypothesis that may contribute to the eventual control of WSSV outbreaks.     

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.     

Development and application of monoclonal antibodies for the detection of white spot syndrome virus of penaeid shrimp.

Monoclonal antibodies (MAbs) were produced against white spot syndrome virus (WSSV) of penaeid shrimp. The virus isolate used for immunization was obtained from China in 1994 and was passaged in Penaeus vannamei. The 4 hybridomas selected for characterization all produced MAbs that reacted with the 28 kD structural protein by Western blot analysis. The MAbs tested in dot-immunoblot assays were capable of detecting the virus in hemolymph samples collected from moribund shrimp during an experimentally induced WSSV infection. Two of the MAbs were chosen for development of serological detection methods for WSSV. The 2 MAbs detected WSSV infections in fresh tissue impression smears using a fluorescent antibody for final detection. A rapid immunohistochemical method using the MAbs on Davidson's fixed tissue sections identified WSSV-infected cells and tissues in a pattern similar to that seen with digoxigenin-labeled WSSV-specific gene probes. A whole mount assay of pieces of fixed tissue without paraffin embedding and sectioning was also successfully used for detecting the virus. None of the MAbs reacted with hemolymph from specific pathogen-free shrimp or from shrimp infected with infectious hypodermal and hematopoietic necrosis virus, yellow head virus or Taura syndrome virus. In Western blot analysis, the 2 MAbs did not detect any serological differences among WSSV isolates from China, Thailand, India, Texas, South Carolina or Panama. Additionally, the MAbs did not detect a serological difference between WSSV isolated from penaeid shrimp and WSSV isolated from freshwater crayfish.     

Crassostrea gigas oysters as a shrimp farm bioindicator of white spot syndrome virus

This study explored whether Crassostrea gigas oysters can be used as a bioindicator of white spot syndrome virus (WSSV) in shrimp farm water canals. Bioassays showed that C. gigas can accumulate WSSV in their gills and digestive glands but do not become infected, either by exposure to seawater containing WSSV or by cohabitation with infected shrimp. The use of a WSSV nested PCR to screen oysters placed in water canals at the entry of a shrimp farm allowed WSSV to be detected 16 d prior to the disease occurring. The finding that C. gigas can concentrate small amounts of WSSV present in seawater without being harmed makes it an ideal sentinel species at shrimp farms.     

Preliminary study on haemocyte response to white spot syndrome virus infection in black tiger shrimp Penaeus monodon

White spot syndrome virus (WSSV) has been a major cause of shrimp mortality in aquaculture in the past decade. In contrast to extensive studies on the morphology and genome structure of the virus, little work has been done on the defence reaction of the host after WSSV infection. Therefore, we examined the haemocyte response to experimental WSSV infection in the black tiger shrimp Penaeus monodon. Haemolymph sampling and histology showed a significant decline in free, circulating haemocytes after WSSV infection. A combination of in situ hybridisation with a specific DNA probe for WSSV and immuno-histochemistry with a specific antibody against haemocyte granules in tissue sections indicated that haemocytes left the circulation and migrated to tissues where many virus-infected cells were present. However, no subsequent haemocyte response to the virus-infected cells was detected. The number of granular cells decreased in the haematopoietic tissue of infected shrimp. In addition, a fibrous-like immuno-reactive layer appears in the outer stromal matrix of tubule walls in the lymphoid organ of infected shrimp. The role of haemocytes in shrimp defence after viral infection is discussed.     

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.