对虾—病毒互作的分子机制研究

白斑综合征病毒(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。过去10年来,国内外学者在WSSV侵染和对虾抗病毒免疫的研究方面取得了长足的进展,该文主要介绍这方面的研究进展。     

白斑综合征病毒囊膜蛋白在对虾免疫保护应用中的研究进展

白斑综合征自上世纪90年代初在水产养殖业中爆发以来,其病原体白斑综合征病毒的研究一直在深入开展,特别是WSSV结构蛋白的功能学研究尤为广泛,其主要方向集中在病毒囊膜蛋白对虾体的免疫保护上,并取得了显著的保护效果。从利用病毒囊膜蛋白作为亚单位疫苗免疫虾体、利用囊膜蛋白对应抗体保护虾体、构建囊膜蛋白基因核酸疫苗和利用RNAi干扰技术保护虾体等四个方面,对当前WSSV囊膜蛋白在对虾免疫保护中的应用进行了概述,并对其应用前景作一展望,旨在为及早开发出有效防治白斑综合征疾病的技术途径提供借鉴参考。     

对虾抗病毒免疫研究现状

白斑综合征病毒（white spot syndrome virus,wssv）,是对虾养殖中主要的致病病毒,在全球范围内引起急性感染和致死反应,带来巨大的经济损失。之前的研究主要集中在对虾的先天免疫反应上,在抗病毒反应方面的尚所知有限。总结了近年来对虾抗病毒免疫研究取得的主要成果,概括了病毒侵染对虾后分子水平上的改变,旨在为更加有效的预防和治疗白斑综合症提供参考。     

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.     

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.     

渤海西岸急性致死性对虾病的病毒病原研究

目前,在全世界养殖及野生对虾中已发现至少有10～20种病毒。近年来,我国沿海省份相继发生养殖对虾大批死亡现象,造成大部分虾场严重减产甚至绝收,对滩涂对虾养殖业造成巨大经济损失。虾病已成为对虾养殖业的重要限制因素。因此研究虾病的病原,传染途径,对有效防治暴发流行性虾病,发展对虾养殖业具有重要意义。本文报导我们对渤海西岸养殖的中国对虾暴发流行病病原的部分研究结果。1材料与方法1．五病好和病虾组织的超薄切片观察病虾取自辽宁锦西首钢前所虾场加工厂冰冻中国对虾,以及上海东海水产研究所固定保存的活病虾组织。从已死…     

对虾白斑综合征杆状病毒同源性比较的研究

比较我国沿海不同海域对虾白斑综合征杆状病毒三个分离株即唐海分离株（渤海湾）,宁波分离株（东海）,深圳分离株（南海）的同源性。三个WSSV分离株基因组的限制性内切酶(Sac I,Hind III,Pst I)酶切多态（RFLP）以及病毒结构蛋白图谱完全一致,证实造成我国从南至北对虾爆发性流行病的对虾白斑杆状病毒为同一种病毒。利用高保真Taq酶,分别以报道的日本对虾杆状病毒（RV-PJ＝PRDV）,斑节对虾白斑综合征杆状病毒（WSBV＝PmNOBIII）基因组核酸片段特异性引物进行PCR扩增,结果均能从中国对虾白斑杆状病毒（WSSV）基因组中扩增得到相应大小的PCR产物,扩增产物序列分析表明中国对虾白斑杆状病毒（WSSV）与斑节对虾白斑综合征杆状病毒（WSBV＝PmNOBIII）,日本对虾杆状病毒（RV－PJ＝PRDV）同源率分别为100％与97％,其结果为证实亚洲及太平洋地区对虾白斑综合征杆状病毒为同一种病毒或同一种病毒的不同株系提供了证据。     

对虾白斑综合征杆状病毒同源性比较的研究

比较我国沿海不同海域对虾白斑综合征杆状病毒三个分离株：即唐海分离株（渤海湾）、宁波分离株（东海）,深圳分离株（南海）的同源性。三个WSSV分离株基因组的限制笥内切酶（Sac Ⅰ,HindⅢ,PstⅠ）酶切多态（RFLP）以及病毒结构蛋白图谱完全一致,证实造成我国从南对北对虾爆发性流行病的对虾白斑杆状病毒为同一种病毒。利用高保真Taq酶,分别以报道的日本对虾杆状病毒（RV－PJ－PRDV）,斑节对虾白斑综合征杆状病毒（WSBV－PmNOBⅢ）基因组核酸片段特异性引物进行PCR扩增,结果均能从中国一杆状病毒（WSSV）基因组中扩增得到相应大小的PCR产物,扩增产物序列分析表明中国对虾白斑杆状病毒（WSSV）与斑节对虾白斑综合征杆状病毒（WSBV－PmNOBⅢ）,日本对虾相状RV-PJ=PRDV)同源率分别为100％与97％,其结果为证实亚洲及太平洋地区对虾白斑综合征杆状病毒为同一种病毒或同一种病毒的不同株系提供了依据。     

二温式多重PCR检测对虾白斑综合征病毒和桃拉病毒的研究

正对虾白斑综合征(WSS)和桃拉病(TS)是两种严重危害当前对虾养殖业的对虾病毒性疾病。目前对虾病毒病的诊断手段主要包括病理学和生物学方法、免疫学方法、分子杂交方法及PCR方法1-4等。其中PCR方法是这些方法中特异性最强、敏感最高的病原检测手段,在国外已被广泛应用于对虾病毒病的检测和诊断。多重PCR是一种特殊PCR形式,其最突出特点,即一次PCR反应,就可同时检测、鉴别出多种病原体,在临床混合感染的鉴别诊断上具有其独特优势和很高的实用价值5,6。本试验建立了二温式多重PCR同时检测鉴别WSSV和TSV的方法,并用该多重PCR方法对广西沿海地区对虾养殖业WSSV和TSV感染状况进行了初步调查。现将结果报告如下。       

1996年中国对虾暴发性流行病病毒病原研究

１９９６年６月至８月,青岛地区养殖的中国对虾大面积暴发流行病,死亡率达９０％以上。发病对虾典型表征为甲壳白斑。病虾鳃组织匀浆滤液经微孔滤膜过滤除菌后,注射给健康对虾进行人工感染试验,９天内累计死亡率达１００％,发病症状及体征与自然发病对虾相似。电镜下自然发病对虾鳃、胃、头胸甲下表皮、淋巴样器官、触角腺等组织细胞核内发现大量杆状病毒,未见包涵体;人工感染对虾相同组织中可见大量同样病毒。切片中病毒粒子     

Enhancement of Shrimp Antiviral Immune Response Through Caspase-Dependent Apoptosis by Small Molecules

Epidemic diseases cost large amount of economic loss in the shrimp aquaculture. To control the epidemic diseases, it is a very efficient approach to enhance the shrimp immunity by immunostimulants. In aquaculture, however, the applications of the available immunostimulants are very limited due to the lack of information about the roles of these immunostimulants in animal immunity. In the present study, a caspase protein (PjCaspase), required in shrimp antiviral apoptosis, was used as the target protein to screen for small molecules which would enhance the shrimp immunity. Based on screening using the EGFP-PjCaspase fusion protein in insect cells, four small molecules could enhance the activity of PjCaspase protein. Among them, IL-2 and evodiamine were further evidenced to enhance the apoptotic activity of shrimp hemocytes in vivo, suggesting that the small molecules improved the activity of apoptosis through the activation of the PjCaspase protein. The results indicated that the enhancement of apoptotic activity effectively inhibited the white spot syndrome virus (WSSV) infection in shrimp, which further led to the decrease of mortalities of WSSV-infected shrimp. Therefore, our study, for the first time, presented that the strategy using the key proteins in immune responses of aquatic organisms as the target proteins was a very efficient approach for the screening of immunostimulants to prevent the aquatic organisms from pathogen infections.     

Identification of a WSSV neutralizing scFv antibody by phage display technology and in vitro screening

White spot syndrome virus (WSSV) is one of the most significant viral pathogens causing high mortality and economic damage in shrimp aquaculture. Although intensive efforts were undertaken to detect and characterize WSSV infection in shrimp during the last decade, we still lack methods either to prevent or cure white spot disease. Most of the studies on neutralizing antibodies from sera have been performed using in vivo assays. For the first time, we report use of an in vitro screening method to obtain a neutralizing scFv antibody against WSSV from a previously constructed anti-WSSV single chain fragment variable region (scFv) antibody phage display library. From clones that were positive for WSSV by ELISA, 1 neutralizing scFv antibody was identified using an in vitro screening method based on shrimp primary lymphoid cell cultures. The availability of a neutralizing antibody against the virus should accelerate identification of infection-related genes and the host cell receptor, and may also enable new approaches to the prevention and cure of white spot disease.     

Use of RT-PCR for diagnosis of infectious salmon anaemia virus (ISAV) in carrier sea trout Salmo trutta after experimental infection

This paper describes a new bacterial white spot syndrome (BWSS) in cultured tiger shrimp Penaeus monodon. The affected shrimp showed white spots similar to those caused by white spot syndrome virus (WSSV), but the shrimp remained active and grew normally without significant mortalities. The study revealed no evidence of WSSV infection using electron microscopy, histopathology and nested polymerase chain reaction. Electron microscopy indicated bacteria associated with white spot formation, and with degeneration and discoloration of the cuticle as a result of erosion of the epicuticle and underlying cuticular layers. Grossly the white spots in BWSS and WSS look similar but showed different profiles under wet mount microscopy. The bacterial white spots were lichen-like, having perforated centers unlike the melanized dots in WSSV-induced white spots. Bacteriological examination showed that the dominant isolate in the lesions was Bacillus subtilis. The occurrence of BWSS may be associated with the regular use of probiotics containing B. subtilis in shrimp ponds. The externally induced white spot lesions were localized at the integumental tissues, i.e., cuticle and epidermis, and connective tissues. Damage to the deeper tissues was limited. The BWS lesions are non-fatal in the absence of other complications and are usually shed through molting.     

Costs and benefits of freedom from shrimp diseases in the European Union

The growth in penaeid shrimp aquaculture has been mirrored by the emergence of a number of serious diseases, some of which (e.g. white spot syndrome virus - WSSV) spread rapidly across the globe through movement of infected stock. The World Organisation for Animal Health (OIE) lists six penaeid shrimp pathogens of which three are notifiable in the EU: WSSV (listed as non-exotic to the EU), Taura syndrome virus (TSV) and yellow head disease (YHD) (both listed as exotic). EU Member States (MS) must determine a status for non-exotic diseases (e.g. disease free, unknown, infected). In developing a policy for WSSV, import risk analysis (IRA) can be used to systematically assess the risks of introduction and justify risk mitigation to maintain freedom. OIE guidelines recommend that countries assess the risk of disease introduction via commodities, not listed by the OIE as safe, and apply sanitary measures if necessary. The sanitary measures necessary to maintain freedom from WSSV may not be compatible with current EU animal health legislation. The recent revision by OIE of products listed as safe for international trade strengthens the case for the risks of TSV and YHD introduction into the EU to be assessed. Freedom from WSSV is an important criterion for the development of shrimp aquaculture in the EU. However, in developing disease control policy, governments need to balance the potentially competing interests of all stakeholders, including consumers. Thus economic modelling of the impact of possible sanitary measures on consumer prices of imported products is needed to support decision making. The creation of disease free compartments and post-import risk mitigation for commodities may create the conditions conducive to the development of shrimp aquaculture whilst minimising the costs of maintaining disease freedom.     

White spot syndrome virus (WSSV) in Litopenaeus vannamei captured from the Gulf of California near an area of extensive aquaculture activity

For the shrimp farming industry of Mexico, disease outbreaks caused by white spot syndrome virus (WSSV) are relatively recent. Efforts to control the virus are assisted by monitoring for its prevalence in aquaculture systems, but few attempts have been made to search for it in carriers from coastal waters. To search for WSSV carriers in the Gulf of California, we made surveys off the coast of Sinaloa, Mexico, in March 2001, November 2001, and September 2003 using polymerase chain reaction (PCR) assays and histopathology. WSSV-positive shrimp were detected only in November 2001, after hurricane Julliete. This suggested possible dispersal of WSSV to the marine environment from infected shrimp farms.     

Effects of immunostimulants targeting Ran GTPase on phagocytosis against virus infection in shrimp

The global shrimp aquaculture has been consistently beset by diseases that cause severe losses in production. To fight various harmful pathogens, the enhanced shrimp immunity by immunostimulants would play key roles against the invading pathogens. In aquaculture, however, the target proteins/genes which can be used for the screening of immunostimulants are very limited. Based on our previous study, in the present study, the shrimp Ran protein, which was required in shrimp antiviral phagocytosis, was used as the target protein to screen for immunostimulants. The GTPase activity assays showed that the IL-4 and lysophosphatidylcholine molecules could enhance the activity of Ran protein, suggesting that the two molecules might function in phagocytosis. When the IL-4 and lysophosphatidylcholine were respectively injected into shrimp, the results indicated that the two molecules enhanced the hemocytic phagocytosis against white spot syndrome virus (WSSV), suggesting that they improved the activity of phagocytosis through the activation of the Ran protein. It was evidenced that the enhancement of phagocytosis activity effectively inhibited the WSSV infection in shrimp, which further led to the decrease of mortalities of WSSV-infected shrimp. Therefore, our study presented a novel strategy for the screening of immunostimulants by using the key proteins in immune responses of aquatic organisms as the target proteins, which would be very helpful for the development of efficient approaches to prevent the aquatic organisms from pathogen infections.     

Loose shell syndrome of farmed Penaeus monodon in India is caused by a filterable agent

Loose shell syndrome (LSS) of farmed black tiger shrimp Penaeus monodon has been reported from Indian shrimp farms since 1998 and is recognized as a major disease problem causing significant economic loss to the shrimp aquaculture sector. Unlike the rapid mortalities associated with viral pathogens such as white spot syndrome virus and yellow head virus, progression of LSS is gradual, leading to low-level progressive mortalities. The signs of LSS include a flaccid spongy abdomen due to muscular dystrophy, space between the exoskeleton and muscle, and a shrunken hepatopancreas. The feed conversion efficiency is reduced, and shrimp have poor meat quality, caused by impairment of the hepatopancreatic functions such as digestion and absorption as evidenced by the atrophy of the hepatopancreas. Histopathological investigations on LSS-affected shrimp showed shrinkage of extensor and flexor muscles with occasional hemocytic infiltration. The hepatopancreas showed inflammation of hepatopancreatic tubules with enlargement of intertubular spaces, hemocytic infiltration, and low levels of lipid reserves in the R cells. In advanced stages of LSS, many tubules were in highly necrotic condition with a sloughed epithelium, reflecting the dysfunction of the digestive gland. LSS could be induced in healthy tiger shrimp by challenge studies using membrane-filtered LSS-affected shrimp tissues, suggesting involvement of a filterable infectious agent.