对虾白斑综合症病毒囊膜蛋白VP28的表达及其抗病毒感染作用

根据GenBank上WSSV囊膜蛋白基因vp28的序列,设计并合成引物,PCR扩增得到vp28基因,成功构建重组表达载体pET22b-vp28并转化大肠杆菌BL21(DE3)。基因工程菌株37℃IPTG诱导,表达产物经Western-blot和SDS-PAGE检测显示有与预期大小32kDa相符合的目的蛋白。用Ni2 -柱纯化的目的蛋白分别直接注射螯虾和包被饲料投喂螯虾,实验结果表明vp28在大肠杆菌中的表达产物有显著提高虾体抗WSSV感染力的作用,而且注射效果更好。     

白斑综合症病毒囊膜蛋白VP19、VP28的融合表达及中和抗体的制备

根据GenBank上WSSV囊膜蛋白基因vp19和vp28的序列,设计并合成两对引物,PCR扩增得到vp19和vp28两基因,大小分别为370bp和630bp.通过EcoRI位点连接两基因,再按正确的阅读框插入表达载体pET-22b(+)中,构建出重组表达载体pET-vp(19+28)并转化大肠杆菌BL21(DE3).基因工程菌株35℃IPTG诱导,表达产物经SDS-PAGE检测显示有与预期大小41kDa相吻合的融合蛋白带.用Ni2+-柱纯化的基因工程蛋白免疫新西兰大白兔制备抗血清,进行螯虾活体中和病毒实验,结果表明抗血清对WSSV的中和效率达到了100%.     

对虾白斑综合症病毒囊膜蛋白VP19的融合表达及其抗病毒感染作用

根据GenBank上WSSV囊膜蛋白基因vp 19的序列,设计并合成引物,PCR扩增得到vp19基因并克隆到pGEM‐T载体中,经过BamHⅠ/Hind Ⅲ酶切、连接并将vp19插入到pET32b表达载体中.用重组质粒pET32b-vp19转化大肠杆菌Origami(DE3)pLysS,在IPTG诱导下,融合蛋白Trx-VP19以可溶性的形式得到表达,经SDS-PAGE和Western-blot检测显示其分子量与预期的大小相符合.目的蛋白经Ni2+柱纯化并定量后分别直接注射鳌虾和包被饲料投喂鳌虾.实验结果表明注射Trx-VP19可以提高鳌虾个体抗WSSV感染力的作用.     

白斑综合症病毒囊膜蛋白VP19、VP28的融合表达及中和抗体的制备

根据GenBank上WSSV囊膜蛋白基因vp19和vp28的序列,设计并合成两对引物,PCR扩增得到vp19和vp28两基因,大小分别为370bp和630bp。通过EcoRI位点连接两基因,再按正确的阅读框插入表达载体pET-22b( )中,构建出重组表达载体pET-vp(19 28)并转化大肠杆菌BL21(DE3)。基因工程菌株35℃IPTG诱导,表达产物经SDS-PAGE检测显示有与预期大小41kDa相吻合的融合蛋白带。用Ni^2 -柱纯化的基因工程蛋白免疫新西兰大白兔制备抗血清,进行螯虾活体中和病毒实验,结果表明抗血清对WSSV的中和效率达到了100％。     

对虾白斑综合症病毒囊膜蛋白VP19的融合表达及其抗病毒感染作用

根据GenBank上WSSV囊膜蛋白基因vp19的序列,设计并合成引物,PCR扩增得到vp19基因并克隆到pGEM‐T载体中,经过BamHⅠ/HindⅢ酶切、连接并将vp19插入到pET32b表达载体中。用重组质粒pET32b-vp19转化大肠杆菌Origam(iDE3)pLysS,在IPTG诱导下,融合蛋白Trx-VP19以可溶性的形式得到表达,经SDS-PAGE和Western-blot检测显示其分子量与预期的大小相符合。目的蛋白经Ni2 柱纯化并定量后分别直接注射鳌虾和包被饲料投喂鳌虾。实验结果表明注射Trx-VP19可以提高鳌虾个体抗WSSV感染力的作用。     

鲤鱼生长激素和对虾白斑病毒囊膜蛋白VP28的融合表达及功能研究

鲤鱼生长激素GH是鲤鱼生长腺体分泌并促进鲤鱼生长的一种分泌蛋白.对虾白斑综合病毒(WSSV)VP28蛋白为囊膜蛋白,是病毒感染宿主的必需因子.根据gh和vp28的上下游序列,分别设计合成两对引物,PCR扩增gh和vp28基因,将基因gh和vp28按先后次序融合后插入穿梭质粒pPIC6αC多克隆位点,构建成重组分泌表达穿梭质粒pPIC6αC-(gh vp28),用Bstx1单酶切穿梭质粒pPIC6αC-(gh vp28)线形化,转化毕赤酵母X-33.重组菌株30℃甲醇诱导,实现在酵母中的融合分泌表达,获得融合蛋白.表达产物经SDS-PAGE检测和Western Blot印迹鉴定,显示与预期大小66kD相吻合的融合蛋白带.用Ni2 -柱纯化后的基因工程蛋白注射鳌虾进行蛋白生物功能测试,结果表明该蛋白获得了促鳌虾生长和抗WSSV感染的双重功效.     

转基因聚球藻7942中vp28基因表达效率及其光合特性分析

背景:对虾白斑综合征病毒(white spot syndrome virus,WSSV)是对虾养殖业中危害最严重的病毒之一,至今尚无规模应用的有效药物防治方法。但近年来在WSSV免疫防治上进展较大。Vp28蛋白是WSSV囊膜上的主要结构蛋白,2004年以来其编码基因已在8种宿主中表达成功,在实验室试验中对WSSV的防治疗效显著,但目前尚未见到其在对虾产业中的应用。目的:利用对虾的天然饵料聚球藻表达Vp28重组蛋白,这种药食同源可简化操作,降低成本,有助其在生产中应用。方法:用荧光定量PCR方法检测转vp28基因聚球藻7942中vp28基因的表达效率。通过氧电极的方法测得转vp28基因型聚球藻在不同温度、光照、pH和盐度下的光合活性变化,找到它的最适生长条件。结果:检测了vp28基因表达效率为9.52%,是在鱼腥藻7120表达效率的3倍。最适采收时间是对数生长后期(15d左右)。转基因型蓝藻7 942的最适生长条件是:温度为40℃,盐度为0~0.1mol/L NaCl,pH为7.5,光强为450μmol/(m~2·s)。结论:确定了vp28基因在聚球藻中的表达效率及该转基因藻的最适培养条件,这些研究结果为用转vp28基因型聚球藻7942规模制备药食同源的口服剂提供了依据。     

一种新的螯虾丝氨酸蛋白酶抑制物基因的克隆表达及其活性分析

根据本课题组从克氏原螯虾中新发现的丝氨酸蛋白酶抑制物的基因序列(GenBank登录号CD644775)设计一对引物,应用逆转录-聚合酶链式反应(RT-PCR)技术,从螯虾血淋巴细胞中扩增出丝氨酸蛋白酶抑制物基因PCI188,将其连入原核表达载体pET-32a,转化至大肠杆菌Rosetta株和BL21株中进行蛋白表达,结果该蛋白只在前者表达。表达产物用免疫转印检测,出现50kD的特异性条带,与螯虾PCI188基因编码的蛋白大小相符。将融合蛋白纯化后免疫新西兰兔,用免疫血清与螯虾血淋巴作用后测定酚氧化酶活力,结果显示,酚氧化酶活力有所升高,从而首次证实螯虾PCI188编码的蛋白对丝氨酸蛋白酶有抑制作用。     

对虾白斑综合征病毒的细胞因子受体基因的分析与表达

在对虾白斑综合征病毒(White spot syndrome virus,WSSV)的基因组中发现一个具有细胞因子受体特征的开放阅读框,该阅读框全长2022个核苷酸,编码674个氨基酸,蛋白质理论分子量为76kDa.该基因含有真核生物细胞因子gpl30受体特征序列.为了研究该基因的功能,采用PCR方法从病毒基因组中扩增出基因片段,克隆到pGEM-T Easy载体中,经BamH I和Sal I双酶切后插入pET28b表达载体中.重组质粒转化到大肠杆菌BL21中,IPTG诱导后,经SDS-PAGE电泳表明在76kDa处有目的蛋白表达.用冰浴超声波对诱导后的菌液进行处理以获得初步纯化的蛋白,作为抗原人工免疫实验兔子以获得含特异性抗体的抗血清.该基因的表达成功,为其功能的进一步深入研究奠定了基础.     

对虾白斑综合征病毒新株型WSSV-CN-Pc的毒力研究

对虾白斑综合征病毒(white spot syndrome virus,WSSV)是一种能够感染虾类并且造成其大面积死亡的环状双链DNA病毒。WSSV有多种分离株,其毒力有所差异。从克氏原螯虾(Procambarus clarkii)中分离得到1株WSSV新分离株WSSV-CN-Pc,其毒力尚不清楚。本研究采用肌肉注射和经口注射的方法,以WSSVTW型作为阳性对照,分别对克氏原螯虾(P.clarkii)和罗氏沼虾(Macrobrachium rosenbergii)进行活体实验。实验结果显示:肌肉注射WSSV-CN-Pc和WSSV-TW的克氏原螯虾均在第6天出现100%的死亡;罗氏沼虾在肌肉注射WSSV-TW后未出现死亡,但在注射WSSV-CN-Pc后的第9天死亡率达100%。经口注射WSSV-CN-Pc和WSSV-TW的克氏原螯虾均在第16天出现100%的死亡;罗氏沼虾经口注射WSSV-CN-Pc后的第19天死亡率为100%,但注射WSSV-TW的实验组并未出现死亡。结果表明,对于克氏原螯虾,WSSV-CN-Pc具有和WSSV-TW相似的毒力,而对罗氏沼虾存在明显的毒力差异。提示克氏原螯虾是WSSV传播途径中的重要因素。     

Haemocyte reactions in WSSV immersion infected Penaeus monodon

White spot syndrome virus (WSSV) has been a major cause of shrimp mortality in aquaculture worldwide in the past decades. In this study, WSSV infection (by immersion) and behaviour recruitment of haemocytes is investigated in gills and midgut, using an antiserum against the viral protein VP28 and a monoclonal antibody recognising haemocytes (WSH8) in a double immunohistochemical staining and in addition transmission electron microscopy was applied. More WSH 8(+) haemocytes were detected at 48 and 72 h post-infection in the gills of infected shrimp compared to uninfected animals. Haemocytes in the gills and midgut were not associated with VP28-immunoreactivity. In the gills many other cells showed virus replication in their nuclei, while infected nuclei in the gut cells were rare. Nevertheless, the epithelial cells in the midgut showed a clear uptake of VP28 and accumulation in supranuclear vacuoles (SNV) at 8h post-infection. However, epithelial nuclei were never VP28-immunoreactive and electron microscopy study suggests degradation of viral-like particles in the SNV. In contrast to the gills, the midgut connective tissue shows a clear increase in degranulation of haemocytes, resulting in the appearance of WSH8-immunoreactive thread-like material at 48 and 72 h post-infection. These results indicate recruitment of haemocytes upon immersion infection in the gills and degranulation of haemocytes in less infected organs, like the midgut.     

Replication of the Shrimp Virus WSSV Depends on Glutamate-Driven Anaplerosis

Infection with the white spot syndrome virus (WSSV) induces a metabolic shift in shrimp that resembles the “Warburg effect” in mammalian cells. This effect is triggered via activation of the PI3K-Akt-mTOR pathway, and it is usually accompanied by the activation of other metabolic pathways that provide energy and direct the flow of carbon and nitrogen. Here we show that unlike the glutamine metabolism (glutaminolysis) seen in most cancer cells to double deaminate glutamine to produce glutamate and the TCA cycle intermediate α-ketoglutarate (α-KG), at the WSSV genome replication stage (12 hpi), although glutaminase (GLS) expression was upregulated, only glutamate was taken up by the hemocytes of WSSV-infected shrimp. At the same time, we observed an increase in the activity of the two enzymes that convert glutamate to α-KG, glutamate dehydrogenase (GDH) and aspartate aminotransferase (ASAT). α-ketoglutarate concentration was also increased. A series of inhibition experiments suggested that the up-regulation of GDH is regulated by mTORC2, and that the PI3K-mTORC1 pathway is not involved. Suppression of GDH and ASAT by dsRNA silencing showed that both of these enzymes are important for WSSV replication. In GDH-silenced shrimp, direct replenishment of α-KG rescued both ATP production and WSSV replication. From these results, we propose a model of glutamate-driven anaplerosis that fuels the TCA cycle via α-KG and ultimately supports WSSV replication.     

Protection of Shrimp Penaeus monodon from WSSV Infection Using Antisense Constructs

White spot syndrome caused by white spot syndrome virus (WSSV) is one of the most threatening diseases of shrimp culture industry. Previous studies have successfully demonstrated the use of DNA- and RNA-based vaccines to protect WSSV infection in shrimp. In the present study, we have explored the protective efficacy of antisense constructs directed against WSSV proteins, VP24, and VP28, thymidylate synthase (TS), and ribonucleotide reductase-2 (RR2) under the control of endogenous shrimp histone-3 (H3) or penaedin (Pn) promoter. Several antisense constructs were generated by inserting VP24 (pH3–VP24, pPn–VP24), VP28 (pH3–VP28, pPn–VP28), TS (pH3–TS, pPn–TS), and RR2 (pH3–RR2) in antisense orientation. These constructs were tested for their protective potential in WSSV infected cell cultures, and their effect on reduction of the viral load was assessed. A robust reduction in WSSV copy number was observed upon transfection of antisense constructs in hemocyte cultures derived from Penaeus monodon and Scylla serrata. When tested in vivo, antisense constructs offered a strong protection in WSSV challenged P. monodon. Constructs expressing antisense VP24 and VP28 provided the best protection (up to 90 % survivability) with a corresponding decrease in the viral load. Our work demonstrates that shrimp treated with antisense constructs present an efficient control strategy for combating WSSV infection in shrimp aquaculture.     

WSSV: VP26 binding protein and its biological activity

White spot syndrome virus (WSSV) is one of the major causes of disease in the shrimp culture industry causing enormous economic losses. In this study, we displayed peptides from a cDNA library obtained from the hemolymph of shrimp infected with WSSV, on the surface of phage and screened for the peptides that interacted with the WSSV. One WSSV binding protein (WBP) gene was found to consist of 171 bp that had no matches in the NCBI database. This WBP was shown to bind to the VP26 protein of the WSSV by Western blotting. In addition, WBP reduced the binding of WSSV to shrimp haemocytes from 2.0 × 10(7)copies in the control to 6.0 × 10(2) after treatment with 80 μg of WBP. The survival rate of shrimp after WSSV were mixed with WBP at 80 μg, was 89% and the binding of WBP remained unchanged for at least 24h. Therefore, the results indicate that the WBP can bind to VP26 and inhibit the invasion of WSSV into host cells. This finding may introduce another future way to try to fight this disease in shrimp culture.     

White spot syndrome virus (WSSV) interaction with crayfish haemocytes

WSSV particles were detected in separated granular cells (GCs) and semigranular cells (SGCs) by in situ hybridisation from WSSV-infected crayfish and the prevalence of WSSV-infected GCs was 5%, whereas it was 22% in SGCs. This indicates that SGCs are more susceptible to WSSV and that this virus replicated more rapidly in SGCs than in GCs and as a result the number of SGCs gradually decreased from the blood circulation. The effect of haemocyte lysate supernatant (HLS), containing the degranulation factor (peroxinectin), phorbol 12-myristate 13-acetate (PMA), the Ca(2+) ionophore A23187 on GCs from WSSV-infected and sham-injected crayfish was studied. The results showed that the percentage of degranulated GCs of WSSV-infected crayfish treated with HLS or PMA was significantly lower than that in the control, whereas no significant difference was observed when treated with the Ca(2+) ionophore. It was previously shown that peroxinectin and PMA have a degranulation effect via intracellular signalling involving protein kinase C (PKC), whereas the Ca(2+) ionophore uses an alternative pathway. HLS treatment of GCs and SGCs from WSSV-infected crayfish results in three different morphological types: non-spread, spread and degranulated cells. The non-spread cell group from both GCs and SGCs after treatment with HLS had more WSSV positive cells than degranulated cells, when detected by in situ hybridisation. Taken together, it is reasonable to speculate that the PKC pathway might be affected during WSSV infection. Another interesting phenomenon was that GCs from non-infected crayfish exhibited melanisation, when incubated in L-15 medium, while no melanisation was found in GCs of WSSV-infected crayfish. However, the phenoloxidase activities of both sham- and WSSV-injected crayfish in HLS were the same as well as proPO expression as detected by RT-PCR. This suggests that the WSSV inhibits the proPO system upstream of phenoloxidase or simply consumes the native substrate for the enzyme so that no activity is shown. The percentage of apoptotic haemocytes in WSSV-infected crayfish was very low, but it was significantly higher than that in the sham-injected crayfish on day 3 or 5 post-infection. The TEM observation in haematopoietic cells (hpt cells) suggests that WSSV infect specific cell types in haematopoietic tissue and non-granular hpt cells seem more favourable to WSSV infection.     

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。     

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.