多重RT-PCR体系检测4种虾病毒的方法

根据多重RT-PCR的技术原理,利用对虾传染性表皮与造血组织坏死症病毒、白斑综合征病毒、黄头病毒和桃拉综合征病毒的基因序列分别设计了4对特异引物,建立多重RT-PCR体系用于虾4种病毒的检测。多重RT-PCR体系能特异地扩增出IHHNV、WSSV、YHV和TSV的目的片段:TSV特异性扩增片段508 bp,WSSV 特异性扩增片段435 bp,IHHNV 特异性扩增片段301 bp 和YHV。特异性扩增片段614 bp。结果表明,多重PCR虾病毒检测系统具有较高的特异性和敏感性,并对其它对虾病原呈阴性。IHHNV、TSV、WSSV和YHV模板在多重PCR虾病毒检测体系中的检测下限分别为0.1,1,0.02和0.2 pg。病毒感染病料检测试验中,该检测体系的检测结果与单纯PCR的检测结果呈现出较好的吻合度。     

应用PCR和RT-PCR技术对4种对虾病毒的检测

探讨了应用PCR和RT－PCR技术对4种主要的对虾病毒进行检测的方法。同时使用该方法检测了对虾天然饵料－－卤虫中的4种对虾病毒。结果显示，含病毒核酸的阳性对照样品分别扩增出了大小为824bp,705bp,260bp和216bp的预期产物，但未能从卤虫样品中检测到此4种病毒的存在。本文报道的病毒检测方法具有快速、灵敏、准确的特点，可以用于进出口贸易中对活体或冰冻对虾，虾苗，对虾饵料等进行相关对虾病毒的检疫，也为制定我国对虾病毒检疫检验规范提供了技术参考。     

江苏地区对虾3种病毒病的流行病学调查及5株IHHNV的编码区基因序列分析

对虾白斑综合征病毒(WSSV)、桃拉综合征病毒(TSV)、传染性皮下及造血组织坏死病毒(IHHNV)是威胁对虾养殖的重要病毒。为了调查这3种病在江苏境内的流行情况,根据世界动物卫生组织(OIE)推荐的《水生动物疾病诊断手册》的PCR检测法对2015年5月—2016年5月采集的1436尾对虾样品进行3种疾病的流行病学调查。结果显示WSSV阳性率为17.20%,TSV阳性率为0%,IHHNV阳性率为39.48%。对江苏不同地区分离出的5株IHHNV进行基因序列分析,数据显示这5个地区的毒株均属于Ⅰ型感染株,与韩国株的进化关系较为接近。本研究通过调查以上3种病毒病在江苏境内的流行情况,并进行序列分析,发现江苏不同地区的凡纳滨对虾IHHNV感染均为Ⅰ型,研究结果对养殖虾的疾病防控有重要参考价值。     

Multiple infections caused by white spot syndrome virus and Enterocytozoon hepatopenaei in pond‐reared Penaeus vannamei in India and multiplex PCR for their simultaneous detection

White leg shrimp, Penaeus vannamei, were collected on a monthly basis from grow‐out ponds located at Tamil Nadu and Andhra Pradesh states along the east coast of India for screening of viral and other pathogens. Totally 240 shrimp samples randomly collected from 92 farms were screened for white spot syndrome virus (WSSV), infectious hypodermal and haematopoietic necrosis virus (IHHNV), infectious myonecrosis virus (IMNV) and Enterocytozoon hepatopenaei (EHP). The number of shrimp collected from shrimp farms ranged from 6 to 20 based on the body weight of the shrimp. All the shrimp collected from one farm were pooled together for screening for pathogens by PCR assay. Among the samples screened, 28 samples were WSSV‐positive, one positive for IHHNV and 30 samples positive for EHP. Among the positive samples, four samples were found to be positive for both WSSV and EHP, which indicated that the shrimp had multiple infections with WSSV and EHP. This is the first report on the occurrence of multiple infections caused by WSSV and EHP. Multiplex PCR (m‐PCR) protocol was standardized to detect both pathogens simultaneously in single reaction instead of carrying out separate PCR for both pathogens. Using m‐PCR assay, naturally infected shrimp samples collected from field showed two prominent bands of 615 and 510 bp for WSSV and EHP, respectively.     

Pre-exposure to infectious hypodermal and haematopoietic necrosis virus or to inactivated white spot syndrome virus (WSSV) confers protection against WSSV in Penaeus vannamei (Boone) post-larvae

Larvae and post-larvae of Penaeus vannamei (Boone) were submitted to primary challenge with infectious hypodermal and haematopoietic necrosis virus (IHHNV) or formalin-inactivated white spot syndrome virus (WSSV). Survival rate and viral load were evaluated after secondary per os challenge with WSSV at post-larval stage 45 (PL45). Only shrimp treated with inactivated WSSV at PL35 or with IHHNV infection at nauplius 5, zoea 1 and PL22 were alive (4.7% and 4%, respectively) at 10 days post-infection (p.i.). Moreover, at 9 days p.i. there was 100% mortality in all remaining treatments, while there was 94% mortality in shrimp treated with inactivated WSSV at PL35 and 95% mortality in shrimp previously treated with IHHNV at N5, Z1 and PL22. Based on viral genome copy quantification by real-time PCR, surviving shrimp previously challenged with IHHNV at PL22 contained the lowest load of WSSV (0-1x10(3) copies microg-1 of DNA). In addition, surviving shrimp previously exposed to inactivated WSSV at PL35 also contained few WSSV (0-2x10(3) copies microg-1 of DNA). Consequently, pre-exposure to either IHHNV or inactivated WSSV resulted in slower WSSV replication and delayed mortality. This evidence suggests a protective role of IHHNV as an interfering virus, while protection obtained by inactivated WSSV might result from non-specific antiviral immune response.     

White spot syndrome virus epizootic in cultured Pacific white shrimp Litopenaeus vannamei (Boone) in Taiwan

White spot syndrome virus (WSSV) has caused significant losses in shrimp farms worldwide. Between 2004 and 2006, Pacific white shrimp Litopenaeus vannamei (Boone) were collected from 220 farms in Taiwan to determine the prevalence and impact of WSSV infection on the shrimp farm industry. Polymerase chain reaction (PCR) analysis detected WSSV in shrimp from 26% of farms. Juvenile shrimp farms had the highest infection levels (38%; 19/50 farms) and brooder shrimp farms had the lowest (5%; one of 20 farms). The average extent of infection at each farm was as follows for WSSV‐positive farms: post‐larvae farms, 71%; juvenile farms, 61%; subadult farms, 62%; adult farms, 49%; and brooder farms, 40%. Characteristic white spots, hypertrophied nuclei and basophilic viral inclusion bodies were found in the epithelia of gills and tail fans, appendages, cephalothorax and hepatopancreas, and virions of WSSV were observed. Of shrimp that had WSSV lesions, 100% had lesions on the cephalothorax, 96% in gills and tail fans, 91% on appendages and 17% in the hepatopancreas. WSSV was also detected in copepoda and crustaceans from the shrimp farms. Sequence comparison using the pms146 gene fragment of WSSV showed that isolates from the farms had 99.7–100% nucleotide sequence identity with four strains in the GenBank database – China ( AF332093 ), Taiwan ( AF440570 and U50923 ) and Thailand ( AF369029 ). This is the first broad study of WSSV infection in L. vannamei in Taiwan.     

Competition of infectious hypodermal and haematopoietic necrosis virus (IHHNV) with white spot syndrome virus (WSSV) for binding to shrimp cellular membrane

Infectious hypodermal and haematopoietic necrosis virus (IHHNV) and white spot syndrome virus (WSSV) are two widespread shrimp viruses. The interference of IHHNV on WSSV was the first reported case of viral interference that involved crustacean viruses and has been subsequently confirmed. However, the mechanisms underlying the induction of WSSV resistance through IHHNV infection are practically unknown. In this study, the interference mechanisms between IHHNV and WSSV were studied using a competitive ELISA. The binding of WSSV and IHHNV to cellular membrane of Litopenaeus vannamei was examined. The results suggested that there existed a mutual competition between IHHNV and WSSV for binding to receptors present on cellular membrane of L. vannamei and that the inhibitory effects of WSSV towards IHHNV were more distinct than those of IHHNV towards WSSV.     

对虾6种病毒多重PCR检测方法的建立

本研究针对养殖对虾6种病毒,包括白斑综合征病毒(WSSV)、传染性皮下及造血组织坏死病毒(IHHNV)、肝胰腺细小病毒(HPV)、桃拉综合征病毒(TSV)、对虾杆状病毒(BP)和传染性肌肉坏死病毒(IMNV),选择各自的基因分别设计特异性引物和探针,首先进行了单一病毒的PCR验证,在此基础上建立了同时特异性检测6种对虾病毒的多重PCR检测体系。对反应条件进行优化并进行特异性和灵敏度的验证。50μl反应体系,Mg2+的最佳浓度为5mmol/L,ExTaq酶最佳用量为3.75U,反应程序中最佳退火温度为55.5℃。6种病毒之间以及与对虾基因组都存在很好的特异性。最终经试验验证,该系统的检测灵敏度对WSSV可达104拷贝,IHHNV可达102拷贝,HPV可达104拷贝,TSV可达103拷贝,BP可达105拷贝,IMNV可达105拷贝。虽然该多重PCR方法灵敏度不如单一的PCR检测高,但是通过实际样品检测验证了该方法省时、消耗较少,又不失准确性,在实际应用中具有可靠性和应用价值。     

A single-step multiplex PCR for simultaneous detection of white spot syndrome virus and infectious hypodermal and haematopoietic necrosis virus in penaeid shrimp

White spot syndrome virus (WSSV) and infectious hypodermal and haematopoietic necrosis virus (IHHNV) are the major viral pathogens of penaeid shrimp worldwide (Lightner & Redman 1998). Litopenaeus vannamei was introduced into China from the Americas, and quickly became widely cultured. Following its introduction, both IHHNV and WSSV have become important pathogens of cultured penaeid shrimp and have had a huge impact on the culture industry in China in recent years.     

The molecular detection of Taura syndrome virus emerging with White spot syndrome virus in penaeid shrimps of Thailand

This study is to investigate the outbreak of the Taura syndrome (TS) in penaeid shrimps of Thailand. Following the outbreak in 2003, the Taura syndrome virus (TSV) was detected in two closely related penaeids; the Pacific white shrimp, Penaeus vannamei, and the black tiger prawn, Penaeus monodon. Multiple viral infections were detected, we found that the TSV-infected P. vannamei also presented evidence of the White spot syndrome virus (WSSV) as evidenced by histological examination and molecular diagnostic methods. Infections of TSV and WSSV were investigated over a period of ten months between October 2003 and July 2004. TSV infection in shrimps was diagnosed by RT-PCR using the OIE recommended 9195/9992 primers. Positive shrimp gave the expected amplicon of 231 bp. We also amplified and sequenced a fragment of the vp1 gene (354 bp). The pairwise comparisons of vp1 revealed that Thai TSV was phylogenetically related to the Taiwanese strains (98.3% identity).     

多重PCR检测对虾白斑综合症病毒和传染性皮下组织坏死病毒

采用对虾白斑综合症病毒和传染性皮下组织坏死病毒的特异引物,在一个PCR反应中同时扩增到大小分别为271 bp和356 bp的病毒特异片段,多重PCR条件优化后可从最少100 fg级病毒DNA模板中定性检测出此两种病毒。     

Development of a multiplex PCR system for the simultaneous detection of white spot syndrome virus and hepatopancreatic parvovirus infection

A multiplex PCR kit for simultaneous detection of white spot syndrome virus (WSSV) and hepatopancreatic parvovirus (HPV) was developed and field testing was conducted. A 604‐bp target sequence was selected from the vp28 gene of WSSV. A primer set was developed to amplify a 338‐bp DNA fragment at the junction of the NS2 and NS1 protein genes of HPV after alignment of eight sequences from different strains. Another internal positive control primer set produced a 139‐bp PCR fragment from the β‐actin gene by alignment of this gene from Litopenaeus vannamei, Fenneropenaeus chinensis and Penaeus monodon. The detection limits, tested using purified plasmids, for WSSV and HPV were 21.4 and 19.0 copies respectively. The optimum ratio for HPV, WSSV and β‐actin was 3:1:1, with an optimum annealing temperature of 57°C. Field test of the multiplex PCR with 170 L. vannamei individuals from 17 aquaculture farms showed 41.8% coinfection with WSSV and HPV, and 40.0% and 3.5% single infection with WSSV and HPV respectively. No virus‐free shrimp farm was found. Ten wild catch F. chinensis individuals showed 60% coinfection, and 40% were infected with HPV.     

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.     

Prevalence of Infectious Hypodermal and Hematopoietic Necrosis Virus (IHHNV) and White Spot Syndrome Virus (WSSV) in Litopenaeus vannamei in the Pacific Ocean off the Coast of Panama

Abstract.— In March 2000, 104 wild caught Litopenaeus wannamei broodstock, captured off the Pacific coast of Panama, were screened for the following penaeid viruses: infectious hypodermal and hematopoietic necrosis virus (IHHNV) and white spot syndrome virus (WSSV). The purpose of this study was to determine the prevalence of IHHNV and WSSV in wild shrimp in this area of the Western Hemisphere and to acquire specific pathogen free (SPF) L. vannamei for inclusion into the Oceanic Institute's genetic breeding program. The prevalence of the viruses was determined using the dot blot hybridization format, which is a commercially available molecular method for detecting these viruses. Dot blot hybridization assays can be used as an initial screening method to detect moderately to highly infected shrimp. The results from the dot blot assays indicated the prevalence of IHHNV in 28% and WSSV in 2% of the 104 hemolyrnph samples tested. Results from this study were used to establish the initial candidate SPF status of the animals that were assessed and to determine the prevalence of two serious pathogens of penaeid shrimp captured from the wild of the Pacific Ocean in the Central American region off the coast of Panama.     

传染性皮下及造血组织坏死病毒致病性研究进展

传染性皮下及造血组织坏死病毒(IHHNV)是一种分布较广、危害较大的对虾病毒,已被世界动物卫生组织(OIE)列为须向其申报的甲壳类重要疫病病原。IHHNV在我国已形成了一定的流行趋势,目前仍是严重危害我国养殖虾类的重要病毒。本文从IHHNV的流行地区及危害、宿主、致病类型、对宿主不同年龄阶段的致病性差异、与白斑综合征病毒(WSSV)的干扰作用、感染机制和致病机理方面,综述了与IHHNV致病性相关的研究进展,以期为进一步深入研究IHHNV防控提供参考资料。     

凡纳滨对虾(Litopenaeus vannamei)传染性皮下及造血组织坏死病毒(IHHNV)及虾肝肠胞虫(EHP)的荧光定量PCR检测

2013年,河北、天津等地区养殖的凡纳滨对虾(Litopenaeus vannamei)育苗期出现死苗、出苗率低的情况,生产上,仔虾个体大小差异较大,造成了严重损失.本研究采用荧光定量PCR方法(Real-time PCR)对天津大港地区采集的108尾凡纳滨对虾仔虾样品进行单尾病原检测.结果显示,传染性皮下及造血组织坏死病毒(Infectious hypodermal and hematopoietic necrosis virus,IHHNV)和虾肝肠胞虫(Enterocytozoon hepatopenaei,EHP)均有检出.IHHNV阳性检出率100％,每微克对虾组织DNA的病毒拷贝数为103-107,且个体较大的样品(1.2-2.0 cm)携带病毒拷贝数偏高;EHP阳性检出率为49.1％,每微克对虾组织DNA的拷贝数为103-105,且集中于个体较小样品(0.7-1.1 cm).对IHHNV和EHP阳性凡纳滨对虾样品进行生物学体长与病毒载量指数相关性分析,显示IHHNV载量指数与对虾生长速率呈正相关,虾组织IHHNV平均载量达8.51×104 copies/μg DNA,为较高的感染水平;EHP的载量与对虾生长速率呈负相关关系,与较大个体阳性检出率较低相对应,虾组织EHP平均载量达到2.19× 104 copies/μg DNA,为较高的感染水平.由此,该批凡纳滨对虾仔虾患病为IHHNV和EHP的混合感染所致,本研究数据为IHHNV和EHP病原混合感染流行情况及其对养殖育苗期仔虾生长的影响提供科学依据.     

Detection of monodon baculovirus and white spot syndrome virus in apparently healthy Penaeus monodon postlarvae from India by polymerase chain reaction

The simultaneous presence of monodon baculovirus (MBV) and white spot syndrome virus (WSSV) in apparently healthy postlarvae of Penaeus monodon from different hatcheries in India was studied by nested polymerase chain reaction (PCR). MBV could be detected in 54% of the samples. However, only 15% of samples were positive by non-nested reaction. WSSV could be detected in 75% of samples, 19% being positive by non-nested reaction. The results show simultaneous presence of WSSV and MBV in many samples at various degrees of infection. Only 14% of the samples analysed were negative for both viruses.     

Detailed monitoring of white spot syndrome virus (WSSV) in shrimp commercial ponds in Sinaloa, Mexico by nested PCR

WSSV has caused great losses to the global shrimp industry in recent years. This virus can infect shrimps asymptomatically. However, once the clinical signs are developed, mortalities can reach 100% in 3-10 days. PCR has been extensively used to detect WSSV in a specific and sensitive manner. Nested PCR is even more sensitive than single-step PCR and had been used for the detection of WSSV in asymptomatic populations. In this work, a detailed monitoring of WSSV by nested PCR in shrimp commercial ponds in Guasave County, State of Sinaloa, Mexico, is presented. Five ponds from two different farms were monitored for growth and presence of WSSV. At the beginning of the culture, ponds from both farms showed no or very slight WSSV presence. A 3-day period of rain occurred at both farms 10 and 14 weeks of culture for farms 1 and 2, respectively. At this time, WSSV was widely distributed in the shrimp populations of farm 1 according to nested-PCR data, although no visual symptoms were observed. In ponds of farm 2, WSSV was present at low level. However, the number of PCR-positive groups was drastically increased in both farms by nested and single-step PCR. Abrupt fluctuations in temperature and salinity were documented in farm 2 after the rain, which may have contributed to the increasing of viral load in the pond's shrimp populations. Twelve days after the rain period, estimated mortalities of 80% occurred in farm 1. Nevertheless, the study ponds at farm 2 culture continued normally for three more weeks and were harvested successfully (52% and 67% of survival for ponds 1 and 2, respectively). The removal of 40% and 50% of shrimp population 2-4 days after the raining period may have contributed to the thriving of the cultures. Analyses of the presence of WSSV in individuals of both sexes indicated that there is no preference for this virus to infect male or female shrimp. Also, no differences in weight were found between WSSV infected and non-infected individual shrimps, as well as nested-PCR positive against single-step PCR positive organisms. Nested PCR is more useful to monitor shrimp cultures than single-step PCR since it allows knowing how widely distributed the virus is in asymptomatically populations.     

Indian isolates of white spot syndrome virus exhibit variations in their pathogenicity and genomic tandem repeats

To detect genomic variation of white spot syndrome virus (WSSV) isolates from different geographical regions of India, the variable number of the tandem repeat (VNTR) region of the ORF 94 (Thailand WSSV isolate – GeneBank Accession No. AF369029 ) was analysed using five specific sets of primers. Analysis of 70 WSSV‐positive samples showed the presence of 14 different genotypes of WSSV with VNTRs ranging from 2 to 16 tandem repeats with the majority (85.47%) having 6–12 tandem repeats. Occurrence of different genotypes of WSSV was found to be neither correlated to any specific geographical region nor to the different growth stage of the tiger shrimp, Penaeus monodon. Pathogenicity studies conducted with 25 isolates of WSSV revealed the presence of virulent and avirulent strains of WSSV in Indian shrimp farms. However, an unambiguous link could not be established between the different genotypes and their virulence.