一例猪细小病毒病的诊断

从取自某猪场表现初产母猪流产胎儿的肾脏、脾脏、肠系膜淋巴结组织,进行研磨后接种猪原代肾细胞,成功分离到一株病毒。该病毒的豚鼠红细胞血凝活性为27,用针对猪细小病毒结构蛋白VP2的特异性引物对分离病毒进行扩增,将扩增结果进行克隆测序,结果经BLAST分析后,证实分离到一株猪细小病毒。     

Interepizootic survival of porcine parvovirus

Porcine parvovirus (PPV) was transmitted by direct contact between experimentally infected and susceptible pigs at 1 and 2 weeks, but not at 4, 8, 16, or 25 weeks, after experimental infection. In contrast, PPV was found to remain infectious for at least 14 weeks in uncleaned rooms previously vacated by experimentally infected pigs. These findings suggest that facilities contaminated by secretions and excretions of infected pigs may provide the major means by which PPV survives between episodes of acute infection.     

Efficacy of porcine parvovirus vaccines

Three inactivated porcine parvovirus vaccines were tested for efficacy in 66 susceptible gilts. The gilts were challenged with virulent virus on the 40th day of gestation. All the vaccines provided excellent protection against fetal mortality despite insignificant serological responses to one of them. Good protection was obtained with two of the vaccines even when the dose was substantially reduced. Unvaccinated controls had very few viable fetuses.     

Effect of porcine parvovirus vaccination on the development of PMWS in segregated early weaned pigs coinfected with type 2 porcine circovirus and porcine parvovirus

The objectives of this study were to determine if coinfection of segregated early weaned (SEW) pigs with porcine circovirus type 2 (PCV2) and porcine parvovirus (PPV) induces an increase in the incidence of post-weaning multisystemic wasting syndrome (PMWS) compared to singular PCV2 infection, and to determine if vaccination against PPV protects pigs against PMWS associated with PCV2/PPV coinfection in SEW pigs. Seventy, 3-week-old, SEW pigs were randomly assigned to one of the five groups. Pigs in group 1 (n = 14) served as the negative controls, group 2 pigs (n = 14) were inoculated with PCV2, group 3 pigs (n = 12) were inoculated with PPV, groups 4 (n = 16) and 5 (n = 14) pigs were inoculated with both PCV2 and PPV. Pigs in groups 1-3 and 5 were vaccinated with two doses of a killed parvovirus-leptospira-erysipelothrix (PLE) vaccine prior to inoculation. The PCV2/PPV-coinfected pigs (groups 4 and 5) had significantly (P < 0.05) higher and more persistent fevers than the singular PCV2-infected pigs. One pig in each of the coinfected groups developed clinical disease (fever, respiratory disease, jaundice, weight loss) consistent with PMWS. Lymphoid depletion was significantly (P < 0.05) more severe in the dually-infected pigs at 42 days post-inoculation (DPI). Vaccinated, coinfected pigs (group 5) remained viremic significantly (P < 0.05) longer and had higher copy numbers of genomic PCV2 DNA in sera at 28, 35, and 42 DPI compared to the unvaccinated coinfected pigs (group 4). PPV-viremia was detected only in the unvaccinated group 4 pigs. PLE-vaccination prevented PPV-viremia but did not prevent clinical PMWS or reduce the severity of lymphoid depletion in PCV2/PPV-coinfected pigs. Evidence of increased incidence of clinical PMWS due to vaccination was not observed in this model.     

An economic assessment of porcine parvovirus vaccination

SUMMARY A decision analysis model was designed to evaluate the cost effectiveness of a vaccination program for preventing endemic or epidemic porcine parvovirus (PPV) Induced reproductive failure in a 100-sow pig herd. The results showed that the cost of vaccination was less than the cost incurred by continuing endemic PPV infection, or the cost of a severe epidemic. A long term vaccination program is a cost effective method for controlling PPV-induced reproductive failure in pig herds suffering endemic and epidemic PPV infection.     

新型猪细小病毒感染的分子流行病学调查

近几年来,世界范围内的猪群出现了多种新型猪细小病毒(porcine parvovirus,PPV)的感染,其中我国南方地区的猪群也出现了不同程度的感染。本研究利用PCR方法对实验室保存的2008—2013年期间的送检病料,进行猪细小病毒2型(PPV2)、PPV3、PPV4、猪类博卡病毒(PBo-likeV)和猪博卡病毒(PBoV)感染的分子流行病学调查,结果显示阳性率依次为46.4%、21.1%、6.8%、12.3%和5.5%。结合PRRSV和PCV2检测结果,并对新型细小病毒与这2种病毒共感染情况进行初步分析,结果显示PPV3和PRRSV、PBo-likeV和PCV2混合感染的几率较高,提示它们在感染过程中可能存在着协同作用。本研究为细小病毒流行病学和致病机理的研究奠定了一定的基础。     

猪细小病毒病弱毒疫苗免疫效力评价及临床免疫试验

为制定猪细小病毒病弱毒疫苗效力检验的标准,用3批猪细小病毒病弱毒疫苗进行接种猪与接种豚鼠的平行试验;同时进行临床免疫试验。3批疫苗接种豚鼠和猪后定期进行PPVHI抗体检测;猪于免疫后攻毒,并进行病毒分离。免疫母猪在怀孕早期进行强毒攻击,40d扑杀进行病毒分离。用3批疫苗免疫后备母猪统计产仔成绩。结果显示,豚鼠接种后21d、猪接种后7d全部产生抗体反应。免疫攻毒的猪均未从血浆和内脏中分离到病毒,而从对照猪分离到病毒;怀孕母猪强毒攻击后扑杀,胎儿病毒分离均为阴性,而对照猪胎儿病毒分离为阳性;统计数据表明免疫猪的产仔成绩比未免疫猪高,平均每窝多产活仔1.85头,少产死胎木乃伊胎0.65头。结果表明,当免疫豚鼠PPV HI≥64时,免疫猪能抵抗PPV强毒攻击,两者呈正相关;免疫母猪的攻毒试验表明免疫母猪能抵抗PPV经胎盘感染;临床免疫试验证明疫苗具有良好的免疫原性和安全性。     

猪细小病毒在PK15细胞中增殖规律的研究

猪细小病毒毒株在不同细胞系上的生长情况不尽相同,如不能掌握其规律,将难以生产出优质的疫苗。对PPV（长春株）在PK15和ST细胞上生长情况进行了研究,在PK15细胞系中重点比较了不同的病毒接种方法、病毒接种量和病毒收获时间等因素对病毒产量的影响。研究结果显示：本毒株在PK15和ST两种细胞系上的病变特征不同,但生长规模相似。在PK15细胞上按2％接种量、分步接种、80h时收获病毒,最终得到的病毒滴度（TCID50）最高。提示这是一种比较好的生产方案。然而,进一步的大规模培养试验是有必要的。     

Studies on the multiplication of a porcine parvovirus

A porcine parvovirus has been characterized with regard to its replication in foetal porcine kidney cells and certain biophysical properties. Electron microscopy of infected cells at selected times postinfection revealed that porcine parvovirus replication took place within or near a series of granular intranuclear inclusions which may be contiguous with cellular heterochromatin. Developing virions were observed to aggregate into a nuclear-like amorphous mass which gradually disrupted as cellular integrity was lost. Purified virions were found to have a buoyant density in CsCl of 1.38 g/ml, while ‘empty’ particles has a buoyant density of 1.29 g/ml. The particle diameter was calculated to be approximately 22 nm.     

猪细小病毒细胞适应株的培育及鉴定

从临床表现为皮炎消瘦症状的仔猪肝脏中分离到1株病毒,经聚合酶链式反应（PCR）证实为猪细小病毒（PPV）,采用仔猪原代肾细胞和传代ST细胞分离培养,经蚀斑克隆纯化,培育1株ST传代细胞培养适应毒株,命名为PPV-BQ2007株。免疫过氧化物酶单层细胞试验（IPMA）检测病毒抗原主要分布在细胞核及细胞质内。病毒感染细胞可被已知PPV阳性血清中和。免疫电镜可清晰见到聚集成团的大小不一的病毒粒子,近似圆形,无囊膜,直径大小约20nm-22nm。该分离株经ST细胞培养传代,能够产生典型的细胞病变,病毒滴度随代次显著增加,第30代后毒价达10^7 TCID50/mL以上,且毒价和血凝价稳定。测序结果表明PPV-BQ2007株VP2基因与NCBI公布的皮炎型毒株Kresse株的同源性最高,达99.8％,在系统进化分支上处于同一个分支。PPV-BQ2007株传代细胞培养适应株的成功培育和鉴定,为进一步开展该病毒流行病学、致病机理、疫苗免疫与诊断研究等奠定了良好基础。     

猪细小病毒灭活疫苗安全性试验及佐剂的筛选

本研究以猪细小病毒(PPV)现地分离株(BQ)第30代细胞培养毒株作为灭活疫苗研究用种毒,通过优化病毒增殖条件和培养方法,获得较高滴度的病毒传代细胞培养物用于PPV灭活疫苗的制备.PPV细胞培养毒株分别用甲醛和β-丙内酯进行灭活,对2种灭活剂灭活的病毒液分别用国产铝胶佐剂、进口矿物质白油佐剂以及法国赛比克公司的MONTANIDETM ISA 206、ISA15AVG、IMS251CVG 3种佐剂制备10种灭活疫苗,然后分别进行10日龄乳鼠、60日龄仔猪、不同妊娠阶段母猪的安全性试验及成年豚鼠的免疫效果对比试验.通过比较不同灭活疫苗的安全性和对成年豚鼠的免疫效果,初步确认甲醛灭活的病毒液与佐剂ISA15AVG的组合为PPV灭活疫苗的最佳灭活剂和佐剂组合.     

环介导等温扩增技术快速检测猪细小病毒的试验

利用环介导等温核酸扩增技术(LAMP),建立了一种灵敏、特异、快速的猪细小病毒(PPV)检测方法.该方法针对猪细小病毒非结构蛋白(NS-1)基因保守区域设计6条特异引物,在63℃的等温条件下45 min即可完成反应.最低检测限量为10拷贝的PPV目的基因,比常规聚合酶链式反应(PCR)方法敏感100倍,并具有良好的特异性.以钙黄绿素和Mn2+作为荧光指示剂,可快速、直观判定反应结果.通过对149份临床样品进行检测比较,LAMP与PCR检出阳性样本数分别为33份和27份,表明LAMP方法阳性检出率高于PCR.     

猪细小病毒与猪伪狂犬病毒二重SYBR GreenⅠ实时荧光PCR方法的建立与检测

本研究旨在建立一种能快速、灵敏、同时检测出猪细小病毒与猪伪狂犬病毒的基于SYBR GreenⅠ实时荧光定量PCR方法。参照GenBank中登录的相关基因序列,设计了2对引物分别用于扩增PRV gH基因与PPV NS1基因的部分片段。将测序正确的PRV gH基因与PPV NS1基因片段克隆入pGEM-T Easy载体,转化大肠杆菌DH5α,经测序鉴定后得到阳性重组质粒,作为标准品模板建立SYBR GreenⅠ荧光定量PCR标准曲线和熔解曲线,并对其灵敏性、特异性和重复性进行验证。结果表明,猪细小病毒与猪伪狂犬病毒荧光定量PCR的标准曲线的Tm值分别为80.9℃和86.5℃,熔解曲线特异,灵敏度分别可达248拷贝/μL和160拷贝/μL,是普通PCR检测方法的100倍。本次建立的猪细小病毒与猪伪狂犬病毒荧光定量PCR检测方法实现了2种病毒的同时检测,能够对PRV、PPV混合感染的临床病料进行快速诊断。     

多重PCR检测猪细小病毒和猪伪狂犬病病毒的研究

根据GenBank上已发表的猪细小病毒（Porcine parvovirus，PPV）的VP2基因序列和猪伪狂犬病病毒（Porcine pseudorabies virus，PRV）的gH基因序列，设计合成了两对特异引物，分别建立了PPV和PRV的单项PCR诊断方法，通过对扩增条件的筛选，最终成功地建立了PPV和PRV的复合PCR诊断方法，即利用一次PCR反应，可同时扩增PPV的751bp和PRV355bp的特异性片段，而扩增猪圆环病毒Ⅱ型（PCV．2）及相应的培养细胞（PK-15）核酸结果均为阴性，对PPV和PRV的最低检出量分别为100Pg和10Pg的DNA。该方法适合对PPV和PRV的联合检测和鉴别诊断。     

猪细小病毒N株弱毒苗田间试验

猪细小病毒感染普遍流行于世界各地猪群,为了有效防制该病,我们研制出能预防该病感染的猪细小病毒N株弱毒疫苗(PPV-N株)[1].该弱毒苗具有良好的免疫原性和安全性[2].我们按要求制备三批PPV-N株弱毒疫苗对三个规模化猪场的后备母猪进行田间试验,现将结果报告如下.     

实时荧光定量PCR检测猪细小病毒

根据已报道的猪细小病毒基因组序列,设计并合成了引物和探针,从猪细小病毒(PPV)感染的细胞中提取DNA,经PCR扩增,产物纯化后与pGEM-T-easy连接,转化大肠杆菌JM109,筛选后得到重组标准品质粒,对重组标准品质粒进行PCR和测序鉴定,表明目的片段已经成功克隆.将104～108拷贝反应的重组标准品质粒进行荧光定量PCR,系统自动分析软件显示Ct值与标准品浓度的对数之间存在良好的线性关系.动力学曲线分析表明,在该反应体系和反应条件下,标准曲线的灵敏度为102拷贝.本方法的建立为猪细小病毒感染的早期诊断奠定了基础.     

Detection of porcine parvovirus using nonradioactive nucleic acid hybridization

Nonradioactive slot blot hybridization assays were established for the detection of porcine parvovirus (PPV), using either a digoxigenin-labeled DNA probe or a biotinylated RNA probe. All probes were prepared from a 3.3-kb Pst1-EcoR1 DNA fragment of the NADL8 isolate of PPV. The sensitivity and specificity of the probes in a slot blot system were evaluated in comparison with a 32P-radiolabeled RNA probe. Using an anti-digoxigenin alkaline phosphatase detection system, at least 1 ng of viral replicative form (RF) DNA, or the equivalent of 100 plaque forming units (PFU) of infectious virus, could be detected by the digoxigenin-labeled DNA probe. When the biotinylated RNA probe and a strepavidin-alkaline phosphatase detection system were employed, 0.1 ng of RF DNA, or the equivalent of 10 PFU of infectious virus, were detected, comparable to the sensitivity of the 32P-radiolabeled RNA probe. Hybridization was not observed with control DNA samples extracted from swine testicle cells, porcine kidney (PK-15) cells, uninfected mixed swine fetal tissue, or from an unrelated DNA virus (pseudorabies virus) infected PK-15 cells. Different isolates of PPV, namely NADL8, NADL2, KBSH, and Kresse, reacted on an equimolar basis in sensitivity and specificity to the biotinlyated probe. Extraction of DNA directly on the filter membrane (direct filter hybridization) was employed in an attempt to reduce processing time by eliminating DNA extraction steps. Direct filter hybridization was indeed less time consuming; it was also comparable in sensitivity and specificity to those methods employing purified DNA.