Pathotyping of Newcastle disease virus with a filamentous bacteriophage

A filamentous phage bearing the peptide sequence TLTTKLY was isolated from a heptapeptide phage display library against a velogenic Newcastle disease virus (NDV). In order to investigate the potential of this specific phage as an immunological reagent in virus pathotyping, an enzyme-linked immunosorbent assay (ELISA)-based method was developed. This method can differentiate the velogenic strains from the mesogenic and lentogenic strains. An equilibrium-binding assay in solution showed that the interactions between the phage and all the NDV strains gave rise to two widely differing dissociation constants (Kdrel). Based upon the first Kdrel values, NDV strains can be classified into two groups; the first comprises the velogenic strains, and the second consists of the mesogenic and lentogenic strains. These results indicate a high degree of correlation between the binding affinities and pathotyping of NDV strains using the TLTTKLY phage.     

Detection of avian influenza virus and newcastle disease virus by duplex one step RT PCR

Newcastle disease Virus (NDV), a member of the Paramyxoviridae family, and Influenza virus, from the Orthomyxoviridae family, are two main avian pathogens that cause serious economic problems in poultry farming. NDV strains are classified into three major pathotypes: velogenic, mesogenic, and lentogenic. Avian influenza viruses (AIV) are also divided into: low pathogenic (LPAI) and highly pathogenic (HPAI) strains. Both viruses are enveloped, single stranded, negative-sense RNA viruses which give similar symptoms ranging from sub-clinical infections to severe disease, including loss in egg production, acute respiratory syndrome, and high mortality, depending on their level of pathogenicity. This similarity hinders diagnosis when based solely on clinical and post mortem examination. Most of the currently available molecular detection methods are also pathogenspecific, so that more than one RT-PCR is then required to confirm or exclude the presence of both pathogens. To overcome this disadvantage, we have applied a One Step Duplex RT-PCR method to distinguish between those two pathogens. The main objective of the project was to develop a universal, fast, and inexpensive method which could be used in any veterinary laboratory.     

Detection of Newcastle disease virus using nucleic acid sequence-based amplification.

Newcastle disease (ND) is a contagious and widespread avian disease affecting most species of birds. ND virus (NDV) is the only member of the avian paramyxovirus serotype 1 (APMV1) causing ND outbreak in bird flocks. The technique of nucleic acid sequence-based amplification (NASBA) is a potential method to rapidly and reliably detect NDV isolates. Here, we describe an effective and unprecedented method for detecting NDV strains of all pathotypes. A conserved region of the fusion protein gene was used for designing oligonucleotides specific to all NDV pathotypes. The dynamic range of this NDV NASBA detection method is comparable to virus culture and therefore the NDV NASBA method is a potential alternative for NDV screening and surveillance.     

Different Regions of the Newcastle Disease Virus Fusion Protein Modulate Pathogenicity

Newcastle disease virus (NDV), also designated as Avian paramyxovirus type 1 (APMV-1), is the causative agent of a notifiable disease of poultry but it exhibits different pathogenicity dependent on the virus strain. The molecular basis for this variability is not fully understood. The efficiency of activation of the fusion protein (F) is determined by presence or absence of a polybasic amino acid sequence at an internal proteolytic cleavage site which is a major determinant of NDV virulence. However, other determinants of pathogenicity must exist since APMV-1 of high (velogenic), intermediate (mesogenic) and low (lentogenic) virulence specify a polybasic F cleavage site. We aimed at elucidation of additional virulence determinants by constructing a recombinant virus that consists of a lentogenic NDV Clone 30 backbone and the F protein gene from a mesogenic pigeon paramyxovirus-1 (PPMV-1) isolate with an intracerebral pathogenicity index (ICPI) of 1.1 specifying the polybasic sequence R-R-K-K-R*F motif at the cleavage site. The resulting virus was characterized by an ICPI of 0.6, indicating a lentogenic pathotype. In contrast, alteration of the cleavage site G-R-Q-G-R*L of the lentogenic Clone 30 to R-R-K-K-R*F resulted in a recombinant virus with an ICPI of 1.36 which was higher than that of parental PPMV-1. Substitution of different regions of the F protein of Clone 30 by those of PPMV-1, while maintaining the polybasic amino acid sequence at the F cleavage site, resulted in recombinant viruses with ICPIs ranging from 0.59 to 1.36 suggesting that virulence is modulated by regions of the F protein other than the polybasic cleavage site.     

Effects of Naturally Occurring Six- and Twelve-Nucleotide Inserts on Newcastle Disease Virus Replication and Pathogenesis

Newcastle disease virus (NDV) isolates contain genomes of 15,186, 15,192 or 15,198 nucleotides (nt). The length differences reflect a 6-nt insert in the 5′ (downstream) non-translated region (NTR) of the N gene (15,192-nt genome) or a 12-nt insert in the ORF encoding the P and V proteins (causing a 4-amino acid insert; 15,198-nt genome). We evaluated the role of these inserts in the N and P genes on viral replication and pathogenicity by inserting them into genomes of two NDV strains that have natural genome lengths of 15,186 nt and represent two different pathotypes, namely the mesogenic strain Beaudette C (BC) and the velogenic strain GB Texas (GBT). Our results showed that the 6-nt and 12-nt inserts did not detectably affect N gene expression or P protein function. The inserts had no effect on the replication or virulence of the highly virulent GBT strain but showed modest degree of attenuation in mesogenic strain BC. We also deleted a naturally-occurring 6-nt insertion in the N gene from a highly virulent 15,192-nt genome-length virus, strain Banjarmasin. This resulted in reduced replication in vitro and reduced virulence in vivo. Thus, although these inserts had no evident effect on gene expression, protein function, or replication in vivo, they did affect virulence in two of the three tested strains.     

鹅副粘病毒SF02 F基因的序列分析及SF02的多重RT—PCR鉴别

对新近分离的鹅副粘病毒SF0 2采用RT PCR方法 ,扩增F基因后测序 ,得到全长的F基因。该基因的ORF总长为 16 6 2nt,编码 5 5 3个氨基酸 ,其裂解位点的序列为112 R R Q K R F117,与新城疫病毒强毒株的特征相符。其核苷酸和氨基酸同源性分析 ,并与国内新城疫病毒标准强毒株F4 8E9相比较 ,表明该毒株在F基因上已发生了较大的变异 ,而与近年来在我国台湾和部分西欧国家流行的禽副粘病毒有很高的亲缘关系。在分析F基因序列的基础上 ,设计 3条引物 ,建立了一种新的多重RT PCR方法 ,能区分鸡新城疫病毒与鹅副粘病毒。     

Structural analysis of peptides that interact with Newcastle disease virus

A peptide with the sequence CTLTTKLYC has previously been identified to inhibit the propagation of Newcastle disease virus (NDV) in embryonated chicken eggs and tissue culture. NDV has been classified into two main groups: the velogenic group, and mesogenic with lentogenic strains as the other group based on its dissociation constants. In this study the peptide, CTLTTKLYC, displayed on the pIII protein of a filamentous M13 phage was synthesized and mutated in order to identify the amino acid residues involved in the interactions with NDV. Mutations of C1 and K6 to A1 and A6 did not affect the binding significantly, but substitution of Y8 with A8 dramatically reduced the interaction. This suggests that Y8 plays an important role in the peptide-virus interaction. The three-dimensional structure of the peptide was determined using circular dichroism (CD), nuclear magnetic resonance (NMR), and molecular modeling. The peptide exhibited two possible conformers. One that consists of consecutive beta-turns around T2-L3-T4-T5 and K6-L7-Y8-C9. The other conformer exhibited a beta-hairpin bend type of structure with a bend around L3-T4-T5-K6.     

一株基因Ⅱ型新城疫强毒株的分子特性

从患病肉鸡群分离到一株新城疫病毒(NewcastleDiseasevirus,NDV)SQZ04。经蚀斑纯化后接种40日龄SPF鸡可诱发典型病变。经蚀斑纯化前和后的MDT为50·5h和51·2h,ICPI为2·0和1·92,IVPI为2·8和2·68,表明属强毒株。但F基因分型表明SQZ04属基因Ⅱ型,而且其与已知基因Ⅱ型的疫苗株LaSota、B1和Texas48的同源性分别为99·3%、98·7%和96·9%,显著高于与基因Ⅶ或Ⅸ型强毒株的同源性88·3%~88·6%或91·3%~92·1%。这是国内第一株属于基因Ⅱ型的NDV强毒株。SQZ04F多肽氨基酸裂解位点的序列为111GGRQGRL117,与弱毒株序列完全相同,这也是国内外首次报道具有这一氨基酸序列的强毒野毒株。然而,SQZ04株与其他已知强毒株的HN氨基酸同源性高达95·3%~97·3%,显著高于与弱毒株LaSota等的同源性87·8%~89·5%。     

三株新城疫病毒强毒株的生物学特性及全基因组序列分析

2009～2011年从北方发病鸡群和鸭群中分离出3株新城疫病毒（Newcastle disease virus,NDV）。通过致病性指数测定及交叉血凝抑制试验初步分析了3个毒株的毒力和相互之间的同源性。选取鸡源分离株SDLY01与新城疫疫苗株（LaSota）进行了交叉保护试验,选取鸭源毒株SD03对樱桃谷鸭进行攻毒实验,同时设计引物对3个毒株进行了全基因组测序,并与36株NDV参考株进行了分子进化分析。结果表明3个分离株F蛋白裂解位点的氨基酸序列均为112R-R-Q-K-R-F117符合强毒株的序列特征,并与致病性指数测定结果相符。交叉血凝抑制试验发现3个分离株与疫苗株LaSota 的抗原同源性较低为82.5%～89.4%,两个鸡源分离株间的抗原同源性为90%,而鸭源毒株SD03与鸡源毒株SDSG01同源性为100%。交叉保护试验和攻毒实验结果显示传统的LaSota疫苗能对SDLY01流行株提供100%免疫保护,但第5天仍检测到排毒;鸭源毒株SD03对樱桃谷鸭不致病,但能检出排毒,排毒期最长为5d。全基因组测序与分析表明3个毒株基因组长度均为15192bp,属于基因Ⅶd型毒株,与同期流行的鹅源及鸭源NDV毒株之间全基因组核苷酸序列具有高度的同源性,揭示鸭源、鹅源NDV与鸡源NDV在遗传学和流行病学上密切相关。     

抗鸡新城疫病毒单克隆抗体及所测定的毒株的抗原差异

作者以3种不同毒力型的新城疫病毒(NDV)为免疫抗原,获得21株特异单克隆抗体(以下简称单抗),按其血凝抑制、溶血抑制和病毒中和能力的不同,将它们分成3组。21株单抗中有15株与所有被试的35个国内外分离的参考毒株起反应,另外6株单抗仅与部份毒株起反应。根据与上述单抗的不同反应谱,将这些NDV毒株分成7个群,同一群内的毒株在重要的流行病学和生物学特征方面一致。单抗LD_2、LC10-5只与疫苗毒株B1、La Sota及其克隆化毒株N79及1株生物学特性不明的野外分离物起反应。     

AIV血凝素亚型同步检测基因芯片技术研究

对流感病毒14个血凝素亚型的基因芯片检测技术进行了初步研究。通过RT-PCR克隆禽流感病毒血凝素基因片段,获得重组质粒。从重组质粒扩增大约500bp的DNA片段,浓缩后点到氨基化玻璃载体上,制成芯片。待检病毒样品用TRIzolLS提取RNA,反转录过程中用Cy5标记样品cDNAs。将标记样品与芯片杂交,扫描芯片上待检样品与芯片上捕捉探针的结合位点,杂交信号与预期设想一致。结果显示,DNA芯片技术可以提供一种有效的AIV血凝素亚型鉴别诊断方法。     

Overexpression of Newcastle disease virus (NDV) V protein enhances NDV production kinetics in chicken embryo fibroblasts

Newcastle disease virus (NDV) is not only one of the most economically important pathogen of poultry but also has a potential as anticancer virotherapy. The role of NDV V protein in virus-production kinetics was investigated using DF-1 cell-based production system. The presence of an anti-interferon (IFN)-alpha antibody resulted in enhanced NDV production kinetics in a dose-dependent manner by blocking binding of NDV-induced IFN to its receptor. To prepare DF-1 cell whose cellular IFN signaling is blocked efficiently, stable cell lines expressing either lentogenic or velogenic NDV V protein known as an IFN antagonist were established. The overexpression of NDV V protein enhanced NDV production kinetics and expedited the rate of NDV production, while it had no effect on Japanese encephalitis virus production. NDV V protein functions as an IFN antagonist by inhibiting the increase in type I IFNs by NDV infection. The IFN signals in cells expressing NDV V protein were weakened by decreased activation or expression of the dsRNA-activated enzymes. These IFN antagonist activities enhance rapid virus replication and spread in the early phase of viral infection and will be useful in improving the production of viral vaccine strains.     

Complete Genome Sequence of Newcastle Disease Virus Mesogenic Vaccine Strain R2B from India

Mesogenic vaccine strains of Newcastle disease virus (NDV) are widely used in many countries of Asia and Africa to control the Newcastle disease of poultry. In India, the mesogenic strain R2B was introduced in 1945; it protects adult chickens that have been preimmunized with a lentogenic vaccine virus and provides long-lasting immunity. In this article, we report the complete genome sequence of the hitherto unsequenced Indian vaccine virus strain R2B. The viral genome is 15,186 nucleotides in length and contains the polybasic amino acid motif in the fusion protein cleavage site, indicating that this vaccine strain has evolved from a virulent virus. Phylogenetic analysis of this mesogenic vaccine virus classified it with the viruses belonging to genotype III of the class cluster II of NDV.     

表达H5亚型AIV血凝素的重组NDV构建及免疫原性

利用反向遗传技术获得表达H5亚型禽流感病毒(AIV)血凝素(HA)的新城疫病毒(NDV)。克隆NDV clone 30的全长基因,通过在NDV的融合蛋白基因和血凝素-神经氨酸酶(HN)基因之间插入编码高致病性AIV分离株A/chicken/italy/8/98(H5N2)的血凝素基因开放阅读框从而获得两株重组新城疫病毒NDVH5和NDVH5m。NDVH5感染的细胞可以检测到两种HA转录产物。对于重组病毒NDVH5m,NDV位于HA ORF的转录终止信号序列被沉默突变消除,产生2.7个全长HA转录产物的折叠,从而使修饰过的HA得到稳定地高表达。1日龄小鸡的脑内接种证实了两种重组病毒均无致病性。鸡群在NDVH5m诱导产生的NDV和H5亚型AIV HA特异性抗体的免疫力下能够免于致死剂量的NDV与高致病性AIV的感染。血清学研究结果表明NDVH5m免疫鸡群产生的抗体可结合NP蛋白抗体的检测从而用于区分免疫和感染AIV的动物。因此,NDVH5m重组病毒可作为抗NDV和AIV的"二联疫苗",也可成为控制AJ的标记疫苗。     

Relationship of Plaque Size and Virulence for Chickens of 14 Representative Newcastle Disease Virus Strains

Ability of 14 Newcastle disease virus strains to produce large plaques was related to virulence for chickens. Plaque-size comparisons were made under standard conditions in chick embryo cell monolayers. All plaque-producing strains showed a range of plaque sizes modified to a degree by the overlay medium used. An increase in size was found for most strains under methyl-cellulose overlay medium. Markedly larger plaques were found under this medium for both Calif-RO and Calif-CG strains. Heterogeneity in plaque size was most pronounced in velogenic (high virulence) strains. Only populations of small plaques were found in mesogenic (intermediate virulence) strains, and plaques were rarely found in lentogenic (low virulence) strains. Statistical analysis showed that the plaque size of velogenic strains differed significantly from mesogenic strains. None of the 11 plaque-producing strains had a normal distribution of plaque sizes, owing primarily to the presence of different genotypes within the plaquing population of a strain. This was demonstrated by derivation of clones from two of the strains. The populations of the large (Herts L) and small (Herts S) clear plaque clones derived from Eng-Herts were homogenous and distinct from one another on the basis of plaque size. Herts L was more virulent than Herts S. Although Herts L became more heterogenous in respect to plaque size upon repeated passage in embryonated eggs, no decrease in virulence of the strain was observed.     

四株不同宿主来源的Class I基因3型新城疫病毒全基因组序列测定及比较分析

为了解析基因型相同但宿主来源不同的新城疫病毒的全基因组差异。本文采用RT-PCR方法分别获得4株（JS/3/09/Ch,ZJ/3/10/Ch,AH/2/10/Du,JS/9/08/Go）Class I 基因3型病毒的全基因组核苷酸序列,并与GenBank中已公布的Class I基因3型病毒全基因组序列进行比对分析。本实验4株病毒的基因组长度均为15198bp,在基因组1607～1608位有6碱基的缺失,在2381～2382位有12碱基的插入,裂解位点为112EQ/RQE/GRL117是标准弱毒特征。5株Class I基因3型病毒之间全基因组同源性超过93%;而与Class II弱毒株同源性最低只有72.2%;比较6个结构蛋白基因的同源性,NP基因的同源性最高(98.3%～96.4%),而P基因最低(96.1%～91.9%)。结果表明不同宿主来源的Class I基因3型新城疫病毒在遗传信息方面差异不大,但NP/F/L基因的变异幅度较P/M/HN基因明显。     

鸭圆环病毒与鸭Ⅰ型肝炎病毒二重 PCR 检测方法的建立

目的：建立一种同时检测鸭圆环病毒（DuCV）和鸭I型肝炎病毒（DHV）病原体的二重PCR技术。方法：根据DuCV和DHV的基因文库,分别设计了2对与DuCV和DHV某段基因序列互补的引物,用这2对引物对同一样品中DuCV和DHV模板进行二重PCR扩增。结果与结论：用建立的方法均同时得到了2条特异性的大小与实验设计相符（DuCV：245bp;DHV：569bp）的二重PCR扩增带,而且对其他禽病病原的PCR扩增结果均为阴性,能同时检出56Pg的DHVRNA模板和6Pg的DuCVDNA模板。     

我国肾综合征出血热疫苗生产株LR1株的全基因组序列分析

为测定我国肾综合征出血热疫苗生产株LR1株的全基因组序列 ,了解该株分子基础 ,从提取的细胞总RNA逆转录PCR扩增 ,产物纯化后克隆T载体纯化后测序 ,结果证明 ,LR1株全基因组序列由L6 5 33、M36 16、S片段的16 92个核苷酸组成 ,依各自读码框架分别编码 2 15 1、1135、42 9个氨基酸。序列同源比较分析表明 ,LR1毒株与国外HTN型毒株高度同源 ,属同一亚型 ,尤其与HTN代表株 76 - 1183个片段同源率高达 99 3%～ 99 8% ,而与国内的HTN型病毒差异较大 ,同源率仅为 79 4%～ 84 6 %。氨基酸比较也显示了同样的结果。     

罗氏沼虾诺达病毒的核酸检测及其部分序列分析

根据安替列群岛分离的罗氏沼虾诺达病毒株基因组序列(MrNV-ant),制备特异性核酸探针,设计特异性引物,用点杂交和RT-PCR的方法检测在中国境内分离的罗氏沼虾诺达病毒(MrNV-chin).点杂交的方法可以检测出少于26ng的患肌肉白浊症的组织样品中的病毒,或少于25ng的病毒RNA样品;RT-PCR可以检测出少于25pg的RNA样品.扩增的MrNV-chin RNA1序列长858个核苷酸,与MrNV-ant的核苷酸一致率为957%,两者翻译后的氨基酸序列的一致率为99.7%.扩增的MrNV-chin RNA 2序列长1121个核苷酸,与MrNV-ant的核苷酸一致率为92%,两者翻译后的氨基酸序列的一致率为93.2%.因此,MrNV-ant和MrNV-chin应属于同一种病毒的不同分离株.用两株罗氏沼虾诺达病毒的RNA聚合酶序列与其它6株诺达病毒RNA聚合酶序列比较后构建的进化树中,罗氏沼虾诺达病毒与Alphanodavirus的亲缘关系近于与Betanodavirus的亲缘,组成了一个新的分支.     

Octaplex PCR and fluorescence-based capillary electrophoresis for identification of human diarrheagenic Escherichia coli and Shigella spp

A multiplex PCR assay, amplifying seven specific virulence genes and one internal control gene in a single reaction, was developed to identify the five main pathotypes of diarrheagenic Escherichia coli and Shigella spp. The virulence genes selected for each category were Stx1, Stx2, and eaeA for enterohemorrhagic E. coli (EHEC), eaeA for enteropathogenic E. coli (EPEC), STIb and LTI for enterotoxigenic E. coli (ETEC), ipaH for enteroinvasive E. coli (EIEC) and Shigella spp., and aggR for enteroaggregative E. coli (EAEC). Each forward primer was labelled with a fluorochrome and the PCR products were separated by multicolour capillary electrophoresis on an ABI PRISM310 Genetic Analyzer (Applied Biosystems). If present, several gene variants of each virulence gene were identified. The internal control gene rrs, encoding 16S rRNA, was amplified in all 110 clinical strains analyzed. Virulence genes were demonstrated in 103 (94%) of these strains. In the majority of the cases (98/103, 95%), classification obtained by the novel multiplex PCR assay was in agreement with that previously determined by phenotypic assays combined with other molecular genetic approaches. Numerous multiplex PCR assays have been published, but only a few of them detect all five E. coli pathotypes within a single reaction, and none of them has used multicolour capillary electrophoresis to separate the PCR products. The octaplex PCR assay followed by capillary electrophoresis presented in the present paper provides a simple, reliable, and rapid procedure that in a single reaction identifies the five main pathotypes of E. coli, and Shigella spp. This assay will replace the previous molecular genetic methods used in our laboratory and work as an important supplement to the more time-consuming phenotypic assays.