两株基因III型强毒新城疫的全基因组测序及其与I系苗的亲缘性分析

[目的]研究基因Ⅲ型新城疫(Newcastle disease,ND)强毒分离株Js/7/05/Ch和JS/9/05/Go与中等毒力疫苗株Mukteswar的亲缘性关系,分析三株新城疫病毒(Newcastle disease virus,NDV)的全基因差异.[方法]采用RT-PCR方法获得两株NDV分离株的全基因组核苷酸序列,与GenBank中公布的Mukteswar序列比对分析.[结果]强毒分离株与中等毒力疫苗株Mukteswar全基因组核苷酸同源性均为99.7%;病毒6个阅读框核苷酸序列与Mukteswar同源性为99.6%～99.9%;预测的8种病毒编码蛋白同源性在98.8%～99.8%.然而,测定MDT,ICPI和IVPI发现JS/7/05/Ch和JS/9/05/Go毒力明显强于Mukteswar,其中JS/7/05/Ch株的IVPI达到了2.18.[结论]综合3株NDV的遗传分析结果和已有的流行病学资料可以推断分离株JS/7/05/Ch和JS/9/05/Go是由疫苗株Mukteswar自然进化而来的返强毒株.因此,必须停止使用中等毒力疫苗以免造成更大的危害.     

新城疫病毒V_4株NP基因的克隆、序列测定及真核表达载体的构建

研究新城疫病毒 ( NDV)核衣壳蛋白基因的生物学作用 ,以提纯的 NDV V4 株基因组 RNA为模板 ,化学合成 NP基因的特异核苷酸引物 ,RT- PCR扩增 NP基因 c DNA,得到一条 1 .5kb的DNA带 ,与 NDV NP基因大小一致 ,平端连接克隆到 p UC1 1 9质粒中 .阳性克隆经酶切鉴定及序列分析表明已获得新城疫病毒 V4 株 NP基因克隆 .将 NDV V4 株 NP基因碱基序列与已发表的NDV Beaudettec C株、La Sota株、D2 6株的 NP基因的碱基序列比较 ,同源性分别为 90 .64%、90 .1 7%、98.0 3% ,氨基酸序列差异率是 4.50 %、5.93%、2 .45% .NDV V4 株 NP基因与已发表的NDV Beaudettec C株、La Sota株、D2 6株的 NP基因有所不同 ,但具有高度同源性 .将 NDV V4 株NP基因 c DNA克隆到 pc DNA3 真核表达载体中 ,构建表达 NP蛋白真核质粒     

陕西省9株乙脑病毒的分离及E基因序列分析

分析陕西省分离的9株乙脑病毒基因组序列特征。使用乙脑病毒全基因组序列测定引物进行RT-PCR扩增,扩增产物进行测序,拼接后获得基因组序列。利用MEGA 4.1、MegAlin、MEGA7.0等软件进行毒株的系统进化分析,并与P3株、减毒活疫苗SA14-14-2株及覆盖5个基因型别的其他乙脑病毒进行E基因序列比对。9株分离株3株分离自猪舍、6株分离自羊舍,其中4株获得全基因组序列,5株测得E基因序列。基于E基因序列进行毒株核苷酸、氨基酸同源性比较,结果显示分离株均与基因I型GI-b亚型毒株核苷酸和氨基酸同源性最高,核苷酸同源性范围为96.5%～99.7%、氨基酸同源性范围99.2%～100.0%;与SA14-14-2株核苷酸同源性范围为87.5%～88.9%、氨基酸同源性范围96.3%～97.2%;与P3株核苷酸同源性范围为87.6%～88.1%、氨基酸同源性范围96.7%～97.6%。分析09年（陕南地区）分离株与18年（关中地区）分离株的E基因核苷酸差异率为1.8%～2.9%、氨基酸差异率为0%～0.8%。陕西省自然界中循环的乙脑病毒以基因Ⅰ型为主,与P3株在抗原毒力关键位点无差异,...     

鸽新城疫病毒BJ-C分离株基因组测序及系统发育分析

【背景】鸽新城疫是由鸽Ⅰ型副黏病毒(pigeon paramyxovirus type Ⅰ,PPMV-1)感染引起的危害最严重的疫病之一,至今尚无有效的防控制剂。【目的】分析鸽新城疫病毒BJ-C株的基因组信息及系统发育关系,为鸽新城疫的防控提供科学依据。【方法】设计首尾重叠的6对特异性引物,利用分段扩增的方法,以鸽新城疫病毒BJ-C株基因组cDNA为模板,分别扩增、测序后进行全基因组序列拼接。以NCBI数据库中发布的新城疫病毒序列为参考,针对鸽新城疫病毒BJ-C株的基因组、F基因建立系统发育树。【结果】鸽新城疫病毒BJ-C株的基因组全长为15192nt。基于全基因组的系统发育分析发现其与PPMV-1/BJ-01/CH株的系统发育关系最近,核苷酸相似性为99.96%,氨基酸相似性高达100%,属于同一个分支,而与LaSota疫苗株等其他新城疫毒株的亲缘关系相对较远。基于F基因序列的系统发育树分析发现BJ-C株F基因与我国的BJP2013株同属一个分支。ClassⅡ类Ⅵ亚型F基因高变区序列(47-420nt)比对结果显示,安徽株Pigeon/Anhui/2369/2012、广东株Pigeon/Guangdong/GZ288/2013、北京株BJP13、浙江株Pigeon/Zhejiang/2036/2012及比利时株PPMV-1/Belgium/11-09620/2011等与BJ-C毒株处于同一个分支,同属Ⅵb亚型。【结论】本研究获得了鸽新城疫病毒BJ-C株全基因组序列,分析了其系统发育关系,确定其属于ClassⅡ类Ⅵb型,为后续防控产品的开发提供了理论依据。     

我国2009年新分离乙脑病毒全基因组序列特征研究

本研究对我国2009年新分离的两株乙脑病毒进行全基因组序列测定和分析,以了解病毒全基因组分子特征。通过RT-PCR和核苷酸序列测定方法获得病毒全基因组序列,采用ClustalX、DNASTAR、MEGA等生物学软件完成核苷酸序列及氨基酸序列分析和系统进化分析等。研究结果显示,新分离两株乙脑病毒YN0911和YN0967株基因组全长均为10 965个核苷酸,编码3 432个氨基酸。这2株乙脑病毒之间核苷酸同源性为98.7%,氨基酸同源性为99.8%。与国际乙脑病毒流行株相比,核苷酸同源性为83.5%～98.9%,氨基酸同源性为94.8%～99.7%。与乙脑病毒疫苗株SA14-14-2相比,在E蛋白有13个氨基酸差异位点,但都位于抗原关键位点之外。这2株病毒在3′UTR区域存在11nt缺失。基于C/PrM区段、E基因、全基因组系统进化分析结果均显示新分离2株乙脑病毒为G I乙脑病毒,并且和越南、四川、贵州、广西以往的分离株遗传进化关系较近。本研究提示我国新分离的2株乙脑病毒均为G I乙脑病毒,决定病毒毒力的关键氨基酸位点未见明显变化。     

简化cDNA末端快速扩增技术测定基因Ⅲ、Ⅵb和Ⅶ d型新城疫病毒基因组末端序列及分析

[目的]简化cDNA末端快速扩增技术(Rapid amplification of cDNA ends,fLAcE)流程,测定基因Ⅲ、VIb)和VIId型新城疫病毒(Newcastle disease virus,NDV)基因组两侧末端序列,并对NDV的leader和trailer进行分析.[方法]利用T4 RNA连接酶将特定寡聚核苷酸片段的连接于病毒基因组RNA和eDNA,再利用RT-PCR或PCR方法对病毒基因组的末端进行快速的扩增.[结果]建立一套操作简单、低成本、可重复性高的RACE方法,测定了三种基因型5株NDV 3'末端leader和5'末端trailer序列比对分析.[结论]本实验测定的鹅源VII型毒株JS/7/05/Ch基因组的15,184 nt由一个T变为了C,5'端trailer与3'端leader的连续互补序列由8 nt变为12 nt,而其它4株基因Ⅲ型和VI型NDV均未发现该突变.通过RNA的二级结构分析,NDV基因组和反向基因组RNA的3'末端形成一个发卡结构.JS/7/05/Ch等3株NDV U→C(T→C)的突变位于发卡环上,不影响二级结构的形成,发卡环的RNA序列突变为3'-UCUC-5',与基因组3'端发卡环的3'-UCUUA-5'相似,推测可能影响了基因组RNA的复制速度.     

2012年江苏省柯萨奇病毒A组14型分离株全基因序列分析

目的探讨2012年江苏省手足口病(HFMD)病原体CVA14病毒的全基因序列特点。方法采集江苏省邳州市2012年HFMD患儿的咽拭子或肛拭子样本,分离培养得到2株CVA14病毒,利用RT-PCR扩增CVA14全长基因。利用DNAStar软件包的Meg Align进行核苷酸序列分析,构建系统进化树。结果扩增得到覆盖CVA14全基因组的3个片段,拼接后为CVA14全基因组,分别命名为PZ05Y/JS/2012和PZ15G/JS/2012。同源性分析结果显示,这2株分离株之间同源性为99.4%,原型株(G-14)的核苷酸同源性为84.4%。进化树结果显示,所有的CVA14形成A、B和C共3个分支。结论获得了江苏省CVA14的全基因序列,分析了该毒株的进化特点,补充了中国CVA14病毒的基因信息。     

云南省疫苗衍生脊髓灰质炎病毒全基因组序列遗传特征分析

为了解云南省疫苗衍生脊髓灰质炎病毒(Vaccine-derived Poliovirus,VDPV)的基因组特征,对2010年及2012年监测到的4株VDPV进行全基因组序列测定。结果显示,2株Ⅱ型VDPV的基因组全长均为7439nt,与Sabin Ⅱ疫苗株全基因组核苷酸和氨基酸的序列同源性分别为95.4%和97.7%;2株I型VDPV基因组全长均为7441nt,与Sabin I疫苗株全基因组核苷酸和氨基酸序列的同源性分别为93.9%和97.9%。减毒位点分析发现II型和I型VDPV毒株分别有两个(nt 481和nt 2909)和三个减毒位点(nt 480、nt 2795和nt 6203)发生了回复突变。VP1序列分析显示II型和I型VDPV毒株与相应Sabin株的变异分别为1%和2.3%,重组分析显示II型和I型VDPV的基因组结构分别为S2/S3和S1/S2/S1/S3,后者的重组次数高达3次,显示了重组的普遍性和复杂性,也表明了病毒在人体内复制和传播的持久性与重组的多样性成正相关。因此,从分子水平分析VDPV的特性,可掌握病毒的变异动态,为制定科学可行的VDPV控制策略提供理论依据。     

我国登革3型病毒广西80-2株基因组全序列分析

对我国登革 3型病毒 80 2株基因组进行全序列测定 ,为了解其基因组结构与功能的关系提供依据 .根据登革 3型病毒H87株的序列设计并合成引物 ,应用RT PCR和RACE法 ,对 80 2株基因组RNA进行扩增、克隆测序后获得我国登革 3型病毒广西株基因组序列 .该株病毒基因组全长10 696nt ,不含poly(A)尾 ,4种碱基数分别为A :3 4 3 7,C :2 2 15,G :2 773 ,U :2 2 71.包含一个读码框架 ,自 95至 10 2 67位 ,共 10 170个碱基 ,编码 3 3 90个氨基酸 ,5′和 3′非编码区长度分别为 94nt和4 3 2nt.与H 87株比较 ,核苷酸和氨基酸序列同源性均在 99%以上 ,有 2 8个碱基发生改变 ,其中 2 6个碱基突变发生在读码框架内 ,碱基转换 18个 ,颠换 10个 ;碱基突变引起 14个氨基酸的改变 .80 2株与H87株病毒的基因组全序列同源性高 ,变异度小 .     

狂犬病病毒aG株全基因组序列测定及遗传稳定性分析

目的探究狂犬病病毒(Rabies virus,RV)aG株全基因组序列特征及遗传稳定性。方法严格按疫苗生产工艺进行传代,提取主种子批、工作种子批及疫苗原液病毒RNA,通过RT-PCR技术扩增全基因组各片段基因,然后分别将其克隆到p GEM-T载体中,并进行序列测定;采用DNAStar软件包对aG株与Gen Bank中4aGV参考株(JN234411)以及18株基因1型RV参考株进行同源性分析。结果 aG株全基因组由11 925个核苷酸组成,共编码3 600个氨基酸。疫苗原液与主种子批全基因组核苷酸和氨基酸同源性均为100%,而工作种子批与主种子批的核苷酸与氨基酸同源性分别为99.97%和99.92%;aG株与4aGV参考株全基因组核苷酸与推导的氨基酸同源性均为99.9%,其与18株基因1型参考株核苷酸与氨基酸序列同源性分别为84.2%~97.6%和93.7%~98.3%;aG株传代病毒与4aGV参考株全基因组氨基酸序列高度保守,且各主要功能区未发生变异。结论狂犬病病毒aG株在实验室长期生产传代过程中,全基因组遗传特性稳定。     

Complete genome sequencing and analysis of an anti-tumor Newcastle disease virus strain

HBNU/LSRC/F3, a Newcastle disease virus (NDV) strain stored in our lab, exhibited an anti-tumor ability in our previous studies. Nonetheless, very little is known about its genome sequence, which is vital for further study. Here, the complete HBNU/LSRC/F3 genome was fully sequenced and compared with other NDV sequences. Its genome contained 15,192 nucleotides (nt) consisting of two termini and six genes in the following order: 3′-Le-NP-P-M-F-HN-L-Tr-5′. Phylogenetic analysis indicated that this NDV strain belonged to the Class II genotype IX group. A multibasic amino acid (aa) sequence was found at the cleavage site (¹¹²RRQRR↓F¹¹⁷) within the fusion (F) protein, and a 6 nt insertion was present in the 5′ non-coding region of the NP gene. The whole genome sequence was highly similar to other genotype IX NDV genomes reported in China. Overall, this study provides insight into the sequence characteristics of genotype IX NDVs, which will be useful for subsequent investigations.     

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.     

Comparative genomics of the T4-Like Escherichia coli phage JS98: implications for the evolution of T4 phages

About 130 kb of sequence information was obtained from the coliphage JS98 isolated from the stool of a pediatric diarrhea patient in Bangladesh. The DNA shared up to 81% base pair identity with phage T4. The most conserved regions between JS98 and T4 were the structural genes, but their degree of conservation was not uniform. The head genes showed the highest sequence conservation, followed by the tail, baseplate, and tail fiber genes. Many tail fiber genes shared only protein sequence identity. Except for the insertion of endonuclease genes in T4 and gene 24 duplication in JS98, the structural gene maps of the two phages were colinear. The receptor-recognizing tail fiber proteins gp37 and gp38 were only distantly related to T4, but shared up to 83% amino acid identity to other T6-like phages, suggesting lateral gene transfer. A greater degree of variability was seen between JS98 and T4 over DNA replication and DNA transaction genes. While most of these genes came in the same order and shared up to 76% protein sequence identity, a few rearrangements, insertions, and replacements of genes were observed. Many putative gene insertions in the DNA replication module of T4 were flanked by intron-related endonuclease genes, suggesting mobile DNA elements. A hotspot of genome diversification was located downstream of the DNA polymerase gene 43 and the DNA binding gene 32. Comparative genomics of 100-kb genome sequence revealed that T4-like phages diversify more by the accumulation of point mutations and occasional gene duplication events than by modular exchanges.     

Genome analysis of phage JS98 defines a fourth major subgroup of T4-like phages in Escherichia coli

Numerous T4-like Escherichia coli phages were isolated from human stool and environmental wastewater samples in Bangladesh and Switzerland. The sequences of the major head gene (g23) revealed that these coliphages could be placed into four subgroups, represented by the phages T4, RB69, RB49, and JS98. Thus, JS98 defines a new major subgroup of E. coli T4-like phages. We conducted an analysis of the 169-kb JS98 genome sequence. Overall, 198 of the 266 JS98 open reading frames (ORFs) shared amino acid sequence identity with the reference T4 phage, 41 shared identity with other T4-like phages, and 27 ORFs lacked any database matches. Genes on the plus strand encoded virion proteins, which showed moderate to high sequence identity with T4 proteins. The right genome half of JS98 showed a higher degree of sequence conservation with T4 and RB69, even for the nonstructural genes, than did the left genome half, containing exclusively nonstructural genes. Most of the JS98-specific genes were found in the left genome half. Two came as a hypervariability cluster, but most represented isolated genes, suggesting that they were acquired separately in multiple acquisition events. No evidence for DNA exchange between JS98 phage and the E. coli host genome or coliphages other than T4 was observed. No undesired genes which could compromise its medical use were detected in the JS98 genome sequence.     

香蕉束顶病毒基因克隆和序列分析

对香蕉束顶病毒（ＢＢＴＶ）中国分离株ＤＮＡ组份Ｉ（ＤＮＡ－１）、外壳蛋白（ＣＰ）和运转蛋白（ＭＰ）基因进行了克隆和序列分析。ＢＢＴＶＤＮＡ－１含有１１０３个核苷酸,与南太平洋和亚洲分离株分别有８７％－８８％ ９６．９－９８％的核苷酸序列同源性。由ＤＮＡ－１编码的复制酶含有１８６个在酸残基。与南太平洋和亚洲分离株分别有８４．４％－９５．８％和９７．６％、９８．０％的氨基酸序列同源性。外壳蛋白基因由５     

Genomic characterisation of two virulent Newcastle disease viruses isolated from crested ibis (Nipponia nippon) in China

This paper describes the complete genomic sequences of two virulent Newcastle disease virus (NDV) isolates, Shaanxi06 (prevalent genotype VIId) and Shaanxi10 (novel sub-genotype VIi), from sick crested ibises. The genomes of both isolates were 15,192 nt long and consisted of six genes in the order of 3′-NP-P-M-F-HN-L-5′. The genomes of the two isolates were highly similar to other reference NDV strains. However, some unique features were found in the HN protein of Shaanxi06 and the F gene end of Shaanxi10. Shaanxi06 and Shaanxi10 shared the same virulent motif ^112 −R-R-Q-K-R-F^− 117 at the F protein cleavage site, which coincided with previous pathogenicity test results. Phylogenetic analysis revealed that both isolates were clustered within class II NDV, with Shaanxi06 in genotype VII and Shaanxi10 in genotype VI. Both isolates shared high homology with the prevalent genotype NDV strains that circulate in fowls and waterfowls. This study is the first to provide genomic information about a novel sub-genotype VIi NDV strain and another genotype VIId virus, which will be useful for subsequent investigations.     

Natural Infection by Tospoviruses of Cucurbitaceous and Fabaceous Vegetable Crops in India

Natural infection of tospoviruses on three cucurbitaceous (Cucumis sativus, cucumber; Luffa acutangula, ridge gourd; Citrullus lanatus, watermelon) and three fabaceous (Vigna unguiculata, cowpea; Phaseolus vulgaris, French bean; Dolichos lablab, sem) vegetable crops in India was identified on the basis of nucleocapsid protein (NP) gene characteristics. The complete NP gene of the cowpea isolate from Kerala and the sem isolate from Tamil Nadu was 831 nucleotides long, encoding a protein of 276 amino acids. For other Tospovirus isolates from cucumber, French bean, ridge gourd and watermelon, the partial NP gene (291 nt) was sequenced. Comparative NP gene sequence analyses revealed that fabaceous isolates shared maximum identity both at the nucleotide (92–97%) and amino acid (93–97%) levels with the corresponding region of Groundnut bud necrosis virus (GBNV), whereas cucurbitaceous isolates shared maximum identity both at nucleotide (93–99%) and amino acid (95–98%) levels with the corresponding region of Watermelon bud necrosis virus (WBNV), results suggesting that the Tospovirus isolates infecting fabaceous hosts should be regarded as strain of GBNV, whereas those infecting cucurbitaceous hosts as a strain of WBNV. Nucleocapsid protein gene was conserved both in GBNV and WBNV isolates originating from different hosts and locations.