我国2002−2016年间鸡传染性支气管炎病毒基因组序列重组分析

【目的】传染性支气管炎病毒(Infectious bronchitis virus,IBV)主要引起鸡群呼吸道与肾脏疾病,是影响养禽业重要的病毒性病原之一。了解我国IBV的流行及基因重组情况。【方法】收集GenBank中我国2002?2016年间分离的92株IBV S1基因及55株IBV基因组序列,并对这些序列进行比对分析。【结果】IBV S1基因序列分析结果表明,2002?2016年间我国流行的92株IBV可以分为13个基因型,包括QX、4/91、Mass、tl/CH/LDT3/03、CK/CH/LSC/99I、TW-I、TW-II、TC07-2、Ck/CH/LDL/97I、N1/62-associated、Arkansas、New-I及一个新鉴定的基因分支New-II。值得注意的是,属于美国相关基因分支的ck/CH/LSD/110712已在我国出现。RDP4方法进行重组分析显示,新出现的基因分支New-II病毒S1基因来源于tl/CH/LDT3/03型与QX型毒株重组,我国2002?2016年间流行的55株IBV中有52株IBV基因组存在重组事件,其中25个IBV分离株基因组中发现有疫苗型(Mass,tl/CH/LDT3/03及4/91型等)病毒基因组片段的重组,这一结果在SimPlot分析中进一步得到确认。【结论】根据生物信息学分析结果,证明流行于我国的IBV基因型众多,疫苗毒株基因频繁参与了IBV基因重组,导致IBV新的基因型或变异株出现,提示在防控IB时要注意合理使用IBV疫苗。     

Complete Genome Sequence of an Infectious Bronchitis Virus Chimera between Cocirculating Heterotypic Strains

To date, multiple serotypes and genotypes of infectious bronchitis virus (IBV) have been isolated and identified. In order to provide more information on the viral evolution of IBVs, a new virulent strain named GX-NN09032, isolated from Guangxi, China, in 2009, was sequenced, and phylogenetic and recombination analyses were conducted. Furthermore, potential recombination events associated with GX-NN09032 were found in four IBV strains, including GX-YL5, DY07, CK/CH/SD09/005, TC07-2. The present study suggested that GX-NN09032 might contribute to the emergence of modern IBV variants through recombination.     

几种鸡传染性支气管炎病毒活疫苗对中国流行毒株CK/CH/LDL/97I的保护作用评价

选择我国应用的五株鸡传染性支气管炎活疫苗毒株(JAAS、IBN、Jlin、J9和H120)和当地流行毒株(CK/CH/LDL/97 Ⅰ)作为研究对象,对其S1基因进行序列比对分析,结果表明疫苗株与流行毒株的核昔酸序列及推导的氨基酸序列同源性分别不超过76.4%和78.7%.S1基因的核苷酸系统发育树显示,疫苗株与流行毒株分属不同进化群,亲缘关系较远,属于不同的基因型.用这五株活疫苗进行针对强毒株CK/CH/LDL/97Ⅰ株的免疫保护实验,可见临床发病率为30%～100%;攻毒5d后每组随机扑杀10只鸡,采集器官,应用RT-PCR法检测病毒,气管样品病毒检出率为50%～90%,肾脏样品病毒检出率为10%～30%.由此可见:我国目前使用的主要活疫苗对异种IBV分离株的感染不能提供完全的保护作用.     

Infectious bronchitis viruses with a novel genomic organization

A number of novel infectious bronchitis viruses (IBVs) were previously identified in commercial poultry in Australia, where they caused significant economic losses. Since there has been only limited characterization of these viruses, we investigated the genomic and phenotypic differences between these novel IBVs and other, classical IBVs. The 3' 7.5 kb of the genomes of 17 Australian IBV strains were sequenced, and growth properties of 6 of the strains were compared. Comparison of sequences of the genes coding for structural and nonstructural proteins revealed the existence of two IBV genotypes: classical and novel. The genomic organization of the classical IBVs was typical of those of other group III coronaviruses: 5'-Pol-S-3a-3b-E-M-5a-5b-N-untranslated region (UTR)-3'. However, the novel IBV genotype lacked either all or most of the genes coding for nonstructural proteins at the 3' end of the genome and had a unique open reading frame, X1. The gene order was either 5'-Pol-S-X1-E-M-N-UTR-3' or 5'-Pol-S-X1-E-M-5b-N-UTR-3'. Phenotypically, novel and classical IBVs also differed; novel IBVs grew at a slower rate and reached lower titers in vitro and in vivo and were markedly less immunogenic in chicks. Although the novel IBVs induced histopathological lesions in the tracheas of infected chicks that were comparable to those induced by classical strains, they did not induce lesions in the kidneys. This study has demonstrated for the first time the existence of a naturally occurring IBV genotype devoid of some of the genes coding for nonstructural proteins and has also indicated that all of the accessory genes are dispensable for the growth of IBV and that such viruses are able to cause clinical disease and economic loss. The phylogenic differences between these novel IBVs and other avian coronaviruses suggest a reservoir host distinct from domestic poultry.     

传染性支气管炎病毒核衣壳蛋白基因克隆及在E.coli中的表达

核衣壳蛋白基因 (N基因 )是传染性支气管炎病毒的重要结构基因 .根据已报道的序列设计引物 ,利用RT PCR技术从病毒RNA中扩增和克隆到了N基因的cDNA ,并测定了核苷酸序列 .克隆的N基因片段ORF全长 12 30bp ,编码 4 0 9个氨基酸 .将该片段序列与其他IBV病毒株比较 ,核苷酸的同一性为 87 0 %～ 98 6 %,氨基酸的同一性为 91 0 %～ 98 1%.将该cDNA亚克隆到pBV2 2 0表达载体 ,转化大肠杆菌DH5α菌株 ,Western印迹检测 ,获得了分子量约 4 5kD表达蛋白     

广西不同时期IBV分离株S1基因高变区Ⅰ的遗传变异分析

对广西1985-2007年间分离到的22株传染性支气管炎病毒（IBV）的S1基因高变区I（HVRI）进行序列测定,并与发表的其他IBV参考株及鸽子分离的冠状病毒株的基因序列进行比较和分析。系统进化关系显示毒株可分为5个基因群,其中有16个广西分离株属第1群,它们与鸽子冠状病毒分离株的氨基酸序列同源性较高,与Massachusetts（Mass）型疫苗株的同源性较低。有15个分离株在33-34位和34～35之间分别有4个和3个氨基酸残基的插入,GX-NN6在33～34位和34～35位之间则均有4个氨基酸残基的插入;GX-YL1、GX-NN2与常用的Mass型疫苗株的亲缘关系最近,同属于第Ⅱ群;GX-G、GX-XD与日本同一时期分离的毒株JP Miyazaki 89亲缘关系最近,属于第Ⅲ群;GX-YL6、GX-NN7与欧洲毒株4／91亲缘关系较近,属于第V群。结果表明广西存在着多种类型IBV毒株的流行,毒株S1基因HVRI碱基的突变或插入比较普遍,可导致其氨基酸序列的变化,绝大部分毒株与目前常用的Mass型疫苗株的亲缘关系较低。同一时期的分离株同源性较高,但无明显的地域性差异。     

Complete Genome Sequence of a Recombinant Nephropathogenic Infectious Bronchitis Virus Strain in China

Recently, nephropathogenic infectious bronchitis virus (IBV) outbreaks have occurred in commercial broiler flocks and have been associated with a high incidence and morbidity in China. The CK/CH/Zhejiang/06/10 strain (IBV-YX10) was isolated from a 12-day-old broiler chicken in a flock of chickens with swollen speckled kidneys and distended ureters filled with uric acid in China in 2010. Here we reported the complete genomic sequence of the IBV-YX10 which was a natural recombinant nephropathogenic infectious bronchitis virus strain. These findings will contribute additional insights into the molecular characteristics of evolving IBV genomes and the need for effective control of IBV in China.     

Replication and packaging of coronavirus infectious bronchitis virus defective RNAs lacking a long open reading frame.

The construction of a full-length clone of the avian coronavirus infectious bronchitis virus (IBV) defective RNA (D-RNA), CD-91 (9,080 nucleotides [Z. Penzes et al., Virology 203:286-293]), downstream of the bacteriophage T7 promoter is described. Electroporation of in vitro T7-transcribed CD-91 RNA into IBV helper virus-infected primary chick kidney cells resulted in the production of CD-91 RNA as a replicating D-RNA in subsequent passages. Three CD-91 deletion mutants were constructed--CD-44, CD-58, and CD-61--in which 4,639, 3,236, and 2,953 nucleotides, respectively, were removed from CD-91, resulting in the truncation of the CD-91 long open reading frame (ORF) from 6,465 to 1,311, 1,263, or 2,997 nucleotides in CD-44, CD-58, or CD-61, respectively. Electroporation of in vitro T7-transcribed RNA from the three constructs into IBV helper virus-infected cells resulted in the replication and packaging of CD-58 and CD-61 but not CD-44 RNA. The ORF of CD-61 was further truncated by the insertion of stop codons into the CD-61 sequence by PCR mutagenesis, resulting in constructs CD-61T11 (ORF: nucleotides 996 to 1,058, encoding 20 amino acids), CD-61T22 (ORF: nucleotides 996 to 2,294, encoding 432 amino acids), and CD-61T24 (ORF: nucleotides 996 to 2,450, encoding 484 amino acids), all of which were replicated and packaged to the same levels as observed for either CD-61 or CD-91. Analysis of the D-RNAs showed that the CD-91- or CD-61-specific long ORFs had not been restored. Our data indicate that IBV D-RNAs based on the natural D-RNA, CD-91, do not require a long ORF for efficient replication. In addition, a 1.4-kb sequence, corresponding to IBV sequence at the 5' end of the 1b gene, may be involved in the packaging of IBV D-RNAs or form part of a cis-acting replication element.     

Development and characterization of a recombinant infectious bronchitis virus expressing the ectodomain region of S1 gene of H120 strain

Infectious bronchitis (IB), caused by infectious bronchitis virus (IBV), is a highly contagious chicken disease, and can lead to serious economic losses in poultry enterprises. The continual introduction of new IBV serotypes requires alternative strategies for the production of timely and safe vaccines against the emergence of variants. Modification of the IBV genome using reverse genetics is one way to generate recombinant IBVs as the candidates of new IBV vaccines. In this study, the recombinant IBV is developed by replacing the ectodomain region of the S1 gene of the IBV Beaudette strain with the corresponding fragment from H120 strain, designated as rBeau-H120(S1e). In Vero cells, the virus proliferates as its parental virus and can cause syncytium formation. The peak titer would reach 10^5.9 50 % (median) tissue culture infective dose/mL at 24 h post-infection. After inoculation of chickens with the recombinant virus, it demonstrated that rBeau-H120(S1e) remained nonpathogenic and was restricted in its replication in vivo. Protection studies showed that vaccination with rBeau-H120 (S1e) at 7-day after hatch provided 80 % rate of immune protection against challenge with 10³ 50 % embryos infection dose of the virulent IBV M41 strain. These results indicate that rBeau-H120 (S1e) has the potential to be an alternative vaccine against IBV based on excellent propagation property and immunogenicity. This finding might help in providing further information that replacement of the ectodomain fragment of the IBV Beaudette S1 gene with that from a present field strain is promising for IBV vaccine development.     

传染性支气管炎病毒江苏分离株核蛋白基因序列测定与同源性分析

将本室鸡传染性支气管炎病毒（IBV）江苏省地方分离肾型毒株JS／95／03接种鸡胚,分离、纯化病毒,提取单股RNA做为反转录－聚合酶链反应（RT－PCR）的扩增模板。用Genbank公开序列多重比较后设计一对引物,使用单管RT－PCR方法,物异扩增IBV核蛋白（N）基因5'端854bp的片段,扩增产物纯化后测,序列分析表明,IBV N基因也存在较大变异,此毒株与呼吸型疫苗株M41序列同源性最高。     

Infectious Bronchitis Virus as a Vector for the Expression of Heterologous Genes

The avian coronavirus infectious bronchitis virus (IBV) is the causative agent of the respiratory disease infectious bronchitis of domestic fowl, and is controlled by routine vaccination. To explore the potential use of IBV as a vaccine vector a reverse genetics system was utilised to generate infectious recombinant IBVs (rIBVs) expressing the reporter genes enhanced green fluorescent protein (eGFP) or humanised Renilla luciferase (hRluc). Infectious rIBVs were obtained following the replacement of Gene 5 or the intergenic region (IR) with eGFP or hRluc, or the replacement of ORFs 3a and 3b with hRluc. The replacement of Gene 5 with an IBV codon-optimised version of the hRluc gene also resulted in successful rescue of infectious rIBV. Reporter gene expression was confirmed by fluorescence microscopy, or luciferase activity assays, for all successfully rescued rIBVs following infection of primary chick kidney (CK) cells. The genetic stability of rIBVs was analysed by serial passage on CK cells. Recombinant IBV stability varied depending on the genome region being replaced, with the reporter genes maintained up to at least passage 8 (P8) following replacement of Gene 5, P7 for replacement of the IR and P5 for replacement of ORFs 3a and 3b. Codon-optimisation of the hRluc gene, when replacing Gene 5, resulted in an increase in genome stability, with hRluc expression stable up to P10 compared to P8 for standard hRluc. Repeated passaging of rIBVs expressing hRluc at an MOI of 0.01 demonstrated an increase in stability, with hRluc expression stable up to at least P12 following the replacement of Gene 5. This study has demonstrated that heterologous genes can be incorporated into, and expressed from a range of IBV genome locations and that replacement of accessory Gene 5 offers a promising target for realising the potential of IBV as a vaccine vector for other avian pathogens.     

传染性支气管炎病毒江苏分离株 核蛋白基因序列测定与同源性分析

将本室鸡传染性支气管炎病毒（IBV）江苏省地方分离肾型毒株JS/95/03接种鸡胚,分离、纯化病毒,提取单股RNA做为反转录-聚合酶链反应（RT-PCR）的扩增模板。用Genbank公开序列多重比较后设计一对引物,使用单管RT-PCR方法,特异扩增IBV核蛋白（N）基因5'端854 bp的片段。扩增产物纯化后测序,序列分析表明,IBVN基因也存在较大变异,此毒株与呼吸型疫苗株M41序列同源性最高。     

Proteolytic processing of the coronavirus infectious bronchitis virus 1a polyprotein: identification of a 10-kilodalton polypeptide and determination of its cleavage sites.

Proteolytic processing of the polyprotein encoded by mRNA 1 is an essential step in coronavirus RNA replication and gene expression. We have previously reported that an open reading frame (ORF) 1a-specific proteinase of the picornavirus 3C proteinase group is involved in processing of the coronavirus infectious bronchitis virus (IBV) 1a/1b polyprotein, leading to the formation of a mature viral protein of 100 kDa. We report here the identification of a novel 10-kDa polypeptide and the involvement of the 3C-like proteinase in processing of the ORF 1a polyprotein to produce the 10-kDa protein species. By using a region-specific antiserum, V47, raised against a bacterial-viral fusion protein containing IBV sequence encoded between nucleotides 11488 and 12600, the 10-kDa polypeptide was detected in lysates from both IBV-infected and plasmid DNA-transfected Vero cells. Coexpression, deletion, and mutagenesis studies showed that this novel polypeptide was encoded by ORF 1a from nucleotide 11545 to 11878 and was cleaved from the 1a polyprotein by the 3C-like proteinase domain. Evidence presented suggested that a previously predicted Q-S (Q3783 S3784) dipeptide bond encoded by ORF 1a between nucleotides 11875 and 11880 was responsible for the release of the C terminus of the 10-kDa polypeptide and that a novel Q-N (Q3672 N3673) dipeptide bond encoded between nucleotides 11542 and 11547 was responsible for the release of the N terminus of the 10-kDa polypeptide.     

cis-acting sequences required for coronavirus infectious bronchitis virus defective-RNA replication and packaging

The parts of the RNA genome of infectious bronchitis virus (IBV) required for replication and packaging of the RNA were investigated using deletion mutagenesis of a defective RNA (D-RNA) CD-61 (6.1 kb) containing a chloramphenicol acetyltransferase reporter gene. A D-RNA with the first 544, but not as few as 338, nucleotides (nt) of the 5' terminus was replicated; the 5' untranslated region (UTR) comprises 528 nt. Region I of the 3' UTR, adjacent to the nucleocapsid protein gene, comprised 212 nt and could be removed without impairment of replication or packaging of D-RNAs. A D-RNA with the final 338 nt, including the 293 nt in the highly conserved region II of the 3' UTR, was replicated. Thus, the 5'-terminal 544 nt and 3'-terminal 338 nt contained the necessary signals for RNA replication. Phylogenetic analysis of 19 strains of IBV and 3 strains of turkey coronavirus predicted a conserved stem-loop structure at the 5' end of region II of the 3' UTR. Removal of the predicted stem-loop structure abolished replication of the D-RNAs. D-RNAs in which replicase gene 1b-derived sequences had been removed or replaced with all the downstream genes were replicated well but were rescued poorly, suggesting inefficient packaging. However, no specific part of the 1b gene was required for efficient packaging.     

IBV青岛腺胃分离株（SD／97／02）S1蛋白基因的序列测定和分析

参考Genbank上发表的IBV S1纤突蛋白基因序列,设计了一对引物,对鸡传染性支气管炎病毒青岛腺胃分离株（SD／97／02）RNA进行RT－PCR扩增。将PCR产物克隆入pMD18-T载体中进行序列测定和分析。序列分析表明,该毒株的S1基因的G＋C％含量较少,为37.0%,存在HindⅢ,BamHⅠ,BglIⅠ,SacⅠ和SalⅠ位点,无EcoRⅠ位点,与其他毒株的同源性在87.02%－94.21%之间,在第154－429nt处为高度的变异区;将基因序列翻译成氨基酸后,假定的S1蛋白由540个氨基酸组成,等电点8.24,在蛋白质内部存在18个Cys,在S1与S2蛋白之间的剪切位点为HRRRR,这与大多数IBV毒株（RRF／SRR）不一样,有三个区域的氨基酸序列高度保守;169－181aa,230-250aa,485-506aa;与其他毒株进行抗原性比较后发现,在该毒株的320－326aa及390－401aa处的抗原表位消失,而在325－345aa、379－389aa处则出现了很强的抗原表位;第438－444aa处,其他IBV毒株（除ZJ971株外）原来存在的强抗原位点在本毒株中消失。在53－65位的氨基酸抗原性与其他毒株相比明显变弱。     

Comparative proteome analysis of tracheal tissues in response to infectious bronchitis coronavirus,Newcastle disease virus,and avian influenza virus H9 subtype virus infection

Infectious bronchitis coronavirus (IBV), Newcastle disease virus (NDV), and avian influenza virus (AIV) H9 subtype are major pathogens of chickens causing serious respiratory tract disease and heavy economic losses. To better understand the replication features of these viruses in their target organs and molecular pathogenesis of these different viruses, comparative proteomic analysis was performed to investigate the proteome changes of primary target organ during IBV, NDV, and AIV H9 infections, using 2D‐DIGE followed MALDI‐TOF/TOF‐MS. In total, 44, 39, 41, 48, and 38 proteins were identified in the tracheal tissues of the chickens inoculated with IBV (ck/CH/LDL/97I, H120), NDV (La Sota), and AIV H9, and between ck/CH/LDL/97I and H120, respectively. Bioinformatics analysis showed that IBV, NDV, and AIV H9 induced similar core host responses involved in biosynthetic, catabolic, metabolic, signal transduction, transport, cytoskeleton organization, macromolecular complex assembly, cell death, response to stress, and immune system process. Comparative analysis of host response induced by different viruses indicated differences in protein expression changes induced by IBV, NDV, and AIV H9 may be responsible for the specific pathogenesis of these different viruses. Our result reveals specific host response to IBV, NDV, and AIVH9 infections and provides insights into the distinct pathogenic mechanisms of these avian respiratory viruses.     

RIG-I敲除293T细胞系的建立及其对B型流感病毒复制的影响

CRISPR/Cas9基因编辑技术是通过人工设计的单向导RNA(Single-guide RNA,sgRNA)指导Cas9蛋白对目的基因靶位点进行特异性的识别、结合和切割后,通过细胞的非同源末端连接或同源末端重组修复机制来完成对基因组的敲除与敲入的编辑技术。RIG-I是机体的一种模式识别受体,能够识别胞质中的含5′-三磷酸基团的RNA,并通过与下游信号分子MAVS相互作用,激活IRF3/7和NF-κB,从而启动I型干扰素和炎性因子的表达。已有研究表明,B型流感病毒(IBV)在感染早期能够上调RIG-I的表达水平。为了探索RIG-I是否为B型流感病毒激活抗病毒天然免疫信号通路的主要受体及其对IBV复制的影响,本研究利用CRISPR-Cas9技术对293T细胞中的RIG-I基因进行了敲除,经嘌呤霉素压力筛选到了一株稳定敲除RIG-I基因的293T(RIG-I-/-293T)细胞系。Western blotting检测发现,IBV或仙台病毒感染后该细胞系中RIG-I不再表达,说明该敲除细胞系构建成功。IBV感染RIG-I-/-293T细胞后,干扰素、炎性因子及干扰素刺激基因的转录水平与野生型...