利用基因芯片技术区分禽流感病毒主要亚型

[目的]研制可同时区分AIV的H5、H7、H9血凝素亚型及N1、N2神经氨酸酶亚型的基因诊断芯片.[方法]分别克隆了禽流感病毒的M基因,H5、H7、H9亚型HA基因,N1、N2亚型NA基因以及看家基因GAPDH的重组质粒.以重组质粒为模板,用PCR方法扩增制备探针,纯化后点于氨基修饰的片基上,制备基因芯片.在PCR过程中对待检样品进行标记,然后与芯片杂交,洗涤,扫描并进行结果分析.[结果]结果显示检测探针可特异性的与相应的标记样品进行杂交,呈现较强的杂交信号,且无交叉杂交.同时用RT-PCR、鸡胚接种和基因芯片方法对H1-H15亚型AIV参考毒株、30份人工感染样品、21份现地疑似样品进行检测,结果发现,对人工感染样品芯片检测方法与鸡胚接种和RT-PCR的符合率分别为100%和96%,现地样品符合率为100%.[结论]研究表明该方法可用于同步鉴别部分主要流行的禽流感亚型,是一种有效的新方法.     

2019-2020年苏中地区某活禽市场H9N2禽流感病毒分子进化

【背景】20世纪90年代以来,H9N2禽流感病毒成为危害我国养禽业及人类健康和公共卫生的重要病原。【目的】了解苏中地区2019-2020年活禽市场H9N2禽流感病毒的分子进化特征。【方法】通过荧光定量PCR法对标本进行流感病毒分型检测,原始标本用SPF鸡胚进行病毒分离,用特异性引物对病毒分离物进行全基因组测序,利用BLAST、ClustalX和MEGA6等软件进行序列比对和系统发育分析。【结果】2019-2020年间从苏中地区某农贸市场采集到231份环境和禽类标本,共检出34份甲型流感病毒,其中33份为H9N2亚型。阳性标本接种SPF鸡胚,分离到20株H9N2病毒。对其中11株病毒进行全基因组测序,系统发育分析表明11株病毒的HA和NA都属于H9N2禽流感Y280-like系的G57基因型。根据HA和NA的进化特征,11株病毒可分为5个基因组合(A、B、C、D和E),其中A (n=5)是优势流行基因组合。11株H9N2分离病毒的HA蛋白HA1和HA2亚单位的裂解位点是一个碱性氨基酸R,具有低致病性禽流感病毒的特征。HA蛋白的受体结合部位有4个氨基酸位点(I155T、H183N、A190...     

云南省2009～2014年甲型H1N1流感病毒HA及NA基因特征分析

了解云南省2009~2014年甲型H1N1流感病毒的流行趋势,研究HA和NA基因进化特征。对云南省近6年来上报的流感监测病例数据进行病原谱总结,挑选出23株甲型H1N1流感毒株进行HA及NA基因分析。利用MEGA 5.0软件对测序结果构建进化树分析基因同源性。2009~2014年云南省共监测到4次甲型H1N1流感流行高峰,核酸检测结果中甲型H1N1流感占检出总量的28.8%。测序结果显示,HA与NA基因均分为3个类群,检测到一株具有H275Y突变位点的毒株。甲型H1N1流感是导致本省流感流行的重要亚型之一,2009~2014年间分离的毒株主要有Goup1、Gourp7和Gourp6三个支系,绝大部分甲型H1N1流感毒株仍对神经氨酸酶抑制剂敏感。     

基于颜色判定的环介导逆转录等温扩增技术检测人甲型H1N1流感病毒基因

建立了一种基于颜色判定的简单、快速和灵敏的检测方法,即环介导逆转录等温核酸扩增技术(RT-LAMP)应用于人甲型H1N1流感病毒基因检测。该技术使用对应于人甲型H1N1流感病毒HA序列中8个基因区段的6条特异引物,在等温条件下(65℃)进行核酸扩增反应1.5h,在扩增前加入染料HNB(羟基萘酚蓝)作为反应指示剂,以HNB的颜色变化做为结果判定标准并经琼脂糖凝胶电泳验证。文中利用这种技术对不同来源及亚型的流感病毒进行了特异性分析,对体外转录的人甲型H1N1流感病毒HA基因RNA的系列稀释物进行了灵敏度分析,成功检测美国CDC提供的人甲型H1N1流感病毒标准品,利用RT-LAMP和RT-PCR同时检测了30份人甲型H1N1和26份季节性流感咽拭子标本。结果显示RT-LAMP方法特异性高,灵敏度可达到60个拷贝RNA分子水平,对临床标本的检出率与常规RT-PCR法相当,利用650nm的比色分析通过标准曲线可以实现对样品的定量。因此,基于颜色判定的环介导逆转录等温扩增方法可用于人甲型H1N1流感病毒感染的快速筛选,具有在基层疾病预防控制中心流感监测网络实验室和哨点医院推广和应用的潜力。     

2009−2015年中国甲型H1N1流感病毒血凝素基因进化分析

【目的】为了解中国地区2009?2015年甲型H1N1流感病毒流行态势,分析血凝素(Hemagglutinin,HA)基因的变异情况及其遗传进化特征。【方法】汇集国家流感中心2009?2015年流感周报的流感流行数据,分析甲型H1N1流感的流行病学特征;从全球共享禽流感数据倡议组织数据库及美国国家生物技术中心数据库下载甲型H1N1流感病毒HA基因序列,采用生物学软件进行系统进化和遗传特性的分析。【结果】2009?2015年全国共发生4次甲型H1N1流感的流行高峰。2009?2015年毒株与参考毒株A/California/07/2009(H1N1)的HA基因同源性逐年降低。遗传进化分析显示同一年份的毒株在系统进化树上基本呈现集中分布,2011年的毒株独立形成2个分支。分子特征表现为HA基因的4个抗原决定簇氨基酸位点均有变异,其中Ca区的203位、Sa区的163位和Sb区的185位氨基酸位点逐渐替换为新的氨基酸。除2010年与2012年,其他年份的毒株通过不同模型均得到正向压力选择HA氨基酸位点240。【结论】甲型H1N1流感在中国地区成为主要流行的亚型之一。HA基因与其编码的氨基酸逐年变异,未来进一步的流感监测能力还需加强。     

同时检测新甲型H1N1及人季节性H1N1和H3N2流感病毒的单管多重荧光定量PCR方法

本研究设计的一种4重荧光定量RT-PCR检测方法,以A型流感病毒各亚型的血凝素基因(HA)为检测靶标,实现了同时检测新甲型H1N1流感病毒、人季节性H1N1流感病毒和人季节性H3N2流感病毒。本法使用人细胞RNA酶P基因作为内参,以判断标本来源和实施质量控制。利用不同来源和亚型的流感病毒验证了该方法的特异性;利用连续稀释的新甲型H1N1流感病毒HA全基因体外转录物进行灵敏度分析。结果表明该方法灵敏度高,可检测低至20个拷贝的RNA;特异性强,每对引物只检测出对应的病毒,无交叉反应;并且成功地验证性检验了34份新甲型H1N1流感病毒阳性临床标本和20份人季节性H1N1和H3N2流感病毒及人乙型(HB)流感病毒阳性临床标本。因此,该多重荧光定量RT-PCR法是一种可同时检测2009年新甲型流感病毒及季节性流感病毒的有效方法。     

用液相芯片方法同时检测流感病毒H5N1和H7N9亚型

基于液相芯片(Multi-analyte suspension array,MASA)技术建立一种同时对H5N1和H7N9亚型流感病毒进行快速检测的新方法。对国家生物技术信息中心(National center for biotechnology information,NCBI)和欧洲生物信息学中心(The european bioinformatics institute,EBI)核酸数据库中已有的H5、N1、H7和N9核酸片段进行比对分析,并参考世界卫生组织,美国疾病预防控制中心和中国疾病预防控制中心等的相关资料,设计简并引物和探针,将合成的探针与荧光编码微球进行偶联,建立检测方法。利用该方法检测H5N1和H7N9亚型流感病毒和其它常见亚型(H1N1、甲流H1N1、H5N2、BH3N2和H9N2)的标本。建立了一种快速的流感病毒分型方法。这种方法可以同时检测H5N1和H7N9,用已知基因型的样本对这种方法进行验证显示它的特异性很好。灵敏度分析实验也表明这种方法具有很高的灵敏度,可以对含有5个拷贝的样本进行有效的检测。利用液相芯片技术研制的H5N1和H7N9亚型流感病毒检测方法能够用于流感病毒H5N1和H7N9亚型的快速、灵敏、特异性的检测及鉴定。     

高致病性A(H5N8)亚型禽流感病毒NA基因核酸检测方法的建立

建立以Real-time PCR为基础的新型高致病性A(H5N8)亚型禽流感病毒NA基因检测方法。针对2016年6月起频繁暴发的H5N8禽流感疫情,从GenBank和Global Initiative on Sharing All Influenza Data(GISAID)下载2014年以来的H5N8亚型禽流感病毒的NA序列,通过序列比对,在相对保守区域设计适用于实时荧光逆转录聚合酶链式反应(rRT-PCR)的引物和探针。选用28株不同NA亚型的流感病毒进行特异性验证,结果显示本文设计的引物探针组合能够特异性检测高致病性H5N8亚型禽流感病毒的NA基因。灵敏度检测结果显示,本文设计的引物探针组合能检出最低23个拷贝的RNA。本文建立了高致病性H5N8亚型禽流感病毒NA基因特异性荧光定量检测方法,与世界卫生组织(WHO)推荐的A型流感病毒M基因、H5基因检测引物探针的最低检测限一致,可以组合用于H5N8亚型禽流感病毒的检测。     

2008～2009年珠海市H3N2亚型流感病毒HA1基因特性分析

为了解2008~2009年珠海市H3N2亚型流感病毒HA1基因变异情况,选择珠海市2008~2009年期间不同时间点的经狗肾传代细胞(MDCK)培养分离的H3N2亚型流感毒株20株,提取病毒RNA,通过RT-PCR扩增HA1基因片段,将产物纯化并测序,推导氨基酸序列,进行基因进化特性分析。与同时期的疫苗株比较,2008年珠海市流行的H3N2亚型流感毒株HA1区抗原决定簇的氨基酸位点变异数少于4个;2009年珠海市流行的H3N2亚型流感毒株除09-0056外,HA1区存在5个位于抗原决定簇内的变异氨基酸位点。2008年H3N2亚型流感毒株的HA1区的糖基化位点与疫苗株一致;2009年H3N2亚型流感毒株HA1区丢失第144位糖基化位点。2008~2009年H3N2亚型流感毒株RBS氨基酸序列未见明显变异。与2008年H3N2亚型流感毒株比较,2009年H3N2亚型流感毒株HA1区抗原决定簇内存在多个位点的氨基酸替换。这些说明2008年珠海市流行的H3N2亚型流感病毒不是新变种;2009年流行的H3N2亚型流感病毒为新的变异株,这可能是H3N2亚型流感病毒在2009年6-9月为珠海地区季节性流感流行优势株的原因。     

山东省甲型H1N1流感病毒病原学及基因特性研究

在2009~2010年监测年度开展甲型H1N1流感病毒学监测并进行病原学分离鉴定,以及对血凝素基因(HA)和神经氨酸酶基因(NA)特性分析,研究其基因变异情况。采集了17 126份发热患者的鼻、咽拭子标本,采用逆转录实时荧光定量RT-PCR(Real-Time RT-PCR)进行核酸检测,其中甲型H1N1流感病毒核酸检测阳性4004份,总阳性率为23.38%。对阳性标本开展病毒分离,并对分离的甲型H1N1流感病毒的HA、NA基因序列进行测序。利用DNAStar软件对序列进行同源性分析发现与WHO推荐的疫苗株相比,山东省甲型H1N1流感流行株HA、NA基因同源性分别为96.9%~99.3%和99.1%~99.6%;利用Mega 4.0软件进行基因进化分析和氨基酸进化分析发现,与WHO推荐的疫苗株相比,山东省甲型H1N1流感流行株有21个血凝素基因的氨基酸发生替换,其中11个氨基酸位点位于抗原决定簇区,一个糖基化位点发生改变;有16个神经氨酸酶基因的氨基酸发生了替换,一个糖基化位点发生改变;未发生神经氨酸酶蛋白275位H→Y的替换。结果显示山东省甲型H1N1流感暴发流行株HA基因和NA基因均具有高度同源性,HA蛋白和NA蛋白均存在不同程度的氨基酸替换,部分流行株抗原决定簇和糖基化位点发生改变,所有病毒均对达菲类药物敏感。     

禽流感病毒分型基因芯片的研制

[目的]禽流感病毒是一种全球重要的人和动物呼吸道病病原,快速确定其不同亚型对于全球流感监测具有重要的意义.本研究意在研制一种可同时鉴定禽流感病毒所有亚型的方法.[方法]根据GenBank上已发表的禽流感病毒不同亚型(16个HA亚型和9个NA亚型)的基因序列,设计合成了25对特异性引物和1对通用引物,然后以各亚型病毒的参考株RNA作为模板,建立扩增不同亚型的多重RT-PCR方法.参考各亚型病毒靶cDNAs区域的保守序列设计了52条亚型特异的探针,进而利用扩增的各亚型病毒的靶cDNAs对其特异性进行评价.在此基础上,将设计好的探针点制到处理好的玻片上,制备了禽流感病毒分型鉴定基因芯片,结合所建立的扩增不同亚型的多重RT-PCR方法,开发了禽流感病毒亚型鉴定基因芯片试剂.利用收集自49个地区的2653份标本对其特异性和敏感性进行了初步评价.[结果]用于评价的各亚型参考毒株均出现良好的特异性杂交信号,检测的敏感度可达2.47 PFU/mL或2.5 ng靶DNA片段,而且与禽类常见的IBV、NDV等6种病毒均无交叉反应.[结论]证明该病毒分型基因芯片具有良好的特异性、敏感性.     

Microarray for diagnostics of human pathogenic influenza-a virus subtypes

An oligonucleotide microarray was developed for diagnostics of human pathogenic influenza-A virus subtypes. It contained discriminating probes for H1, H2, H3, H5, H7, and H9 subtypes of hemagglutinin and for N1, N2, and N7 subtypes of neuraminidase. An additional set of probes was used for revealing the M-gene of the influenza-A virus. The proposed microarray was tested on samples of pathogenic H5N1 avian influenza virus, pandemic H1N1 swine influenza virus, and seasonal H1N1 and H3N2 influenza viruses. The microarray can be used for the analysis both of cultivated strains and clinical specimens.     

Identification of reassortant pandemic H1N1 influenza virus in Korean pigs

Since the 2009 pandemic human H1N1 influenza A virus emerged in April 2009, novel reassortant strains have been identified throughout the world. This paper describes the detection and isolation of reassortant strains associated with human pandemic influenza H1N1 and swine influenza H1N2 (SIV) viruses in swine populations in South Korea. Two influenza H1N2 reassortants were detected, and subtyped by PCR. The strains were isolated using Madin- Darby canine kidney (MDCK) cells, and genetically characterized by phylogenetic analysis for genetic diversity. They consisted of human, avian, and swine virus genes that were originated from the 2009 pandemic H1N1 virus and a neuraminidase (NA) gene from H1N2 SIV previously isolated in North America. This identification of reassortment events in swine farms raises concern that reassortant strains may continuously circulate within swine populations, calling for the further study and surveillance of pandemic H1N1 among swine.     

Genetically Diverse Low Pathogenicity Avian Influenza A Virus Subtypes Co-Circulate among Poultry in Bangladesh

Influenza virus surveillance, poultry outbreak investigations and genomic sequencing were assessed to understand the ecology and evolution of low pathogenicity avian influenza (LPAI) A viruses in Bangladesh from 2007 to 2013. We analyzed 506 avian specimens collected from poultry in live bird markets and backyard flocks to identify influenza A viruses. Virus isolation-positive specimens (n = 50) were subtyped and their coding-complete genomes were sequenced. The most frequently identified subtypes among LPAI isolates were H9N2, H11N3, H4N6, and H1N1. Less frequently detected subtypes included H1N3, H2N4, H3N2, H3N6, H3N8, H4N2, H5N2, H6N1, H6N7, and H7N9. Gene sequences were compared to publicly available sequences using phylogenetic inference approaches. Among the 14 subtypes identified, the majority of viral gene segments were most closely related to poultry or wild bird viruses commonly found in Southeast Asia, Europe, and/or northern Africa. LPAI subtypes were distributed over several geographic locations in Bangladesh, and surface and internal protein gene segments clustered phylogenetically with a diverse number of viral subtypes suggesting extensive reassortment among these LPAI viruses. H9N2 subtype viruses differed from other LPAI subtypes because genes from these viruses consistently clustered together, indicating this subtype is enzootic in Bangladesh. The H9N2 strains identified in Bangladesh were phylogenetically and antigenically related to previous human-derived H9N2 viruses detected in Bangladesh representing a potential source for human infection. In contrast, the circulating LPAI H5N2 and H7N9 viruses were both phylogenetically and antigenically unrelated to H5 viruses identified previously in humans in Bangladesh and H7N9 strains isolated from humans in China. In Bangladesh, domestic poultry sold in live bird markets carried a wide range of LPAI virus subtypes and a high diversity of genotypes. These findings, combined with the seven year timeframe of sampling, indicate a continuous circulation of these viruses in the country.     

近年来华东地区家鸭中禽流感病毒的亚型分布

[目的]为了研究近年来华东地区家鸭中禽流感病毒的亚型分布情况.[方法]对2002-2006年分离自华东地区家鸭的180株禽流感病毒的HA亚型和其中88株禽流感病毒的NA亚型分别进行了测定.[结果]近年来华东地区家鸭中至少存在9种HA亚型和6种NA亚型组成的H1N1,H3N1,H3N2,H3N8,H4N6,H5N1,H5N2,H6N2,H6N8,H8N4,H9N2,H10N3,H11N2共13种亚型的禽流感病毒.[结论]华东地区家鸭中有多种亚型的禽流感病毒分布,应加强家鸭禽流感的监测和防制工作.     

Differential suppressive effect of promyelocytic leukemia protein on the replication of different subtypes/strains of influenza A virus

Promyelocytic leukemia protein (PML) plays an important role in the defense against a number of viruses, including influenza A virus. However, the sensitivity of influenza A virus subtypes/strains to PML is unknown. We investigated the role of PML in the replication of different influenza A virus subtypes/strains using pan-PML knock-down A549 cells and PML-VI-overexpressed MDCK cells. We found that (i) depletion of pan-PML by siRNA rendered A549 cells more susceptible to influenza A virus strains PR8(H1N1) and ST364(H3N2), but not to strains ST1233(H1N1), Qa199(H9N2) and Ph2246(H9N2); (ii) overexpression of PML-VI in MDCK cells conferred potent resistance to PR8(H1N1) infection, while lacked inhibitory activity to ST1233(H1N1), ST364(H3N2), Qa199(H9N2) and Ph2246(H9N2). Our results suggest that the antiviral effect of PML on influenza A viruses is viral subtype/strain specific.     

Subtyping animal influenza virus with general multiplex RT-PCR and Liquichip high throughput (GMPLex)

This study developed a multiplex RT-PCR integrated with luminex technology to rapidly subtype simultaneously multiple influenza viruses. Primers and probes were designed to amplify NS and M genes of influenza A viruses HA gene of H1, H3, H5, H7, H9 subtypes, and NA gene of the N1 and N2 subtypes. Universal super primers were introduced to establish a multiplex RT-PCR (GM RT-PCR). It included three stages of RT-PCR amplification, and then the RT-PCR products were further tested by LiquiChip probe, combined to give an influenza virus (IV) rapid high throughput subtyping test, designated as GMPLex. The IV GMPLex rapid high throughput subtyping test presents the following features: high throughput, able to determine the subtypes of 9 target genes in H1, H3, H5, H7, H9, N1, and N2 subtypes of the influenza A virus at one time; rapid, completing the influenza subtyping within 6 hours; high specificity, ensured the specificity of the different subtypes by using two nested degenerate primers and one probe, no cross reaction occurring between the subtypes, no non-specific reactions with other pathogens and high sensitivity. When used separately to detect the product of single GM RT-PCR for single H5 or N1 gene, the GMPLex test showed a sensitivity of 10⁻⁵(= 280ELD₅₀) forboth tests and the Luminex qualitative ratio results were 3.08 and 3.12, respectively. When used to detect the product of GM RT-PCR for H5N1 strain at the same time, both showed a sensitivity of 10⁻⁴(=2800 ELD₅₀). The GMPLex rapid high throughput subtyping test can satisfy the needs of influenza rapid testing.Key words: Influenza Virus, General multiplex RT-PCR, Iuminex assay, Subtyping, HA and NA genes     

Analysis of the potentials of molecular hybridization of nucleic acids as a method of the laboratory diagnosis of influenza

The possibilities of using the DNA copies of different genes of influenza A virus for the detection of virus-specific RNa by molecular dot hybridization have been studied. High specificity and sensitivity of the RNA determination techniques have been demonstrated, as well as the efficacy of using DNA probes with the sequences of conservative genes (polymerase, nucleoprotein and matrix genes) for the detection of influenza A virus subtypes H1N1, H2N2, H3N2 and probes with the copies of the corresponding hemagglutinin genes for the differential determination of subtypes H3N2 and H1N1. The complex analysis of nasopharyngeal washings has confirmed the efficacy of the dot hybridization method for epidemiological investigations, particularly for deciphering influenza outbreaks, especially those of mixed etiology.