新的猪源性甲型H1N1流感病毒

2009年3月在美国和墨西哥流感样患者的呼吸道标本中鉴定出新的猪源性甲型H1N1流感病毒。该病毒可人一人传播,已蔓延到172个国家和地区。现就猪源性甲型H1N1流感病毒的鉴定、基因组结构特征做一综述。     

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。     

猪源性甲型H1N1流感病毒研究概况

2009年3月在美国和墨西哥流感样患者的呼吸道标本中鉴定出新的猪源性甲型H1N1流感病毒。该病毒可人-人传播,已蔓延到112个国家和地区。为了遏制不断重组或重配的流感病毒,各国学者对甲型H1N1流感病毒的分子生物学特征、复制周期及实验室诊断做了细致的研究,以研发相应的药物或疫苗,这些成就为世界各国防控今年新鉴定的猪源性甲型H1N1流感病毒感染发挥了重要作用。现就猪源性甲型H1N1流感病毒的鉴定、基因组结构特征做一综述。     

H1N1感染背景对H9N2感染家猪的免疫保护作用

为了探索H1N1病毒感染史对H9N2病毒感染家猪的影响,本研究采用H9N2病毒分别感染有/无H1N1病毒感染史的家猪,比较两组家猪鼻腔泄毒滴度及血清转阳情况。研究发现:与无感染背景的家猪相比,H1N1病毒预感染过的家猪在接种了H9N2病毒后未检测到呼吸道泄毒。尽管两组家猪都产生了H9N2抗体,但有H1N1感染史的家猪体内的H1N1抗体水平在H9N2接种后快速显著上升,这些H1N1抗体与H9N2病毒并无血清学交叉反应。本研究提示,在自然界中,H1N1病毒在猪群中的流行极有可能为H9N2病毒在猪中的感染及传播构筑了天然的屏障,从而延缓了H9N2禽流感病毒通过家猪这一宿主获得哺乳动物适应性的进程。     

2009年中国流行的甲型流感病毒（H1N1）血凝素特征分析

目的研究甲型流感病毒（H1N1）暴发流行以来中国各地甲型流感病毒血凝素（HA）的特征。方法搜索甲型流感病毒（H1N1）暴发流行以来中国各地报道的血凝素（HA）的氨基酸序列,比较当年不同时期血凝素（HA）的氨基酸序列的变化,并比较2009年报道的血凝素（HA）的氨基酸序列和2008年、2007年报道的血凝素（HA）的氨基酸序列作比较,以分析和前2年血凝素（HA）氨基酸序列相比所发生的变化。结果2009年中国各地甲型流感病毒（H1N1）的血凝素（HA）的氨基酸序列（人源）的同源性为99%-100%,但和2008年以及2007年的同源性非常低,分别为70%-77%和71%-90%。结论2009年暴发流行的甲型流感病毒（H1N1）的血凝素氨基酸序列较往年发生了很大程度的变异,这可能是今年甲型流感病毒（H1N1）暴发流行的主要原因。     

深圳市新甲型H1N1流感病毒感染病例的血清学及分子特点分析

本研究通过对深圳市4名甲流重症患者的血清抗体及其所感染的新甲型H1N1流感病毒的抗原性和分子特点的分析,发现这些患者在感染后短期内产生的血清中和抗体滴度均不超过1:20,不能起到有效的保护作用;交叉血凝抑制实验的结果显示新H1N1病毒与季节性H1N1和H3N2流感病毒无任何交叉反应,抗原性差异很大,而患者所感染的病毒与标准株的抗原性则没有太大差异;分子特点的分析表明新H1N1病毒进入人群后依然属于经典的猪流感亚系,4名重症患者感染的病毒不具备高致病性流感病毒的遗传特点,几个氨基酸位点的变异没有影响病毒的毒力和致病性,只有一株毒株的NA蛋白发生了His275Tyr的突变,产生了对达菲等神经氨酸酶抑制剂的耐药性。     

一株达菲耐药的甲型H1N1流感病毒全基因特征分析

目的分析1株甲型H1N1流感达菲耐药病毒株的全基因特征,为指导流感临床治疗与防控提供依据。方法采用鸡胚进行病毒分离,提取病毒RNA,通过RT-PCR扩增其全基因组8个基因片段,测定核苷酸序列,利用生物信息软件拼接全基因组序列,绘制基因进化树并分析重要基因位点变异情况。结果 A/Fuzhou/SWL11609/2013(H1N1)流感毒株的8个节段基因均处于2013-2014年度进化簇中,且与A/California/07/2009(H1N1)疫苗株高度同源,8个基因同源性均在97.4%以上;其HA和NA基因与A/Hubei-Wuchang/SWL1322/2013(H1N1)达菲耐药株同源性最高,分别为100.0%和99.6%;初步判断该毒株未发生重配现象,其重要致病性基因位点未发生变异;NA基因中具有H275Y典型达菲耐药位点特征,缺失一个糖基化位点(N386K),降低了基因结构的稳定性,同时在V241I和N369K的作用下降低了病毒的适应性。结论本次研究的甲型H1N1流感达菲耐药病毒株表现为低致病性流感病毒特征,但具备较好的人传人能力,需进一步加强监测,谨防耐药株的广泛流行。     

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。     

甲型H1N1流感病毒HA蛋白抗原表位及受体结合位点突变特性的对比研究

人群中流行的H1N1病毒按其来源可分为两类:人感染的猪H1N1病毒与人类季节性H1N1流感病毒。这两类病毒在流行频率、易感性和致病性等方面存在明显差异。文章收集了1918～2009年间17株人感染的猪甲型H1N1毒株以及21株季节性H1N1毒株,通过序列比对、氨基酸残基保守性分析及3D结构对比等生物信息学方法,揭示造成这两类病毒流行病学和感染性差异的机制。研究发现这两类病毒HA蛋白的进化路径并不相同,且两者具有不同的突变特征,人感染的猪H1N1病毒中,Ca1、Ca2、Sa和Sb四个位点均较为保守,仅Cb位点的突变较快;季节性H1N1病毒仅有Ca1位点较为保守,其他四个抗原性位点均具有较快的突变速率,且较多的突变为新类型的氨基酸。另外,对受体结合位点的研究也显示,这两类病毒的该区域存在5个氨基酸水平的差异(ALA138SER、GLN192LYS、GLN196HIS、ALA198GLU和ALA227GLU),这些位点的差异使得人感染的猪H1N1流感病毒比人类季节性H1N1病毒的易感性更强。这些研究结果可为阐明两类H1N1流感病毒感染性及致病性差异提供更多的信息,并有助于进一步认识H1N1流感病毒的进化机制。     

江苏首例甲型H1N1(2009)流感病毒分离及其血凝素分子遗传特征分析

2009年6月12日,江苏确诊首例甲型H1N1(2009)病例。通过细胞和鸡胚分离系统,我们分离到一株具有较高血凝活性的病毒,命名为A/Jiangsu/1/2009。为了跟踪病毒的变异情况,我们开展了病毒的全基因组测序工作,在此基础上对其血凝素基因(Haemagglutinin,HA)的遗传特性进行了详细研究。分离株HA蛋白不具有多碱基HA裂解位点,具有低致病性流感病毒特点。与参考株A/California/04/2009相比,分离株A/Jiangsu/1/2009HA蛋白的有4个氨基酸发生了突变,但都不在已知的抗原位点上。分离株有5个潜在糖基化位点,这与近年来古典猪H1N1和北美三源重配猪H1病毒完全一致,保留了古典猪H1的特点。与禽流感H1病毒相比,分离株HA蛋白受体结合位点上的E190D和G225D发生突变,这可能成为新甲型H1N1(2009)在人际间传播的一个重要分子基础。此外,其它受体结合位点上相关氨基酸同时具有人和猪流感病毒的特点。本研究首次对早期流行的甲型H1N1(2009)流感病毒的HA蛋白的分子遗传特征进行了详细研究,对进一步监测病原变异具有重要指导意义。     

Emergence of Eurasian Avian-Like Swine Influenza A (H1N1) Virus from an Adult Case in Fujian Province,China

正Dear Editor,As we known,pigs play a vital role as genetic mixing vessels for human and avian influenza viruses as their tracheal epitheliums possess both sialic acid a-2,6-Gal and a-2,3-Gal receptors(Ma et al.2008),and swine influenza viruses occasionally infect humans(Shinde et al.2009).The Eurasian avian-like swine influenza A(H1N1)virus     

欧亚类禽猪流感病毒病原学研究进展

欧亚类禽猪流感病毒被认为是引起下次流感大流行可能性最大的动物流感病毒之一。1979年,第一次在猪群中分离到欧亚类禽猪流感病毒,该病毒随后在欧洲流行。欧亚类禽猪流感病毒从2005年起在我国猪群中广泛存在,偶尔可突破种属屏障感染人;在江苏、河北和湖南等地区已出现人感染欧亚类禽猪流感病毒,由此对公共卫生和生猪养殖业均有一定的威胁和影响。本文综述了欧亚类禽猪流感病毒的流行情况、病原学特征及其相关致病分子机制研究进展,旨在为欧亚类禽猪流感病毒的风险评估提供科学依据。     

Predicted Enhanced Human Propensity of Current Avian-Like H1N1 Swine Influenza Virus from China

Influenza A virus (IAV) subtypes against which little or no pre-existing immunity exists in humans represent a serious threat to global public health. Monitoring of IAV in animal hosts is essential for early and rapid detection of potential pandemic IAV strains to prevent their spread. Recently, the increased pandemic potential of the avian-like swine H1N1 IAV A/swine/Guangdong/104/2013 has been suggested. The virus is infectious in humans and the general population seems to lack neutralizing antibodies against this virus. Here we present an in silico analysis that shows a strong human propensity of this swine virus further confirming its pandemic potential. We suggest mutations which would further enhance its human propensity. We also propose conserved antigenic determinants which could serve as a component of a prepandemic vaccine. The bioinformatics tool, which can be used to further monitor the evolution of swine influenza viruses towards a pandemic virus, are described here and are made publically available (http://www.vin.bg.ac.rs/180/tools/iav_mon.php; http://www.biomedprotection.com/iav_mon.php).     

Epidemiology and Genotypic Diversity of Eurasian Avian-Like H1N1 Swine Influenza Viruses in China

Eurasian avian-like H1 N1(EA H1 N1) swine influenza virus(SIV) outside European countries was first detected in Hong Kong Special Administrative Region(Hong Kong, SAR) of China in 2001. Afterwards, EA H1 N1 SIVs have become predominant in pig population in this country. However, the epidemiology and genotypic diversity of EA H1 N1 SIVs in China are still unknown. Here, we collected the EA H1 N1 SIVs sequences from China between 2001 and 2018 and analyzed the epidemic and phylogenic features, and key molecular markers of these EA H1 N1 SIVs. Our results showed that EA H1 N1 SIVs distributed in nineteen provinces/municipalities of China. After a long-time evolution and transmission, EA H1 N1 SIVs were continuously reassorted with other co-circulated influenza viruses, including 2009 pandemic H1 N1(A(H1 N1)pdm09), and triple reassortment H1 N2(TR H1 N2) influenza viruses, generated 11 genotypes. Genotype 3 and 5, both of which were the reassortments among EA H1 N1, A(H1 N1)pdm09 and TR H1 N2 viruses with different origins of M genes, have become predominant in pig population. Furthermore, key molecular signatures were identified in EA H1 N1 SIVs. Our study has drawn a genotypic diversity image of EA H1 N1 viruses, and could help to evaluate the potential risk of EA H1 N1 for pandemic preparedness and response.     

H1N1亚型猪流感病毒的拯救

利用8质粒拯救系统成功拯救出了猪流感病毒毒株A/Swine/TianJin/01/2004(H1N1)(A/S/TJ/04)。将猪流感病毒8个基因节段经RT-PCR合成cDNA后, 分别克隆到RNA聚合酶I/II双向表达载体PHW2000中, 构建成8个重组质粒。用8个重组质粒共转染COS-1细胞, 30 h后加入TPCK-胰酶至终浓度0.5 mg/mL。共转染48小时后收获COS-1细胞及其上清, 经尿囊腔接种9日龄SPF鸡胚。收获死亡鸡胚尿囊液并继续用SPF鸡胚传3代, 得到有感染性的病毒。经血凝、血凝抑制验、测序分析、电镜观察等均证实了A/S/TJ/04猪流感病毒的成功拯救。这是目前国内首次报道拯救出H1N1亚型猪流感病毒, 为进一步研究猪流感病毒基因组结构与功能的关系、流感跨种传播的机制以及构建新型猪流感疫苗株奠定了基础。     

H1N1亚型猪流感病毒的拯救

利用8质粒拯救系统成功拯救出了猪流感病毒毒株A/Swine/TianJin/01/2004(H1N1)(A/S/TJ/04)。将猪流感病毒8个基因节段经RT-PCR合成cDNA后, 分别克隆到RNA聚合酶I/II双向表达载体PHW2000中, 构建成8个重组质粒。用8个重组质粒共转染COS-1细胞, 30 h后加入TPCK-胰酶至终浓度0.5 mg/mL。共转染48小时后收获COS-1细胞及其上清, 经尿囊腔接种9日龄SPF鸡胚。收获死亡鸡胚尿囊液并继续用SPF鸡胚传3代, 得到有感染性的病毒。经血凝、血凝抑制验、测序分析、电镜观察等均证实了A/S/TJ/04猪流感病毒的成功拯救。这是目前国内首次报道拯救出H1N1亚型猪流感病毒, 为进一步研究猪流感病毒基因组结构与功能的关系、流感跨种传播的机制以及构建新型猪流感疫苗株奠定了基础。     

Swine Influenza H1N1 Virus Induces Acute Inflammatory Immune Responses in Pig Lungs: a Potential Animal Model for Human H1N1 Influenza Virus

Pigs are capable of generating reassortant influenza viruses of pandemic potential, as both the avian and mammalian influenza viruses can infect pig epithelial cells in the respiratory tract. The source of the current influenza pandemic is H1N1 influenza A virus, possibly of swine origin. This study was conducted to understand better the pathogenesis of H1N1 influenza virus and associated host mucosal immune responses during acute infection in humans. Therefore, we chose a H1N1 swine influenza virus, Sw/OH/24366/07 (SwIV), which has a history of transmission to humans. Clinically, inoculated pigs had nasal discharge and fever and shed virus through nasal secretions. Like pandemic H1N1, SwIV also replicated extensively in both the upper and lower respiratory tracts, and lung lesions were typical of H1N1 infection. We detected innate, proinflammatory, Th1, Th2, and Th3 cytokines, as well as SwIV-specific IgA antibody in lungs of the virus-inoculated pigs. Production of IFN-γ by lymphocytes of the tracheobronchial lymph nodes was also detected. Higher frequencies of cytotoxic T lymphocytes, γδ T cells, dendritic cells, activated T cells, and CD4⁺ and CD8⁺ T cells were detected in SwIV-infected pig lungs. Concomitantly, higher frequencies of the immunosuppressive T regulatory cells were also detected in the virus-infected pig lungs. The findings of this study have relevance to pathogenesis of the pandemic H1N1 influenza virus in humans; thus, pigs may serve as a useful animal model to design and test effective mucosal vaccines and therapeutics against influenza virus.Swine influenza is a highly contagious, acute respiratory viral disease of swine. The causative agent, swine influenza virus (SwIV), is a strain of influenza virus A in the Orthomyxoviridae family. Clinical disease in pigs is characterized by sudden onset of anorexia, weight loss, dyspnea, pyrexia, cough, fever, and nasal discharge (21). Porcine respiratory tract epithelial cells express sialic acid receptors utilized by both avian (α-2,3 SA-galactose) and mammalian (α-2,6 SA-galactose) influenza viruses. Thus, pigs can serve as “mixing vessels” for the generation of new reassortant strains of influenza A virus that may contain RNA elements of both mammalian and avian viruses. These “newly generated” and reassorted viruses may have the potential to cause pandemics in humans and enzootics in animals (52).Occasional transmission of SwIV to humans has been reported (34, 43, 52), and a few of these cases resulted in human deaths. In April 2009, a previously undescribed H1N1 influenza virus was isolated from humans in Mexico. This virus has spread efficiently among humans and resulted in the current human influenza pandemic. Pandemic H1N1 virus is a triple reassortant (TR) virus of swine origin that contains gene segments from swine, human, and avian influenza viruses. Considering the pandemic potential of swine H1N1 viruses, it is important to understand the pathogenesis and mucosal immune responses of these viruses in their natural host. Swine can serve as an excellent animal model for the influenza virus pathogenesis studies. The clinical manifestations and pathogenesis of influenza in pigs closely resemble those observed in humans. Like humans, pigs are also outbred species, and they are physiologically, anatomically, and immunologically similar to humans (9, 23, 39, 40). In contrast to the mouse lung, the porcine lung has marked similarities to its human counterpart in terms of its tracheobronchial tree structure, lung physiology, airway morphology, abundance of airway submucosal glands, and patterns of glycoprotein synthesis (8, 10, 17). Furthermore, the cytokine responses in bronchoalveolar lavage (BAL) fluid from SwIV-infected pigs are also identical to those observed for nasal lavage fluids of experimentally infected humans (20). These observations support the idea that the pig can serve as an excellent animal model to study the pathogenesis of influenza virus.Swine influenza virus causes an acute respiratory tract infection. Virus replicates extensively in epithelial cells of the bronchi and alveoli for 5 to 6 days followed by clearance of viremia by 1 week postinfection (48). During the acute phase of the disease, cytokines such as alpha interferon (IFN-α), tumor necrosis factor alpha (TNF-α), interleukin-1 (IL-1), IL-6, IL-12, and gamma interferon (IFN-γ) are produced. These immune responses mediate both the clinical signs and pulmonary lesions (2). In acute SwIV-infected pigs, a positive correlation between cytokines in BAL fluid, lung viral titers, inflammatory cell infiltrates, and clinical signs has been detected (2, 48).Infection of pigs with SwIV of one subtype may confer complete protection from subsequent infections by homologous viruses and also partial protection against heterologous subtypes, but the nature of the immune responses generated in the swine are not fully delineated. Importantly, knowledge related to host mucosal immune responses in the SwIV-infected pigs is limited. So far only the protective virus-specific IgA and IgG responses in nasal washes and BAL fluid, as well as IgA, IgG, and IgM responses in the sera of infected pigs, have been reported (28). Pigs infected with H3N2 and H1N1 viruses have an increased frequency of neutrophils, NK cells, and CD4 and CD8 T cells in the BAL fluid (21). Pigs infected with the pandemic H1N1 virus showed activated CD4 and CD8 T cells in the peripheral blood on postinfection day (PID) 6 (27). Proliferating lymphocytes in BAL fluid and blood and virus-specific IFN-γ-secreting cells in the tracheobronchial lymph nodes (TBLN) and spleen were detected in SwIV-infected pigs (7). Limited information is available on the mucosal immune responses in pig lungs infected with SwIV, which has a history of transmission to humans.In this study, we examined the acute infection of SwIV (strain SwIV OH07) in pigs with respect to viral replication, pathology, and innate and adaptive immune responses in the respiratory tract of these pigs. This virus was isolated from pigs which suffered from respiratory disease in Ohio, and the same virus was also transmitted to humans and caused clinical disease (43, 55). Interestingly, like pandemic H1N1 influenza virus, SwIV also infects the lower respiratory tract of pigs. Delineation of detailed mucosal immune responses generated in pig lungs during acute SwIV OH07 infection may provide new insights for the development of therapeutic strategies for better control of virus-induced inflammation and for the design and testing of effective vaccines.     

Characterization of Avian-like Influenza A (H4N6) Virus Isolated from Caspian Seal in 2012

正Dear Editor Marine mammals are widely distributed and can be found almost in all coastal waters and coastlines around the world. The interface areas between marine and terrestrial environments provide natural habitats for aquatic and semiaquatic mammals as well as for reservoir species of avian influenza viruses (AIV)(Runstadler et al. 2013). Previous     

浙江省首例人禽流感病例的病原学与分子生物学研究

为确认浙江省首例疑似人禽流感病例,进行病原学分析,对患者气管吸出物进行核酸RT-PCR、荧光定量RT-PCR检测以及病毒分离,并对患者血清进行HI抗体测定.结果表明患者气管吸出物H5N1亚型和A型流感病毒特异核酸均呈阳性,分离到禽流感病毒A/Zhejiang/16/06(H5N1)株;双份血清中禽流感病毒(H5N1)HI抗体滴度分别为1320和1640,从病原学和血清学上证实为人禽流感病例.分离毒株测序结果显示,A/Zhejiang/16/06(H5N1)株在HA裂解位点为多个碱性氨基酸,符合高致病性禽流感病毒特征;该毒株的HA、NA、PB2、NP、M和NS基因序列均为禽源,与2005年我国福建、安徽等地禽流感病毒分离株高度同源,而与越南、泰国以及香港1997年分离到的禽流感病毒株之间存在明显差异.