H7N3 avian influenza virus found in a South American wild duck is related to the Chilean 2002 poultry outbreak, contains genes from equine and North American wild bird lineages, and is adapted to domestic turkeys

An H7N3 avian influenza virus (AIV) was isolated from a Cinnamon Teal (Anas cyanoptera) (A/CinnamonTeal/Bolivia/4537/01) during a survey of wild waterfowl in Bolivia in 2001. The NA and M genes had the greatest identity with North American wild bird isolates, the NS was most closely related to an equine virus, and the remaining genes were most closely related to isolates from an outbreak of H7N3 in commercial poultry in Chile in 2002. The HA protein cleavage site and the results of pathogenesis studies in chickens were consistent with a low-pathogenicity virus, and the infective dose was 10(5) times higher for chickens than turkeys.     

Emergence and genetic variation of neuraminidase stalk deletions in avian influenza viruses

When avian influenza viruses (AIVs) are transmitted from their reservoir hosts (wild waterfowl and shorebirds) to domestic bird species, they undergo genetic changes that have been linked to higher virulence and broader host range. Common genetic AIV modifications in viral proteins of poultry isolates are deletions in the stalk region of the neuraminidase (NA) and additions of glycosylation sites on the hemagglutinin (HA). Even though these NA deletion mutations occur in several AIV subtypes, they have not been analyzed comprehensively. In this study, 4,920 NA nucleotide sequences, 5,596 HA nucleotide and 4,702 HA amino acid sequences were analyzed to elucidate the widespread emergence of NA stalk deletions in gallinaceous hosts, the genetic polymorphism of the deletion patterns and association between the stalk deletions in NA and amino acid variants in HA. Forty-seven different NA stalk deletion patterns were identified in six NA subtypes, N1-N3 and N5-N7. An analysis that controlled for phylogenetic dependence due to shared ancestry showed that NA stalk deletions are statistically correlated with gallinaceous hosts and certain amino acid features on the HA protein. Those HA features included five glycosylation sites, one insertion and one deletion. The correlations between NA stalk deletions and HA features are HA-NA-subtype-specific. Our results demonstrate that stalk deletions in the NA proteins of AIV are relatively common. Understanding the NA stalk deletion and related HA features may be important for vaccine and drug development and could be useful in establishing effective early detection and warning systems for the poultry industry.     

H5N2 avian influenza outbreak in Texas in 2004: the first highly pathogenic strain in the United States in 20 years?

In early 2004, an H5N2 avian influenza virus (AIV) that met the molecular criteria for classification as a highly pathogenic AIV was isolated from chickens in the state of Texas in the United States. However, clinical manifestations in the affected flock were consistent with avian influenza caused by a low-pathogenicity AIV and the representative virus (A/chicken/Texas/298313/04 [TX/04]) was not virulent for experimentally inoculated chickens. The hemagglutinin (HA) gene of the TX/04 isolate was similar in sequence to A/chicken/Texas/167280-4/02 (TX/02), a low-pathogenicity AIV isolate recovered from chickens in Texas in 2002. However, the TX/04 isolate had one additional basic amino acid at the HA cleavage site, which could be attributed to a single point mutation. The TX/04 isolate was similar in sequence to TX/02 isolate in several internal genes (NP, M, and NS), but some genes (PA, PB1, and PB2) had sequence of a clearly different origin. The TX/04 isolate also had a stalk deletion in the NA gene, characteristic of a chicken-adapted AIV. By analyzing viruses constructed by in vitro mutagenesis followed by reverse genetics, we found that the pathogenicity of the TX/04 virus could be increased in vitro and in vivo by the insertion of an additional basic amino acid at the HA cleavage site and not by the loss of a glycosylation site near the cleavage site. Our study provides the genetic and biologic characteristics of the TX/04 isolate, which highlight the complexity of the polygenic nature of the virulence of influenza viruses.     

中国H5N1禽流感病毒HA基因的分子进化分析

为了阐明中国H5N1禽流感病毒血凝素(HA)基因的分子进化规律,从GenBank下载中国近年来分离的27株禽流感H5N1病毒的HA基因,利用LaserGene软件包中的EditSeq程序剪切共同序列并翻译成氨基酸序列,与DNAMAN软件进行比对,并以LaserGene软件包中的MegAlign程序构建分子进化树,结合背景资料分析其传播流行规律。结果显示:①在HA裂解位点上游毗邻的位置,gdch04、gddu04、gxch0405、gxdu05、gxqu0502、hkcph05、stch05、stqu05、ynch0502株都缺失了三个碱基;②27株毒株在HA裂解位点上游毗邻的位置存在多个连续的碱性氨基酸;③来自广西的gxch0405、gxdu05、gxqu0502和来自香港的hkcph05、hkgh04的序列同源性很高,很可能与苍鹭的迁移有关;④来自广西的gxqu0502和来自香港的hkcph05亲源关系很近,很可能来自同一祖先。     

鸽源H5N1亚型禽流感病毒株的HA和NA基因特征性分析

本研究自行设计合成两对特异性引物,通过RT-PCR扩增出1株鸽源H5N1亚型禽流感病毒血凝素（HA）和神经氨酸酶（NA）两个基因的cDNA片段,将它们成功克隆于pMD18-T载体上,然后进行序列测定。结果表明,HA基因全长1707bp,编码568个氨基酸, HA基因有7个糖基化位点,在裂解位点附近有连续6个碱性氨基酸（R-R-R-K-K-R）的插入,具有高致病性毒株的分子特征。受体结合位点的氨基酸分别为YWIHELY,左侧壁氨基酸为SGVSSA,右侧壁为NGQSGR;NA基因全长1350bp,编码446个氨基酸,NA基因有3个糖基化位点。     

Genome sequencing and phylogenetic analysis of three avian influenza H9N2 subtypes in Guangxi

Three isolates of H9N2 Avian Influenza viruses (AIV) were isolated from chickens in Guangxi province. Eight pairs of specific primers were designed and synthesized according to the sequences of H9N2 at GenBank. phylogenetic analysis showed a high degree of homology between the Guangxi isolates and isolates from Guangdong and Jiangsu provinces, suggesting that the Guangxi isolates originated from the same source. However, the eight genes of the three isolates from Guangxi were not in the same sublineages in their respective phylogenetic trees, which suggests that they were products of natural reassortment between H9N2 avian influenza viruses from different sublineages. The 9 nucleotides ACAGAGATA which encode amino acids T, G, I were absent between nucleotide 205 and 214 in the open reading frame of the NA gene in the Guangxi isolates. AIV strains that infect human have, in their HA proteins, leucine at position 226. The analysis of deduced amino acid sequence of HA proteins showed that position 226 of these isolates contained glycine instead of leucine, suggesting that these three isolates differ from H9N2 AIV strains isolated from human infections.     

一株鹅源H5N2亚型高致病性禽流感病毒的分离鉴定及生物学特性分析

分离到一株鹅源 H5N2亚型高致病性禽流感病毒,SPF鸡静脉接种致病指数为2.99,但鸭子对该病毒不敏感．病毒感染小鼠后不致病,但能够在肺内有效复制,表明其具有感染哺乳动物的潜在风险．血凝素(hemagglutinin, HA)蛋白裂解位点上插入有多个连续的碱性氨基酸(-RRRKKR-),从分子上证实这是一株高致病性禽流感病毒．核酸序列比较分析表明,分离的流感病毒HA基因与A/chicken/Hubei/489/2004 (H5N1)同源率达到99.4%,神经氨酸酶(neuraminidase, NA)基因与A/chicken/Jilin/53/01(H9N2)同源率达到99.8%;氨基酸水平上,HA与2004年分离到的A/chicken/Hubei/489/2004(H5N1)、A/swan/Guangxi/307/2004(H5N1)、A/wildduck/Guangdong/314/　2004(H5N1)和A/chicken/Henan/210/2004(H5N1)同源率均为99.3%,NA 与A/chicken/Jilin/53/01(H9N2)同源率为99.6%．进化树分析结果表明,该流感病毒分离株可能是由H5N1和H9N2两个亚型病毒重排而来．     

2017–2019年我国南方地区高致病性H5N6亚型禽流感病毒血凝素蛋白分子特征分析

【背景】自2014年以来,H5N6禽流感病毒在我国家禽和活禽市场持续进化,成为人类和动物健康的重大威胁。【目的】对2017-2019年中国南方地区93株高致病性H5N6禽流感病毒的HA基因进行分子进化分析。【方法】接种9-11日龄鸡胚分离核酸检测阳性的H5N6标本,运用下一代测序平台对病毒分离物进行全基因组测序,从NCBI和GISAID数据库下载参考序列,利用BLAST、MEGA6.1及Clustal X等软件进行序列分析。【结果】2017-2019年,从189份江苏省H5亚型禽类/环境标本和1名H5N6患者咽拭子标本中共分离到43株病毒,完成了33株H5N6病毒的全基因组测序。下载网上同时期中国其他地区流行的H5N6毒株序列,对总计93株H5N6病毒的HA基因进行分子进化分析。93株H5N6病毒中有78株属于Clade 2.3.4.4h,9株病毒属于Clade 2.3.4.4e,4株H5N6病毒属于Clade 2.3.4.4b,1株属于Clade 2.3.4.4f,1株属于Clade 2.3.4.4g。所有93株病毒HA蛋白的裂解位点含有多个碱性氨基酸,表明它们都属于高致病性禽流感病毒。所有93株病毒HA蛋白的Q222和G224位氨基酸没有发生突变,保留了禽类受体α2-3半乳糖苷唾液酸(SAα2-3Gal)结合特性;158位点丧失糖基化,同时124位出现一个新的潜在糖基化位点。【结论】2017-2019年间中国南方地区H5N6病毒进化活跃,具有明显的基因多样性,需要加强对病毒分子进化的监测。     

表达H5N1亚型禽流感病毒HA蛋白的重组鼠白血病病毒的特性

通过反转录 聚合酶链式反应 (RT PCR)扩增了H5N1亚型鹅源禽流感病毒 (AIV)完整的血凝素 (HA)基因并进行了克隆与鉴定。序列测定结果已经登陆GenBank ,登陆号为AY6 394 0 5。序列分析表明所扩增的HA基因开放性阅读框架 (ORF)由170 7个核苷酸组成 ,共编码 5 6 8个氨基酸 ,裂解位点的氨基酸组成为RKKR↓GLF ,含连续的碱性氨基酸 ,具有高致病性AIVHA基因裂解位点的特征。构建了含HA基因的真核表达载体pcDNA HA ,通过与鼠白血病病毒 (MuLV)假病毒构建体系的两种质粒pHIT6 0和pHIT111共转染人胚肾细胞 2 93T ,4 8h后收集假病毒上清 ,超离后通过Western blot证明HA蛋白能够在假病毒颗粒表面表达 ,表明HA能够整合到此病毒粒子表面。通过感染 2 93T、COS 7和NIH3T3三种不同的靶细胞 ,证实所构建的假病毒粒子具有感染性和泛嗜性。本研究成功构建了具有感染性的MuLV HA假病毒体系 ,为研究鹅源禽流感病毒侵入细胞的机理及其组织嗜性的变异提供一种新方法。     

家禽市场污水来源的H5N1亚型禽流感病毒NS基因分析

对长沙市家禽市场污水来源的H5N1亚型禽流感病毒(Avian influenza viruses,AIV)的非结构蛋白(Non-structural,NS)基因进行进化和分子特征分析,探讨污水中H5N1病毒的传播风险。9份家禽市场环境污水H5N1亚型AIV标本进行NS基因TA克隆测序,测序结果利用Lasergene和Mega5软件进行氨基酸(amine acid,aa)比对和进化树分析。共得到8个阳性克隆,进化树构建显示8个H5N1的NS基因均属于A亚群,其编码的NS1和NS2蛋白与A亚群代表株(A/chicken/Hubei/w h/1999)aa同源性分别为90.1%～92.5%和91.0%～92.6%,8个H5N1的NS1和NS2aa之间的同源性分别为93.8%～100.0%和98.4%～100.0%。8个H5N1的NS1蛋白均具有缺失80～84位aa、C末端携带有ESEV的PL基序和第92位aa为E的高致病性分子特征。家禽市场污水来源的H5N1亚型AIV的NS基因具有高致病性的分子特征,这种基因特征表明污水可能传播H5N1病毒。     

H9与H5亚型禽流感病毒血凝素基因的快速鉴别

建立一步法RT-PCR检测方法,对禽流感病毒(Avian influenza virus,AIV)的血凝素(Hemagglutinin,HA)分型进行了研究。参照AIV的HA基因序列设计1对引物,对H9和H5亚型AIV进行了扩增,产物大小分别为579bp和177bp。经测试,该引物不与新城疫病毒等鸡的其它传染性病原及鸡肌肉组织的核酸发生交叉反应。敏感性分析发现,从50pg的AIV总RNA中亦能扩增到目的条带。结果表明,此次利用1对引物建立的一步法RT-PCR方法简便适用,可以在一次反应中同时将H9和H5亚型AIV进行快速检测和分型。另外,两个亚型的扩增产物均包含了HA裂解位点在内的基因序列,可通过测序推导氨基酸顺序以预测H5或H9亚型禽流感病毒的潜在毒力。     

B cell epitopes in the intrinsically disordered regions of neuraminidase and hemagglutinin proteins of H5N1 and H9N2 avian influenza viruses for peptide-based vaccine development

Avian influenza viruses (AIV) are very active in several parts of the globe and are the cause of huge economic loss for the poultry industry and also human fatalities. Three dimensional modeling was carried out for neuraminidase (NA) and hemagglutinin (HA) proteins of AIV. The C-score, estimated TM-Score, and estimated root-mean-square deviation (RMSD) score for NA of H5N1 were −1.18, 0.57 ± 0.15, and 9.8 ± 7.6, respectively. The C-score, estimated TM-Score, and estimated RMSD score for NA of H9N2 were −1.43, 0.54 ± 0.15, and 10.5 ± 4.6, respectively. The C-score, estimated TM-Score, and estimated RMSD score for HA of H5N1 were −0.03, 0.71 ± 0.12, and 7.7 ± 4.3, respectively. The C-score, estimated TM-Score, and estimated RMSD score for HA of H9N2 were −0.57, 0.64 ± 0.13, and 8.9 ± 4.6, respectively. Intrinsically disordered regions were identified for the NA and HA proteins of H5N1 and H9N2 with the use of PONDR program. Linear B cell epitope was predicted using BepiPred 2 program for NA and HA of H5N1 and H9N2 avian influenza strains. Discontinuous epitopes were predicted by Discotope 2 program. The linear epitopes that were considered likely to be immunogenic and within the intrinsically disordered region for the NA of H5N1 was TKSTNSRSGFEMIWDPNGWTGTDSSFSVK, and for H9N2 it was VGDTPRNDDSSSSSNCRDPNNERGAP. In the case of HA of H5N1, it was QRLVPKIATRSKVNGQSG and ATGLRNSPQRERRRKK; for H9N2 it was INRTFKPLIGPRPLVNGLQG and SLKLAVGLRNVPARSSR. The discontinuous epitopes of NA of H5N1 and H9N2 were identified at various regions of the protein structure spanning from amino acid residue positions 90 to 449 and 107 to 469, respectively. Similarly, the discontinuous epitopes of HA of H5N1 and H9N2 were identified in the amino acid residue positions 27 to 517 and 136 to 521, respectively. This study has identified potential and highly immunogenic linear and conformational B-cell epitopes towards developing a vaccine against AIV both for human and poultry use.     

Molecular determinants within the surface proteins involved in the pathogenicity of H5N1 influenza viruses in chickens

Although it is established that the cleavage site and glycosylation patterns in the hemagglutinin (HA) play important roles in determining the pathogenicity of H5 avian influenza viruses, some viruses exist that are not highly pathogenic despite possessing the known characteristics of high pathogenicity (i.e., their HA contains multiple basic amino acids at the cleavage site and has glycosylation patterns similar to that of the highly pathogenic H5 viruses). Currently little is known about the H5N1 viruses that fall into this intermediate category of pathogenicity. We have identified strains of H5N1 avian influenza viruses that have markers typical of high pathogenicity but distinctly differ in their ability to cause disease and death in chickens. By analyzing viruses constructed by reverse-genetic methods and containing recombinant HAs, we established that amino acids 97, 108, 126, 138, 212, and 217 of HA, in addition to those within the cleavage site, affect pathogenicity. Further investigation revealed that an additional glycosylation site within the neuraminidase (NA) protein globular head contributed to the high virulence of the H5N1 virus. Our findings are in agreement with previous observations that suggest that the activities of the HA and NA proteins are functionally linked.     

Isolation and characterization of avian influenza viruses, including highly pathogenic H5N1, from poultry in live bird markets in Hanoi, Vietnam, in 2001

Since 1997, outbreaks of highly pathogenic (HP) H5N1 and circulation of H9N2 viruses among domestic poultry in Asia have posed a threat to public health. To better understand the extent of transmission of avian influenza viruses (AIV) to humans in Asia, we conducted a cross-sectional virologic study in live bird markets (LBM) in Hanoi, Vietnam, in October 2001. Specimens from 189 birds and 18 environmental samples were collected at 10 LBM. Four influenza A viruses of the H4N6 (n = 1), H5N2 (n = 1), and H9N3 (n = 2) subtypes were isolated from healthy ducks for an isolation frequency of over 30% from this species. Two H5N1 viruses were isolated from healthy geese. The hemagglutinin (HA) genes of these H5N1 viruses possessed multiple basic amino acid motifs at the cleavage site, were HP for experimentally infected chickens, and were thus characterized as HP AIV. These HA genes shared high amino acid identities with genes of other H5N1 viruses isolated in Asia during this period, but they were genetically distinct from those of H5N1 viruses isolated from poultry and humans in Vietnam during the early 2004 outbreaks. These viruses were not highly virulent for experimentally infected ducks, mice, or ferrets. These results establish that HP H5N1 viruses with properties similar to viruses isolated in Hong Kong and mainland China circulated in Vietnam as early as 2001, suggest a common source for H5N1 viruses circulating in these Asian countries, and provide a framework to better understand the recent widespread emergence of HP H5N1 viruses in Asia.     

我国部分禽流感病毒H5N1之HA序列变异演化分析

从GenBank上获得我国人(Homo sapiens)、家禽和野鸟42株H5N1亚型禽流感病毒的HA基因核酸序列,利用DNAStar分析HA蛋白关键位点氨基酸残基的变化,比较HA基因核苷酸序列同源性,构建遗传进化树.探讨我国部分人、家禽和野鸟H5N1病毒基因的遗传进化关系.序列分析结果表明:禽流感病毒H5N1亚型的HA基因持续地发生着变异,但并非以均一速度进行,时间间隔愈长,核苷酸同源性愈低;我国同一地区或临近地区,当年或前后两年发生的人及家禽感染的禽流感病毒高度同源.推测我国部分人发生的禽流感可能是通过家禽感染的;候鸟的迁徙在传播病毒过程中所起的作用有待深入探讨.     

禽流感病毒A/Chicken/Guangdong/SS/94(H9N2)HA基因的克隆及序列分析

禽流感是由A型流感病毒引起的禽的一种疾病综合症.1878年首次在意大利爆发流行,当时称该病为"鸡瘟".之后,许多国家和地区都有该病的报道,包括美国、英国、澳大利亚、爱尔兰、比利时、荷兰、法国、俄罗斯、加拿大、以色列、匈牙利、日本、中国(包括香港)等[1-3].     

1株H6N6亚型禽流感病毒分子遗传特性分析

本研究采用无特定病原体(specific pathogen free,SPF)鸡胚,从某活禽市场环境中分离出1株H6N6亚型禽流感病毒(A/environment/Zhenjiang/zj18/2013,en/zj18)。通过二代测序技术进行全基因组测序,通过BLASTn 进行同源性检索,并采用MEGA5.0软件构建系统发生树。基因进化树分析表明,分离株en/zj18的所有8个基因节段(PB2、PB1、PA、HA、NP、NA、M和NS)均与近年来中国华东地区流行的H6N6亚型禽流感病毒的相应基因位于同一进化分支,与参考株的核苷酸同源性达96.7%～99.6%。分离株en/zj18的HA蛋白裂解位点为PQIETR↓GL,是低致病性禽流感病毒的分子特征。HA蛋白上关键受体结合位点190和228位(按H3亚型的HA蛋白序列排序)氨基酸分别是E和G,理论上更易与α2,3-半乳糖苷唾液酸受体结合。结果提示,需加强活禽市场禽流感病毒的持续监测,从而为有效应对禽流感病毒对公共卫生的持续威胁提供科学依据。     

鸭源H9N2AIV血凝素基因序列比较

为明确国内外鸭源H9N2亚型禽流感病毒(Avian influenza virus,AIV)血凝素基因(hemagglutinin,HA)的遗传进化关系、血凝素蛋白裂解位点的氨基酸结构特征和血凝素蛋白受体结合位点的氨基酸变异特征,本研究选取GenBank中登录鸭源H9N2亚型AIV HA基因,通过MEGA4.1进行比对和分析,并绘制其遗传进化树。结果表明,鸭源H9N2亚型AIV在遗传进化上分为2大谱系:即Ck-Bj-1-94-like和North-Ame-like,中国大陆鸭源H9N2亚型AIV和亚欧美其它国家鸭源H9N2亚型AIV在遗传进化上分居完全不同的谱系,相互之间遗传进化关系较远。从血凝素受体结合位点看,亚欧美国家鸭源H9N2亚型AIV在第183、190和226位点的氨基酸均为鸭源AIV经典H、E和Q,且高度保守。但中国大陆地区H9N2亚型AIV第183位为N;第190位为A or V or T,与中国大陆鸡源H9N2亚型AIV一致;第226位中国鸭源H9N2亚型AIV有相当一部分为L,且近年福建省H9N2亚型AIV分离株在此处均为L。提示我们,中国大陆地区H9N2亚型AIV鸭鸡和鸡鸭相互交叉感染较为普遍。     

神经氨酸酶茎部氨基酸缺失对H5N1亚型禽流感病毒生物学特性的影响

近年来H5N1亚型禽流感病毒(AIV)神经氨酸酶(NA)茎部15~20个氨基酸的自发缺失时有报道,突变对于AIV生物学特性的影响还没有得到系统研究。应用反向遗传操作技术,拯救获得5株具有不同NA茎部长度的H5N1/PR8重组AIV。重组病毒的内部基因和血凝素(HA)基因来源相同,NA基因来源不同,并在NA茎部进行20个氨基酸的删除或添加突变。通过研究其生物学特性发现,5株重组病毒在SPF鸡胚中繁殖良好,其EID50、MDT和平均病毒滴度相似;NA茎部长短影响病毒的解凝能力,长茎病毒红细胞解脱能力比短茎病毒强;NA茎部15或20个氨基酸删除突变提高了重组病毒在MDCK细胞上的繁殖能力,短茎病毒释放出的病毒粒子数量是长茎病毒的10~100倍,释放时间提前6~10h,短茎病毒在MDCK细胞上形成的空斑也明显比长茎病毒的空斑大。实验结果揭示了AIV NA茎部氨基酸缺失突变的生物学意义,NA茎部15或20个氨基酸删除突变增强了AIV的细胞适应性,可能与现阶段H5N1亚型AIV宿主范围进一步扩大有关。利用反向遗传技术成功拯救了5株H5N1/PR8重组流感病毒,为流感病毒基因功能研究和重组疫苗研究建立了技术平台。通过对AIV NA茎部氨基酸的删除突变提高了病毒在MDCK细胞上的繁殖产量,为流感病毒细胞苗的生产提供了新的思路。     

Use of a mammalian internal ribosomal entry site element for expression of a foreign protein by a transfectant influenza virus.

The ribonucleoprotein transfection system for influenza virus allowed us to construct two influenza A viruses, GP2/BIP-NA and HGP2/BIP-NA, which contained bicistronic neuraminidase (NA) genes. The mRNAs derived from the bicistronic NA genes have two different open reading frames (ORFs). The first ORF encodes a foreign polypeptide (GP2 or HGP2) containing amino acid sequences derived from the gp41 protein of human immunodeficiency virus type 1. The second ORF encodes the NA protein; its translation is achieved via an internal ribosomal entry site which is derived from the 5' noncoding region of the human immunoglobulin heavy-chain-binding protein mRNA. The GP2 (79 amino acids) and HGP2 (91 amino acids) polypeptides are expressed in cells infected with the corresponding transfectant virus. The HGP2 polypeptide, which contains transmembrane and cytoplasmic domains identical to those of the hemagglutinin (HA) protein of influenza A/WSN/33 virus, is packaged into virus particles. This novel influenza virus system involving an internal ribosomal entry site element may afford a way to express a variety of foreign genes in mammalian cells.