我国H7N2亚型禽流感病毒CK/HB/1/02株分离鉴定

从鸡组织中获得了一株分离物,能凝集鸡红细胞,经负染后电镜观察可见球形、外被囊膜的病毒颗粒,直径约90～100nm;经血凝抑制和神经氨酸酶抑制试验鉴定为H7N2亚型禽流感病毒(Avian in fluenza virus,AIV),命名为A/Chicken/Hebei/1/2002(H7N2)(简称CK/HB/1/02).将该病毒接种SPF鸡,测得静脉接种致病指数(IVPI)为0.00,剖检可见实验鸡多种组织器官有出血性变化,判为低致病力AIV;接种后7d从实验鸡泄殖腔棉拭中回收到病毒,并在血清中检测到H7亚型AIV抗体.经RT-PCR扩增了病毒HA1基因片段(约1.1kb),测定其核苷酸序列并与GenBank中的序列比较.结果表明,该病毒的HA1基因序列与AIV标准株A/Afri.Star./Eng Q/79(H7N1)的HA1基因同源性最高,为99.4%;与以色列和意大利H7N2AIV的同源性较高,为96.8%～98.2%;与美国H7N2病毒的同源性很低,约为81.0%;其HA裂解位点的氨基酸序列为KGR-GLF-,符合低致病力AIV的特征.     

禽流感病毒分离株NS基因同源性及等位基因类型分析

目的　克隆测定国内具有代表性的禽流感病毒 (AIV)的非结构 (NS)蛋白基因核苷酸序列 ,分析其同源性和等位基因类型 ,为进一步探索禽流感NS蛋白抗体监测方法奠定基础。方法　经RT PCR扩增了国内 3株H9N2、2株H5N1、2株H7N2亚型AIV分离株的NS蛋白基因 ,并把扩增的基因片段克隆到pGEM T载体中测序 ,将测序结果与GenBank中的核苷酸序列进行同源性比较 ,绘制基因进化树。结果　经测序获得了各AIV分离株NS基因的完整编码序列。同源性分析表明 ,3株H9亚型AIV的NS基因之间的同源性为 96 %～ 98% ;两株H5亚型AIVNS基因同源性为 91 6 % ;两株H7亚型AIV的NS基因同源性为 98 9%。H5和H9亚型分离株的NS基因之间的同源性均高于 90 % ;而H7N2亚型分离株与其它两种亚型分离株的NS基因同源性约为 6 0 %～ 70 %。在AIVNS基因系统发育进化树中 ,H5、H9亚型分离株都处于等位基因A群内 ;3株H9亚型分离株的进化关系较近 ,与香港、广东的部分H5N1病毒株起源相同 ,而 2株H5病毒的NS基因则处于不同分枝内 ;2株H7亚型分离株的NS基因都处于等位基因B群内 ,进化关系较近。结论　这 7株国内AIV分离株的NS基因之间的同源性差异较大 ,约为 6 0 %～ 99% ,且包括A、B两种类型的等位基因     

番鸭源H6N6亚型禽流感病毒全基因组的分子特征

【目的】为了丰富水禽源禽流感病毒的分子流行病学资料,明确我国国内首次分离的番鸭源H6N6亚型禽流感(Avian influenza virus,AIV)病毒A/Muscovy Duck/Fujian/FZ01/2008(H6N6)(以下简称MD/FJ/F1/08)全基因组的分子特征,弄清该病毒的遗传进化特点。【方法】对其8个基因片段分别进行扩增和序列测定,并利用分子生物学软件对测序结果进行序列分析。【结果】MD/FJ/F1/08的HA裂解位点附近的氨基酸序列为PSMKVIV↓GL,为非连续的碱性氨基酸,其静脉接种指数(the intravenoys pathogenicity index,IVPI)为0.15,推测其为一株低致病力AIV。其HA基因、NP基因、M基因和PB2基因均与我国台湾分离株A/duck/Kingmen/E322/04(H6N2)该基因的核苷酸同源性最高,分别高达94.2%、95.7%、97.2%和95.6%,均处于同一遗传进化分支。其NA基因和我国远东分离株A/duck/Eastern China/01/2007(H4N6)同源性最高,达97.1%;其颈部有11个氨基酸的缺失(TNSTTTIINNN),为N6亚型神经氨酸酶基因中首次报道,在遗传进化上和H4N6亚型AIV的NA基因处于相同的分支。NS基因和香港地区分离株A/duck/HongKong/3600/99(H6N2)同源性最高,达96.1%;PB1和PA均与高致病性禽流感病毒株A/duck/HongKong/140/1998(H5N1)同源性最高,达95.6%和96.7%。且MD/FJ/F1/08的8基因与H6N6亚型流感病毒北美洲分离代表株均不处在同一遗传进化分支上,相互之间遗传关系较远。【结论】MD/FJ/F1/08可能是由H6N2、H4N6和H5N1等多亚型AIV基因重组而成。     

一株H5N1亚型禽流感病毒的分离与鉴定

2004年1月湖北宜昌某鸡场暴发疫病,从该鸡场濒死鸡肺组织中分离到了一株病毒,电镜切片观察到典型的禽流感病毒粒子;采用ELISA检测禽流感抗原为阳性;RT-PCR扩增HA、NA基因并测序,经BLAST分析,HA基因与A／Goose／Guangdong／1／96(H5N1)HA基因同源性为97％;NA基因与A／Goose／Guangdong／1／96(H5N1)NA基因同源性为96％,确定该分离株为禽流感病毒H5N1亚型(A／Chicken／Yichang／Lung-1／04(H5N1))。     

禽流感病毒H7N2血凝素HA1基因在大肠杆菌中的表达

目的　表达H7N2亚型禽流感病毒 (AIV)HA1基因 ,用于感染H7亚型禽流感病毒抗体的检测和HA1蛋白功能研究。方法　采用RT PCR方法对H7N2亚型AIVHA1基因进行扩增 ,将PCR产物克隆于pGEM T Easy载体 ,将该基因插入pGEX 4T 2中构建HA1基因原核表达载体 ,转化BL2 1大肠杆菌后 ,在IPTG诱导下表达HA1蛋白 ,Westernblot鉴定表达HA1蛋白。电洗脱方法纯化表达HA1蛋白 ,建立间接ELISA方法 ,对感染AIVH7、H9、H5亚型AIV阳性血清进行检测。结果　成功克隆H7N2亚型AIV的HA1基因 ,其核苷酸序列长度 96 6bp ,编码 32 2个氨基酸残基。构建HA1基因原核表达载体在大肠杆菌内表达出约 6 1× 10 3的HA1融合蛋白。Westernblot和ELISA方法鉴定表明 :表达HA1蛋白与感染H7亚型AIV鸡血清有反应 ,与H5、H9亚型AIV阳性血清没有反应。结论　本研究在大肠杆菌中成功表达了H7N2亚型AIVHA1基因蛋白 ,具有与感染H7亚型AIV阳性血清反应原性 ,不与H5和H9亚型AIV感染阳性血清发生反应。     

利用反向遗传技术产生8基因全禽源流感病毒疫苗候选株

利用反向遗传技术将含有A/Chicken/Shanghai/F/98(H9N2)株禽流感病毒(avian influenza virus,AIV)的6个内部基因与H5N1亚型AIV的2个表面基因HA和NA共转染COS-1细胞,产生了6 2全禽源的重配AIV。将H5N1亚型AIV的HA基因经基因突变致弱,然后将A/Chicken/Shanghai/F/98(H9N2)AIV的6个内部基因的cD-NA和以上致弱的禽源HA基因及NA基因的cDNA分别克隆到转录/表达载体pHW2000中,构建成8个转录/表达质粒。将8个质粒共转染COS-1细胞,24h后收获细胞及上清接种SPF鸡胚,72~90h后鸡胚死亡,收取鸡胚尿囊液进行血凝、血凝抑制试验、序列分析、病毒致病性试验和动物免疫保护试验,最终证实产生了致弱的全禽源AIV疫苗候选株。     

H5N1亚型禽流感病毒A/duck/Shandong/093/2004株的全基因克隆及序列分析

应用流感病毒通用引物［4］和H5N1亚型禽流感（Avian influenza virus, AIV）的型特异性引物,成功的扩增出H5N1亚型禽流感病毒A/duck/Shandong/093/2004株（简称A/D/SD/04）的全基因序列（包括5′和3′端的非编码区序列）。A/D/SD/04的基因组核苷酸全序列与18株网上公布的禽流感基因序列进行比较和分析,结果与4株鸭源H5N1的5～7个基因具99%以上的同源性;与14株H5N1有至少一个以上内部基因同源性在95%以上。与H9亚型AIV代表株A/Quail/Hongkong/G1/97（简称G1株）和A/Chicken/Beijing/1/94（简称BJ94）比较,除了非结构基因（Nonstructural gene, NS）与G1株的同源性为95.3%外,其余基因均在36.6%～92.1%之间。说明A/D/SD/04没有H9N2基因的直接整合,是H5N1毒株在自然界的重组株。推导的HA氨基酸序列分析,A/D/SD/04 的血凝素（Heamgglutinin,HA）裂解位点与比较的16株AIV的序列一致,是高致病性禽流感的分子特征（PQRERRRKKR/G）,第226位氨基酸是对禽类和哺乳细胞均具有亲嗜性的蛋氨酸（Met）。神经氨酸酶（Neuraminidase, NA）在第48位氨基酸（颈部）后有20个氨基酸的缺失,但非结构蛋白（NS）没有在79～84氨基酸发生缺失。碱性聚合酶2（PB2）的627位氨基酸是亲禽类细胞的谷氨酸（Glu, E）。结合生物学特性和分子特征,A/D/SD/04对小鼠的致病力是由多种因素决定,其可能是一株对鸡高度致病,并逐渐获得对哺乳动物致病能力的中间重组病毒。     

水禽流感病毒分离株A/Duck/Yangzhou/233/02(H6N2)膜蛋白基因遗传进化分析

采用常规的血清学收验和特异性RT-PCR方法对华东地区家养水禽中流感病毒的带毒状况进行两年多的监测,分离鉴定出多株H6亚型禽流感病毒。对其中的一株A/Duck/Yangzhou/233/02(H6N2)(简称DkYZ23302)(H6N2)的表面膜蛋白基因进行了序列测定,并与GenBank中收录的其它序列进行了比较,遗传进化结果表明DkYZ23302的血凝素基因(HA)与近年香港分离的鸭源毒株DkHK346199(H6N1)、中国台湾鸡源毒株CkTaiwanna398的亲缘关系最近;而神经氨酸酶基因(NA)遗传进化分析结果表明DkYZ23302(H6N2)的NA基因起源于禽源H9N2亚型流感病毒,这可能是不同亚型禽流感病毒在水禽体内发生基因重配的结果。DkYZ23302(H6N2)的HA推导的氨基酸剪切位点序列为P-Q-I-E-T-R-D,为典型低致病性禽流感病毒的特征序列,与对SPF鸡的致病力试验相吻合。     

利用8质粒系统拯救A/Chicken/Shanghai/F/98（H9N2）株禽流感病毒

应用反向遗传技术将含有1998年中国大陆分离株H9N2亚型禽流感病毒(Avianinfluenzavirus,AIV)的8个基因片段的质粒共转染COS_1细胞,产生了与野生病毒生物学特性相同的H9N2亚型AIV。将A Chicken Shanghai F 98(CK SH F 98)株H9N2亚型AIV的8个基因组cDNA分别克隆到polⅠ_polⅡ转录 表达载体pHW2 0 0 0中,构建成8个转录表达载体重组质粒。将这8个质粒共转染COS_1细胞,2 4h后收获细胞及上清接种SPF鸡胚,4 8h后收取鸡胚尿囊液继续进行鸡胚传代,产生能致死鸡胚的病毒。经血凝、血凝抑制试验、序列分析和电镜观察,证实产生了CK SH F 98(H9N2 )株AIV。     

2017年河北省蛋鸡养殖场H9N2亚型禽流感病毒的遗传演化和抗原性分析

【背景】H9N2亚型禽流感病毒在鸡群中广泛流行,引起巨大损失。【目的】了解河北省蛋鸡养殖场H9N2亚型禽流感病毒(avian influenza virus,AIV)的基因序列和抗原性的变异情况,为该病原的科学防控提供理论依据。【方法】于2017年从河北省部分蛋鸡养殖场分离鉴定出7株H9N2亚型AIV,对其HA基因进行序列测定,并进行遗传演化、关键氨基酸位点及抗原性分析。【结果】7株分离毒株HA基因同源性在95.5%?97.2%之间;与2016年前的流行毒株相比,分离病毒HA裂解位点均为典型低致病性AIV特征,在受体结合区域出现变异,潜在糖基化位点无明显差异;抗原分析结果显示分离毒株与早期分离株相比抗原性发生了变异,形成了新的抗原群;抗原性相关位点分析显示,分离毒株在9个位点发生了较为明显的突变,可能是导致抗原性变异的分子基础。【结论】河北省蛋鸡养殖场H9N2亚型AIV中的流行毒株在关键功能区发生基因突变,并且抗原性发生变异,提示应持续监测H9N2亚型AIV的遗传变异情况,并及时更换疫苗株。     

Isolation and identification of swine influenza recombinant A/Swine/Shandong/1/2003(H9N2) virus

Ten influenza virus isolates were obtained from infected pigs from different places in Shandong province showing clinical symptoms from October 2002 to January 2003. All 10 isolates were identified in China's National Influenza Research Center as influenza A virus of H9N2 subtype. The complete genome of one isolate, designated A/Swine/Shandong/1/2003(H9N2), was sequenced and compared with sequences available in GenBank. The results of analyses indicated that the sequence of A/Swine/Shandong/1/2003(H9N2) was similar to those of several chicken influenza viruses and duck influenza viruses recently prevalent in South China. According to phylogenetic analysis of the complete gene sequences, A/Swine/Shandong/1/2003(H9N2) possibly originated from the reassortment of chicken influenza viruses and duck influenza viruses. It was found that the amino acid sequence at the HA cleavage site in Sw/SD/1/2003 is R-S-L-R-G, differing clearly from that of other H9N2 subtype isolates of swine influenza and avian influenza, which is R-S-S-R-G.     

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．     

A型猪流感病毒山东分离株鉴定及其HA基因序列分析

从山东各地疑似流感发病猪分离到10株流感病毒,经国家流感中心鉴定均为A型流感病毒H9N2亚型。将其中一株Sw／SD／1／2003(H9N2)的血凝素全基因(HA)进行克隆与测序,与GenBank收录的其它猪流感和禽流感H9N2亚型的HA基因进行比较,发现Sw／SD／1／2003(H9N2)的血凝素基因在核苷酸序列方面同广西1999年分离的禽流感毒株Ck／GX／99(H9N2)和2000年云南分离的禽流感毒株Ck／YN／2000(H9N2)的同源性最高;进化树分析表明Sw／SD／1／2003(H9N2)起源于禽源的H9N2亚型流感病毒;Sw／SD／1／2003的HA氨基酸裂解位点与其他H9N2亚型不问,Sw／SD／1／2003的HA氨基酸裂解位点是R-S-L-R-G,而其它猪流感和禽流感H9N2亚型都是R-S-S-R-G。     

Selection of a single amino acid substitution in the hemagglutinin molecule by chicken eggs can render influenza A virus (H3) candidate vaccine ineffective.

This study investigated whether a single amino acid change in the hemagglutinin (HA) molecule influenced the efficacy of formalin-inactivated influenza A (H3N1) vaccine candidates derived from high-growth reassortants between the standard donor of high-yield genes (A/PR/8/34 [H1N1]) and host cell variants generated from the same clinical isolate (A/Memphis/7/90 [H3N2]) by passage in embryonated chicken eggs. Two clones of the isolate generated by growth in eggs differed from the parent virus (represented by an MDCK cell-grown counterpart) solely by the presence of Lys (instead of Glu) at position 156 or Ile (instead of Ser) at position 186 in the HA1 subunit. The protective efficacy of egg-grown HA Lys-156 and HA Ile-186 reassortant variants was compared with that of the MDCK cell-grown reassortant vaccine. Classically, antibody titers in serum have been used to demonstrate vaccine efficacy. Here, parameters of B-cell responsiveness were monitored, including the kinetics, character, and localization of the primary antibody-forming cell (AFC) response and the development of B-cell memory in lymphoid tissues associated with the priming site (spleen) and responsive to pulmonary challenge with infectious virus (upper and lower respiratory tract lymph nodes). We show that the egg-grown HA Lys-156 variant induced an AFC profile vastly different from that elicited by the other two reassortant vaccines. The vaccine was poorly immunogenic; it induced antibodies that were cross-reactive prior to challenge but which, postchallenge with a lethal dose of the MDCK cell-grown reassortant virus, were targeted primarily to the HA Lys-156 variant, were of the immunoglobulin M isotype, were nonprotective, and were derived from the spleen. In contrast, the egg-grown HA Ile-186 variant was remarkably like the MDCK cell-grown virus in that protective immunoglobulin G antibodies were unaffected by the Ile-186 substitution but poorly recognized HA with Lys-156. Furthermore, memory AFC responsiveness was localized to regional lymphoid tissue in the upper respiratory tract, where challenge HA was found. Thus, it is recommended that in the selection of vaccine candidates, virus populations with the egg-adapted HA Lys-156 substitution be eliminated and that, instead, egg-grown isolates which minimally contain Ile-186 be used as logical alternatives to MDCK cell-grown viruses.     

E190V substitution of H6 hemagglutinin is one of key factors for binding to sulfated sialylated glycan receptor and infection to chickens

Avian influenza viruses (AIVs) recognize sialic acid linked α2,3 to galactose (SAα2,3Gal) glycans as receptors. In this study, the interactions between hemagglutinins (HAs) of AIVs and sulfated SAα2,3Gal glycans were analyzed to clarify the molecular basis of interspecies transmission of AIVs from ducks to chickens. It was revealed that E190V and N192D substitutions of the HA increased the recovery of viruses derived from an H6 duck virus isolate, A/duck/Hong Kong/960/1980 (H6N2), in chickens. Recombinant HAs from an H6 chicken virus, A/chicken/Tainan/V156/1999 (H6N1), bound to sulfated SAα2,3Gal glycans, whereas the HAs from an H6 duck virus did not. Binding preference of mutant HAs revealed that an E190V substitution is critical for the recognition of sulfated SAα2,3Gal glycans. These results suggest that the binding of the HA from H6 AIVs to sulfated SAα2,3Gal glycans explains a part of mechanisms of interspecies transmission of AIVs from ducks to chickens.     

Complete Genome Sequence of a Novel Reassortant H11N2 Avian Influenza Virus Isolated from a Live Poultry Market in Eastern China

A/chicken/Nanjing/908/2009(H11N2) (CK908) was isolated from a live poultry market in Nanjing, China. Using PCR and sequencing analysis, we obtained the complete genome sequences of the CK908 virus. The sequence analysis demonstrated that this H11N2 virus was a novel reassortant AIV whose PB1, PB2, PA, HA, NP, NA, M, and NS genes originated from H9N2, H7N7, H5N2, H11N8, H3N6, H6N2, H1N1, and H5N1, respectively. Knowledge regarding the complete genome sequences of the CK908 virus will be useful for epidemiological surveillance.     

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     

A new generation of modified live-attenuated avian influenza viruses using a two-strategy combination as potential vaccine candidates

In light of the recurrent outbreaks of low pathogenic avian influenza (LPAI) and highly pathogenic avian influenza (HPAI), there is a pressing need for the development of vaccines that allow rapid mass vaccination. In this study, we introduced by reverse genetics temperature-sensitive mutations in the PB1 and PB2 genes of an avian influenza virus, A/Guinea Fowl/Hong Kong/WF10/99 (H9N2) (WF10). Further genetic modifications were introduced into the PB1 gene to enhance the attenuated (att) phenotype of the virus in vivo. Using the att WF10 as a backbone, we substituted neuraminidase (NA) for hemagglutinin (HA) for vaccine purposes. In chickens, a vaccination scheme consisting of a single dose of an att H7N2 vaccine virus at 2 weeks of age and subsequent challenge with the wild-type H7N2 LPAI virus resulted in complete protection. We further extended our vaccination strategy against the HPAI H5N1. In this case, we reconstituted an att H5N1 vaccine virus, whose HA and NA genes were derived from an Asian H5N1 virus. A single-dose immunization in ovo with the att H5N1 vaccine virus in 18-day-old chicken embryos resulted in more than 60% protection for 4-week-old chickens and 100% protection for 9- to 12-week-old chickens. Boosting at 2 weeks posthatching provided 100% protection against challenge with the HPAI H5N1 virus for chickens as young as 4 weeks old, with undetectable virus shedding postchallenge. Our results highlight the potential of live att avian influenza vaccines for mass vaccination in poultry.     

Development of an immunochromatographic kit for rapid diagnosis of H5 avian influenza virus infection

Highly pathogenic avian influenza (HPAI) caused by the H5N1 subtype has given rise to serious damage in poultry industries in Asia. The virus has expanded its geographical range to Europe and Africa, posing a great risk to human health as well. For the control of avian influenza, a rapid diagnosis by detecting the causative virus and identifying its subtype is essential. In the present study, a rapid diagnosis kit combining immunochromatography with enzyme immunoassay which detects the H5 HA antigen of influenza A virus was developed using newly established anti-H5 HA monoclonal antibodies. The present kit specifically detected all of the H5 influenza viruses tested, and did not react with the other HA subtypes. H5 HA antigens were detected from swabs and tissue homogenates of chickens infected with HPAI virus strain A/chicken/Yamaguchi/7/04 (H5N1) from 2 days post inoculation. The kit showed enough sensitivity and specificity for the rapid diagnosis of HPAI.     

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.