甲型H1N1流感疫苗中神经氨酸酶含量双抗体夹心ELISA检测方法的建立与应用

目的建立甲型H1N1流感疫苗中神经氨酸酶(Neuraminidase,NA)含量双抗体夹心ELISA检测方法,并对其进行验证及初步应用。方法以HCA3通用抗体作为包被抗体,N1抗血清作为显示抗体建立双抗体夹心ELISA,确定线性范围,验证该方法的准确度及精密度,并用该方法对3个厂家共9批次甲型H1N1流感疫苗中的NA含量进行测定。结果 NA质量浓度在0~50 ng/m L时线性良好(r20.99);回收率为97.54%~104.02%;实验内CV10%,实验间CV15%。不同厂家的甲型H1N1流感疫苗中NA含量差异很大,NA与HA(血凝素)的百分比最高达到29.85%,而最低的只有7.00%;而同一厂家各批次疫苗间的NA与HA的比例较为稳定。结论成功建立了甲型H1N1流感疫苗中NA含量双抗体夹心ELISA检测方法,该法具有良好的线性及灵敏度,准确度和精密度高,能满足甲型H1N1流感疫苗NA含量的检测需求。     

甲型N9亚型流感病毒神经氨酸酶基因进化分析

通过对甲型N9亚型流感病毒神经氨酸酶(NA)核苷酸进化趋势的研究,进而探寻2013年新型H7N9亚型禽流感病毒产生的根源。本次研究选取美国国立生物技术信息中心(NCBI)的甲型N9亚型流感病毒的NA序列,采用生物软件ClustalX 2.0和MEGA 6.0建立进化树形图。对其欧亚分支,采用BEAST软件2.1.2和Datamonkey interface在线软件,计算和分析选择压力和进化速率。采用Bioedit软件对NA的氨基酸置换熵值计算并分析。系统进化树表明2013年新型H7N9亚型禽流感病毒可划分至现代欧亚分支之内,并且该分支的每位点每年核苷酸置换速率均值为3.8354×10-3,选择压力dN/dS均值为0.140413。16、19、40、53、81、84、112、256、335、359和401的氨基酸变异位点熵值0.5。研究分析表明2013年新型H7N9亚型禽流感病毒的NA片段基因可能来自甲型N9亚型流感病毒逐步进化的结果,最早可追溯到1996年的A/duck/Siberia/700/1996(H11N9)流感毒株,新型H7N9亚型禽流感病毒来源不是来自外界环境压力引起突变的结果。     

A/H7N9流感病毒神经氨酸酶进化分析

世界卫生组织报道2013年在中国出现首例人感染H7N9流感病毒病例,这在我国一定的范围内造成了危害,引起了恐慌,因此利用生物信息技术对其进行研究显得十分必要。神经氨酸酶NA是流感病毒最重要的抗原之一,也是抗流感药物的重要作用靶点。从美国国家生物技术信息中心(National Center for Biotechnology Information,NCBI)数据库下载A/H7N9流感病毒NA基因核酸序列及其编码蛋白序列,利用MEGA5.0软件对核苷酸编码序列构建系统进化树,利用BioEdit软件进行比对,分别作核苷酸与氨基酸同源性计算,继而分析NA基因重要位点变异情况,结果显示H7N9流感病毒传播呈现一定的地域关系和时间关系,2013年流行的中国的毒株属于亚欧型,其NA茎区发生了比较明显的变异,这也许是该病毒感染人类的原因之一。这些分析结果对于研究H7N9流感病毒基因的进化关系和变异趋向具有重要的参考价值。     

H5N1亚型禽流感病毒神经氨酸酶基因的克隆与表达

根据已知H5N1亚型禽流感病毒神经氨酸酶基因(na)序列设计、合成克隆引物。自H5N1亚型病毒感染的鸡胚尿囊液中提取总RNA,反转录后采用高可信度DNA聚合酶(PyobestTMDNAPolymerase)扩增na基因,采用Invitrogen定向表达系统(ChampionTMpETdirectionalTOPOexpressionsystem)进行克隆表达,纯化获得N末端携带多聚组氨酸标签的重组神经氨酸酶,分子量约53.8kDa。分析重组NA的免疫反应性和免疫原性,结果表明:重组NA能与H5N1亚型病毒抗血清发生特异性结合,且其免异动物后能诱导机体产生特异性抗体,具有良好的抗原性。     

H5N1亚型禽流感病毒神经氨酸酶基因的克隆与表达

根据已知H5N1亚型禽流感病毒神经氨酸酶基因(na)序列设计、合成克隆引物.自H5N1亚型病毒感染的鸡胚尿囊液中提取总RNA,反转录后采用高可信度DNA聚合酶(PyobestTMDNAPolymerase)扩增na基因,采用Invitrogen定向表达系统(ChampionTM pET directional TOPO expression system)进行克隆表达,纯化获得N末端携带多聚组氨酸标签的重组神经氨酸酶,分子量约53.8kDa.分析重组NA的免疫反应性和免疫原性,结果表明重组NA能与H5N1亚型病毒抗血清发生特异性结合,且其免异动物后能诱导机体产生特异性抗体,具有良好的抗原性.     

流感病毒H1N1血凝素基因和神经氨酸酶基因在酵母菌中的表达

在成功克隆流感病毒H1N1全长HA(Hemagglulinin,HA)、NA(Neuramidinase,NA) 基因并测序的基础上,将部分基因序列克隆到表达载体pMETA上,构建了重组表达质粒pMETA/HA(52~1 557 bp)、pMETA/NA(121~1 263 bp),电转化真核酵母菌pMAD16,甲醇诱导表达,利用Ni2+亲和层析柱对重组蛋白进行纯化,并用Western blotting和ELISA方法检测其抗原性。SDS-PAGE显示重组蛋白在酵母菌中可以高效表达,蛋白纯度占总蛋白的95％以上,ELISA和Western blotting实验证实,重组蛋白具有良好的抗原性。成功克隆和表达了流感病毒H1N1 HA、NA基因序列,为流感病毒H1N1诊断试剂和疫苗的开发等进一步的研究提供了参考。     

用免疫信息学技术设计新型H1N1流感神经氨酸酶抗原表位肽

神经氨酸酶(NA)是一种具有唾液酸酶活性的流感毒粒表面糖蛋白,切断病毒HA与细胞膜上神经氨酸残基之间的连接,使病毒能够从宿主细胞表面释放.检测了新型H1N1流感NA基因核苷酸序列,用免疫信息学方法预测、筛选和鉴定B细胞表位;人工合成NA抗原多肽SE8和RE6,并免疫新西兰兔制备抗血清.两种抗血清具有体外中和新型H1N1流感病毒能力(微量中和实验),而且还具有拮抗血凝释放作用.根据2009年全球毒株NA基因序列检测和比对结果,发现多肽SE8和RE6序列未变异.实验揭示,多肽SE8和RE6可以作为新型H1N1流感候选多肽疫苗.     

H1N1型流感病毒神经氨酸酶的原核表达、纯化及免疫原性分析

目的：研究H1N1型流感病毒神经氨酸酶（NA）在原核系统中的表达、纯化方法及其免疫原性。方法：构建了大肠杆菌表达载体pET22b-NA,并转化了大肠杆菌BL21（DE3）;通过SP-Sepharose Fast Flow柱对重组NA进行分离纯化,并用Sephadex G-25柱对SP柱后获得的NA进行柱上复性;用不同剂量的重组NA免疫BALB/c小鼠,并检测其诱导产生的抗体滴度。结果：大肠杆菌表达的NA以包涵体形式存在,通过分离及柱上复性,纯化得到重组NA;NA抗原的免疫原性是剂量依赖的,随着剂量的增加,其免疫原性相应增强,3次免疫后,3μg NA诱导小鼠产生的抗体滴度最高,为1∶7000。结论：大肠杆菌表达的NA具有一定的诱导小鼠产生针对天然NA的抗体的能力,为流感病毒基因工程疫苗研究提供了初步线索。     

猪流感病毒H1N1血凝素基因和神经氨酸酶基因在大肠杆菌中的表达

克隆、表达和鉴定猪流感病毒H1N1 HA,NA基因序列,为制备抗体和基因工程疫苗打下基础。在成功克隆猪流感病毒H1N1全长HA、NA基因并测序的基础上,将部分基因序列克隆到表达载体pET32a(+)上,全基因序列克隆到表达载体pGEX4T-1上,构建了重组表达质粒pET32a(+)/HA(截短),pET32a(+)/NA(截短),pGEX4T-1/NA,转化大肠杆菌BL21/Rosetta,IPTG诱导表达,利用Ni2+亲和层析柱和GSTrap 4B亲和层析柱对重组蛋白进行纯化,并用Western Blotting和ELISA方法检测其抗原性。结果显示,重组蛋白在大肠杆菌中可以高效表达,SDS-PAGE显示其相对分子质量与预计大小一致。ELISA和Western blotting试验证实,重组蛋白具有良好的抗原性。本研究成功克隆和表达了猪流感病毒H1N1 HA、NA基因序列,为猪流感病毒H1N1诊断试剂和疫苗的开发等进一步的研究奠定了基础。     

基于分子对接技术筛选中草药中潜在的H1N1病毒神经氨酸酶抑制剂

甲型H1N1流感病毒是一种高度接触性急性呼吸道传染病,给人类健康造成了极大威胁。作为一个已经被证明的抗流感药物靶点,神经氨酸酶在流感病毒复制和传播中发挥重要作用,并且其活性中心的氨基酸组成高度保守。本研究中,我们使用分子对接技术筛选从中草药小分子数据库中筛选神经氨酸酶潜在的抑制剂,结果得到4个亲和力高于奥司他韦(Osel-tamivir)的化合物,并确定了他们的中草药来源。为从草药中提取,设计以及实验合成新的神经氨酸酶抑制剂提供了一定的依据和指导。     

Molecular distribution of amino acid substitutions on neuraminidase from the 2009 (H1N1) human influenza pandemic virus

The pandemic influenza AH1N1 (2009) caused an outbreak of human infection that spread to the world. Neuraminidase (NA) is an antigenic surface glycoprotein, which is essential to the influenza infection process, and is the target of anti-flu drugs oseltamivir and zanamivir. Currently, NA inhibitors are the pillar pharmacological strategy against seasonal and global influenza. Although mutations observed after NA-inhibitor treatment are characterized by changes in conserved amino acids of the enzyme catalytic site, it is possible that specific amino acid substitutions (AASs) distant from the active site such as H274Y, could confer oseltamivir or zanamivir resistance. To better understand the molecular distribution pattern of NA AASs, we analyzed NA AASs from all available reported pandemic AH1N1 NA sequences, including those reported from America, Africa, Asia, Europe, Oceania, and specifically from Mexico. The molecular distributions of the AASs were obtained at the secondary structure domain level for both the active and catalytic sites, and compared between geographic regions. Our results showed that NA AASs from America, Asia, Europe, Oceania and Mexico followed similar molecular distribution patterns. The compiled data of this study showed that highly conserved amino acids from the NA active site and catalytic site are indeed being affected by mutations. The reported NA AASs follow a similar molecular distribution pattern worldwide. Although most AASs are distributed distantly from the active site, this study shows the emergence of mutations affecting the previously conserved active and catalytic site. A significant number of unique AASs were reported simultaneously on different continents.     

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.     

Chalcones as novel influenza A (H1N1) neuraminidase inhibitors from Glycyrrhiza inflata

The emergence of highly pathogenic influenza A virus strains, such as the new H1N1 swine influenza (novel influenza), represents a serious threat to global human health. During our course of an anti-influenza screening program on natural products, one new licochalcone G (1) and seven known (2-8) chalcones were isolated as active principles from the acetone extract of Glycyrrhiza inflata. Compounds 3 and 6 without prenyl group showed strong inhibitory effects on various neuraminidases from influenza viral strains, H1N1, H9N2, novel H1N1 (WT), and oseltamivir-resistant novel H1N1 (H274Y) expressed in 293T cells. In addition, the efficacy of oseltamivir with the presence of compound 3 (5 μM) was increased against H274Y neuraminidase. This evidence of synergistic effect makes this inhibitor to have a potential possibility for control of pandemic infection by oseltamivir-resistant influenza virus.     

Diagnosis of influenza viruses with special reference to novel H1N1 2009 influenza virus

On 15 April and 17 April 2009, novel swineorigin influenza A (H1N1) virus was identifi ed in specimens obtained from two epidemiologically unlinked patients in the United States. The ongoing outbreak of novel H1N1 2009 influenza (swine influenza) has caused more than 3,99,232 laboratory confi rmed cases of pandemic influenza H1N1 and over 4735 deaths globally. This novel 2009 influenza virus designated as H1N1 A/swine/California/04/2009 virus is not zoonotic swine flu and is transmitted from person to person and has higher transmissibility then that of seasonal influenza viruses. In India the novel H1N1 virus infection has been reported from all over the country. A total of 68,919 samples from clinically suspected persons have been tested for influenza A H1N1 across the country and 13,330 (18.9%) of them have been found positive with 427 deaths. At the All India Institute of Medical Sciences, New Delhi India, we tested 1096 clinical samples for the presence of novel H1N1 influenza virus and seasonal influenza viruses. Of these 1096 samples, 194 samples (17.7%) were positive for novel H1N1 influenza virus and 197 samples (18%) were positive for seasonal influenza viruses. During outbreaks of emerging infectious diseases accurate and rapid diagnosis is critical for minimizing further spread through timely implementation of appropriate vaccines and antiviral treatment. Since the symptoms of novel H1N1 influenza infection are not specifi c, laboratory confi rmation of suspected cases is of prime importance.     

甲型H1N1流感病毒佐剂疫苗小鼠免疫效果

为了探讨甲型H1N1流感病毒氢氧化铝佐剂疫苗对小鼠的免疫作用及对小鼠繁殖性能的影响,以不同剂量、不同免疫程序免疫小鼠后定期采血;用血凝抑制(HI)方法检测血清H1N1流感病毒HI抗体滴度,观察H1N1流感病毒佐剂疫苗对小鼠受孕、产仔、哺乳的影响;比较孕鼠及非孕鼠的抗体滴度,免疫后孕鼠所产仔鼠的体重及H1N1胎传抗体水平。结果显示,以0.5μg组开始的不同剂量、不同免疫程序均可使小鼠产生90倍以上水平的H1N1流感病毒抗体;免疫后的小鼠不影响受孕、产仔及哺乳;仔鼠保护性抗体可持续1个月以上。H1N1流感病毒佐剂疫苗是一种高免疫原性的制剂,用低剂量免疫,即可产生90倍以上持续时间较长的保护性抗体。这种佐剂疫苗对小鼠的繁殖性能无明显影响,免疫产生的抗体经胎盘可垂直传递给仔鼠。     

Comparative analysis of hemagglutinin of 2009 H1N1 influenza A pandemic indicates its evolution to 1918 H1N1 pandemic

To gain insight into the possible origin of the hemagglutinin of 2009 outbreak, we performed its comparative analysis with hemagglutinin of influenza viral strains from 2005 to 2008 and the past pandemics of 1977, 1968, 1957 and 1918. This insilico analysis showed a maximum sequence similarity between 2009 and 1918 pandemics. Primary structure analysis, antigenic and glycosylation site analyses revealed that this protein has evolved from 1918 pandemic. Phylogenetic analysis of HA amino acid sequence of 2009 influenza A(H1N1) viruses indicated that this virus possesses a distinctive evolutionary trait with 1918 influenza A virus. Although the disordered sequences are different among all the isolates, the disordered positions and sequences between 2009 and 1918 isolates show a greater similarity. Thus these analyses contribute to the evidence of the evolution of 2009 pandemic from 1918 influenza pandemic. This is the first computational evolutionary analysis of HA protein of 2009 H1N1 pandemic.     

Investigation of flexibility of neuraminidase 150-loop using tamiflu derivatives in influenza A viruses H1N1 and H5N1

This study focuses on design, synthesis and in vitro evaluation of inhibitory potency of two series of sialylmimetic that target an exosite (“150-cavity”) adjacent to the active site of influenza neuraminidases from A/California/07/2009 (H1N1) pandemic strain and A/chicken/Nakorn-Patom/Thailand/CU-K2-2004 (H5N1). The structure-activity analysis as well as 3-D structure of the complex of parental compound with the pandemic neuraminidase p09N1 revealed high flexibility of the 150-cavity towards various modification of the neuraminidase inhibitors. Furthermore, our comparison of two methods for inhibition constant determination performed at slightly different pH values suggest that the experimental conditions of the measurement could dramatically influence the outcome of the analysis in the compound-dependent manner. Therefore, previously reported K_i values determined at non-physiological pH should be carefully scrutinized.     

甲型H1N1流感病毒裂解疫苗的免疫原性和安全性

目的评价甲型H1N1流感病毒裂解疫苗(简称甲型H1N1流感疫苗)的免疫原性和安全性。方法按照随机、双盲、安慰剂对照的原则,采用0、21天免疫程序,选择3岁及3岁以上健康者1 202人。分组为3~11岁、12~17岁、≥60岁组,按照人数基本为1∶1的比例随机分别接种7.5μg和15.0μg甲型H1N1流感疫苗;18~59岁组按照人数基本为1∶1∶1的比例随机分别接种7.5μg、15.0μg甲型H1N1流感疫苗和安慰剂对照。观察各组接种后的不良反应率以及免疫前后血凝抑制(HI)抗体阳转率、保护率、GMT水平和平均增长倍数。结果受试对象的安全性结果显示7.5μg和15.0μg组不良反应发生率分别为8.74%(48/549)和13.88%(74/533),其中Ⅱ级反应率分别为0.36%(2/549)和1.13%(6/533),未观察到Ⅲ级及以上不良反应和其他异常反应及严重不良事件。2剂接种未见不良反应叠加现象。7.5μg或15.0μg试验疫苗首剂免疫后,血清抗体阳性率分别为85.13%(395/464)和90.77%(413/455),保护率分别为85.56%(397/464)和91.43%(416/455),抗体GMT较免疫前分别增长36.1倍和52.6倍。2剂免疫后,血清抗体阳性率分别是97.84%(454/464)和99.12%(451/455),保护率分别是98.06%(455/464)和9 9.56%(453/455),抗体GMT较免疫前分别增长63.3倍和96.0倍。4个年龄组(3~11岁、12~17岁、18~59岁及≥60岁年龄组)7.5μg和15.0μg组HI抗体阳性率和保护率均大于70%,GMT较免疫前均增长2.5倍以上,结果显示7.5μg和15.0μg甲型H1N1流感疫苗接种1剂后抗体水平已达到研究方案中设定的预期标准,免疫2剂后抗体阳性率和抗体水平明显提高。结论临床试验表明甲型H1N1流感疫苗具有良好的安全性和免疫原性,且接种1剂15.0μg甲型H1N1流感疫苗,即可在3岁和3岁以上人群中产生良好的免疫效果。     

Effect of prior vaccination with a seasonal trivalent influenza vaccine on the antibody response to the influenza pandemic H1N1 2009 vaccine: a randomized controlled trial

Vaccination with the non-adjuvanted split-virion A/California/7/2009 influenza vaccine (pandemic H1N1 2009 vaccine) began in October 2009 in Japan. The present study was designed to assess the effect of prior vaccination with a seasonal trivalent influenza vaccine on the antibody response to the pandemic H1N1 2009 vaccine in healthy adult volunteers. One hundred and seventeen participants aged 22 to 62 were randomly assigned to two study groups. In Group 1 (the priming group), participants were first vaccinated with the seasonal trivalent influenza vaccine followed by two separate one-dose vaccinations of the pandemic H1N1 2009 vaccine, whereas in Group 2 (the non-priming group), the participants were first vaccinated with one dose of the pandemic H1N1 2009 vaccine, followed by simultaneous vaccination of the seasonal trivalent vaccine and the second dose of the pandemic H1N1 2009 vaccine. The participants in Group 2 had a seroprotection rate (SPR) of 79.7% and a seroconversion rate (SCR) of 79.7% in the hemagglutination-inhibition test after the first dose of the pandemic H1N1 2009 vaccine, indicating that the pandemic H1N1 2009 vaccine is sufficiently immunogenic. On the other hand, the participants of Group 1 had a significantly weaker antibody response, with a SPR of 60.8% and a SCR of 58.5%. These results indicate that prior vaccination with the seasonal trivalent influenza vaccine inhibits the antibody response to the pandemic H1N1 2009 vaccine. Therefore, the pandemic H1N1 2009 vaccine should be administered prior to vaccination with the seasonal trivalent influenza vaccine.