H9亚型禽流感病毒HF株的分离鉴定和免疫原性评价

2015年,从安徽合肥某养鸡场分离出一株H9N2亚型禽流感病毒（AIV）,命名为HF株。该毒株鸡胚半数感染量（EID₅₀）为10^9.17/0.1 mL,最小致死量的平均死亡时间（MDT）为87 h。对其HA基因分析发现,其氨基酸裂解位点为RSSR↓GLF,符合低致病性AIV特征;HA基因的遗传进化分析结果表明,该分离株属于h9.4.2.5谱系,符合当前毒株流行趋势。将HF株与2006-2018年分离自全国各地的10株H9N2亚型AIV分离株同时制备灭活疫苗,免疫SPF鸡,制备阳性血清,通过交叉血凝抑制试验分析病毒抗原性,结果显示HF株与2014年之前毒株抗原相关性介于0.50~0.56之间,与2014年及之后毒株抗原相关性介于0.89~1.00之间,表明该分离株与2014年之后的流行毒株具有良好的抗原相关性。用0.2%甲醛灭活HF株病毒液,其HA效价在灭活前后未发生变化;用灭活抗原制备油乳剂灭活疫苗免疫SPF鸡,免疫后21 d HI抗体效价几何平均值达到9.0log2以上,可使免疫鸡完全抵抗H9亚型AIV的感染,提供100%的攻毒保护。研究结果表明,HF株具有良好的免疫原性,可作为疫苗候选株用于H9N2亚型禽流感疫苗的研制。     

Re-8株H5亚型禽流感灭活疫苗对野鸟源H5N8流感病毒的免疫保护性研究

为评估当前应用的Re-8株种毒相关禽流感灭活疫苗对野鸟源H5N8流感病毒的免疫预防效果,本研究将重组禽流感病毒(AIV)H5亚型Re-8株灭活疫苗(H5N1亚型,Re-8株)和重组AIV(H5+H7)灭活疫苗(H5N1Re-8株+H7N9 H7 Re-1株)分别以0.3 m L/只的剂量接种3周龄SPF鸡,免疫3周时进行HI抗体检测和攻毒试验。结果显示,上述2种疫苗免疫的SPF鸡血清中针对H5亚型Re-8株抗原的HI抗体均在8 log2以上,以105EID50的剂量、鼻腔感染途径攻击野鸟源H5N8病毒BHG/QH/2/16和BHG/Tibet/3/16后,所有免疫组鸡在14 d观察期内均全部健活,不排毒,而对照组鸡在攻毒后4 d内全部发病、死亡、排毒。现地免疫重组AIV H5亚型三价灭活疫苗(Re-6株+Re-7株+Re-8株)的商品蛋鸡直接进行HI抗体检测和攻毒试验,结果显示,免疫蛋鸡血清中针对Re-8株抗原的HI抗体平均滴度为8.3 log2,以相同攻毒方式和剂量分别攻击2株H5N8病毒后,免疫鸡也获得完全免疫保护,不发病、不死亡、不排毒。本研究结果表明,含有重组AIV H5 Re-8株抗原的灭活疫苗可有效防控野鸟源H5N8流感病毒,为我国及其他国家H5N8亚型禽流感免疫防控提供了科学依据。     

悬浮培养MDCK细胞制备的H9亚型禽流感灭活疫苗免疫剂量试验

为研究由悬浮培养的MDCK细胞制备的H9亚型AIV抗原所制备的灭活疫苗的免疫剂量,在生物反应器中悬浮培养MDCK细胞,接种H9亚型禽流感病毒WD98和HN04种毒,收获抗原液,以2种抗原液分别制备2个毒株的单价油佐剂灭活疫苗。每种疫苗均按照0.3、0.2、0.1、0.05mL/只(107.5 EID50/只~105.52 EID50/只)的剂量接种21日龄SPF鸡,免疫接种后3周采血测定AIV的HI抗体,采血后分别用与制苗株同源的H9亚型AIV种毒静脉注射攻毒,测定疫苗保护率。2种疫苗不同剂量免疫接种后21d的AIV HI抗体水平达到3.8log2~5.6log2,对照组鸡AIV HI抗体均为0log2。攻毒试验证实,以105.52 EID50/只~107.5 EID50/只剂量进行免疫接种,免疫鸡只获得了80%以上的保护。按照兽药典H9亚型禽流感疫苗攻毒保护率90%为合格的标准,悬浮培养MDCK细胞制备的H9亚型禽流感疫苗的最小免疫接种剂量为106.82 EID50/只。     

H9亚型禽流感病毒HF株灭活疫苗对流行毒株的免疫保护研究

为评价H9N2亚型禽流感病毒HF株灭活疫苗对流行毒株的免疫保护效果,将禽流感病毒HF株灭活疫苗和商品化鸡新城疫、禽流感(H9亚型)二联灭活疫苗分别以0.3 mL/只接种21日龄SPF鸡,3周后采血测定HI抗体效价,并用2018年-2019年分离的4株H9亚型禽流感病毒分别进行攻毒。结果显示,免疫后21 d, HF株灭活疫苗免疫组HI抗体效价达到9.1 log2以上,商品化疫苗HI抗体效价几何平均值则为6.3 log2以内。4株H9亚型禽流感病毒流行毒株以10~(7.0)EID_(50)的剂量静脉攻毒后,HF株灭活疫苗免疫组可抵抗流行毒株的攻击,保护率为100%;而商品化疫苗对流行毒株的攻毒保护率仅为40%～60%。说明H9N2亚型禽流感病毒HF株灭活疫苗具有较强的免疫原性,能使免疫鸡抵抗流行毒株的攻击。     

重组禽流感病毒灭活疫苗(H9N2亚型,Re-9株)对2010年～2011年流行病毒株免疫效力的研究

为评价H9N2亚型重组禽流感病毒(AIV)灭活疫苗Re-9株的免疫效力,本研究选取2010年～2011年分离的5株H9N2亚型AIV进行攻毒保护实验。这5个分离株均为类A/CK/Beijing/1/94病毒株,其HA和NA基因与Re-9株及其亲本株的同源性介于90.6%～97.5%和88.1%～98.7%之间,其抗原相关值在66.67%～100%之间。将Re-9株为种毒制备灭活疫苗,免疫4周龄SPF雏鸡后,3周时平均HI抗体效价达9.5 log2;在免疫后3周以2×107EID50的剂量攻击亲本株和5株流行病毒株,攻毒后采集3 d、5 d、7 d的拭子,免疫组拭子样品病毒检测均为阴性;对照组3 d、5 d拭子病毒检测的阳性率均在80%以上,7 d的阳性率在60%以下。以上结果表明灭活疫苗Re-9株抗原针对性强,而且具有良好的免疫效力,能够抵御近年来分离的H9N2亚型AIV,是理想的H9N2亚型禽流感疫苗株。     

8株H9亚型禽流感病毒的分离鉴定与抗原交叉保护性分析

为了探讨河南省鹤壁市H9亚型禽流感病毒的流行情况及抗原的差异性,试验采用病毒分离鉴定及交叉攻毒免疫保护试验对8株H9亚型禽流感病毒进行了抗原差异性分析。结果表明:利用SPF鸡胚从疑似感染H9亚型禽流感病毒的病料中分离鉴定出8株病毒,这8株病毒诱导的SPF鸡产生的HI抗体效价基本相同,能抵抗不同毒株的攻击。说明河南省鹤壁市H9亚型禽流感病毒流行毒株间具有较好的交叉保护力。     

表达H9亚型禽流感病毒血凝素的重组HVT活疫苗免疫效力评价

为在SPF鸡和商品蛋鸡上评价一株表达H9亚型禽流感病毒(AIV)血凝素基因的重组HVT(r HVT-H9)活疫苗的免疫保护效力,试验将1日龄SPF鸡分为r HVT-H9疫苗组、灭活疫苗组和空白对照组,共3组(n=60,每组20只);1日龄商品蛋鸡除上述三组外另增加r HVT-H9疫苗与禽流感灭活疫苗(H9亚型,F株)联合免疫组,共4组(n=80,每组20只)。免疫后,通过血凝抑制试验检测血清中针对H9亚型AIV的抗体效价;并于免疫后28 d,将全部试验组及空白对照组以H9亚型AIV F株进行静脉注射攻毒。攻毒后第3、5天分别采集喉头、泄殖腔棉拭子检测排毒情况;并于攻毒后第10天将全部试验鸡进行剖检。结果显示:SPF鸡r HVT-H9疫苗组能达到100%免疫保护,而灭活疫苗组仅能达到80%保护;商品蛋鸡r HVT-H9疫苗组保护率为40%,灭活疫苗组保护率为70%,但联合免疫组能达到100%的免疫保护。因此,该重组病毒r HVT-H9疫苗可作为H9亚型禽流感的有效疫苗候选株,与现有商品化禽流感H9亚型灭活疫苗联合使用,效果更佳,为其防控提供一定的技术支持。     

重组禽流感病毒二价灭活疫苗对H5N1亚型7.2分支病毒的攻毒保护性研究

为有效防控2006年以来出现的H5亚型7.2分支禽流感病毒(AIV)引起的免疫鸡群高致病性禽流感(HPAI)的流行,我们构建了重组AIV Re-4疫苗株,研制出含有重组AIV Re-4株的H5亚型二价系列灭活疫苗,并在我国北方地区使用,有效地控制了其流行。2012年我国北方地区再次出现7.2分支病毒引起的HPAI疫情。为评估现有H5亚型二价系列灭活疫苗对该分支病毒的免疫保护效力,本研究首先通过SPF鸡进行免疫攻毒试验评估。结果表明,分别以每羽份(0.3 mL/只)的Re-5+Re-4株和Re-6+Re-4株重组AIV H5二价油乳剂灭活疫苗免疫SPF鸡,免疫3周后针对重组AIV Re-4株的HI抗体均达到8 log2以上;经鼻腔接种7.2分支AIV CK/NX/2/12株(100 LD50)攻毒后,免疫鸡均获得完全保护,即无任何临床症状和排毒现象,而对照组SPF鸡全部发病死亡。此外,以哈尔滨当地养殖场中免疫H5亚型AIV灭活疫苗的48只商品蛋鸡进行攻毒试验,结果显示,商品蛋鸡血清中针对重组AIV Re-4株HI抗体平均滴度为8.3 log2,采用相同方式攻毒后也获得完全保护。本研究结果表明,Re-5+Re-4株和Re-6+Re-4株重组AIV H5二价灭活疫苗均能够对H5亚型7.2分支病毒的攻击提供良好的免疫保护效果。     

悬浮培养和鸡胚尿囊液抗原制备的H9亚型禽流感疫苗免疫效力比较试验

为了探讨悬浮培养和鸡胚尿囊液培养得到的H9亚型禽流感病毒(AIV)抗原制备的疫苗的免疫效力,试验用3株H9亚型AIV株分别接种微载体悬浮培养的MDCK细胞制备3种悬浮培养的细胞疫苗抗原,以3株H9亚型AIV株接种10日龄SPF鸡胚制备3种鸡胚尿囊液抗原,测定6种抗原液HA效价和鸡胚半数感染量(EID50);分别使用6种抗原液制备灭活疫苗,免疫21日龄SPF鸡,并在免疫后第21天采血测定HI抗体水平,采血后进行攻毒并在攻毒后第5天进行病毒分离试验。结果表明:两种方式制备的AIV抗原HA效价为7~9 lb,鸡胚半数感染量为1×106.9~7.9EID50,疫苗免疫后第21天用同源毒株作为工作抗原测定的免疫鸡HI效价差异不大,用异源毒株测定时有一定差异;两种方法得到的抗原制备的疫苗均能获得很好攻毒保护。     

鸡新城疫、传染性支气管炎、禽流感(H9亚型)三联灭活疫苗对禽流感H9亚型流行株攻毒的保护作用

为了监测鸡新城疫、传染性支气管炎、禽流感(H9亚型)三联灭活疫苗(LaSota株+M41株+SS/94株)对H9亚型禽流感病毒流行毒株的免疫保护效果,采用H9亚型禽流感病毒SS/94株及2009—2010年现地分离的3株H9亚型禽流感病毒对已免疫上述三联灭活苗的SPF鸡进行攻毒试验。结果显示,试验鸡以0.3 mL/只的剂量免疫三联灭活苗后21 d,其H9亚型禽流感病毒的HI抗体效价可达8～11log2,此抗体水平可抵抗2×106EID50的H9亚型禽流感病毒SS/94株、BLCN09株、WDZ09株、YT10株的攻击,攻毒保护率均达90%(9/10)以上。可见,以SS/94株作为禽流感疫苗抗原制备的三联灭活苗具有良好的免疫原性,能使免疫鸡抵抗2009—2010年期间现地分离的多株H9亚型禽流感病毒的攻击。     

Isolation,Identification and Immunogenicity Evaluation of H9N2 Subtype Avian Influenza Virus HF Strain

In 2015,an H9N2 subtype avian influenza virus (AIV) strain was isolated from a chicken farm in Hefei,Anhui,and named HF strain.The results of the chicken embryo proliferation characteristics study showed that the half infection rate of chicken embryo (EID₅₀) was 10^9.17/0.1 mL,and the mean time to death for minimum lethal dose(MDT) was 87 h.The analysis result of HA gene showed that its amino acid cleavage site was located in RSSR↓GLF,which accorded with the characteristics of low pathogenic avian influenza.The genetic evolution analysis of HA gene revealed that the isolate belonged to the h9.4.2.5 lineage,which accorded with the current virus strain epidemic characteristics.The HF strain was prepared with 10 H9N2 subtype AIV isolates which isolated from all over the country from 2006 to 2018 to prepare inactivated vaccines,immunize SPF chickens,prepare positive sera,and analyze the virus antigenicity by cross hemagglutination inhibition test.The results showed that the correlation between the HF strain and the virus antigens before 2014 and was between 0.50-0.56,and the virus antigen correlation after 2014 was 0.89-1.00.This showed that the isolate had good antigenic correlation with epidemic strains in recent years.Inactivate HF strain virus solution with 0.2% formaldehydel,and its HA titer did not change before and after inactivation.After the inactivated virus solution was prepared into an oil emulsion inactivated vaccine to immunize SPF chickens,21 days after immunization,the average value of the HI antibody titer reached 9.0log2.It could make immune chicken completely resistant to H9 subtype AIV infection and provide 100% protection from challenge.The above research results showed that the HF strain had good immunogenicity and could be used as a vaccine candidate strain for the prevention of H9N2 subtype AIV.     

Expression of H9N2 Subtype Avian Influenza Virus HA Gene and Preparation of its Mono-specific Serum

To prepare the mono-specific serum to diagnose H9N2 avian influenza virus (AIV),this test extracted H9N2 subtype AIV RNA and then amplified the upper HA1 gene,the middle HA2 gene and the lower HA3 gene by RT-PCR,respectively.Then they were inserted into expression vector pET-32a(+) and transformed into BL21(Rosetta) expression strain.The expressed proteins were used to immune Kunming White mice to prepare antiserum.Recombinant fusion proteins of HA1 HA2 and HA3 were obtained successfully and they showed good immunogenicity.Indirect immunofluorescence assay (IFA) showed that the two serums obtained by the upper HA1 and the middle HA2 could react with the H9N2 subtype AIV,while that of the lower HA3 could not.Recombinant Marek's disease virus (MDV) MZC12 HA/NA also proved that the serums prepared by HA1 and HA2 could recognize the expression of HA gene.The mono-specific serum of H9N2 subtype AIV was prepared successfully,which could lay the foundation for the diagnosis and research of H9N2 subtype AIV.     

H9N2亚型禽流感病毒HA基因的表达及其单因子血清的制备

为了制备特异性识别H9N2亚型禽流感病毒(AIV)的单因子血清,本试验提取H9N2亚型AIV RNA,RT-PCR后,分别扩增上段HA1、中段HA2和下段HA33段基因。将他们插入原核表达载体pET-32a(+)中,转化BL21(Rosetta)菌株中表达。将表达的蛋白常规免疫昆明白小鼠,以制备抗血清。结果显示,成功获得3段重组融合蛋白,且均具有良好的免疫原性。间接免疫荧光试验(IFA)结果显示,上段HA1、中段HA2制备的单因子血清均可与H9N2亚型AIV反应,而下段HA3则不能。重组马立克氏病病毒(MDV)MZC12 HA/NA同样证明HA1、HA2两段制备的单因子血清能识别HA基因的表达。本试验成功制备了识别H9N2亚型AIV HA的单因子血清,为H9N2亚型AIV的鉴别诊断及研究奠定了基础。     

H9N2亚型禽流感病毒与其他病原混合感染的研究进展

H9N2亚型禽流感病毒（Avian influenza virus,AIV）属于低致病性AIV,但因其分布广泛、传播迅速,可引起感染家禽生产性能下降,给家禽业带来了极大的经济损失。H9N2亚型AIV在感染家禽过程中可引起严重的免疫抑制,使家禽极易继发上呼吸道细菌、消化道细菌等感染,从而导致H9N2亚型AIV致病力增强,细菌黏附定植能力增强,家禽死亡率显著升高。另外,H9N2亚型AIV还能与禽传染性支气管炎病毒、禽传染性法氏囊病病毒、新城疫病毒等发生混合感染,病毒入侵时有可能出现协同作用或颉颃作用,从而相互促进或抑制病毒的复制和排毒;H9N2亚型AIV还极易发生突变或与其他亚型流感病毒在混合感染时发生基因重组产生感染人的新亚型毒株,给人类健康和公共卫生安全带来重大威胁。作者综述了H9N2亚型AIV与其他病原混合感染的研究进展,通过阐述H9N2亚型AIV与细菌或病毒混合感染的协同或颉颃作用,以期为临床上H9N2亚型AIV混合感染的防治提供参考。     

2株云南H9N2亚型禽流感病毒HA和NA基因序列分析

在2019年1月-2019年6月对云南出现呼吸道疫病的57个鸡场进行H9亚型禽流感检测的基础上,选取石林和楚雄2个H9亚型禽流感阳性样品进行病毒分离。从分离的H9N2亚型禽流感病毒感染鸡胚尿囊液中提取总RNA,采用特异性引物经反转录PCR分别扩增HA和NA基因,PCR产物纯化后进行测序。序列比对及系统发育分析结果表明,云南2株H9N2毒株HA基因核苷酸序列同源性为94.2%,NA基因核苷酸序列同源性为93.6%,系统进化分析表明云南H9N2亚型禽流感病毒HA和NA基因均属于欧亚谱系中的类ADKHKY28097分支（Y280-like）,ACKYN12019和ACKYN72019 HA基因之间的同源性为94.3%,与参考毒株ACKJX2448的同源性最高,为95.6%~98.5%,与中国流行的H9N2代表株和疫苗株同源性较低。HA蛋白333-340位裂解位点为PSRSSR↓GLF,具有低致病性禽流感病毒分子特征,受体结合位点均发生E198T和Q234L的突变,具有人样受体结合特征,在29、141、298、305、313、492位氨基酸有6个糖基化位点。ACKYN12019和ACKYN72019 NA基因同源性为93.6%,与Y280-like代表毒株的同源性分别为97.1%~97.5%和93.7%~94.6%,NA蛋白缺失63、64、65位氨基酸,在44、69、86、146、200、234位氨基酸处存在6个潜在的糖基化位点,NA蛋白红细胞结合（HB）位点分析发现,368-369、399-403、432位氨基酸处存在变异。研究结果显示,H9N2亚型禽流感病毒一直处于不断的变异之中,故应加强其监测与防控。     

鸭坦布苏病毒病-H9亚型禽流感二联灭活疫苗免疫佐剂筛选

为筛选出理想的鸭TMUV-AIV(H9亚型)二联灭活疫苗免疫佐剂,将灭活的坦布苏病毒液和禽流感病毒(H9亚型)尿囊液分别与白油佐剂、卡波姆佐剂、铝胶佐剂、蜂胶佐剂制成抗原含量相同的TMUV-AIV二联灭活疫苗。应用阻断ELISA方法和血凝抑制方法测定免疫鸭血清中坦布苏病毒和禽流感病毒抗体,比较不同佐剂疫苗对试验鸭的免疫效力。结果表明,以白油作为佐剂的灭活疫苗组免疫效果最好,抗体产生快、抗体水平优于其他各组,免疫2周后60%(6/10)血清样品HI抗体可达1∶8以上,80%血清样品呈TMUV抗体阳性,是制备鸭TMUV-AIV(H9亚型)二联灭活疫苗的理想佐剂。     

Cloning and Sequence Analysis of HA and NA Genes of One Strain of H6N6 Subtype Avian Influenza Virus Isolated from Guizhou Province

To investigate the epidemic situation of H6N6 subtype avian influenza virus (AIV) in Guizhou province,A/duck/Guizhou/013/2014 was isolated from Sansui duck in live poultry market of Guizhou in 2014,the hemagglutinin (HA) and neuraminidase (NA) genes of DK/GZ/14 were subjected to clone and sequence analysis.The results showed that HA gene had the highest nucleotide homologies (97.5%) with the duck-origin H6N6 subtype AIV isolated from Eastern China in 2009,and the strains of HA gene proteolytic cleavage sites was P-Q-I-E-T-R-G,which accordeol with the molecular characteristic of low pathogenic AIV (LPAIV).However,NA gene of A/duck/Guizhou/013/2014 had the highest nucleotide homologies (98.2%) with the duck-origin H6N6 subtype AIV isolated from Fujian in 2007.The phylogenetic tree showed that A/duck/Guizhou/013/2014 and Hunan strains located in the same branch,while three duck-origin H6N6 subtype AIV isolated from Guizhou in 2007 and A/duck/Guizhou/013/2014 located in the different branch for HA and NA genes in genetic evolution,which suggested that A/duck/Guizhou/013/2014 was far with the local H6N6 subtype.The results also clearly indicated that duck-origin H6N6 subtype AIV had genetic diversity in duck population in Guizhou.     

1株H6N6亚型禽流感病毒贵州分离株HA和NA基因克隆与序列分析

为了解 H6亚型禽流感病毒(AIV)在贵州地区的流行情况,本研究对2014年从贵州省三穗鸭体内分离鉴定出的1株H6N6亚型AIV (A/duck/Guizhou/013/2014) HA和NA基因进行了克隆和序列分析。结果显示,A/duck/Guizhou/013/2014的HA基因与华东地区2009年鸭源H6N6亚型AIV同源性最高,达97.5%,HA蛋白裂解位点的氨基酸序列为P-Q-I-E-T-R-G,符合低致病性AIV的分子特征;而NA基因则与福建2007年鸭源H6N6亚型AIV同源性最高,达98.2%;由遗传进化树分析结果可知,HA和NA基因在遗传进化关系上,与湖南毒株位于同一分支,而与2007年贵州分离的3株H6N6亚型AIV不处于同一分支,说明A/duck/Guizhou/013/2014与本地区的H6N6亚型AIV亲缘关系较远。本研究结果表明当前贵州地区H6N6亚型AIV存在明显的遗传多样性。     

Generation and evaluation of reassortant influenza vaccines made by reverse genetics for H9N2 avian influenza in Korea

The prevalence and continuous evolution of H9N2 avian influenza viruses in poultry have necessitated the use of vaccines in veterinary medicine. Because of the inadequate growth properties of some strains, additional steps are needed for producing vaccine seed virus. In this study, we generated three H9N2/PR8 reassortant viruses using a total cDNA plasmid-transfection system, as an alternative strategy for developing an avian influenza vaccine for animals. We investigated the vaccine potency of the reassortant viruses compared with the existing vaccine strain which was adapted by the 20th serial passages in embryonated eggs with A/Ck/Kor/01310/01 (H9N2). The H9N2/PR8 reassortant viruses, containing the internal genes of the high-yielding PR8 strain and the surface gene of the A/Ck/Kor/01310/01 strain, could be propagated in eggs to the same extent as existing vaccine strain without additional processing. Similar to vaccine strain, the H9N2/PR8 reassortant viruses induced hemagglutination-inhibiting antibodies in chickens and prevented virus shedding and replication in multiple organs in response to homologous infection. However, due to the continuing evolution and increasing biologic diversity of H9N2 influenza in Korea, the vaccine provided only partial protection against currently isolates. Taken together, our results suggest that the H9N2/PR8 reassortant virus can be used as a seed virus for avian influenza vaccines in poultry farm. Considering the constant genetic changes in H9 strains isolated in Korea, this reverse genetic system may offer a prompt and simple way to change the vaccine seed virus and mitigate the impact of unexpected influenza outbreaks.