表达绿色荧光蛋白重组新城疫病毒 LaSota疫苗株的构建

新城疫病毒是理想的新型活病毒疫苗载体,具有巨大的优势和应用前景。采用生产实践中广泛应用、免疫效果良好的NDV LaSota弱毒疫苗株,建立了反向遗传操作系统。在此基础上,进一步构建了表达绿色荧光蛋白（GFP）的重组NDV基因组cDNA克隆,成功救获了重组病毒rLaSota_EGFP,病毒F1代尿囊病毒液按1×10.4EID50接种9～10日龄SPF鸡胚尿囊腔,接种后分别于24h、48h、72h及96h收获尿囊液,检测平均HA滴度分别为2.8、2 10.3、2 11.3和2 11,每mL尿囊液病毒量EID50分别为108.64、109.22、109.21和109.64,重组病毒与亲本株生长滴度在相近时间达到峰值,生长动力学特性与亲本株无明显差异。各代次重组病毒按1×10.6EID50病毒量接种9～10日龄SPF鸡胚,96h内完全不致死鸡胚。救获重组病毒保持了LaSota弱毒疫苗亲本毒株对鸡胚良好的高滴度生长适应和低致病特性,并且鸡胚连续传9代次仍保持GFP的稳定表达及生物学特性不变。重组病毒rLaSota_EGFP的成功救获为开展新城疫病毒活载体疫苗研制提供了可行的技术平台。     

禽呼肠孤病毒感染对鸡法氏囊及免疫应答的影响

研究LY株禽呼肠孤病毒(ARV)感染1日龄SPF鸡后对法氏囊发育影响,对传染性法氏囊病毒(IBDV)、禽流感病毒(AIV)、新城疫病毒(NDV)疫苗免疫诱发的抗体的影响,及对强毒株IBDV致病作用的影响。结果表明,LY株ARV感染1日龄SPF鸡可引起法氏囊萎缩和部分淋巴细胞减少,但对增重及AIV和NDV疫苗免疫后抗体滴度却没有显著影响。ARV感染可降低弱毒IBDV疫苗免疫后的抗体反应,但对随后IBDV强毒株攻毒的抵抗力却与对照鸡无显著差异。经IBDV弱毒疫苗免疫后,再接种强毒株IBDV,不会引起死亡,但却仍能显著抑制对AIV、NDV疫苗免疫后的抗体滴度。然而,对于1~7日龄经ARV感染的鸡,IBDV强毒的这种免疫抑制作用又显著低于未经ARV感染的对照鸡。     

短发夹结构RNA干扰新城疫病毒的增殖

 以新城疫病毒（NDV）NP基因为标靶,构建3个细胞内表达发夹样结构小干扰RNA（shRNA）的质粒载体,在鸡胚成纤维细胞（CEF）和鸡胚上进行了RNAi试验,筛选出一个有效抑制病毒复制的小分子ndv1.用阳离子脂质体转染试剂Silent-fect 将ndv1转染CEF,以不相关shRNA质粒载体HK为阴性对照,4 h后接种NDV,与对照相比,干涉组在病毒感染后3 h NP基因的表达量降低2.3倍,6 h 降低21.1倍,9 h降低9.8倍;ndv1能在48 h内完全阻断NDV在CEF中的增殖,延缓病变出现时间,减轻病变程度.将Silent-fect-ndv1混合物与NDV同时注入10日龄SPF鸡胚绒毛尿囊腔,能使10⁵ ELD₅₀NDV感染后17 h鸡胚尿囊液中病毒增殖量减少94.4%,使10⁶ ELD₅₀NDV感染后17　h鸡胚尿囊液中病毒增殖量减少62.5%.实验结果证实,在CEF中存在RNAi机制,抑制NDV NP基因的表达能有效阻断该病毒增殖,说明NP基因在NDV复制过程中起重要作用.实验结果为进一步利用RNAi技术在CEF和鸡胚中研究病毒基因组功能及筛选抗病毒小分子奠定了基础.     

新城疫病毒(NDV)疫苗株的纯化和结构蛋白的初步鉴定

本文报道新城疫Ⅰ系和Ⅳ系疫苗病毒的分离纯化,以及对其结构蛋白的初步鉴定。 将中国兽医药品监察所提供的冻干苗(NDV Ⅰ系和Ⅳ系)复壮2次,使其鸡胚感染滴度达10~6,血凝滴度为640(0.1ml)以上。按常规接种9～10日龄受精SPF鸡胚,35℃培养,收集36～72小时鸡胚尿囊液,测定血凝及滴度,置-20℃冰箱备用。     

弱毒疫苗中鸡传染性贫血病毒低剂量污染对SPF鸡体重和疫苗免疫抗体的影响

为了观察使用污染有低剂量鸡传染性贫血病毒(Chicken infectious anemia virus,CIAV)弱毒疫苗后对鸡免疫和体重的影响,本研究通过人工模拟试验观察了CIAV低剂量污染对SPF鸡体重以及对NDV疫苗抗体产生的影响。结果显示使用每羽份污染10个EID50CIAV和5个EID50CIAV两种剂量的NDV疫苗后均造成了SPF鸡体重的下降,与使用未污染疫苗组相比差异显著;并且使用污染两种剂量CIAV的疫苗后NDV抗体水平与使用无污染组相比也降低了,差异显著。使用污染两种剂量CIAV的NDV疫苗后第2周开始均检测到一定比例的CIAV抗体阳性,而通过核酸检测在使用污染疫苗后第1周就检测到很高比例的CIAV核酸阳性。研究结果不仅展示了弱毒疫苗中CIAV污染对SPF鸡生产性能和免疫机能的影响,也提示我们在通过SPF鸡检查法检测外源病毒污染时增加对病毒核酸检测有助于节省检测时间和提高检出率。     

鸡肾型传染性支气管炎病毒FX株的分离和鉴定

从自然发生的鸡肾病变型传染性支气管炎病例采集病死鸡肾脏为材料,通过接种9－11日龄SPF鸡胚尿囊腔,进行病毒的分离和传代,分离到1株病毒（FX）,敏感鸡人工感染后出现呼吸症状,剖检病鸡时大我鸡肾肿大并有尿酸盐沉积,病毒能死鸡胚和产生侏儒胚;病毒能干扰鸡新城疫病毒LaSota株在鸡胚中增殖,病毒经电镜观察,其大小在80－120nm之间,囊膜外有纤,病毒经IBV单抗ELISA检测呈强阳性反应。研究结果初步表明,FX毒株为肾型IBV。     

整合REV LTR序列的MDV弱毒株的分离鉴定与生物学特性

【目的】从非免疫健康三黄鸡中分离到一株马立克氏病病毒(MDV),命名为MDV GD06株,本工作系统研究了其生物学特性。【方法】PCR扩增GD06株Meq基因及短末端重复区(RS)序列,进行序列分析,并用间接免疫荧光试验进行血清型特异性鉴定;通过接种SPF鸡和鸡胚成纤维细胞(CEF)来判定GD06株体内外的增殖能力;为确定GD06株的致病性,用1日龄SPF鸡进行攻毒试验。【结果】GD06株为MDV血清I型病毒,其基因组中自然整合禽网状内皮增殖症病毒(REV)的长末端重复序列(LTR),Meq基因富含脯氨酸的结构域比参考强毒株Md5多59个氨基酸,与MD商品化疫苗CVI988/Rispens和814株相符,具有弱毒株的特征。在接种CEF细胞96、120、144、168、192 h,GD06株病毒滴度分别为1.9×105、3.9×105、6.1×105、6.5×105、5.8×105PFU,明显比CVI988/Rispens(病毒滴度分别为1.3×105、3.5×105、5.0×105、5.7×105、4.7×105PFU)高(P0.05);接种SPF鸡21、28天,GD06株在鸡体内的病毒滴度分别为740和350 PFU,明显比CVI988/Rispens株(病毒滴度分别为460、216 PFU)高(P0.05),结果表明,GD06株在CEF细胞和鸡体内具有比CVI988/Rispens更快的增殖能力。人工接种攻毒实验表明,GD06株对SPF鸡没有致病性,不引免疫抑制。【结论】研究结果表明,MDV GD06株为国内首次分离的自然整合有REV LTR序列的重组MDV弱毒株。     

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。     

伪狂犬病病毒上海株gE-/gI-/GFP+缺失株的生物学特性初步研究

在构建了伪狂犬病病毒上海株的缺失载体pgEI-GFP基础上,将pgEI-GFP转染感染了PRV-SH株的BHK-21细胞,待出现80%以上的细胞病变时收获病毒,并以绿色荧光蛋白为标志,通过蚀斑法得到纯化重组病毒gE-/gI-/GFP+缺失株.研究了该缺失株的的安全性、在细胞上的生长特性以及对断奶仔猪的安全性、免疫原性等生物学特性.试验结果显示,缺失了gE-和gI-后,不影响其在RK细胞上的生长状况和病毒的滴度.该疫苗株对小鼠的半数致死量比亲本毒低且对家兔的致死性的时间延长了,这表明该疫苗的毒力比亲本毒有所下降.该缺失株对断奶仔猪安全,无不良接种反应,接种断奶仔猪能抵御高剂量PRV-SH株强毒的感染,攻毒后试验猪的发热期、散毒天数均低于对照组.该缺失株接种仔猪后在试验期间一直维持较高水平的中和抗体.     

伪狂犬病病毒上海株gE-/gI-/GFP+缺失株的生物学特性初步研究

在构建了伪狂犬病病毒上海株的缺失载体pgEI-GFP基础上,将pgEI-GFP转染感染了PRV-SH株的BHK-21细胞,待出现80%以上的细胞病变时收获病毒,并以绿色荧光蛋白为标志,通过蚀斑法得到纯化重组病毒gE-/gI-/GFP+缺失株.研究了该缺失株的的安全性、在细胞上的生长特性以及对断奶仔猪的安全性、免疫原性等生物学特性.试验结果显示,缺失了gE-和gI-后,不影响其在RK细胞上的生长状况和病毒的滴度.该疫苗株对小鼠的半数致死量比亲本毒低且对家兔的致死性的时间延长了,这表明该疫苗的毒力比亲本毒有所下降.该缺失株对断奶仔猪安全,无不良接种反应,接种断奶仔猪能抵御高剂量PRV-SH株强毒的感染,攻毒后试验猪的发热期、散毒天数均低于对照组.该缺失株接种仔猪后在试验期间一直维持较高水平的中和抗体.     

鸽源新城疫病毒JS/07/04/Pi株感染性分子克隆的构建及病毒拯救

参照GenBank上公布的鸽源Ⅵb亚型新城疫病毒JS/07/04/Pi株基因组全序列设计9对引物,RT-PCR扩增目的片段后,依次亚克隆至TVT7/R转录载体,成功构建出含JS/07/04/Pi株基因组全长cDNA的转录载体TVT/071204。然后将其与三个辅助表达质粒pCI-NP、pCI-P和pCI-L共转染BSR-T7/5细胞,60h后将转染细胞及其上清接种鸡胚,收集死亡鸡胚尿囊液进行HA与HI试验。结果显示死亡鸡胚尿囊液HA呈阳性,并能被ND阳性血清所抑制,表明该病毒已成功拯救,且拯救病毒rNDV/071204在细胞上的生长增殖能力同母本病毒相似。该病毒的成功拯救为鸽源Ⅵb亚型NDV感染的宿主特异性及鸽用ND新型疫苗的研究提供了理想的生物材料。     

Rescue and preliminary application of a recombinant newcastle disease virus expressing green fluorescent protein gene

Based on the complete genome sequence of Newcastle disease virus (NDV) ZJI strain, seven pairs of primers were designed to amplify a cDNA fragment for constructing the plasmid pNDV/ZJI, which contained the full-length cDNA of the NDV ZJI strain. The pNDV/ZJI, with three helper plasmids, pCIneoNP, pCIneoP and pCIneoL, were then cotransfected into BSR-T7/5 cells expressing T7 RNA polymerase. After inoculation of the transfected cell culture supernatant into embryonated chicken eggs from specific-pathogen-free (SPF) flock, an infectious NDV ZJI strain was successfully rescued. Green fluorescent protein (GFP) gene was amplified and inserted into the NDV full-length cDNA to generate a GFP-tagged recombinant plasmid pNDV/ZJIGFP. After cotransfection of the resultant plasmid and the three support plasmids into BSR-T7/5 cells, the recombinant NDV, NDV/ZJIGFP, was rescued. Specific green fluorescence was observed in BSR-T7/5 and chicken embryo fibroblast (CEF) cells 48h post-infection, indicating that the GFP gene was expressed at a relatively high level. NDV/ZJIGFP was inoculated into 10-day-old SPF chickens by oculonasal route. Four days post-infection, strong green fluorescence could be detected in the kidneys and tracheae, indicating that the recombinant GFP-tagged NDV could be a very useful tool for analysis of NDV dissemination and pathogenesis.     

Rescue and Preliminary Application of a Recombinant Newcastle Disease Virus Expressing Green Fluorescent Protein Gene

Based on the complete genome sequence of Newcastle disease virus (NDV) ZJI strain, seven pairs of primers were designed to amplify a cDNA fragment for constructing the plasmid pNDV/ZJI, which contained the full-length cDNA of the NDV ZJI strain. The pNDV/ZJI, with three helper plasmids, pCIneoNP, pCIneoP and pCIneoL, were then cotransfected into BSR-T7/5 cells expressing T7 RNA polymerase. After inoculation of the transfected cell culture supernatant into embryonated chicken eggs from specific-pathogen-free (SPF) flock, an infectious NDV ZJI strain was successfully rescued. Green fluorescent protein (GFP) gene was amplified and inserted into the NDV full-length cDNA to generate a GFP-tagged recombinant plasmid pNDV/ZJIGFP. After cotransfection of the resultant plasmid and the three support plasmids into BSR-T7/5 cells, the recombinant NDV, NDV/ZJIGFP, was rescued. Specific green fluorescence was observed in BSR-T7/5 and chicken embryo fibroblast (CEF) cells 48h post-infection, indicating that the GFP gene was expressed at a relatively high level. NDV/ZJIGFP was inoculated into 10-day-old SPF chickens by oculonasal route. Four days post-infection, strong green fluorescence could be detected in the kidneys and tracheae, indicating that the recombinant GFP-tagged NDV could be a very useful tool for analysis of NDV dissemination and pathogenesis.     

Newcastle disease virus V protein is a determinant of host range restriction

It has been demonstrated that the V protein of Newcastle disease virus (NDV) functions as an alpha/beta interferon (IFN-alpha/beta) antagonist (M. S. Park, M. L. Shaw, J. Mu?oz-Jordan, J. F. Cros, T. Nakaya, N. Bouvier, P. Palese, A. García-Sastre, and C. F. Basler, J. Virol. 77:1501-1511, 2003). We now show that the NDV V protein plays an important role in host range restriction. In order to study V functions in vivo, recombinant NDV (rNDV) mutants, defective in the expression of the V protein, were generated. These rNDV mutants grow poorly in both embryonated chicken eggs and chicken embryo fibroblasts (CEFs) compared to the wild-type (wt) rNDV. However, insertion of the NS1 gene of influenza virus A/PR8/34 into the NDV V(-) genome [rNDV V(-)/NS1] restores impaired growth to wt levels in embryonated chicken eggs and CEFs. These data indicate that for viruses infecting avian cells, the NDV V protein and the influenza NS1 protein are functionally interchangeable, even though there are no sequence similarities between the two proteins. Interestingly, in human cells, the titer of wt rNDV is 10 times lower than that of rNDV V(-)/NS1. Correspondingly, the level of IFN secreted by human cells infected with wt rNDV is much higher than that secreted by cells infected with the NS1-expressing rNDV. This suggests that the IFN antagonist activity of the NDV V protein is species specific. Finally, the NDV V protein plays an important role in preventing apoptosis in a species-specific manner. The rNDV defective in V induces apoptotic cell death more rapidly in CEFs than does wt rNDV. Taken together, these data suggest that the host range of NDV is limited by the ability of its V protein to efficiently prevent innate host defenses, such as the IFN response and apoptosis.     

A recombinant newcastle disease virus with low-level V protein expression is immunogenic and lacks pathogenicity for chicken embryos

Newcastle disease virus (NDV) edits its P-gene mRNA by inserting a nontemplated G residue(s) at a conserved editing site (3'-UUUUUCCC-template strand). In the wild-type virus, three amino-coterminal P-gene-derived proteins, P, V, and W, are produced at frequencies of approximately 68, 29, and 2%, respectively. By applying the reverse genetics technique, editing-defective mutants were generated in cell culture. Compared to the wild-type virus, mutants lacking either six nucleotides of the conserved editing site or the unique C-terminal part of the V protein produced as much as 5, 000-fold fewer infectious progeny in vitro or 200,000-fold fewer in 6-day-old embryonated chicken eggs. In addition, both mutants were unable to propagate in 9- to 11-day-old embryonated specific-pathogen-free (SPF) chicken eggs. In contrast, a mutant (NDV-P1) with one nucleotide substitution (UUCUUCCC) grew in eggs, albeit with a 100-fold-lower infectious titer than the parent virus. The modification in the first two mutants described above led to complete abolition of V expression, whereas in NDV-P1 the editing frequency was reduced to less than 2%, and as a result, V was expressed at a 20-fold-lower level. NDV-P1 showed markedly attenuated pathogenicity for SPF chicken embryos, unlike currently available ND vaccine strains. These findings indicate that the V protein of NDV has a dual function, playing a direct role in virus replication as well as serving as a virulence factor. Administration of NDV-P1 to 18-day-old embryonated chicken eggs hardly affected hatchability. Hatched chickens developed high levels of NDV-specific antibodies and were fully protected against lethal challenge, demonstrating the potential use of editing-defective recombinant NDV as a safe embryo vaccine.     

利用反向遗传操作技术产生ZJI株鹅源新城疫病毒

利用反向遗传操作技术,将ZJI株鹅源新城疫病毒全基因组cNDA克隆(NDV3GM122)和含该毒株NP、P及L基因的3个表达载体(pCI-NP、pCI-P与pCI-L)共转染BSR-T7/5细胞;同时,将NDV3GM122与含新城疫病毒La Sota毒株NP、P及L基因的3个表达载体(pCIneoNP、pCIneoP与pCIneoL)进行共转染。通过间接免疫荧光实验(Indiectimmunofluorescence assay,IFA)以及接种鸡胚后进行血凝(Hemagglutinin,HA)与血凝抑制(Hemagglutinininhibition,HI)试验、RT-PCR扩增和电镜观察,结果均证实全基因组cDNA克隆NDV3GM122与La Sota毒株表达载体共转染组产生了有血凝性的鹅源新城疫病毒,而NDV3GM122与ZJI株表达载体共转染组暂未检测到有血凝性的病毒。ZJI株鹅源新城疫病毒的拯救成功为对该病毒进行功能基因组研究和疫苗的研制等后续工作打下了基础。     

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。