表达鸡传染性法氏囊病毒VP2蛋白的干酪乳杆菌免疫保护效力

利用干酪乳杆菌作为传染性法氏囊病毒(IBDV)VP2抗原传递系统,探讨口服雏鸡的免疫次数、免疫剂量、免疫途径和攻毒保护效果。用pLA-VP2重组干酪乳杆菌对5日龄雏鸡进行二次和三次免疫,并设108、109、1010 CFU/mL的重组干酪乳杆菌组,间接ELISA检测血清IgG和小肠洗液sIgA,末免后7 d攻毒,计算保护效果。根据确定的2次免疫和109 CFU/mL免疫剂量免疫5日龄雏鸡,分别口服、滴鼻/点眼pLA-VP2/L.casei,口服、肌注商品活苗及口服pLA/L.casei和PBS为对照,监测IgG和sIgA抗体水平;末免后7 d检测脾淋巴细胞增殖情况并攻毒,7 d后剖检,观察法氏囊损伤程度并记录病变得分和保护率。结果表明各组的特异性sIgA、IgG抗体水平显著高于对照组(P0.01);口服pLA-VP2/L.casei组的淋巴细胞刺激指数显著高于其他组(P0.01),保护率高达83.3%,免疫保护效果优于滴鼻/点眼组。因此,构建的重组干酪乳杆菌的安全性优于商品活苗,可以作为IBDV候选疫苗。     

产气荚膜梭菌α毒素在干酪乳杆菌中的诱导表达及其小鼠口服免疫力

[目的]构建产气荚膜梭菌(Clostridium perfringens,C.perfringents)α毒素基因的重组干酪乳杆菌口服疫苗,为产气荚膜梭菌毒素中毒的防治提供有效方法.[方法]将构建的重组产气荚膜梭菌α毒素基因细胞表面型载体pPG1及分泌表达载体pPG2电转化乳酸乳杆菌(Lactobacillus casei L.casei),获得阳性重组菌pPG1-α/L.case/393乳酸乳杆菌表面表达系统和pPG2-α/L.casei 393乳酸乳杆菌分泌表达系统.重组菌以1%乳糖为诱导物,在MRS培养基中进行诱导,通过Western-blot和间接免疫荧光方法鉴定,确定目的蛋白的表达.将重组菌口服免疫BALB/c小鼠,收集免疫小鼠粪便及眼冲洗液及外生殖道黏液样本测定小鼠产生抗α毒素的特异性slgA抗体水平,采集小鼠血液样本测定血清中抗α毒素的特异性lgG抗体水平.并对免疫小鼠进行α毒素的腹腔攻毒试验及对获得的抗血清进行α毒素中和试验测定.[结果]重组干酪乳杆菌pPG1-α/L.casei 393及pPG2-/L.casei 393免疫小鼠能够产生明显的抗α毒素的slgA和IgG抗体水平,其对α毒素中和试验结果为完全保护.腹腔攻毒实验结果为能抵抗3倍最小致死剂量(minimum lethal dose,MLD100)的α毒素攻击.[结论]表达产气荚膜梭菌α毒素免疫保护性抗原的重组乳酸乳杆菌口服免疫动物能够产生良好的局部和系统体液免疫应答和免疫中和效力.     

产气荚膜梭菌α毒素在干酪乳杆菌中的诱导表达及小鼠口服免疫保护效力的测定

摘要: 【目的】构建产气荚膜梭菌（Clostridium perfringens, C．perfringens）α 毒素基因的重组干酪乳杆菌口服疫苗,为产气荚膜梭菌毒素中毒的防治提供有效方法。【方法】将构建的重组产气荚膜梭菌α毒素基因细胞表面型载体pPG1及分泌表达载体pPG2电转化乳酸乳杆菌（Lactobacillus casei L.casei）,获得阳性重组菌pPG1-α/ L.casei 393 乳酸乳杆菌表面表达系统和pPG2-α/ L.casei393乳酸乳杆菌分泌表达系统。重组菌以1%乳糖为诱导物,在MRS培养基中进行诱导,通过Western-blot和间接免疫荧光方法鉴定,确定目的蛋白的表达。将重组菌口服免疫BALB/c小鼠,收集免疫小鼠粪便及眼冲洗液及外生殖道黏液样本测定小鼠产生抗α毒素的特异性sIgA 抗体水平,采集小鼠血液样本测定血清中抗α毒素的特异性IgG抗体水平。并对免疫小鼠进行α毒素的腹腔攻毒实验及对获得的抗血清进行α毒素中和试验测定。【结果】重组干酪乳杆菌pPG1-α/ L.casei 393及pPG2-/ L.casei 393免疫小鼠能够产生明显的抗α毒素的sIgA 和IgG 抗体水平,其对α毒素中和试验结果为完全保护。腹腔攻毒实验结果为能抵抗3倍最小致死剂量的α毒素攻击。【结论】表达产气荚膜梭菌α毒素免疫保护性抗原的重组乳酸乳杆菌口服免疫动物能够产生良好的局部和系统体液免疫应答和免疫中和效力。     

重组ETEC k88ac-LTB干酪乳杆菌在人工消化液中的生存性能

探讨重组干酪乳杆菌(Lactobacillus casei)在人工消化液中的存活能力。将K88ac-LTB基因从表达载体pQE-30克隆到L. casei细胞表面表达载体pLA中, 构建了重组表达载体pLA-K88ac-LTB, 并将其电转化至L. casei中, 在MRS培养基中培养后, Western blotting检测, 有约71.2 kD蛋白得到了表达, 表达蛋白的大小与理论值相符且可被抗血清所识别, 间接免疫荧光实验及流式细胞结果表明, 多聚谷氨酸合成酶A蛋白(pgsA)能够将融合蛋白成功地展示在菌体表面。将重组菌接种于人工模拟的胃肠液中, 通过平板计数观察其存活能力。结果表明, 重组干酪乳杆菌在人工消化液中均具有良好的存活性能, 符合益生菌的基本特征, 为实验动物模型的建立奠定了基础。     

猪瘟病毒T细胞表位E290多肽与猪细小病毒VP2蛋白在干酪乳杆菌中的共表达及免疫小鼠特异性抗体的测定

将分别编码猪瘟病毒T细胞表位E290多肽和猪细小病毒主要保护性抗原VP2蛋白的重组基因插入干酪乳杆菌分泌型表达载体pPG中,构建了重组表达载体pPG-VP2-E290,将其电转化干酪乳杆菌Lactobacillus casei 393,获得了猪瘟病毒T细胞表位E290多肽与猪细小病毒VP2蛋白的乳酸菌共表达系统,经2%乳糖在MRS培养基中的诱导表达,对诱导表达的菌体及培养上清液进行SDS-PAGE检测表明,有约70kDa蛋白得到了表达,表达蛋白的大小与理论值相符。Western blot分析结果表明所表达的蛋白具有与天然病毒蛋白一样的抗原特异性。以诱导表达上清液作为抗原进行的间接ELISA实验也表明,重组的目的蛋白获得了分泌表达。将该重组干酪乳杆菌经口服接种途径免疫BALB/c小鼠,收集粪便样品检测小鼠产生抗PPV的特异性sIgA抗体,采集血液样本检测血清中抗PPV及抗E290的特异性IgG。结果表明分泌型的重组菌pPG-VP2-E290/L.casei 393免疫小鼠能够产生明显的抗体水平,为重组猪瘟与猪细小病毒乳酸菌口服活菌疫苗的研制奠定了重要的物质基础。     

重组干酪乳杆菌在模拟消化环境中生存性能的研究

目的 探讨重组干酪乳杆菌Lactobacillus casei 393在模拟胃肠道环境中的存活能力.方法 人工模拟胃肠道环境,即人工胃液（pH=1.5～4.5）、人工肠液、胆汁（质量浓度0.3～3.0 g/L）和高盐（质量浓度40～90g/L）.结果 重组干酪乳杆菌在pH为2.5～4.5的人工胃液中具有较强的生存能力,3 h活菌数仍达108/ml;在人工肠液中经过不同时间的作用后,重组干酪乳杆菌显出生长趋势;在0.3%的胆汁环境作用8 h仍有存活,且能耐受7%NaCl浓度的高渗环境.结论 实验为干酪乳杆菌Lactobacillus casei 393能否作为益生菌制剂在胃肠道中发挥作用提供了理论基础.     

表达ETEC F41重组干酪乳杆菌口服及滴鼻免疫效果的比较

摘要：【目的】比较小鼠滴鼻与口服接种ETEC F41重组干酪乳杆菌后,机体所产生的抗ETEC F41的黏膜免疫和系统免疫及免疫保护率的差异,为确定ETEC乳酸菌疫苗免疫程序奠定基础。【方法】将构建的重组质粒pLA-F41电转化入干酪乳杆菌,获得阳性重组菌。重组菌在MRS 培养基中进行表达,经Western blot检测目的蛋白的表达,间接免疫荧光及流式细胞术检测外源蛋白展示到菌体表面。SPF级BALB/c小鼠随机分成4组,每组40只,将重组菌以滴鼻和口服途径分别接种2组小鼠,对照组分别接种同剂量的空质粒菌     

猪细小病毒VP2蛋白在干酪乳杆菌表面的表达

将编码猪细小病毒主要免疫保护性抗原VP2基因插入干酪乳杆菌细胞表面表达载体pPG中,构建了重组表达载体pPG-VP2,将其电转化干酪乳杆菌Lactobacillus casei 393,获得了表达猪细小病毒VP2蛋白的重组干酪乳杆菌系统,经2%乳糖在MRS培养基中的诱导表达,SDS-PAGE检测表明,有约74kD蛋白得到了表达,表达蛋白的大小与理论值相符。Western-blot结果分析表明,表达的蛋白可被鼠源PPV抗血清所识别,间接免疫荧光实验结果表明,所表达的蛋白能够在干酪乳杆菌菌体表面检测到。     

共表达H5N1、H7N1亚型AIV HA与鸡IL-18多价重组鸡痘病毒免疫保护性研究

用本实验室构建的重组鸡痘病毒rFPV-H5HA-IL18、rFPV-H5HA-H7HA-IL18和rFPV-H5HA,经翼蹼免疫1日龄SPF鸡和7日龄商品Leghorn蛋鸡,同时以H5亚型AIV全病毒灭活疫苗作为对照.免疫后测定HI抗体效价、淋巴细胞转化指标、重组疫苗对增重的影响、免疫后的攻毒保护效力、免疫后的抑制排毒情况.免疫后不同时间分别测定特异性抗体和淋巴细胞刺激指数.试验结果表明,3株重组鸡痘病毒株均能诱导鸡体产生血凝抑制抗体(HI);共表达鸡IL-18的rFPV-H5HA-IL18和rFPV H5HA-H7HA-IL18诱导商品蛋鸡的细胞免疫水平明显高于非共表达鸡IL-18的rFPV-H5HA.重组鸡痘疫苗免疫SPF和商品蛋鸡后第21d进行攻毒实验,rFPV-H5HA-IL18和rFPV-H5HA-H7HA-IL18免疫攻毒保护率达10/10,rFPV-H5HA免疫攻毒保护率达9/10,与常规疫苗相当.免疫的商品蛋鸡于攻毒后7d采集泄殖腔棉试子样品,检测排毒情况.结果表明,rFPV-H5HA-IL18、rFPV-H5HA-H7HA-IL18免疫组在攻毒后第7d无排毒,其抑制免疫鸡排毒效果优于常规疫苗和单独表达HA的rFPV-H5HA重组鸡痘病毒.rFPV-H5HA-IL18和rFPV-H5HA-H7HA-IL18免疫组鸡,在14日龄时的体重明显高于rFPV-H5HA免疫组和常规疫苗对照免疫组,表明共表达的鸡IL-18能降低鸡痘病毒载体对雏鸡增重的影响.     

共表达H5N1、H7N1亚型AIV HA与鸡IL-18多价重组鸡痘病毒免疫保护性研究

用本实验室构建的重组鸡痘病毒rFPV-H5HA-IL18、rFPV-H5HA-H7HA-IL18和rFPV-H5HA,经翼蹼免疫1日龄SPF鸡和7日龄商品Leghorn蛋鸡,同时以H5亚型AIV全病毒灭活疫苗作为对照.免疫后测定HI抗体效价、淋巴细胞转化指标、重组疫苗对增重的影响、免疫后的攻毒保护效力、免疫后的抑制排毒情况.免疫后不同时间分别测定特异性抗体和淋巴细胞刺激指数.试验结果表明,3株重组鸡痘病毒株均能诱导鸡体产生血凝抑制抗体（HI）;共表达鸡IL-18的rFPV-H5HA-IL18和rFPV H5HA-H7HA-IL18诱导商品蛋鸡的细胞免疫水平明显高于非共表达鸡IL-18的rFPV-H5HA.重组鸡痘疫苗免疫SPF和商品蛋鸡后第21d进行攻毒实验,rFPV-H5HA-IL18和rFPV-H5HA-H7HA-IL18免疫攻毒保护率达10/10,rFPV-H5HA免疫攻毒保护率达9/10,与常规疫苗相当.免疫的商品蛋鸡于攻毒后7d采集泄殖腔棉试子样品,检测排毒情况.结果表明,rFPV-H5HA-IL18、rFPV-H5HA-H7HA-IL18免疫组在攻毒后第7d无排毒,其抑制免疫鸡排毒效果优于常规疫苗和单独表达HA的rFPV-H5HA重组鸡痘病毒.rFPV-H5HA-IL18和rFPV-H5HA-H7HA-IL18免疫组鸡,在14日龄时的体重明显高于rFPV-H5HA免疫组和常规疫苗对照免疫组,表明共表达的鸡IL-18能降低鸡痘病毒载体对雏鸡增重的影响.     

鸡新城疫口服DNA疫苗的安全性、稳定性与免疫效力

将含新城疫病毒（NDV）F₄₈E₉株融合蛋白（F）基因的真核表达质粒pcDNA3-F的减毒鼠伤寒沙门氏菌ZJ111株（ZJ111/pcDAN3-F）口服接种小鼠和雏鸡。结果表明：利用该减毒株作为载体传递DNA疫苗具有相对安全性。用酶切和PCR鉴定法证实在体内外无抗生素存在的条件下重组质粒在受体菌ZJ111菌株内比较稳定。ZJ111/pcDAN3-F以每羽10⁸cfu免疫雏鸡,2周后二免,二免后4周攻击致死剂量的强毒株F₄₈E₉,观察其免疫效力。结果表明：重组ZJ111/pcDNA3-F菌株不仅能诱导雏鸡产生抗NDV抗体,而且能诱导法氏囊B淋巴细胞和胸腺T淋巴细胞的增殖反应,对强毒株攻击的保护率为66.7%,高于pcDNA3-F裸质粒DNA疫苗注射免疫组（50%）。上述结果初步提示减毒沙门氏菌为载体传递DNA疫苗具有良好的安全性、稳定性和免疫原性,为研制低成本、实用化的口服禽类DNA疫苗奠定了基础。     

携带新城疫病毒DNA疫苗的鼠伤寒沙门氏菌及其安全性与免疫效力

根据GenBank中发表的新城疫病毒(NDV)融合蛋白(F)基因序列,设计一对引物,通过RTPCR扩增出鹅源新城疫病毒分离株JS5F基因,测序确认后,将其克隆入真核表达载体pVAX1,获得重组真核表达质粒pVAX1F。将pVAX1F转化减毒鼠伤寒沙门氏菌SL7207,构建成携带DNA疫苗的重组沙门氏菌SL7207(pVAX1F)。重组菌以不同剂量口服免疫1日龄雏鸡,结果表明,细菌对雏鸡具有良好的安全性,且不影响鸡的增重。将SL7207(pVAX1F)分别以108CFU和109CFU的剂量3次口服免疫1日龄商品代伊莎褐蛋鸡,抗体检测结果显示,在三免后1周,SL7207(pVAX1F)109CFU剂量组的血清抗体效价与空载体组之间存在显著性差异(p<0.05)。重组菌两个剂量组在首免后2周开始出现粘膜抗体,并于二免后2周和3周达到较高水平。免疫保护试验结果显示,SL7207(pVAX1F)109CFU剂量组的保护率为77.27%,与空载体组之间存在显著性差异(p<0.05)。     

鸡新城疫病毒HeB02分离株F基因的克隆及其DNA疫苗的研究

根据GenBank报道的鸡新城疫病毒F基因序列设计了一对引物,以鸡新城疫病毒HeB02分离株基因组为模板,通过RT-PCR扩增出了1·66kb左右的F基因片段,序列分析表明HeB02株F基因与国内标准强毒株F48E9及弱毒疫苗La Sota和Clone30的F基因核苷酸序列的同源性分别为88·1%、84·9%和83·8%。将HeB02株F基因插入真核表达载体pVAX1中,构建了真核表达质粒pSV-F,通过脂质体转染COS-7细胞,SDS-PAGE分析可见表达的特异蛋白条带;Western blot、ELISA和中和试验检测结果表明:真核表达的蛋白与抗新城疫病毒的抗体发生特异性反应,说明F蛋白具有很好的免疫原性。采用活体电击法以真核表达质粒pSV-F免疫3周龄SPF鸡,剂量为50μg/只,3周后加强免疫1次,5周后以100倍鸡胚感染剂量(EID)的F基因同源病毒对所有鸡进行攻毒,攻毒前后每周分别以喉拭子进行病毒分离和HI效价测定。结果显示对照组在攻毒前一直没有检测到抗体效价,攻毒后检测效价为3·0log2±1·40,并且于攻毒后第9天全部死亡;活疫苗组和实验组免疫后第2周检测到抗体效价,第5周最高,HI效价分别为8·3log2±1·30和7·2log2±1·23,攻毒1周后HI效价分别达9·8log2±1·55和8·9log2±1·77,极显著高于对照组(P<0·01)。免疫组未分离到新城疫病毒,对照组全部分离到新城疫病毒。表明所构建的F基因真核表达质粒可作为候选基因疫苗诱导鸡产生免疫保护反应。     

A recombinant Newcastle disease virus (NDV) expressing VP2 protein of infectious bursal disease virus (IBDV) protects against NDV and IBDV

Infectious bursal disease virus (IBDV) causes a highly immunosuppressive disease in chickens. Currently available, live IBDV vaccines can lead to generation of variant viruses. We have developed an alternative vaccine that will not create variant IBDV. By using the reverse genetics approach, we devised a recombinant Newcastle disease virus (NDV) vector from a commonly used vaccine strain LaSota to express the host-protective immunogen VP2 of a variant IBDV strain GLS-5. The gene encoding the VP2 protein of the IBDV was inserted into the most 3'-proximal locus of a full-length NDV cDNA for high-level expression. We successfully recovered the recombinant virus, rLaSota/VP2. The rLaSota/VP2 was genetically stable, at least up to 12 serial passages in chicken embryos, and was shown to express the VP2 protein. The VP2 protein was not incorporated into the virions of recombinant virus. Recombinant rLaSota/VP2 replicated to a titer similar to that of parental NDV strain LaSota in chicken embryos and cell cultures. To assess protective efficacy of the rLaSota/VP2, 2-day-old specific-pathogen-free chickens were vaccinated with the recombinant virus and challenged with a highly virulent NDV strain Texas GB or IBDV variant strain GLS-5 at 3 weeks postvaccination. Vaccination with rLaSota/VP2 generated antibody responses against both NDV and IBDV and provided 90% protection against NDV and IBDV. Booster immunization induced higher levels of antibody responses against both NDV and IBDV and conferred complete protection against both viruses. These results indicate that the recombinant NDV can be used as a vaccine vector for other avian pathogens.     

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.