IL-12增强流感血凝素DNA疫苗在小鼠中抗流感作用

流感病毒的表面抗原血凝素 (hemagglutinin ,HA)能作为DNA疫苗抗流感病毒攻击 ,在小鼠模型中检测白介素 12 (interleukin 12 ,IL 12 )能否作为HADNA疫苗佐剂增强小鼠抗流感病毒攻击。将IL 12和HA共同免疫小鼠 ,免疫 2次 ,间隔 3周 ,加强免疫后用致死量流感病毒攻击。共同免疫IL 12和HADNA与单独免疫HA相比 ,无论初免还是加强免疫后血清中抗HA的IgG抗体显著提高 ,小鼠体重丢失 (一种临床症状 )明显减少且提高了小鼠的存活率。这些结果表明了IL 12能作为一种佐剂提高流感DNA疫苗的免疫效价。     

H5亚型流感病毒HA头部球状结构域在毕赤酵母中的高效表达及其免疫原性分析

为了研究H5亚型流感病毒HA蛋白中头部球状结构的免疫原性及其基因优化对蛋白表达的影响,本研究构建了重组真核表达载体pPICZ?A-H5HA,并将其转化至毕赤酵母,经筛选获得重组菌株。SDS-PAGE和Western blotting结果分析显示,目的蛋白可在酵母中高效分泌表达,发酵液上清中目的蛋白浓度高达0.2 mg/mL,分子量约为37kDa。将酵母发酵上清经浓缩、纯化后,获得重组目的蛋白H5HA。将不同剂量的H5HA与不同佐剂联用后分别以滴鼻和肌肉注射两种方式免疫试验动物,进行免疫效力的评价。试验结果表明,H5HA具有较好的免疫原性,可诱导SPF鸡产生较高水平的IgG (血凝抑制效价达1∶64、病毒中和抗体效价为1∶218),最佳使用剂量为50μg/羽,与白油佐剂联用时效果最佳,且肌肉注射方式的免疫效果优于滴鼻方式。研究结果为H5亚型流感病毒亚单位疫苗的研制提供了理论支撑。     

流感病毒表面抗原血凝素基因在枯草杆菌中的克隆和表达

前言 流行性感冒仍然是全世界最严重的流行病之一。其病原主要是甲型流感病毒,分为甲_1、甲_2、甲_3三个亚型。当前流行的是甲_1和甲_3型。能有效预防流感的措施是用疫苗免疫。血凝素(HA)是流感病毒表面最重要的抗原,能诱导产生流感病毒中和抗体。从纯化的流感病毒颗粒中提取的血凝素,其免疫性与灭活的流感疫苗相似,但作为亚单位疫苗使用,因生产成本过高,并未广泛推广。     

编码流感病毒血凝素基因和CD40L的核酸疫苗抗小鼠流感研究

为了检测表达CD40L的质粒能否作为核酸疫苗佐剂提高A/PR8/34流感病毒血凝素(HA)DNA疫苗的免疫应答,构建了表达鼠CD40L的质粒,并将它与A型流感病毒的 HA DNA疫苗用电击的方法共同免疫BALB/C小鼠(各30μg),免疫两次,间隔三周,第二次免疫后1周,用致死量流感病毒A/PR8/34攻击.发现与单独免疫30μg HA相比,血清中抗HA的IgG抗体量明显提高,且以IgG2a抗体提高为主,小鼠体重减轻非常少且体重恢复加快.实验结果显示,CD40L能作为流感病毒核酸疫苗佐剂,提高小鼠抗流感病毒攻击的能力.     

编码流感病毒血凝素基因和CD40L的核酸疫苗抗小鼠流感研究

为了检测表达CD40L的质粒能台作为核酸疫苗佐剂提高A／PR8／34流感病毒血凝素(HA)DNA疫苗的免疫应答,构建了表达鼠CD40L的质粒,行将它与A型流感病毒的HADNA疫苗用电击的方法共同免疫BALB／C小鼠(各30μg),免疫两次,间隔三周,第二次免疫后1周,用致死量流感病毒A／PR8／34攻击。发现与单独免疫30μgHA相比,血清中抗HA的IgG抗体节明显提高,且以IgG2a抗体提高为主,小鼠体重减轻非常少且体重恢复加快。实验结果显示,CD40L能作为流感病毒核酸疫苗佐剂,提高小鼠抗流感病毒攻击的能力。     

流感HA疫苗鼻内接种中联合使用霍乱毒素B亚单位可加强DTH应答

<正>为提高普通疫苗和合成疫苗的功效,有必要寻找出安全、有效的用于人体的适宜佐剂。近来我们已报导了霍乱毒素B亚单位(CTB),它作为佐剂用于鼻内流感HA疫苗免疫大有希望。即:BALB/c小鼠以A型流感病毒HA疫苗和CTB联合鼻内接种后,即可产生高水平鼻内IgA抗体,这种抗体与不同的A型流感病毒HA疫苗有交叉反应性,又可诱发对病毒攻击的交叉抗性。     

枸杞多糖对H5N1流感全病毒灭活疫苗的体液免疫增强作用

探讨枸杞多糖(Lycium barbarum polysaccharide,LBP)作为佐剂对H5亚型流感病毒全病毒灭活疫苗的体液免疫增强效果。将流感病毒A/Vietnam/1194/2004(H5N1)灭活疫苗与不同剂量的枸杞多糖混合后以腹腔注射的方式共同免疫小鼠,免疫后三周收集血清用于特异性抗体检测。实验中设立氢氧化铝佐剂组作对照共同评价LBP作为佐剂的免疫增强效果。结果显示,小鼠血清中针对H5灭活疫苗的特异性抗体水平在一定范围内随着LBP剂量的增加而提高。LBP在800μg剂量时血清特异性抗体水平较无佐剂组显著增强,并与氢氧化铝佐剂组大致相当。因而,LBP有可能成为一种有效的流感灭活疫苗免疫佐剂。     

阳离子脂质体DOTAP佐剂对H5N1流感病毒裂解疫苗免疫效果的影响

目的研究阳离子脂质体DOTAP佐剂对H5N1型流感病毒裂解疫苗免疫效果的影响。方法制备DOTAP阳离子脂质体流感病毒裂解疫苗(简称DOTAP流感裂解疫苗),检测其包封率。将BALB/c小鼠分为13组,分别用含0.1、1.0、10.0μg HA/只剂量以DOTAP、Al(OH)3、CPG-ODN为佐剂以及不含佐剂的流感裂解疫苗于0、21天皮下免疫,PBS作为对照组,用血凝抑制试验检测小鼠初次免疫后21、42天血清HI抗体滴度;用ELISA检测初次免疫后21、42天血清特异性IgG抗体、IgG1、IgG2a亚类抗体滴度,以及初次免疫后42天小鼠脾脏单个核细胞体外经抗原刺激后细胞因子IL-2、IL-4、IFN-γ的分泌水平。将BALB/c小鼠分为3组,分别用含不同DOTAP剂量(100、300、600μg/只)的DOTAP流感裂解疫苗于0、21天皮下免疫,检测初次免疫后21、42天小鼠血清HI抗体滴度和IgG抗体滴度。结果 DOTAP流感裂解疫苗粒径在300~400 nm,带正电荷,包封率在50%以上;DOTAP流感裂解疫苗诱导的HI抗体水平和特异性IgG抗体水平均高于流感裂解疫苗,而与铝佐剂和Cp G-ODN佐剂间差异无统计学意义;DOTAP流感裂解疫苗产生的抗体仍以IgG1亚类抗体为主,免疫后42天诱导的IgG2a亚类抗体水平高于流感裂解疫苗和铝佐剂,低于Cp G-ODN佐剂;DOTAP流感裂解疫苗免疫后既分泌高水平Th1型细胞因子IFN-γ,同时也分泌高水平Th2型细胞因子IL-4;不同DOTAP剂量的DOTAP流感裂解疫苗免疫后,其HI抗体滴度和IgG抗体滴度在低、中、高剂量组之间存在明显的量效关系。结论 DOTAP作为H5N1型流感病毒裂解疫苗的佐剂可显著提高流感裂解疫苗的免疫原性,其对体液免疫应答的增强作用不低于铝佐剂和Cp G-ODN佐剂,并具有诱导细胞免疫应答的能力。     

含乙型肝炎病毒S-PreS1 基因的DNA疫苗与蛋白颗粒疫苗联合免疫可增强免疫应答

为研制新型有效的HBV治疗性疫苗,构建了含PreS1与S融合基因的HBV DNA疫苗,即pVRC-HBSS1 (PreS1 21–47 aa融合在S抗原1–223的羧基端),并制备了CHO表达相同结构的蛋白颗粒亚单位疫苗HBSS1。在Balb/C小鼠中采用不同的DNA免疫方式 (即肌肉注射、皮内注射加电转) 初免3次,蛋白颗粒亚单位疫苗 (不同佐剂) 肌肉注射加强免疫1次,然后我们分析比较了各组疫苗所引起的免疫应答特点。抗体检测结果表明：皮内注射结合电转初免组产生的PreS1与 S特异性抗体水平皆高于肌肉直接注射组。进一步还发现DNA疫苗与蛋白颗粒亚单位疫苗两种疫苗联合应用后S抗原特异的细胞免疫应答 (IFN-γ ELISpot分析) 明显高于DNA疫苗或蛋白颗粒亚单位单独应用,其中皮内注射+电转结合蛋白颗粒亚单位疫苗联合免疫组可产生最强的细胞免疫应答。这些研究为新型HBV 治疗性疫苗的优化设计与合理应用提供了依据。     

3种市售免疫调节剂作为流感病毒融合蛋白NM2e亚单位疫苗佐剂的研究

目的:观察具有免疫调节作用的市售左旋咪唑、西米替丁、伐地那非作为甲型流感病毒核蛋白(NP)与基质蛋白2胞外区多肽(M2e)融合蛋白NM2e亚单位疫苗佐剂的可能性。方法:将左旋咪唑、西米替丁、伐地那非单独或者分别与Al(OH)3配伍作为NM2e蛋白佐剂,经肌肉注射免疫BALB/c小鼠,通过体液和细胞免疫检测及病毒攻击实验研究这些免疫调节剂作为疫苗佐剂的可能性。结果:左旋咪唑对NM2e蛋白亚单位疫苗无明显的佐剂效应,但与铝佐剂合用可使攻毒后存活小鼠体重恢复加快;西米替丁可以明显提高NM2e蛋白诱发的特异性IgG2a滴度,提高攻毒后小鼠的存活率(30%),但保护效果明显低于铝佐剂(70%),与铝佐剂无明显的协同作用;伐地那非能明显增加NM2e蛋白诱发的特异性IgG1、IgG2a滴度,提高攻毒后小鼠的存活率(36%),但与铝佐剂合用有相互抑制作用。结论:左旋咪唑、西米替丁、伐地那非对NM2e蛋白均有一定的免疫调节作用,其中西米替丁和伐地那非能提高攻毒保护效果,但保护效果明显低于Al(OH)3,与Al(OH)3联合使用均无协同作用。     

Preliminary study about sublingual administration of bacteria-expressed pandemic H1N1 influenza vaccine in miniature pigs

Sublingual (SL) administration of influenza vaccine would be non-invasive and effective way to give human populations protective immunity against the virus, especially when pandemic influenza outbreaks. In this study, the efficacy of pandemic influenza virus-based subunit vaccines was tested after sublingual (SL) adjuvant administration in pigs. Eight specific pathogen-free Yucatan pigs were divided into 4 groups: nonvaccinated but challenged (A) and vaccinated and challenged (B, C, and D). The vaccinated groups were subdivided by vaccine type and inoculation route: SL subunit vaccine (hemagglutinin antigen 1 [HA1] + wild-type cholera toxin [wtCT], B); IM subunit vaccine (HA1 + aluminum hydroxide, C); and IM inactivated vaccine (+ aluminum hydroxide, D). The vaccines were administered twice at a 2-week interval. All pigs were challenged with pandemic influenza virus (A/swine/GCVP-KS01/2009 [H1N1]) and monitored for clinical signs, serology, viral shedding, and histopathology. After vaccination, hemagglutination inhibition titre was higher in group D (320) than in the other vaccinated groups (40–80) at the time of challenge. The mobility and feed intake were reduced in group C. Both viral shedding and histopathological lesions were reduced in groups B and D. Although this study has limitation due to the limited number of pigs (2 pigs per a group), the preliminary data in this study provided the protective potential of SL administration of bacteria-expressed pandemic H1N1 influenza vaccine in pigs. There should be additional animal studies about effective adjuvant system and vaccine types for the use of SL influenza vaccination.     

A viral vaccine vector that expresses foreign genes in lymph nodes and protects against mucosal challenge.

A candidate live-virus vaccine strain of Venezuelan equine encephalitis virus (VEE) was configured as a replication-competent vector for in vivo expression of heterologous immunogens. Three features of VEE recommend it for use as a vaccine vector. (i) Most human and animal populations are not already immune to VEE, so preexisting immunity to the vector would not limit expression of the heterologous antigen. (ii) VEE replicates first in local lymphoid tissue, a site favoring the induction of an effective immune response. (iii) Parenteral immunization of rodents and humans with live, attenuated VEE vaccines protects against mucosal challenge, suggesting that VEE vaccine vectors might be used successfully to protect against mucosal pathogens. Upon subcutaneous (s.c.) inoculation into the footpad of mice, a VEE vector containing the complete influenza virus hemagglutinin (HA) gene expressed HA in the draining lymph node and induced anti-HA immunoglobulin G (IgG) and IgA serum antibodies, the levels of which could be increased by s.c. booster inoculation. When immunized mice were challenged intranasally with a virulent strain of influenza virus, replication of challenge virus in their lungs was restricted, and they were completely protected from signs of disease. Significant reduction of influenza virus replication in the nasal epithelia of HA vector-immunized mice suggested an effective immunity at the mucosal surface. VEE vaccine vectors represent an alternative vaccination strategy when killed or subunit vaccines are ineffective or when the use of a live attenuated vaccine might be unsafe.     

Modified pulmonary surfactant is a potent adjuvant that stimulates the mucosal IgA production in response to the influenza virus antigen

The intranasal administration of influenza hemagglutinin (HA) vaccine with Surfacten, a modified pulmonary surfactant free of antigenic c-type lectins, as a mucosal adjuvant induced the highest protective mucosal immunity in the airway. The intranasal immunization of mice with HA vaccine (0.2 microg)-Surfacten (0.2 microg) selectively induced the neutralizing anti-HA IgA, but not IgG, and conferred nearly maximal protection in the airway, without inducing a systemic response. In contrast, intranasal inoculation of vaccine with 0.2 microg of the potent mucosal adjuvant cholera toxin B* (CT-B*), prepared by adding 0.2% native CT to the B subunit of CT, induced both anti-HA IgA and IgG in the airway and in the serum. The intranasal administration of HA vaccine alone induced a limited amount of mucosal IgA against influenza virus. Although the s.c. administration of HA vaccine prominently induced serum IgG and IgA, Surfacten and CT-B* did not enhance their induction, and the concentrations of Abs leaking into the airways were insufficient to prevent viral multiplication. The intranasal administration of HA-Surfacten stimulated the expression of MHC class II, CD40, and CD86 molecules in the CD11c-positive cells isolated from the nasal mucosa, but not the expression of cells from the lungs or spleens. Lymphocytes isolated from the airway mucosa after intranasal HA-Surfacten immunization prominently induced TGF-beta1 which, compared with inoculation without Surfacten, promoted an Ag-specific mucosal IgA response. Surfacten alone, however, did not induce TGF-beta1. Our observations suggest that Surfacten, by mimicking the natural surfactant, is an effective mucosal adjuvant in the process of airway immunization.     

Protective effect of nasal immunization of influenza virus hemagglutinin with recombinant cholera toxin B subunit as a mucosal adjuvant in mice

To develop an efficient nasal influenza vaccine, influenza A and B virus HA with rCTB as a mucosal adjuvant were administered to mice intranasally. Serum anti-HA IgG and IgA antibody responses for both HA vaccines were significantly increased in the presence of rCTB. Higher HI and neutralizing antibody titers and higher mucosal IgA antibody responses in the respiratory tract were detected when rCTB was added than without rCTB. When mice were immunized with HA vaccine with or without rCTB and challenged by intranasal administration of mouse-adapted pathogenic influenza A virus, all mice immunized with HA plus rCTB survived for seven days without any inflammatory changes in the lungs, while not all the mice immunized with HA without rCTB survived, and all of them had lung consolidations. These results demonstrate that intranasal co-administration of rCTB as a mucosal adjuvant with influenza virus HA is necessary not only for the induction of systemic and mucosal HA antibodies, but also for the protection of mice from morbidity and mortality resulting from virus infection.     

Enhancement of DTH response by cholera toxin B subunit inoculated intranasally together with influenza HA vaccine

The effects of B subunit of cholera toxin (CTB) on delayed-type hypersensitivity (DTH) response to influenza vaccine derived from influenza virus A/PR/8/34 (PR-8, HlNl) virus were investigated in B10 mice that were immunized intranasally with both influenza vaccine and CTB. The result showed that intranasal inoculation of this combination augmented DTH response to influenza vaccine, which reached its peak 6 days after inoculation, and also induced accelerated DTH response upon a second inoculation of influenza vaccine alone 4 weeks later, that the cross-reactive DTH response to PR-8 vaccine was elicited by the injection of the different influenza A-type virus vaccine into the footpad of the vaccinated mice, but was not by influenza B-type virus vaccine, that the DTH-mediating T cells were detected selectively in the lungs of mice that received the nasal inoculation of the vaccine and CTB together, but that subcutaneous inoculation of this combination failed to induce DTH-mediating T cells in the lungs. These results, together with the previous papers (Tamura et al, Vaccine 7: 257-262; 314-320, 1989), suggest that CTB could augment both humoral and DTH responses against influenza vaccine in the respiratory mucosal tract.     

Chitosan Nanoparticle Encapsulated Hemagglutinin-Split Influenza Virus Mucosal Vaccine

Subunit/split influenza vaccines are less reactogenic compared with the whole virus vaccines. However, their immunogenicity is relatively low and thus required proper adjuvant and/or delivery vehicle for immunogenicity enhancement. Influenza vaccines administered intramuscularly induce minimum, if any, mucosal immunity at the respiratory mucosa which is the prime site of the infection. In this study, chitosan (CS) nanoparticles were prepared by ionic cross-linking of the CS with sodium tripolyphosphate (TPP) at the CS/TPP ratio of 1:0.6 using 2 h mixing time. The CS/TPP nanoparticles were used as delivery vehicle of an intranasal influenza vaccine made of hemagglutinin (HA)-split influenza virus product. Innocuousness, immunogenicity, and protective efficacy of the CS/TPP-HA vaccine were tested in influenza mouse model in comparison with the antigen alone vaccine. The CS/TPP-HA nanoparticles had required characteristics including nano-sizes, positive charges, and high antigen encapsulation efficiency. Mice that received two doses of the CS/TPP-HA vaccine intranasally showed no adverse symptoms indicating the vaccine innocuousness. The animals developed higher systemic and mucosal antibody responses than vaccine made of the HA-split influenza virus alone. The CS/TPP-HA vaccine could induce also a cell-mediated immune response shown as high numbers of IFN-γ-secreting cells in spleens while the HA vaccine alone could not. Besides, the CS nanoparticle encapsulated HA-split vaccine reduced markedly the influenza morbidity and also conferred 100% protective rate to the vaccinated mice against lethal influenza virus challenge. Overall results indicated that the CS nanoparticles invented in this study is an effective and safe delivery vehicle/adjuvant for the influenza vaccine.     

Cationic lipid/DNA complex-adjuvanted influenza A virus vaccination induces robust cross-protective immunity

Influenza A virus is a negative-strand segmented RNA virus in which antigenically distinct viral subtypes are defined by the hemagglutinin (HA) and neuraminidase (NA) major viral surface proteins. An ideal inactivated vaccine for influenza A virus would induce not only highly robust strain-specific humoral and T-cell immune responses but also cross-protective immunity in which an immune response to antigens from a particular viral subtype (e.g., H3N2) would protect against other viral subtypes (e.g., H1N1). Cross-protective immunity would help limit outbreaks from newly emerging antigenically novel strains. Here, we show in mice that the addition of cationic lipid/noncoding DNA complexes (CLDC) as adjuvant to whole inactivated influenza A virus vaccine induces significantly more robust adaptive immune responses both in quantity and quality than aluminum hydroxide (alum), which is currently the most widely used adjuvant in clinical human vaccination. CLDC-adjuvanted vaccine induced higher total influenza virus-specific IgG, particularly for the IgG2a/c subclass. Higher levels of multicytokine-producing influenza virus-specific CD4 and CD8 T cells were induced by CLDC-adjuvanted vaccine than with alum-adjuvanted vaccine. Importantly, CLDC-adjuvanted vaccine provided significant cross-protection from either a sublethal or lethal influenza A viral challenge with a different subtype than that used for vaccination. This superior cross-protection afforded by the CLDC adjuvant required CD8 T-cell recognition of viral peptides presented by classical major histocompatibility complex class I proteins. Together, these results suggest that CLDC has particular promise for vaccine strategies in which T cells play an important role and may offer new opportunities for more effective control of human influenza epidemics and pandemics by inactivated influenza virus vaccine.     

A Novel Influenza Virus Hemagglutinin-Respiratory Syncytial Virus (RSV) Fusion Protein Subunit Vaccine against Influenza and RSV

Influenza A virus and respiratory syncytial virus (RSV) cause substantial morbidity and mortality afflicting the ends of the age spectrum during the autumn through winter months in the United States. The benefit of vaccination against RSV and influenza using a subunit vaccine to enhance immunity and neutralizing antibody was investigated. Influenza virus hemagglutinin (HA) and RSV fusion (F) protein were tested as vaccine components alone and in combination to explore the adjuvant properties of RSV F protein on HA immunity. Mice vaccinated with HA and F exhibited robust immunity that, when challenged, had reduced viral burden for both influenza and RSV. These studies show an enhancing and cross-protective benefit of F protein for anti-HA immunity.     

Immune response to human influenza virus hemagglutinin expressed in Escherichia coli

Cloned DNA fragments coding for parts of strain WSN (H1N1) influenza virus hemagglutinin (HA) were fused to a bacterial leader DNA derived from the Escherichia coli trp operon. Fusion proteins produced consisted of 190 amino acids of trpLE' protein at the amino terminus, and HA amino acids, either 1-308, 1-396, or 1-548 (complete HA), at the carboxyl terminus. These proteins were expressed at high levels (10-20% of total protein) in E. coli starved for tryptophan. A CNBr fragment (HA1-211) was derived from HA-308. Each of the proteins was purified and used for immunizing mice and rabbits. The antibody produced was shown to bind to (i) the HA fusion proteins, (ii) detergent-treated viral HA, (iii) HA, on intact virions, and (iv) the HA on the surface of cells infected with influenza virus. This shows that the HA fusion proteins expressed in bacteria can elicit antibodies that recognize at least some determinants of the native viral HA, and probably could lead to development of an anti-influenza vaccine.     

Evaluation of MDCK Cell-Derived Influenza H7N9 Vaccine Candidates in Ferrets

Avian-origin influenza A (H7N9) viruses emerged as human pathogens in China in early 2013 and have killed >100 persons. Influenza vaccines are mainly manufactured using egg-based technology which could not meet the surging demand during influenza pandemics. In this study, we evaluated cell-based influenza H7N9 vaccines in ferrets. An egg-derived influenza H7N9 reassortant vaccine virus was adapted in MDCK cells. Influenza H7N9 whole virus vaccine antigen was manufactured using a microcarrier-based culture system. Immunogenicity and protection of the vaccine candidates with three different formulations (300μg aluminum hydroxide, 1.5μg HA, and 1.5μg HA plus 300μg aluminum hydroxide) were evaluated in ferrets. In ferrets receiving two doses of vaccination, geometric mean titers of hemagglutination (HA) inhibition and neutralizing antibodies were <10 and <40 for the control group (adjuvant only), 17 and 80 for the unadjuvanted (HA only) group, and 190 and 640 for the adjuvanted group (HA plus adjuvant), respectively. After challenge with wild-type influenza H7N9 viruses, virus titers in respiratory tracts of the adjuvanted group were significantly lower than that in the control, and unadjuvanted groups. MDCK cell-derived influenza H7N9 whole virus vaccine candidate is immunogenic and protective in ferrets and clinical development is highly warranted.