Novel Influenza A Nanovaccines for Broad Cross Protection

新型甲型流感纳米疫苗可提供广泛的交叉保护

• 批准号: 8837563
• 负责人: Baozhong Wang
• 金额: $ 58.86万
• 依托单位: EMORY UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2012
• 资助国家: 美国
• 起止时间: 2012-05-15 至 2016-04-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/8837563
• 关键词: Aerosols; Antibodies; Antibody Response; Antigen Presentation; Antigens; Baculoviruses; CD8B1 gene; California; Cavia; Cells; Cellular Immunity; Complement; Dendritic Cells; Development; Disease Outbreaks; Dose; Epidemic; Epitopes; Extracellular Domain; Fc Receptor; Generations; Goals; Head; Hemagglutinin; Immune; Immune Sera; Immune response; Immune system; Immunity; Infection; Influenza; Influenza A Virus, H1N1 Subtype; Influenza A Virus, H3N2 Subtype; Influenza A virus; Influenza Hemagglutinin; Influenza prevention; Insecta; Institutes; Investigation; Knockout Mice; Laboratories; Leucine Zippers; Membrane Proteins; Modeling; Molecular Conformation; Mus; Nanotechnology; Particle Size; Phylogenetic Analysis; Production; Proteins; Public Health; Recombinant Proteins; Recombinants; Regimen; Seasons; Solomon Islands; Structure; T cell response; T-Cell Depletion; Tandem Repeat Sequences; Techniques; Technology; Testing; Uncertainty; Universities; Vaccination; Vaccines; Viral; Virion; Virus; Virus Diseases; Virus Shedding; Wisconsin; Wyoming; base; cytotoxicity; density; efficacy testing; immunogenicity; improved; influenza virus vaccine; nanosized; neutralizing monoclonal antibodies; novel; novel strategies; novel vaccines; pandemic influenza; particle; prevent; protective efficacy; protein expression; seasonal influenza; transmission process; uptake; vaccine candidate

DESCRIPTION (provided by applicant): Influenza is a worldwide public health problem. Although current influenza vaccines are effective in battling closely matched viruses, major limitations of current vaccines are the need to produce new vaccines every season, the uncertainty in choice of the correct strains, and the inability to prevent a new influenza pandemic. Improved vaccines inducing broadly protective immune responses against multiple type A influenza viruses are urgently needed, not only for seasonal influenza but also for pandemic influenza prevention. Conserved epitopes are potent immunogens for such vaccines. Combined strategies including improved antigens, new antigen delivery techniques and vaccination regimens should be considered together to overcome current obstacles in the development of a universal influenza vaccine. In the project we propose to generate constructs encoding conserved influenza antigens which are not usually sensed the by host immune system in natural viral infection and seasonal vaccination. We will use the newest nanotechnology approach to produce nanoclusters self-assembled directly from the resulting antigenic proteins as universal influenza vaccine candidates. We will investigate the breadth of cross-protection induced by these nanovaccines in mouse and guinea pig models, and the immune correlate of the cross protection. The three specific aims to be investigated are: 1. Generation of constructs expressing conformation-stabilized HA stalk domain (csHA-stalk) and tetrameric M2e tandem repeat (tM2et) recombinant proteins. The relatively conserved stalk domain in HA is shielded by its globular head domain in virions and is less effectively sensed by immune cells. A csHA-stalk without the globular head will overcome this limitation, and retain its native conformation. Also, tM2et will retain the tetrameric structure of M2e with increased epitope density. 2. Production of nanoclusters self-assembled from csHA-stalk and tM2e antigens. These nano-size particles will be directly self-assembled from the resulting antigenic recombinant proteins, and release intact antigens after uptake. These particles will maximize antigenic payload, control spatial antigen presentation, and regulate release in DCs. We will characterize the size of the particles, antigen content, distribution and release, and internalization by DCs. 3. Investigation of immune responses and the breadth of protective immunity induced by the above nanoclusters and of immune correlates of broad cross-protection. Vaccines based on a combination of HA stalk domains from the two phylogenetic groups may protect against all influenza A viruses. The addition of tM2et will further increase the potential for broad protection. We will study immune responses induced by different nanovaccine combinations, the cross protection to challenge by a panel of influenza A viral strains, and immune correlates of the cross protection.

描述（由申请人提供）：流感是一个全球性的公共卫生问题。虽然目前的流感疫苗在对抗密切匹配的病毒方面是有效的，但目前疫苗的主要局限性是需要每个季节生产新疫苗，选择正确的毒株的不确定性，以及无法预防新的流感大流行。迫切需要诱导针对多种A型流感病毒的广泛保护性免疫应答的改良疫苗，不仅用于季节性流感，而且用于大流行性流感预防。保守表位是此类疫苗的有效免疫原。应同时考虑包括改进抗原、新抗原递送技术和疫苗接种方案在内的组合策略，以克服目前开发通用流感疫苗的障碍。在本项目中，我们提出构建编码保守流感抗原的构建体，这些抗原在自然病毒感染和季节性疫苗接种中通常不被宿主免疫系统感知。我们将使用最新的纳米技术方法直接从所得抗原蛋白质中产生自组装的纳米簇，作为通用流感疫苗候选物。我们将研究这些纳米疫苗在小鼠和豚鼠模型中诱导的交叉保护的广度，以及交叉保护的免疫相关性。 研究的三个具体目标是：1。表达构象稳定的HA茎域（csHA-茎）和四聚体M2 e串联重复（tM 2 et）重组蛋白的构建体的产生。HA中相对保守的茎结构域被病毒粒子中的球状头结构域屏蔽，并且不太能被免疫细胞有效地感知。没有球状头部的csHA柄将克服这种限制，并保持其天然构象。此外，tM 2 et将保留M2 e的四聚体结构，具有增加的表位密度。2.由csHA-茎和tM 2 e抗原自组装的纳米簇的产生。这些纳米尺寸的颗粒将从所得的抗原重组蛋白直接自组装，并在摄取后释放完整的抗原。这些颗粒将使抗原有效载荷最大化，控制空间抗原呈递，并调节DC中的释放。我们将表征颗粒的大小、抗原含量、分布和释放以及DC的内化。3.研究由上述纳米簇诱导的免疫应答和保护性免疫的广度以及广泛交叉保护的免疫相关性。基于来自两个系统发育组的HA茎域的组合的疫苗可以保护免受所有甲型流感病毒的侵害。tM 2 et的加入将进一步增加 具有广泛的保护潜力。我们将研究不同纳米疫苗组合诱导的免疫应答，对一组甲型流感病毒株攻击的交叉保护，以及交叉保护的免疫相关性。