Infection Site Targeted Antitoxin Antibody (ISTAb) against Bacillus anthracis

针对炭疽杆菌的感染部位靶向抗毒素抗体 (ISTAb)

基本信息

批准号：
9255053
负责人：
Rajan P Adhikari
金额：
$ 29.49万
依托单位：
INTEGRATED BIOTHERAPEUTICS, INC.
依托单位国家：
美国
项目类别：
财政年份：
2017
资助国家：
美国
起止时间：
2017-02-15 至 2019-01-31
项目状态：
已结题

来源：
https://reporter.nih.gov/project-details/9255053
关键词：
Address Adverse effects Affinity Alpha Cell Animals Anthrax Vaccines Anthrax disease Antibiotic Therapy Antibiotics Antibodies Antigens Antitoxins Award Bacillus (bacterium)Bacillus anthracis Bacillus anthracis spore Bacteria Bacterial Toxins Bacteriophages Binding Binding Sites Biological Assay Biological Response Modifier Therapy Bioterrorism Blood Circulation Cartoons Catalytic Domain Cell Wall Cells Centers for Disease Control and Prevention (U.S.)Chimeric Proteins Clostridium difficile Codon Nucleotides Collaborations Complex Contracts Disease Environment Enzymes Escherichia coli Exposure to Fc Receptor Fluorescence Food Generations Goals Gram-Positive Bacteria Human Immune In Vitro Infection Inflammation Journals Laboratories Length Letters Life Link Mammals Maryland Mediating Microscopic Monoclonal Antibodies Mus N-terminal Nature Oral Organism Pathogenesis Performance Phagocytes Play Polysaccharides Powder dose form Probability Proteins Public Health Publishing Recommendation Reporter Reporting Reproduction spores Resistance Risk Role Route Safety Site Skin Species Specificity Specificity Surface Surface Plasmon Resonance Technology Testing Therapeutic Time Tissues Toxin USSR Vaccines Virulence Water Zoonoses aerosolized anthrax lethal factor anthrax protective factor bactericide base cost edema factor efficacy testing endolysin gastrointestinal human monoclonal antibodies immunogenicity improved in vivo killings mass casualty member mouse model neutralizing monoclonal antibodies neutrophil new technology news novel strategies pathogen prevent prototype scaffold screening synergism weapons

项目摘要

Project Summary The Gram-positive bacterium Bacillus anthracis is a very strong candidate for potential bio- weaponization, and believed to have actually been weaponized by the former Soviet Union. Anthrax spores are readily found in nature or produced in the laboratory, are resistant to harsh conditions, and can survive for a long time in the environment. The microscopic spores could be formulated in powder form, sprays, food, or water. Two key toxins generated by combination of the protective antigen (PA) with either lethal factor (LF) or edema factor (EF) play a critical role in B. anthracis virulence. Current CDC recommendations following potential exposure to aerosolized B. anthracis spores consist of a combination of oral antibiotics and PA-based anthrax vaccine. However, in practice, these treatments cannot adequately address the adverse effects of bacterial toxins released post exposure. In this R41 proposal we intend to develop a novel approach to target neutralizing anti- toxin antibodies specifically to the site of infection. The approach exploits the cell wall targeting domains (CWT) of well characterized phage endolysins: PlyG, PlyL and PlyB which bind with species-specificity and high affinity to cell wall components of B. anthracis. Theses CWTs will be fused to specific antitoxin neutralizing monoclonal antibodies to generate Infection Site Targeted Antitoxin antibodies (ISTAbs). ISTAbs are expected to accumulate at the site of infection where they are needed most, and capture and sequester the toxins, thus immediately neutralizing the effects of the toxins and preventing their release into circulation. Bacterium-toxin complex is then expected to be cleared by phagocytes. In this proposal, we will use three anthrax-PA neutralizing monoclonal antibodies fused to high affinity phage endolysin CWTs to generate ISTAbs. In Aim 1 we will screen for best binding CWTs from ten phage endolysins, including those from PlyG, PlyL, and PlyB. We will characterize them based on in vivo and in vitro binding. In Aim 2, based on Aim 1 results, we will select 3 CWTs for generating up to nine ISTAbs by fusing the CWTs with three highly neutralizing anti-Anthrax monoclonal antibody as scaffold and characterize them for in vitro binding and toxin neutralizing activity. In Aim 3 we will further characterize the selected ISTAbs based on stability; bacterial cell binding specificity and affinity, and performance in opsonophagocytic killing assays. In Aim 4, we will perform efficacy testing in pre-challenge and post challenge treatment mouse models and also explore potential immunogenicity of the ISTAbs. Since ISTAb technology provides two therapeutic advantages: immediate toxin neutralization at the site of infection and opsonophagocytic killing by phagocyte, there is a high probability that these molecules will synergize with existing antibiotics. The combination of immediate toxin clearance, phagocytic killing, and concurrent use of antibiotics is expected to create synergy and yield a treatment that is far superior to the current standard of vaccine plus antibiotics. Furthermore, this technology can be applied to a variety of other bacterial pathogens where toxins play a key role in pathogenesis. Overall, this approach has board application as a platform technology across multiple pathogens.

项目概要革兰氏阳性细菌炭疽杆菌是潜在生物武器化的有力候选者，并且据信实际上已被前苏联武器化。炭疽孢子很容易发现于自然或实验室生产，能抵抗恶劣的条件，可以在环境中长期生存环境。微观孢子可以配制为粉末、喷雾剂、食物或水。两种关键毒素由保护性抗原 (PA) 与致死因子 (LF) 或水肿因子 (EF) 结合产生在炭疽芽孢杆菌毒力中起关键作用。潜在接触后 CDC 的当前建议雾化炭疽芽孢杆菌孢子由口服抗生素和基于 PA 的炭疽疫苗组合而成。然而，在实践中，这些治疗方法并不能充分解决细菌毒素的不利影响曝光后发布。在这个 R41 提案中，我们打算开发一种新方法来中和抗- 特异性针对感染部位的毒素抗体。该方法利用细胞壁靶向域 (CWT) 充分表征的噬菌体内溶素：PlyG、PlyL 和 PlyB，它们以物种特异性和高亲和力结合炭疽芽孢杆菌的细胞壁成分。这些 CWT 将与特定的抗毒素中和单克隆抗体融合抗体产生感染部位靶向抗毒素抗体（ISTAb）。 ISTAb 预计在最需要的感染部位积聚，捕获并隔离毒素，从而立即中和毒素的影响并防止其释放到循环中。细菌毒素然后预计复合物将被吞噬细胞清除。在本提案中，我们将使用三种炭疽-PA 中和剂单克隆抗体与高亲和力噬菌体内溶素 CWT 融合以生成 ISTAb。在目标 1 中，我们将筛选十种噬菌体内溶素（包括来自 PlyG、PlyL 和 PlyB 的噬菌体内溶素）的最佳结合 CWT。我们将根据体内和体外结合来表征它们。在目标 2 中，基于目标 1 结果，我们将选择 3 个 CWT 通过将 CWT 与三种高度中和的抗炭疽单克隆抗体融合，生成多达 9 种 ISTAb 抗体作为支架并表征它们的体外结合和毒素中和活性。在目标 3 中，我们将根据稳定性进一步表征所选的 ISTAb；细菌细胞结合特异性和亲和力，以及调理吞噬杀伤试验中的性能。在目标 4 中，我们将在攻击前和攻击前进行功效测试攻击后治疗小鼠模型，并探索 ISTAb 的潜在免疫原性。由于 ISTAb 技术提供了两个治疗优势：感染和吞噬细胞调理吞噬杀伤，这些分子很可能会与现有抗生素有协同作用。立即清除毒素、吞噬细胞杀灭和同时使用抗生素有望产生协同作用并产生远远优于目前的治疗方法疫苗加抗生素的标准。此外，该技术还可应用于多种其他细菌毒素在发病机制中起关键作用的病原体。总的来说，这种方法在电路板应用中作为一种跨多种病原体的平台技术。