ADHESIN-BASED NANOTHERAPEUTICS IN URINARY TRACT INFECTION

基于粘附素的纳米疗法治疗尿路感染

• 批准号: 7884834
• 负责人: DAVID ALAN HUNSTAD
• 金额: $ 39.8万
• 依托单位: WASHINGTON UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2010
• 资助国家: 美国
• 起止时间: 2010-08-01 至 2015-07-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7884834
• 关键词: Acceleration; Acute; Adhesions; Adhesives; Anti-Bacterial Agents; Anti-Infective Agents; Antibiotic Therapy; Antibiotics; Bacteria; Bacterial Adhesins; Bacterial Infections; Bacterial Proteins; Binding; Biochemical; Biochemistry; Bladder; Bladder Tissue; Cancer Vaccines; Capsid Proteins; Cations; Cells; Cellular biology; Chemicals; Chronic; Chronic Cystitis; Communicable Diseases; Communities; Comprehension; Cystitis; Data; Development; Devices; Electron Microscopy; Engineering; Environment; Epithelial; Epithelial Cells; Epithelium; Escherichia coli; Fiber; Goals; Immunity; In Vitro; Invaded; Knowledge; Location; Malignant Neoplasms; Mediating; Medical; Microbial Biofilms; Modeling; Molecular; Morbidity - disease rate; Mus; Oral; Pathogenesis; Pilum; Plague; Polymers; Population; Process; Property; Proteins; Recurrence; Resistance; Resolution; Seeds; Series; Silver; Site; Source; Specificity; Staging; Surface; Syndrome; System; Techniques; Therapeutic; Therapeutic Agents; Toxic effect; Tumor Cell Derivative Vaccine; Urinary tract; Urinary tract infection; Uropathogenic E. coli; Vaccine Antigen; Viral; Woman; Work; antimicrobial; antimicrobial drug; bacterial resistance; base; carbene; cost; design; exhaustion; experience; flexibility; in vivo; microbial; nanoparticle; nanotherapeutic; novel; novel therapeutics; particle; pathogen; prevent; programs; public health relevance; receptor; residence; targeted delivery; therapy resistant

DESCRIPTION (provided by applicant): The need for new anti-infective agents and strategies is underscored by recent acceleration in bacterial resistance to existing antibiotics and the exhaustion of currently known targets of microbial cell biology and biochemistry. Further anti-infectives development will be driven by discovery of the pathogenic molecular processes of infectious diseases, which are often initiated by host-pathogen encounters at epithelial surfaces. Urinary tract infections (UTIs), a major source of morbidity and medical costs worldwide, are caused primarily by uropathogenic Escherichia coli, which employ an adhesive fiber termed the type 1 pilus to bind and invade bladder epithelial cells. Recurrences are common after acute UTI, and recent data suggest that bacteria establish chronic residence within bladder tissue, resist oral antibiotic therapy, and re-emerge to cause these recurrences. In this application, we propose to deliver anti-infective agents into epithelial cells via the conjugation of antimicrobial-bearing polymer nanoparticles (NPs) with a bacterial adhesin, a protein that confers epithelial binding and invasion capacity upon our model Gram-negative pathogen. Our first objective will be to refine the chemical processes by which a subject protein (specifically the binding domain of the E. coli type 1 pilus adhesin FimH) can be conjugated with favorable orientation and distribution to the exterior of a series of polymer NPs. Second, we will demonstrate the adhesin-dependent internalization of these functionalized NPs into bladder epithelial cells in vitro and in vivo, providing uniquely available controls to prove the specificity of the adhesin-receptor interaction. Third, we will optimize the loading of silver cation and structurally modifiable silver carbene antimicrobials into the NPs. Finally, we propose to demonstrate the anti-infective activity of these antimicrobial-bearing, adhesin-coupled NPs, both in vitro and in murine models of acute and chronic cystitis caused by uropathogenic E. coli. Advantages of this system include the capability to deliver antimicrobials in high concentration to the intracellular compartment where pathogens may reside, avoidance of toxicities associated with systemic antibiotic and NP administration, and flexibility in the structural design of both the protein "coat" and the antimicrobial passenger. Though we will model the utility of our system using bacterial infection of the mammalian urinary tract, the delivery of pharmacologic agents of choice into selected epithelial cell populations will have broader applications spanning infectious diseases, cancer, and vaccine antigen delivery. PUBLIC HEALTH RELEVANCE: Recurrent urinary tract infection (UTI) plagues many otherwise healthy women and complicates other urinary tract conditions. We propose to develop nanoscopic particles bearing silver-based antibacterial agents and coated with a bacterial protein to confer adhesion to the bladder surface. We will evaluate the ability of these nanoparticles to prevent and treat UTI.

描述(由申请人提供)：最近细菌对现有抗生素的抗药性加速，微生物细胞生物学和生物化学的已知靶标耗尽，突显了对新的抗感染药物和策略的需求。感染性疾病的致病分子过程的发现将推动进一步的抗感染药物的开发，这些过程通常是由宿主和病原体在上皮表面相遇启动的。尿路感染(UTIs)是世界范围内发病率和医疗费用的主要来源，主要由尿路致病性大肠杆菌引起，它使用一种名为1型菌毛的粘附性纤维来结合和侵袭膀胱上皮细胞。急性尿路感染后复发是常见的，最近的数据表明细菌在膀胱组织中建立长期驻留，抵抗口服抗生素治疗，并再次出现导致这些复发。在这项应用中，我们建议通过将抗菌聚合物纳米颗粒(NPs)与细菌粘附素结合在一起，将抗感染药物输送到上皮细胞中，细菌粘附素是一种赋予上皮结合和侵袭我们模型革兰氏阴性病原体能力的蛋白质。我们的第一个目标将是改进化学过程，通过这些过程，主题蛋白(特别是大肠杆菌1型粘附素FimH的结合域)可以与一系列聚合物NPs的外部具有良好的定向和分布。其次，我们将证明这些功能化的NPs在体外和体内依赖于粘附素内化到膀胱上皮细胞中，提供独特的可用的对照来证明粘附素-受体相互作用的特异性。第三，我们将优化银阳离子和结构可修饰的银卡宾抗菌剂在纳米粒子中的负载。最后，我们建议在体外和由致尿性大肠杆菌引起的急性和慢性膀胱炎小鼠模型中证明这些携带抗菌剂的粘附素偶联纳米粒的抗感染活性。这一系统的优点包括能够将高浓度的抗菌剂输送到病原体可能驻留的细胞内隔间，避免与全身抗生素和NP给药相关的毒性，以及在蛋白质“外壳”和抗菌剂乘客的结构设计上的灵活性。虽然我们将使用哺乳动物尿路的细菌感染来模拟我们的系统的效用，但将选定的药理药物输送到选定的上皮细胞群体中将有更广泛的应用，包括传染病、癌症和疫苗抗原输送。 公共卫生相关性：复发性尿路感染(UTI)困扰着许多原本健康的女性，并使其他尿路疾病复杂化。我们建议开发含有银基抗菌剂并包覆细菌蛋白的纳米颗粒，以实现对膀胱表面的黏附。我们将评估这些纳米颗粒预防和治疗尿路感染的能力。