Research Project
10157412
PROJECT SUMMARY/ABSTRACT Lyme borreliosis, also known as Lyme disease, remains a prevalent tick-borne infection in many parts of the world. In the United States alone, there are over 300,000 new cases occurring each year. The infection is caused by Borrelia burgdorferi sensu lato, which is a group of atypical extracellular bacterial pathogens that survive in nature through a complex enzootic infection cycle, involving ticks belonging to the Ixodes scapularis complex and an array of vertebrate hosts, most commonly wild rodents. Despite serious efforts to control the infection over the past several decades, the infection persists, largely due to the absence of effective control measures against tick infestation, lack of human vaccines, difficulties in diagnosis of early infection, and clinical complications associated with treatment using currently-available antimicrobials. Specifically, several months after standard-care antibiotic therapy, a subset of patients can experience a series of persistent or relapsing symptoms, known as chronic Lyme disease or post-treatment Lyme disease syndrome, for which further treatment options remain unavailable. Therefore, the development of vaccines and new drugs is highly warranted to combat Lyme disease. This project pursues a long-term goal to understand the biological significance of a critical set of microbial virulence determinants and gain knowledge necessary for the development of new therapeutic strategies to intervene with Lyme borreliosis. The emphasis is on protein- protein interactions essential for pathogen infection and persistence in the host, and the goal is to provide comprehensive structural and functional information that defines the biological significance of three spirochete proteins annotated as BB0323, BB0238, and BB0104 (BbHtrA), each of which either independently or as a complex are essential for infection. The previous project cycle demonstrated that the targeted deletion or alteration of either protein partners or short binding epitopes impact protein stability and render the pathogen non-infectious in a mammalian host. The overall objective of the current proposal is to further focus on BB0323 and associated proteins in order to: 1) define the specific events of protein maturation, 2) determine protein-protein interactions, and 3) contribute to the determination of their structures to better understand their roles in dictating spirochete infection in mammals and transmission from ticks. These studies will enlighten our fundamental knowledge of the atypical biology of spirochetes and will facilitate the design of non-traditional anti-infective strategies to combat Lyme borreliosis, including the development of vaccines, small molecule drugs, and biologics.
