Cholesterol metabolism in Mtb is an attractive target for basic research and new drug development efforts. The Mtb cholesterol metabolic pathway is specific to the bacteria and mutants defective in this pathway are attenuated in various infection models. This suggests that chemically inhibiting this pathway will also attenuate Mtb virulence in vivo. We recently discovered a compound series that blocks cholesterol uptake in Mtb and stimulates cAMP overproduction in the bacteria. This is important since cAMP regulates mycobacterial central metabolism, transcription, pathogenicity, dormancy, and stress responses. Thus, chemically stimulating cAMP production in Mtb will perturb multiple different aspects of bacterial physiology in addition to cholesterol utilization. Granulomas are a major pathologic barrier that limits immune cell recruitment and antibiotic diffusion. Within a granuloma Mtb is sequestered in a cholesterol rich and hypoxic microenvironment that is thought to favor bacterial persistence. During infection, M??s produce TNF-? which drives TB tissue pathology and is required to form and maintain granulomas. It is thought that TNF-? depletion can disturb the granuloma architecture and promote enhanced antibiotic availability or disrupt the granuloma microenvironment making TB antibiotics more effective. It has long been known that TNF-? production by M??s can be down regulated in response to high levels of cytosolic cAMP and it is also known that Mtb-derived cAMP down regulates TNF-? production in M??s. Our compound series stimulates enough Mtb-derived cAMP to down regulate TNF-? production at the infected cell level. Thus, stimulating cAMP overproduction in Mtb could be a novel strategy to reduce TNF-? levels specifically in infected M??s to enhance the activity of current TB drugs. Here we propose to characterize the molecular mechanisms of how these probes block cholesterol uptake and stimulate the overproduction of cAMP in Mtb (Aim 1). We also will determine how Mtb-derived cAMP modulates: (i) the host immune response, (ii) M? function, and (iii) evaluate the efficacy of V-59 alone and in combination with known TB antibiotics in vivo with a goal of evaluating the therapeutic potential of V-59 (Aim 2). Because we already have a compound that has excellent potency and demonstrates in vivo efficacy via the oral route, we are well positioned to make progress with a potential TB drug candidate and novel treatment strategy.

Public Health Relevance

Mycobacterium tuberculosis (Mtb) is the causative agent of Tuberculosis and is responsible for approximately 1.5 million deaths annually. A key component of this disease is the bacterium?s ability to persist for long periods of time in the human host. This research will characterize the mechanism of action for compounds that inhibit cholesterol uptake in Mtb and evaluate the efficacy of these compounds against Mtb in infection models. These studies will allow us to better understand cholesterol uptake in Mtb and determine if our cholesterol uptake inhibitors have therapeutic potential.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
1R01AI130018-01A1
Application #
9448277
Study Section
Drug Discovery and Mechanisms of Antimicrobial Resistance Study Section (DDR)
Program Officer
Boyce, Jim P
Project Start
2017-09-25
Project End
2022-08-31
Budget Start
2017-09-25
Budget End
2018-08-31
Support Year
1
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Cornell University
Department
Microbiology/Immun/Virology
Type
Schools of Veterinary Medicine
DUNS #
872612445
City
Ithaca
State
NY
Country
United States
Zip Code
14850
Wilburn, Kaley M; Fieweger, Rachael A; VanderVen, Brian C (2018) Cholesterol and fatty acids grease the wheels of Mycobacterium tuberculosis pathogenesis. Pathog Dis 76:
Johnson, Richard M; Bai, Guangchun; DeMott, Christopher M et al. (2017) Chemical activation of adenylyl cyclase Rv1625c inhibits growth of Mycobacterium tuberculosis on cholesterol and modulates intramacrophage signaling. Mol Microbiol 105:294-308