New drugs for malaria are greatly needed. This program is directed toward the development of new boron-containing small molecules as antimalarial drugs. Our preliminary results suggest that novel boron-containing small molecules (oxaboroles) have potent antimalarial activity and, importantly, are likely to meet standard pharmacokinetic and safety criteria for new drugs and also the unique requirements for antimalarials. We hypothesize that a systematic drug discovery program will identify optimized oxaboroles that are relatively simple to produce and meet established criteria for new antimalarial agents. Further, we will use a systematic approach to identify a specific antimalarial mechanism of action for oxaboroles. Appreciation of the mechanism of action will aid in drug optimization and in the understanding of drug resistance. Specifically, we will test the hypothesis that antimalarial oxaboroles inhibit a plasmodial leucyl tRNA synthetase (LeuRS). This hypothesis is based on specific activity of other oxaboroles against fungal or bacterial LeuRS. In addition, we will assess mechanisms of resistance. Our program will entail continued collaboration between Anacor, the world leader in boron chemistry and a malaria research group at the University of California, San Francisco with nearly two decades experience in antimalarial drug discovery.
Specific aims of our program will be 1) hit-to-lead discovery of oxaborole antimalarials, 2) lead optimization of oxaborole antimalarials, and 3) characterization of the mechanisms of action and resistance for lead oxaboroles. We anticipate that, within the time-frame of this project, we will identify a candidate oxaborole antimalarial for development and that we will gain important insights into the antimalarial mechanisms of action of these compounds.

Public Health Relevance

New drugs to treat malaria are greatly needed. This project is directed toward the development of new boron-containing antimalarial drugs and entails collaboration between Anacor, a company with extensive experience with boron-containing drugs, and an experienced malaria research group at the University of California, San Francisco. Key aims of the project will be to identify and optimize active antimalarial compounds and to characterize the mechanisms by which these compounds inhibit malaria parasites.

National Institute of Health (NIH)
National Institute of Allergy and Infectious Diseases (NIAID)
Research Project (R01)
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Drug Discovery and Mechanisms of Antimicrobial Resistance Study Section (DDR)
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Rogers, Martin J
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University of California San Francisco
Internal Medicine/Medicine
Schools of Medicine
San Francisco
United States
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Sonoiki, Ebere; Palencia, Andres; Guo, Denghui et al. (2016) Antimalarial Benzoxaboroles Target Plasmodium falciparum Leucyl-tRNA Synthetase. Antimicrob Agents Chemother 60:4886-95
Zhang, Yong-Kang; Plattner, Jacob J; Easom, Eric E et al. (2015) Benzoxaborole antimalarial agents. Part 4. Discovery of potent 6-(2-(alkoxycarbonyl)pyrazinyl-5-oxy)-1,3-dihydro-1-hydroxy-2,1-benzoxaboroles. J Med Chem 58:5344-54