Tuberculosis (TB)?which is primarily caused by the bacterial pathogen Mycobacterium tuberculosis (Mtb)?is an ancient disease that remains one of the deadliest communicable diseases worldwide. A paramount concern heading into the future is the rapid rise in drug-resistant TB. The World Health Organization estimated 480,000 cases of TB with 190,000 deaths in 2014 with resistance to the first-line anti-TB drugs isoniazid and rifampicin. Furthermore, totally drug-resistant Mtb has now been documented in multiple countries including the United States. The capuramycin family of glycosylated nucleoside antibiotics are excellent candidates for anti-TB drug discovery and development because they (i) are considered new chemical entities with several unusual structural features compared to all antibiotics including clinical anti-TB drugs, (ii) target a novel and essential enzyme (translocase 1; TL1) in cell wall biosynthesis, (ii) have exceptional anti-Mtb activity in vitro and in vivo, (iv) are bactericidal and kill Mtb faster than any first-line anti-TB drug in vitro, and (v) have no toxicity. Our primary objectives in this proposal are to define a biosynthetic mechanism for the assembly of the unusual unsaturated hexuronic acid component in capuramycins (Aim 1) and establish complementary chemical (via neoglycorandomization;
Aim 2) and biosynthetic (via native and nonnative glycosyltransferases;
Aim 3) platforms for rapidly generating novel hexuronic acid-substituted capuramycins that can be screened for TL1 inhibition, anti-Mtb activity, and improved pharmacological properties. Additionally, these novel capuramycin analogues will be screened as potential substrates or inhibitors of the phosphotransferase CapP, which covalently modifies capuramycin as a strategy of self-resistance within the producing strain and is potentially a widespread resistance mechanism. It is expected that, upon completion of the aims, a new biosynthetic mechanism for sugar incorporation and modification will be defined. Furthermore, the completion of the aims will provide the first practical, comprehensive strategy to rapidly interrogate/modulate the fundamental features of capuramycin core pharmacophore, which will not only be important for the clinical development of capuramycin but can be applied to other glycosylated nucleoside antibiotics, of which dozens are now known with diverse biological activities.

Public Health Relevance

Tuberculosis is the cause of more than 1.1 million deaths annually, and the emergence of multiple and extensively drug-resistant Mycobacterium tuberculosis is becoming a significant threat to global human health. The goals of this proposal are to define a biosynthetic mechanism for the anti-tuberculosis antibiotic capuramycin and use a synergistic combination of innovative synthetic and enzymatic technologies to rapidly interrogate/modulate the chemical functionality of this novel class of anti-tuberculosis agents.

Agency
National Institute of Health (NIH)
Institute
National Institute of Allergy and Infectious Diseases (NIAID)
Type
Research Project (R01)
Project #
1R01AI128862-01
Application #
9246017
Study Section
Special Emphasis Panel (ZRG1)
Program Officer
Boyce, Jim P
Project Start
2017-01-01
Project End
2021-12-31
Budget Start
2017-01-01
Budget End
2017-12-31
Support Year
1
Fiscal Year
2017
Total Cost
Indirect Cost
Name
University of Kentucky
Department
Pharmacology
Type
Schools of Pharmacy
DUNS #
939017877
City
Lexington
State
KY
Country
United States
Zip Code
40526
Huang, Ying; Liu, Xiaodong; Cui, Zheng et al. (2018) Pyridoxal-5'-phosphate as an oxygenase cofactor: Discovery of a carboxamide-forming, ?-amino acid monooxygenase-decarboxylase. Proc Natl Acad Sci U S A 115:974-979
Cui, Zheng; Liu, Xiaodong; Overbay, Jonathan et al. (2018) Enzymatic Synthesis of the Ribosylated Glycyl-Uridine Disaccharide Core of Peptidyl Nucleoside Antibiotics. J Org Chem 83:7239-7249
Goswami, Anwesha; Liu, Xiaodong; Cai, Wenlong et al. (2017) Evidence that oxidative dephosphorylation by the nonheme Fe(II), ?-ketoglutarate:UMP oxygenase occurs by stereospecific hydroxylation. FEBS Lett 591:468-478