Abstract
We design here new nanomolar antituberculotics, inhibitors of Mycobacterium tuberculosis thymidine monophosphate kinase (TMPKmt), by means of structure-based molecular design. 3D models of TMPKmt-inhibitor complexes have been prepared from the crystal structure of TMPKmt cocrystallized with the natural substrate deoxythymidine monophosphate (dTMP) (1GSI) for a training set of 15 thymidine analogues (TMDs) with known activity to prepare a QSAR model of interaction establishing a correlation between the free energy of complexation and the biological activity. Subsequent validation of the predictability of the model has been performed with a 3D QSAR pharmacophore generation. The structural information derived from the model served to design new subnanomolar thymidine analogues. From molecular modeling investigations, the agreement between free energy of complexation (ΔΔG com) and K i values explains 94% of the TMPKmt inhibition (pK i = −0.2924ΔΔG com + 3.234; R 2 = 0.94) by variation of the computed ΔΔG com and 92% for the pharmacophore (PH4) model (pK i = 1.0206 × pK i pred − 0.0832, R 2 = 0.92). The analysis of contributions from active site residues suggested substitution at the 5-position of pyrimidine ring and various groups at the 5′-position of the ribose. The best inhibitor reached a predicted K i of 0.155 nM. The computational approach through the combined use of molecular modeling and PH4 pharmacophore is helpful in targeted drug design, providing valuable information for the synthesis and prediction of activity of novel antituberculotic agents.
Highlights
A substantial number of the influenza A subtype H1N1 death cases reported by WHO occurred in patients with chronic respiratory conditions shedding light on possible impact of influenza on active tuberculosis (TB) patients [1]
We design here new nanomolar antituberculotics, inhibitors of Mycobacterium tuberculosis thymidine monophosphate kinase (TMPKmt), by means of structure-based molecular design. 3D models of TMPKmt-inhibitor complexes have been prepared from the crystal structure of TMPKmt cocrystallized with the natural substrate deoxythymidine monophosphate (1GSI) for a training set of 15 thymidine analogues (TMDs) with known activity to prepare a QSAR model of interaction establishing a correlation between the free energy of complexation and the biological activity
A training set of 15 TMDs and validation set of 6 TMVs were selected from 3 series of compounds with measured activities from the same laboratory [14,15,16]
Summary
A substantial number of the influenza A subtype H1N1 death cases reported by WHO occurred in patients with chronic respiratory conditions shedding light on possible impact of influenza on active tuberculosis (TB) patients [1]. According to WHO in the second millennium decade (2020), over 1 billion people will be newly infected and 36 million will die from TB [5, 6] making it a leading cause of mortality as infectious disease. In this regard, the millennium development goal (MDG) to halve by 2015 TB mortality relative to the 1990 level is problematic [7]. The increased occurrence of MDR and XDR-TB strains is disqualifying the current 40-year-old and long-term DOTS drugs: isoniazid, rifampicin, pyrazinamide, Tuberculosis Research and Treatment and ethambutol [2]. The need of new lowcost and short-term anti-TB therapies is more than urgent regardless those currently in the preclinical or early clinical phase since most of them are improvements on existing antimicrobial compounds with nonnegligible susceptibility to resistance
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