Abstract
The shortcomings of conventional tuberculosis treatments resulting from the development of drug resistance in Mycobacterium tuberculosis drive a need for the formulation of novel therapeutic agents. The diarylquinoline class of drugs such as bedaquiline was recently approved for the treatment of multidrug-resistant strains of tuberculosis, primarily targeting c and ε subunits of the ATP synthases. Yet resistance to bedaquiline has already been reported. Therefore, Rv1311 was used as the target for the identification of possible inhibitors against the M. tuberculosis. The structure of Rv1311 was predicted and common feature pharmacophore models were generated which facilitated the identification of potential inhibitors in the ZINC database. The activities of the selected molecules were compared with known inhibitors of the ATP synthase using quantitative structure–activity relationship. The ZINC classified inhibitors showed comparable predicted activities with that of known inhibitors. Furthermore, the inhibitory behavior of the studied drug molecules was experimentally determined using in vitro techniques and showed the minimum inhibitory concentration as low as 25 μM. The resulted outcomes provide a deeper insight into the structural basis of Rv1311 inhibitions and can facilitate the process of drug design against tuberculosis.
Highlights
Effective treatment and control of Mycobacterium tuberculosis, the causative agent of tuberculosis (TB) has remained a global challenge especially in terms of drug resistance [1,2]
Previous studies by our group aimed to elucidate drug resistance mechanisms present in M. tuberculosis by using genome and metabolic pathway mapping which led to the identification of nine putative targets, which could be used for the development of novel therapeutic agents [13]
The Rv1311 (ε subunit) was selected as a drug target because it is essential for the functioning of the ATP synthase and crucial for the energy generation in M. tuberculosis
Summary
Effective treatment and control of Mycobacterium tuberculosis, the causative agent of tuberculosis (TB) has remained a global challenge especially in terms of drug resistance [1,2]. In order to provide an efficient therapy for MDR TB, the FDA recently approved the use of bedaquiline as a new anti-TB drug [4,5]. ATP synthase is essential for the optimal growth of M. tuberculosis as it is a key enzyme involved in energy metabolism and is regarded as a promising target for anti-TB drugs [6,7]. It catalyzes the production of ATP by using the energy amassed in the form of difference in the transmembrane electrochemical potential of a coupling ion [8].
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