A Rational Approach To Antitubercular Drug Design: Molecular Docking, Prediction of ADME Properties and Evaluation of Antitubercular Activity of Novel Isonicotinamide Scaffold.

Recent advances in anti-infective drug discovery Pub Date : 2024-01-01 DOI:10.2174/2772434418666230710142852

Paramita Das, Sharanakumar R Gumma, Anjali Nayak, Sunil Menghani, Jithendar R Mandhadi, Padmavathi P Prabhu

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Abstract

Introduction: One of the most devastating and leading diseases is Tuberculosis (TB), caused by Mycobacterium tuberculosis. Even though many synthetic drugs are available in the market, to increase the therapeutic efficacy and reduce toxicity. Isoniazid is the primary drug used in the treatment of tuberculosis.

Methods: The main objective of the study is to perform molecular docking studies and synthesize the derivatives of isonicotinamide along with the anti-tubercular activity. The isonicotinamide derivatives (a-j) are prepared using isoniazid, carbon disulphate, methyl cyanide, and benzaldehyde derivatives and characterized by TLC, IR, ¹HNMR, and Mass spectroscopy. The enzyme decaprenylphosphoryl-D-ribose oxidase (DprE1) of M. tuberculosis had good binding capacity with all the ligands revealed in molecular docking studies. In-vitro studies indicated that all the ligands showed anti-tuberculosis with strain M. tuberculosis.

Results: The analysis was based on the binding energy and minimum inhibitory concentration (MIC). The highest and lowest binding energy is -4.22 Kcal/mol (f) and -8.45 Kcal/mol (d), and the MIC for compound d was found to be 644.22 nM. Among all the ligands, compound 5d has the most cytotoxic effect and lower IC₅₀ values and better bioavailability.

Conclusion: This investigation helps in the development of better anti-tubercular therapy.

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抗结核药物设计的合理方法：新型异烟酰胺支架的分子对接、ADME 特性预测和抗结核活性评价。

导言：结核病（TB）是由结核分枝杆菌引起的最具破坏性的主要疾病之一。尽管市场上有许多合成药物，但为了提高疗效和降低毒性，异烟肼是治疗结核病的主要药物。异烟肼是治疗结核病的主要药物：研究的主要目的是进行分子对接研究，合成具有抗结核活性的异烟酰胺衍生物。使用异烟肼、二硫化碳、氰化甲酯和苯甲醛衍生物制备了异烟酰胺衍生物（a-j），并通过色谱、红外光谱、1HNMR 和质谱进行了表征。分子对接研究显示，结核杆菌的十磷酰基-D-核糖氧化酶（DprE1）与所有配体都有良好的结合能力。体外研究表明，所有配体都对结核杆菌菌株具有抗结核作用：结果：分析基于结合能和最低抑菌浓度（MIC）。化合物 d 的结合能最高为-4.22 Kcal/mol（f），最低为-8.45 Kcal/mol（d），最低抑菌浓度为 644.22 nM。在所有配体中，化合物 5d 的细胞毒性作用最强，IC50 值较低，生物利用度较高：结论：这项研究有助于开发更好的抗结核疗法。

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Recent advances in anti-infective drug discovery

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1.80

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0.00%

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