Development and Evaluation of Bis-benzothiazoles as a New Class of Benzothiazoles Targeting DprE1 as Antitubercular Agents.

IF 4 2区医学 Q2 CHEMISTRY, MEDICINAL

ACS Infectious Diseases Pub Date : 2024-09-13 Epub Date: 2024-08-16 DOI:10.1021/acsinfecdis.4c00415

Rabiya Samoon, Shashikanta Sau, Arnab Roy, Kishan Kumar Parida, Kalicharan Sharma, Prasanna Anjaneyulu Yakkala, Rikeshwer Prasad Dewangan, Malik Zainul Abdin, Nitin Pal Kalia, Syed Shafi

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Abstract

Benzothiazole-bearing compounds have emerged as potential noncovalent DprE1 (decaprenylphosphoryl-β-d-ribose-2'-epimerase) inhibitors active against Mycobacterium tuberculosis. Based on structure-based virtual screening (PDB ID: 4KW5), a focused library of thirty-one skeletally diverse benzothiazole amides was prepared, and the compounds were assessed for their antitubercular activity against M.tb H37Ra. Most potent compounds 3b and 3n were further evaluated against the M.tb H37Rv strain by the microdilution assay method. Among the compounds evaluated, bis-benzothiazole amide 3n emerged as a hit molecule and demonstrated promising antitubercular activity with minimum inhibitory concentration (MIC) values of 0.45 μg/mL and 8.0 μg/mL against H₃₇Ra and H₃₇Rv, respectively. Based on the preliminary hit molecule (3n), a focused library of 12 more bis-benzothiazole amide derivatives was further prepared by varying the substituents on either side to obtain new leads and generate a structure-activity relationship (SAR). Among these compounds, 6a, 6c, and 6d demonstrated remarkable antitubercular activity with MIC values of 0.5 μg/mL against H37Ra and 1.0, 2.0, and 8.0 μg/mL against H₃₇Rv, respectively. The most active compound, 6a, also displayed significant efficacy against four drug-resistant tuberculosis strains. Compound 6a was assessed for in vitro cytotoxicity against the HepG2 cell line, and it displayed insignificant cytotoxicity. Furthermore, time-kill kinetic studies demonstrated time- and dose-dependent bactericidal activity of this compound. The GFP release assay revealed that compound 6a targets the inhibition of a cell wall component. SNPs in dprE-1 gene assessment revealed that compound 6a binds to tyrosine at position 314 of DprE1 and replaces it with histidine, causing resistance similar to that of standard TCA1. In silico docking studies further suggest that the strong noncovalent interactions of these compounds may lead to the development of potent noncovalent DprE1 inhibitors.

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开发和评估以 DprE1 为靶点的双苯并噻唑类抗结核药物。

苯并噻唑类化合物已成为潜在的非共价 DprE1（脱羧基磷酰-β-d-核糖-2'-epimerase）抑制剂，对结核分枝杆菌具有活性。通过基于结构的虚拟筛选（PDB ID：4KW5），制备了一个由 31 种不同骨架的苯并噻唑酰胺组成的重点化合物库，并评估了这些化合物对 M.tb H37Ra 的抗结核活性。采用微量稀释法进一步评估了最强化合物 3b 和 3n 对 M.tb H37Rv 菌株的抗结核活性。在评估的化合物中，双苯并噻唑酰胺 3n 成为命中分子，对 H37Ra 和 H37Rv 的最小抑制浓度（MIC）分别为 0.45 μg/mL 和 8.0 μg/mL，显示出良好的抗结核活性。在初步命中分子（3n）的基础上，通过改变两侧的取代基，进一步制备了由另外 12 个双苯并噻唑酰胺衍生物组成的重点化合物库，以获得新的线索并建立结构-活性关系（SAR）。在这些化合物中，6a、6c 和 6d 具有显著的抗结核活性，对 H37Ra 的 MIC 值分别为 0.5 μg/mL，对 H37Rv 的 MIC 值分别为 1.0、2.0 和 8.0 μg/mL。活性最强的化合物 6a 对四种耐药结核菌株也有显著疗效。化合物 6a 对 HepG2 细胞系进行了体外细胞毒性评估，结果显示其细胞毒性不明显。此外，时间杀伤动力学研究表明，该化合物的杀菌活性与时间和剂量有关。GFP 释放试验显示，化合物 6a 以抑制细胞壁成分为目标。dprE-1 基因的 SNPs 评估显示，化合物 6a 与 DprE1 第 314 位的酪氨酸结合，并以组氨酸取代，从而产生与标准 TCA1 类似的抗药性。硅学对接研究进一步表明，这些化合物的强非共价相互作用可能会导致开发出强效的非共价 DprE1 抑制剂。

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来源期刊

ACS Infectious Diseases CHEMISTRY, MEDICINALINFECTIOUS DISEASES&nb-INFECTIOUS DISEASES

CiteScore

9.70

自引率

3.80%

发文量

213

期刊介绍： ACS Infectious Diseases will be the first journal to highlight chemistry and its role in this multidisciplinary and collaborative research area. The journal will cover a diverse array of topics including, but not limited to: * Discovery and development of new antimicrobial agents — identified through target- or phenotypic-based approaches as well as compounds that induce synergy with antimicrobials. * Characterization and validation of drug target or pathways — use of single target and genome-wide knockdown and knockouts, biochemical studies, structural biology, new technologies to facilitate characterization and prioritization of potential drug targets. * Mechanism of drug resistance — fundamental research that advances our understanding of resistance; strategies to prevent resistance. * Mechanisms of action — use of genetic, metabolomic, and activity- and affinity-based protein profiling to elucidate the mechanism of action of clinical and experimental antimicrobial agents. * Host-pathogen interactions — tools for studying host-pathogen interactions, cellular biochemistry of hosts and pathogens, and molecular interactions of pathogens with host microbiota. * Small molecule vaccine adjuvants for infectious disease. * Viral and bacterial biochemistry and molecular biology.