Structural and mechanistic study of a novel inhibitor analogue of M. tuberculosis cytochrome bc₁:aa₃.

NPJ drug discovery Pub Date : 2025-01-01 Epub Date: 2025-04-02 DOI:10.1038/s44386-025-00008-3

Amit K Verma, Robbert Q Kim, Dirk A Lamprecht, Clara Aguilar-Pérez, Sarah Wong, Nicolas Veziris, Alexandra Aubry, José M Bartolomé-Nebreda, Rodrigo J Carbajo, Jennefer Wetzel, Meindert H Lamers

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Abstract

Drug-resistant tuberculosis (TB) continues to challenge treatment options, necessitating the exploration of new compounds of novel targets. The mycobacterial respiratory complex cytochrome bc₁:aa₃ has emerged as a promising target, exemplified by the success of first-in-class inhibitor Q203 in phase 2 clinical trials. However, to fully exploit the potential of this target and to identify the best-in-class inhibitor more compounds need evaluation. Here, we introduce JNJ-2901, a novel Q203 analogue, that demonstrates activity against multidrug-resistant M. tuberculosis clinical strains at sub-nanomolar concentration and 4-log reduction in bacterial burden in a mouse model of TB infection. Inhibitory studies on purified enzymes validate the nanomolar inhibitions observed in mycobacterial cells. Additionally, cryo-EM structure analysis of cytochrome bc₁:aa₃ bound to JNJ-2901 reveals the binding pocket at the menaquinol oxidation site (Qp), akin to other substate analogue inhibitors like Q203 and TB47. Validation of the binding site is further achieved by generating and isolating the JNJ-2901 resistant mutations in M. tuberculosis, followed by purification and resistance analysis of the resistant cytochrome bc₁:aa₃ complex. Our comprehensive work lays the foundation for further clinical validations of JNJ-2901.

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结核分枝杆菌细胞色素bc1:aa3新型抑制物的结构与机制研究。

耐药结核病（TB）继续挑战治疗方案，需要探索新靶点的新化合物。分枝杆菌呼吸系统复合体细胞色素bc1:aa3已成为一个有希望的靶点，一流抑制剂Q203在2期临床试验中取得成功就是一个例子。然而，为了充分利用这一靶点的潜力并确定同类最佳抑制剂，需要对更多的化合物进行评估。在这里，我们介绍了JNJ-2901，一种新的Q203类似物，在亚纳摩尔浓度下对多药耐药结核分枝杆菌临床菌株具有活性，并在结核感染小鼠模型中减少了4倍的细菌负担。对纯化酶的抑制研究证实了在分枝杆菌细胞中观察到的纳摩尔抑制作用。此外，结合JNJ-2901的细胞色素bc1:aa3的低温电镜结构分析显示，在甲基萘酚氧化位点（Qp）有一个结合袋，类似于其他亚状态类似物抑制剂，如Q203和TB47。通过在结核分枝杆菌中产生和分离JNJ-2901耐药突变进一步验证了结合位点，随后对耐药细胞色素bc1:aa3复合物进行纯化和耐药分析。我们的全面工作为JNJ-2901的进一步临床验证奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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NPJ drug discovery

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