Low-level BTZ-043 resistance in Mycobacterium tuberculosis and cross-resistance to bedaquiline and clofazimine.

IJTLD open Pub Date : 2025-10-10 eCollection Date: 2025-10-01 DOI:10.5588/ijtldopen.25.0301

A Ghodousi, I Iannucci, F Saluzzo, J Dreisbach, S Mirold-Mei, M Hoelscher, D M Cirillo

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Abstract

Background: Multidrug- and extensively drug-resistant strains of Mycobacterium tuberculosis complex (MTBC) remain a significant global health challenge. This study investigates resistance mechanisms to BTZ-043, a novel decaprenylphosphoryl-β-D-ribose 2'-epimerase (DprE1) inhibitor, and its potential cross-resistance with bedaquiline (BDQ) and clofazimine (CFZ).

Methods: BTZ-043-resistant mutants were generated in M. tuberculosis H37Rv by serial exposure to escalating drug concentrations. Minimum inhibitory concentrations (MICs) for BTZ-043 were determined for 130 wild-type strains, including 60 H37Rv independent cultures and 70 diverse clinical isolates, plus 33 non-wild-type clinical strains with known BDQ susceptibility. MICs were correlated with whole-genome sequencing (WGS) data to identify genetic factors underlying resistance.

Results: The MIC distribution for clinical MTBC strains was similar to the reference strain, with a mode of 0.002 μg/mL. WGS of resistant mutants revealed mutations in dprE1 and Rv0678. Rv0678 and dprE1 mutations resulted in 4- to 8-fold and >1,000-fold increase in MIC compared with the reference mode, respectively. Sequential clinical strains from BDQ-treated patients showed increased MICs and Rv0678 mutations, indicating low-level cross-resistance. However, Rv0678 mutations in BDQ-susceptible strains did not affect BTZ-043 MICs.

Conclusion: Rv0678 mutations confer low-level cross-resistance to BTZ-043, BDQ, and CFZ, with variable effects on susceptibility. These findings highlight the complexity of resistance mechanisms and the need for ongoing surveillance and early resistance assessments in drug development.

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结核分枝杆菌BTZ-043低水平耐药及对贝达喹啉和氯法齐明的交叉耐药。

背景：结核分枝杆菌复合体多药和广泛耐药菌株（MTBC）仍然是一个重大的全球卫生挑战。本研究探讨了新型十烯丙基磷酸基-β- d -核糖2'-epimerase （DprE1）抑制剂BTZ-043的耐药机制及其与贝达喹啉（BDQ）和氯法齐明（CFZ）的潜在交叉耐药。方法：结核分枝杆菌H37Rv通过连续暴露于不断升高的药物浓度，产生btz -043耐药突变体。测定了130株野生型菌株对BTZ-043的最低抑菌浓度（mic），其中包括60株H37Rv独立培养株和70株不同临床分离株，以及33株已知BDQ敏感性的非野生型临床菌株。MICs与全基因组测序（WGS）数据相关，以确定耐药性的遗传因素。结果：临床MTBC菌株的MIC分布与参考菌株相似，模式为0.002 μg/mL。耐药突变体的WGS显示dprE1和Rv0678突变。与对照相比，Rv0678和dprE1突变导致MIC分别增加4 ~ 8倍和1000倍。bdq治疗患者的连续临床菌株显示mic和Rv0678突变增加，表明低水平交叉耐药。然而，bdq敏感菌株的Rv0678突变对BTZ-043 mic没有影响。结论：Rv0678突变对BTZ-043、BDQ和CFZ具有低水平交叉耐药，对易感性有不同的影响。这些发现突出了耐药机制的复杂性，以及在药物开发中持续监测和早期耐药评估的必要性。

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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IJTLD open

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