Zhang Xiao, Di Yuchang, Zhang Yu, Hu Youwei, Chi Mingzhe, Kang Jian, Zheng Yuqing, Wang Hengyu, Wang Yu, Chen Jiazhen, Zhang Xuelian
State Key Laboratory of Genetic Engineering, School of Life Sciences, Fudan University, Shanghai, People's Republic of China.
Shanghai Sci-Tech Inno Center for Infection & Immunity, Shanghai, People's Republic of China.
Emerg Microbes Infect. 2025 Dec;14(1):2480698. doi: 10.1080/22221751.2025.2480698. Epub 2025 Mar 26.
Ribonucleotide reductase (RNR) catalyzes the synthesis of four deoxyribonucleoside triphosphates (dNTPs), which are essential for DNA replication. Although dNTP imbalances reduce replication fidelity and elevate mutation rates, the impact of RNR dysfunction on Mycobacterium tuberculosis (Mtb) physiology and drug resistance remains unknown. Here, we constructed inducible knockdown strains for the RNR R1 subunit NrdE in Mtb and Mycolicibacterium smegmatis (Msm). NrdE knockdown significantly impaired growth and metabolic imbalances, indirectly disrupting oxidative homeostasis and mycolic acid synthesis, while increasing levels of intracellular ROS accumulation and enhancing cell wall permeability. Additionally, we developed genomic mutant strains, Msm-Y252A and Msm-Q255A, featuring targeted point mutations in the substrate-specific site (S-site) of the RNR loop domain, which determines NDP reduction specificity. The Msm-Y252A displayed a 1.9-fold decrease in dATP and increases in dGTP (1.6-fold), dTTP (9.0-fold), and dCTP (1.3-fold). In contrast, Msm-Q255A exhibited elevated intracellular levels of dGTP (1.6-fold), dTTP (6.1-fold), and dATP (1.5-fold), while dCTP levels remained unchanged. Neither the NrdE knockdown strain nor the S-site mutants exhibited direct resistance development; however, they both showed genomic instability, enhancing the emergence of rifampicin-resistant mutants, even with a 70-fold and a 25-fold increase in mutation frequency for Msm-Y252A and Msm-Q255A, respectively. This study demonstrates that NrdE is integral to Mycobacterium survival and genomic stability and that its RNR dysfunction creates a mutagenic environment under selective pressure, indirectly contributes to the development of drug resistance, positioning NrdE as an effective target for therapeutic strategies and a valuable molecular marker for early detection of drug-resistant Mtb.
核糖核苷酸还原酶(RNR)催化四种脱氧核糖核苷三磷酸(dNTP)的合成,而dNTP对于DNA复制至关重要。尽管dNTP失衡会降低复制保真度并提高突变率,但RNR功能障碍对结核分枝杆菌(Mtb)生理学和耐药性的影响仍不清楚。在此,我们构建了结核分枝杆菌和耻垢分枝杆菌(Msm)中RNR R1亚基NrdE的诱导型敲低菌株。NrdE敲低显著损害生长并导致代谢失衡,间接破坏氧化稳态和分枝菌酸合成,同时增加细胞内ROS积累水平并增强细胞壁通透性。此外,我们开发了基因组突变菌株Msm-Y252A和Msm-Q255A,它们在RNR环结构域的底物特异性位点(S位点)具有靶向点突变,该位点决定了NDP还原特异性。Msm-Y252A的dATP降低了1.9倍,而dGTP(1.6倍)、dTTP(9.0倍)和dCTP(1.3倍)增加。相比之下,Msm-Q255A的细胞内dGTP(1.6倍)、dTTP(6.1倍)和dATP(1.5倍)水平升高,而dCTP水平保持不变。NrdE敲低菌株和S位点突变体均未表现出直接的耐药性发展;然而,它们都表现出基因组不稳定,增强了利福平耐药突变体的出现,Msm-Y252A和Msm-Q255A的突变频率分别增加了70倍和25倍。这项研究表明,NrdE对于分枝杆菌的生存和基因组稳定性不可或缺,其RNR功能障碍在选择性压力下创造了一个诱变环境,间接促进了耐药性的发展,将NrdE定位为治疗策略的有效靶点和早期检测耐药Mtb的有价值分子标志物。
