Shi Xiao-Jie, Shi Kun-Xiong, Han Fu, Wang Li, Cai Xia, Zhao Guo-Ping, Sha Wei, Lyu Liang-Dong
Key Laboratory of Medical Molecular Virology of the Ministry of Education/Ministry of Health, Department of Medical Microbiology and Parasitology, School of Basic Medical Sciences, Fudan University, Shanghai, People's Republic of China.
CAS-Key Laboratory of Synthetic Biology, CAS Center for Excellence in Molecular Plant Sciences, Shanghai Institute of Plant Physiology and Ecology, Chinese Academy of Sciences, Shanghai, China.
Microbiol Spectr. 2025 Sep 2;13(9):e0109625. doi: 10.1128/spectrum.01096-25. Epub 2025 Aug 12.
The adaptation of (Mtb) to a slowly growing or nongrowing state in growth-limited conditions plays a crucial role for drug tolerance. Although the mechanisms of Mtb adaptation under growth-limited conditions have been extensively studied, it remains unclear to what extent the cellular processes necessary to sustain nongrowing state affect drug efficacy. To investigate this, we performed a genome-wide transposon mutant screen, which allowed parallel identification of the genes that influence bacterial fitness and drug efficacy during the stationary phase. Our analysis revealed that genes encoding the SOS response, membrane phospholipid biosynthesis, proteasomal protein degradation, and cell wall remodeling critically determine Mtb fitness in both stationary-phase condition and antibiotic exposure. Surprisingly, we found that many mutants that compromise stationary-phase adaptation result in increased fitness during antibiotic treatment, including the recently identified genetic markers associated with poor clinical outcomes. Furthermore, genes involved in cell envelope biosynthesis and remodeling, antibiotic efflux, and phosphate transport are significantly enriched in the mutants sensitized to antibiotics, indicating that reduced drug entry is a critical factor that limits antibiotic efficacy in nonreplicating Mtb. We demonstrated that mutants deficient in utilization of lipids, the primary carbon sources for Mtb during infection, became tolerant to killing by rifampicin. We provided genetic and metabolic evidence that the activities of lipid metabolism are associated with rifampicin efficacy. These findings provide the detailed assessment of Mtb genes necessary for adaptation to the stationary phase and drug treatment and new insights into the mechanisms of antibiotic tolerance in nongrowing Mtb.IMPORTANCEIt has long been known that antibiotic efficacy is generally proportional to the bacterial growth rate. Yet it remains unclear how and to what extent the growth arrest-induced physiological and metabolic changes affect drug efficacy. Using the genome-wide transposon mutant screen, we identified the mutants that influence adaptation and drug efficacy during the stationary phase of growth. We revealed both positive and negative correlations between stationary phase adaptation and drug sensitivity and identified many mutants that compromise stationary phase adaptation and result in increased fitness during antibiotic treatment, including the identified genetic markers associated with poor clinical outcomes. These results provide new insights into the mechanisms of antibiotic tolerance in nongrowing Mtb and suggest potential targets for drug development.
结核分枝杆菌(Mtb)在生长受限条件下适应缓慢生长或非生长状态对药物耐受性起着关键作用。尽管在生长受限条件下Mtb适应机制已得到广泛研究,但维持非生长状态所需的细胞过程在多大程度上影响药物疗效仍不清楚。为了研究这一点,我们进行了全基因组转座子突变体筛选,该筛选允许并行鉴定在稳定期影响细菌适应性和药物疗效的基因。我们的分析表明,编码SOS反应、膜磷脂生物合成、蛋白酶体蛋白降解和细胞壁重塑的基因在稳定期条件和抗生素暴露期间都至关重要地决定了Mtb的适应性。令人惊讶的是,我们发现许多损害稳定期适应的突变体在抗生素治疗期间导致适应性增加,包括最近鉴定出的与临床结果不佳相关的遗传标记。此外,参与细胞壁生物合成和重塑、抗生素外排和磷酸盐转运的基因在对抗生素敏感的突变体中显著富集,表明药物进入减少是限制非复制性Mtb中抗生素疗效的关键因素。我们证明,在感染期间作为Mtb主要碳源的脂质利用缺陷的突变体对利福平杀伤产生耐受性。我们提供了遗传和代谢证据,表明脂质代谢活动与利福平疗效相关。这些发现提供了对Mtb适应稳定期和药物治疗所需基因的详细评估,并对非生长性Mtb中的抗生素耐受机制有了新的认识。
重要性
长期以来已知抗生素疗效通常与细菌生长速率成正比。然而,尚不清楚生长停滞诱导的生理和代谢变化如何以及在多大程度上影响药物疗效。使用全基因组转座子突变体筛选,我们鉴定了在生长稳定期影响Mtb适应和药物疗效的突变体。我们揭示了稳定期适应与药物敏感性之间的正相关和负相关,并鉴定了许多损害稳定期适应并在抗生素治疗期间导致适应性增加的突变体,包括鉴定出的与临床结果不佳相关的遗传标记。这些结果为非生长性Mtb中的抗生素耐受机制提供了新的见解,并提出了药物开发的潜在靶点。
