大肠杆菌
生物
微生物学
严格的回应
氧化应激
过氧化氢酶
生物化学
细菌
肠杆菌科
DNA损伤
细胞内
氧化磷酸化
抗坏血酸
脂质过氧化
谷胱甘肽
超氧化物歧化酶
新陈代谢
SOS响应
四环素
去铁胺
抗氧化剂
细胞保护
DNA
金属硫蛋白
活性氧
营养不良
螯合作用
作者
Zinuo An,Liangbin Hu,Lili Zhao,Wensheng Liang,Hongbo Li,Lu Tian,Haizhen Mo,Liping Liu
标识
DOI:10.1016/j.micres.2026.128457
摘要
Adherent-invasive Escherichia coli (AIEC) LF82 is closely linked to Crohn's disease and can persist within macrophages in a quiescent, growth-arrested state. Here, we show that cupric gluconate (Cu Glu) promoted cell death in E. coli MG1655, yet drove E. coli LF82 into a viable-but-non-culturable (VBNC) state. VBNC induction was time dependent and modulated by temperature. VBNC cells remained susceptible to ampicillin and tetracycline but were tolerant to ciprofloxacin. To probe whether capsule-associated factors contribute to the strain-dependent outcome, we heterologously expressed kpsM, kpsT, or kpsMT in MG1655. This increased MG1655 tolerance to Cu Glu but did not induce a VBNC phenotype. Cu Glu increased intracellular Cu+ and ROS in LF82 without detectable lipid peroxidation or DNA damage. Copper or ferrous-iron chelation prevented VBNC entry and rescued cells otherwise destined to die, whereas redox modulators shifted VBNC outcomes. Glutathione and catalase resuscitated a small subset, implicating H2O2-driven oxidative stress in VBNC fate. Proteomics revealed repression of energy metabolism together with enhanced outer-membrane maintenance and Fe-S cluster repair. Notably, ascorbic acid (Vc) abolished resuscitation and rapidly killed VBNC cells by promoting labile Fe2+ release and, together with Cu+, amplifying Fenton chemistry to damage membranes without a lipid-peroxidation signature. These findings define a copper-dependent VBNC program in LF82 and provide mechanistic insight into how metal redox imbalance and oxidative stress shape VBNC maintenance and clearance.
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