<p>Cardiac ischemia–reperfusion injury frequently induces malignant arrhythmias because of connexin 43 (Cx43) mislocalization and impaired cardiomyocyte coupling; yet, effective therapies targeting this mechanism remain scarce. Here we show that ischemic cardiomyopathy in humans and ischemia–reperfusion in mice promote the accumulation and stabilization of glutamylated microtubules, disrupting targeted Cx43 trafficking. This remodeling of the glutamylated microtubule network is mediated by the microtubule-severing enzyme spastin. Spastin overexpression in cardiomyocytes reduced microtubule density, whereas its deficiency caused accumulation of glutamylated, stabilized microtubules. Although cardiomyocyte-specific spastin knockout mice displayed normal cardiac structure and function at baseline, they were highly susceptible to stress-induced malignant arrhythmias. Mechanistically, spastin deficiency impaired microtubule plus end dynamics and Cx43 transport. Notably, genetic or pharmacological reduction of microtubule glutamylation before ischemia–reperfusion preserved Cx43 localization and mitigated oxidative stress-induced injury. Together, these findings identify microtubule glutamylation as a key regulator of cardiac electrical stability and a promising therapeutic target in ischemia–reperfusion injury.</p>

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Spastin-mediated severing of glutamylated microtubules controls cardiomyocyte coupling

  • Jiayin Zhang,
  • Xiaozhi Huang,
  • Zhichao Wu,
  • Jinxiu Liang,
  • Shuo Chen,
  • Chen Xu,
  • Xinjian Wang,
  • Ranran Cao,
  • Xue Ji,
  • Zijian Feng,
  • Tao Lin,
  • Xuyun Li,
  • Xinyang Hu,
  • Wei Zhu,
  • Peidong Han

摘要

Cardiac ischemia–reperfusion injury frequently induces malignant arrhythmias because of connexin 43 (Cx43) mislocalization and impaired cardiomyocyte coupling; yet, effective therapies targeting this mechanism remain scarce. Here we show that ischemic cardiomyopathy in humans and ischemia–reperfusion in mice promote the accumulation and stabilization of glutamylated microtubules, disrupting targeted Cx43 trafficking. This remodeling of the glutamylated microtubule network is mediated by the microtubule-severing enzyme spastin. Spastin overexpression in cardiomyocytes reduced microtubule density, whereas its deficiency caused accumulation of glutamylated, stabilized microtubules. Although cardiomyocyte-specific spastin knockout mice displayed normal cardiac structure and function at baseline, they were highly susceptible to stress-induced malignant arrhythmias. Mechanistically, spastin deficiency impaired microtubule plus end dynamics and Cx43 transport. Notably, genetic or pharmacological reduction of microtubule glutamylation before ischemia–reperfusion preserved Cx43 localization and mitigated oxidative stress-induced injury. Together, these findings identify microtubule glutamylation as a key regulator of cardiac electrical stability and a promising therapeutic target in ischemia–reperfusion injury.