Litcius/Paper detail

Ca2+ oscillation in vascular smooth muscle cells control myogenic spontaneous vasomotion and counteract post-ischemic no-reflow

Jinze Li, Yiyi Zhang, Dongdong Zhang, Wentao Wang, Huiqi Xie, Jiayu Ruan, Yuxiao Jin, Tingbo Li, Xuzhao Li, Bingrui Zhao, Xiaoxuan Zhang, Jiayi Lin, Hongjun Shi, Jie‐Min Jia

2024Communications Biology18 citationsDOIOpen Access PDF

Abstract

Abstract Ischemic stroke produces the highest adult disability. Despite successful recanalization, no-reflow, or the futile restoration of the cerebral perfusion after ischemia, is a major cause of brain lesion expansion. However, the vascular mechanism underlying this hypoperfusion is largely unknown, and no approach is available to actively promote optimal reperfusion to treat no-reflow. Here, by combining two-photon laser scanning microscopy (2PLSM) and a mouse middle cerebral arteriolar occlusion (MCAO) model, we find myogenic vasomotion deficits correlated with post-ischemic cerebral circulation interruptions and no-reflow. Transient occlusion-induced transient loss of mitochondrial membrane potential (ΔΨm) permanently impairs mitochondria-endoplasmic reticulum (ER) contacts and abolish Ca 2+ oscillation in smooth muscle cells (SMCs), the driving force of myogenic spontaneous vasomotion. Furthermore, tethering mitochondria and ER by specific overexpression of ME-Linker in SMCs restores cytosolic Ca 2+ homeostasis, remotivates myogenic spontaneous vasomotion, achieves optimal reperfusion, and ameliorates neurological injury. Collectively, the maintaining of arteriolar myogenic vasomotion and mitochondria-ER contacts in SMCs, are of critical importance in preventing post-ischemic no-reflow.

Topics & Concepts

VasomotionIschemiaEndoplasmic reticulumCardiologyMedicineVascular smooth muscleInternal medicineCell biologyBiologyVasodilationSmooth muscleMitochondrial Function and PathologyNeuroinflammation and Neurodegeneration MechanismsNeuroscience and Neuropharmacology Research