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Glutamate drives ‘local Ca2+ release’ in cardiac pacemaker cells

Duanyang Xie, Ke Xiong, Xuling Su, Guanghua Wang, Qicheng Zou, Luxin Wang, Caihong Zhang, Yuting Cao, Beihua Shao, Yixin Zhang, Peidong Zhang, Dandan Liang, Yi Liu, Yihan Chen

2022Cell Research16 citationsDOIOpen Access PDF

Abstract

Abstract The sinoatrial node (SAN) is the origin of the electrical signals for rhythmic heartbeats in mammals. The spontaneous firing of SAN pacemaker cells (SANPCs) triggers cardiac contraction. ‘Local Ca 2+ release’ (LCR), a unique cellular activity, acts as the ‘engine’ of the spontaneous firing of SANPCs. However, the mechanism of LCR initiation remains unclear. Here, we report that endogenous glutamate drives LCRs in SANPCs. Using a glutamate sensor, we unraveled a tight correlation between glutamate accumulation and LCR occurrence, indicating a potential relationship between glutamate and LCRs. Intracellular application of glutamate significantly enhanced the LCRs in both intact and permeabilized SANPCs. Mechanistically, we revealed that mitochondrial excitatory amino acid transporter 1 (EAAT1)-dependent mitochondrial glutamate import promoted ROS generation, which in turn led to the oxidation of Ca 2+ -handling proteins, ultimately resulting in enhanced LCRs. Importantly, EAAT1 depletion reduced both the spontaneous firing rates of isolated SANPCs and the heart rate in vitro and in vivo, suggesting the central role of EAAT1 as a glutamate transporter in the regulation of cardiac autonomic rhythm. In conclusion, our results indicate that glutamate serves as an LCR igniter in SANPCs, adding a potentially important element to the coupled-clock theory that explains the origin of spontaneous firing. These findings shed new light on the future prevention and treatment of cardiac pacemaker cell-related arrhythmias.

Topics & Concepts

Glutamate receptorBiologyExcitatory postsynaptic potentialSinoatrial nodeIntracellularTransporterNeuroscienceCell biologyBiophysicsHeart rateBiochemistryInhibitory postsynaptic potentialEndocrinologyReceptorGeneBlood pressureCardiac electrophysiology and arrhythmiasIon channel regulation and functionNeuroscience and Neural Engineering