Conversion of Ca2+ oscillation into propagative electrical signals by Ca2+-activated ion channels and connexin as a reconstituted Ca2+ clock model for the pacemaker activity
2019
Saeki, Takanori | Kimura, Taisuke | Hashidume, Keigo | Murayama, Takashi | Yamamura, Hisao | Ohya, Susumu | Suzuki, Yoshiaki | Nakayama, Shinsuke | Imaizumi, Yuji
Conversion of intracellular Ca2+ signals to electrical activity results in multiple and differing physiological impacts depending on cell types. In some organs such as gastrointestinal and urinary systems, spontaneous Ca2+ oscillation in pacermaker cells can function essentially as a Ca2+ clock mechanism, which has been originally found in pacemaking in sinoatrial node cell of the heart. The conversion of discrete Ca2+ clock events to spontaneous electrical activity is an essential step for the initiation and propagation of pacemaker activity through the multicellular organs resulting in synchronized physiological functions. Here, a model of intracellular signal transduction from a Ca2+ oscillation to initiation of electrical slow waves and their propagation were reconstituted in HEK293 cells. This was accomplished based on ryanodine receptor (RyR) type 3, Ca2+-activated ion channels, i.e. small conductance Ca2+-activated K+ channel (SK2) or Ca2+-activated Cl− channel (TMEM16A), and connexin43 being heterologously co-expressed. The propagation of electrical waves was abolished or substantially reduced by treatment with selective blockers of the expressed channels and 18β-glycyrrhetinic acid, a gap junction inhibitor, respectively. Thus, we demonstrated that the conversion of Ca2+ oscillation to electrical signals with cell to cell propagation can be reconstituted as a model of Ca2+ clock pacemaker activity by combinational expression of critical elements in heterologous expression system.
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