Yaniv Yael, Ganesan Ambhighainath, Yang Dongmei, Ziman Bruce D, Lyashkov Alexey E, Levchenko Andre, Zhang Jin, Lakatta Edward G
Biomedical Engineering Faculty, Technion-IIT, Haifa, Israel.
Department of Biomedical Engineering, The Johns Hopkins University of Medicine, Baltimore, MD, USA.
J Mol Cell Cardiol. 2015 Sep;86:168-78. doi: 10.1016/j.yjmcc.2015.07.024. Epub 2015 Aug 1.
cAMP-PKA protein kinase is a key nodal signaling pathway that regulates a wide range of heart pacemaker cell functions. These functions are predicted to be involved in regulation of spontaneous action potential (AP) generation of these cells. Here we investigate if the kinetics and stoichiometry of increase in PKA activity match the increase in AP firing rate in response to β-adrenergic receptor (β-AR) stimulation or phosphodiesterase (PDE) inhibition, that alters the AP firing rate of heart sinoatrial pacemaker cells. In cultured adult rabbit pacemaker cells infected with an adenovirus expressing the FRET sensor AKAR3, the EC50 in response to graded increases in the intensity of β-AR stimulation (by Isoproterenol) the magnitude of the increases in PKA activity and the spontaneous AP firing rate were similar (0.4±0.1nM vs. 0.6±0.15nM, respectively). Moreover, the kinetics (t1/2) of the increases in PKA activity and spontaneous AP firing rate in response to β-AR stimulation or PDE inhibition were tightly linked. We characterized the system rate-limiting biochemical reactions by integrating these experimentally derived data into a mechanistic-computational model. Model simulations predicted that phospholamban phosphorylation is a potent target of the increase in PKA activity that links to increase in spontaneous AP firing rate. In summary, the kinetics and stoichiometry of increases in PKA activity in response to a physiological (β-AR stimulation) or pharmacological (PDE inhibitor) stimuli match those of changes in the AP firing rate. Thus Ca(2+)-cAMP/PKA-dependent phosphorylation limits the rate and magnitude of increase in spontaneous AP firing rate.
环磷酸腺苷-蛋白激酶A(cAMP-PKA)蛋白激酶是一条关键的节点信号通路,可调节多种心脏起搏器细胞功能。预计这些功能参与调控这些细胞自发动作电位(AP)的产生。在此,我们研究PKA活性增加的动力学和化学计量是否与响应β-肾上腺素能受体(β-AR)刺激或磷酸二酯酶(PDE)抑制时AP发放率的增加相匹配,β-AR刺激或PDE抑制会改变心脏窦房结起搏器细胞的AP发放率。在感染了表达FRET传感器AKAR3的腺病毒的成年兔培养起搏器细胞中,响应β-AR刺激强度(通过异丙肾上腺素)分级增加时,PKA活性增加的EC50与自发AP发放率增加的幅度相似(分别为0.4±0.1nM和0.6±0.15nM)。此外,响应β-AR刺激或PDE抑制时,PKA活性增加和自发AP发放率增加的动力学(半衰期)紧密相关。我们通过将这些实验得出的数据整合到一个机制计算模型中,对系统限速生化反应进行了表征。模型模拟预测,受磷蛋白磷酸化是PKA活性增加的一个有效靶点,其与自发AP发放率增加相关。总之,响应生理(β-AR刺激)或药理(PDE抑制剂)刺激时PKA活性增加的动力学和化学计量与AP发放率变化的动力学和化学计量相匹配。因此,Ca(2+)-cAMP/PKA依赖性磷酸化限制了自发AP发放率增加的速率和幅度。