Kharouf Qays, Phillips A Marie, Bleakley Lauren E, Morrisroe Emma, Oyrer Julia, Jia Linghan, Ludwig Andreas, Jin Liang, Nicolazzo Joseph A, Cerbai Elisabetta, Romanelli M Novella, Petrou Steven, Reid Christopher A
Florey Institute of Neuroscience and Mental Health, University of Melbourne, Parkville, Victoria, Australia.
School of Biosciences, University of Melbourne, Parkville, Victoria, Australia.
Br J Pharmacol. 2020 Aug;177(16):3712-3729. doi: 10.1111/bph.15088. Epub 2020 Jun 17.
Hyperpolarization-activated cyclic nucleotide-gated (HCN) channels are encoded by four genes (HCN1-4) with distinct biophysical properties and functions within the brain. HCN4 channels activate slowly at robust hyperpolarizing potentials, making them more likely to be engaged during hyperexcitable neuronal network activity seen during seizures. HCN4 channels are also highly expressed in thalamic nuclei, a brain region implicated in seizure generalization. Here, we assessed the utility of targeting the HCN4 channel as an anti-seizure strategy using pharmacological and genetic approaches.
The impact of reducing HCN4 channel function on seizure susceptibility and neuronal network excitability was studied using an HCN4 channel preferring blocker (EC18) and a conditional brain specific HCN4 knockout mouse model.
EC18 (10 mg·kg ) and brain-specific HCN4 channel knockout reduced seizure susceptibility and proconvulsant-mediated cortical spiking recorded using electrocorticography, with minimal effects on other mouse behaviours. EC18 (10 μM) decreased neuronal network bursting in mouse cortical cultures. Importantly, EC18 was not protective against proconvulsant-mediated seizures in the conditional HCN4 channel knockout mouse and did not reduce bursting behaviour in AAV-HCN4 shRNA infected mouse cortical cultures.
These data suggest the HCN4 channel as a potential pharmacologically relevant target for anti-seizure drugs that is likely to have a low side-effect liability in the CNS.
超极化激活的环核苷酸门控(HCN)通道由四个基因(HCN1 - 4)编码,在大脑中具有不同的生物物理特性和功能。HCN4通道在强超极化电位下缓慢激活,使其更有可能在癫痫发作时出现的神经元网络过度兴奋活动中发挥作用。HCN4通道在丘脑核中也高度表达,丘脑是一个与癫痫泛化有关的脑区。在此,我们使用药理学和遗传学方法评估了将HCN4通道作为抗癫痫策略靶点的效用。
使用一种HCN4通道选择性阻滞剂(EC18)和条件性脑特异性HCN4基因敲除小鼠模型,研究降低HCN4通道功能对癫痫易感性和神经元网络兴奋性的影响。
EC18(10 mg·kg)和脑特异性HCN4通道敲除降低了癫痫易感性以及通过脑电图记录的惊厥剂介导的皮层放电,对小鼠的其他行为影响最小。EC18(10 μM)减少了小鼠皮层培养物中的神经元网络爆发。重要的是,EC18对条件性HCN4通道敲除小鼠的惊厥剂介导的癫痫发作没有保护作用,并且在腺相关病毒-HCN4短发夹RNA感染的小鼠皮层培养物中没有降低爆发行为。
这些数据表明HCN4通道是抗癫痫药物潜在的药理学相关靶点,在中枢神经系统中可能具有较低的副作用风险。
