Abstract
HCN channels regulate excitability and rhythmicity in the hippocampal CA1 pyramidal cells. Perturbation in the HCN channel current (Ih) is associated with neuropsychiatric disorders, such as autism spectrum disorders. Recently, protein arginine methyltransferase 7 (PRMT7) was shown to be highly expressed in the hippocampus, including the CA1 region. However, the physiological function of PRMT7 in the CA1 neurons and the relationship to psychiatric disorders are unclear. Here we showed that PRMT7 knockout (KO) mice exhibit hyperactivity and deficits in social interaction. The firing frequency of the CA1 neurons in the PRMT7 KO mice was significantly higher than that in the wild-type (WT) mice. Compared with the WT CA1 neurons, the PRMT7 KO CA1 neurons showed a more hyperpolarized resting potential and a higher input resistance, which were occluded by the Ih-current inhibitor ZD7288; these findings were consistent with the decreased Ih and suggested the contribution of Ih-channel dysfunction to the PRMT7 KO phenotypes. The HCN1 protein level was decreased in the CA1 region of the PRMT7 KO mice in conjunction with a decrease in the expression of Shank3, which encodes a core scaffolding protein for HCN channel proteins. A brief application of the PRMT7 inhibitor DS437 did not reproduce the phenotype of the PRMT7 KO neurons, further indicating that PRMT7 regulates Ih by controlling the channel number rather than the open probability. Moreover, shRNA-mediated PRMT7 suppression reduced both the mRNA and protein levels of SHANK3, implying that PRMT7 deficiency might be responsible for the decrease in the HCN protein levels by altering Shank3 expression. These findings reveal a key role for PRMT7 in the regulation of HCN channel density in the CA1 pyramidal cells that may be amenable to pharmacological intervention for neuropsychiatric disorders.
Highlights
Neuronal signaling within a region and at a circuit level is affected by intrinsic excitability and the distribution of ion channels
We revealed that protein arginine methyltransferase 7 (PRMT7) KO impairs Ih-channel function in the CA1 pyramidal cells as a primary impairment, which in turn produces major changes in intrinsic neuronal excitability
We found that Ih-current inhibition with ZD7288 in the WT CA1 pyramidal cells significantly increased the firing frequency and the input resistance, and these effects were very similar to those of PRMT7 KO
Summary
Neuronal signaling within a region and at a circuit level is affected by intrinsic excitability and the distribution of ion channels. Dysfunction of ion channels can lead to abnormal excitability and subsequent neuronal dysfunction. HCN channels are present throughout the brain and. Four subunits (HCN 1–4) of the HCN channels that conduct the Ih currents have been identified[2,3,4,5]. HCN channels are activated by hyperpolarized states >−40 mV, increasing their activation as cells become more hyperpolarized, and do not display inactivation[6]. Since HCN channels are open at hyperpolarized states >−40 mV, Ih is partially activated under physiological, “resting” conditions, providing constant depolarization of the membrane potential[7,8,9].
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