Azene Ezana M, Xue Tian, Li Ronald A
Institute of Molecular Cardiobiology, The Johns Hopkins University School of Medicine, 720 Rutland Avenue/Ross 844, Baltimore, MD 21205, USA.
J Physiol. 2003 Mar 1;547(Pt 2):349-56. doi: 10.1113/jphysiol.2003.039768. Epub 2003 Jan 31.
Hyperpolarization-activated cyclic-nucleotide-gated (HCN) channels modulate the firing rates of neuronal and cardiac pacemaker cells. HCN channels resemble voltage-gated K+ channels structurally, but much less is known about their structure-function correlation. Although modulation of K+ channel gating by external K+ is a well-known phenomenon, such a link has not been established for HCN channels. Here we examined the effects of external permeant (K+, Na+ and Li+) and non-permeant (NMG+) ions on HCN1 and HCN2 gating. Substituting 64 of 96 mM external K+ with Na+, Li+ or NMG+ positively shifted steady-state activation (approximately 13 mV), and preferentially slowed activation of HCN1. Mutating the pore variant C-terminal to the GYG motif in HCN1, A352, to the analogous conserved Asp in K+ channels or Arg in HCN2 produced a significant hyperpolarizing activation shift (by 5-15 mV), slowed gating kinetics (up to 6-fold), and abolished or attenuated gating responses to external K+. Whereas Na+, Li+ and NMG+ substitutions produced depolarizing activation shifts of HCN2 similar to those of HCN1, deactivation but not activation of HCN2 was exclusively decelerated. We conclude that gating and permeation of HCN channels are coupled, and that modulation of this 'pore-to-gate' coupling by external K+ is isoform-specific.
超极化激活的环核苷酸门控(HCN)通道可调节神经元和心脏起搏细胞的放电频率。HCN通道在结构上类似于电压门控K⁺通道,但对其结构与功能的相关性了解较少。尽管外部K⁺对K⁺通道门控的调节是一个众所周知的现象,但尚未确定HCN通道存在这样的联系。在此,我们研究了外部渗透性(K⁺、Na⁺和Li⁺)和非渗透性(NMG⁺)离子对HCN1和HCN2门控的影响。用Na⁺、Li⁺或NMG⁺替代96 mM外部K⁺中的64 mM会使稳态激活正向移动(约13 mV),并优先减慢HCN1的激活。将HCN1中孔变体C末端的GYG基序A352突变为K⁺通道中类似的保守天冬氨酸或HCN2中的精氨酸,会产生显著的超极化激活移动(5 - 15 mV),减慢门控动力学(高达6倍),并消除或减弱对外部K⁺的门控反应。虽然Na⁺、Li⁺和NMG⁺替代产生的HCN2激活移动与HCN1相似,但HCN2的失活而非激活被专门减慢。我们得出结论,HCN通道的门控和通透是耦合的,并且外部K⁺对这种“孔到门”耦合的调节具有亚型特异性。