通过工程HCN1结构对HCN1-和hcn2编码的起搏器电流的显性负抑制:对结构-功能关系和多化的见解

Tian Xue, E. Marbán, Ronald A. Li
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引用次数: 89

摘要

If是一种由超极化激活的舒张去极化电流,在心脏起搏中起着关键作用。尽管人们已经知道了20多年,但编码基因,即HCN1至4,直到最近才被发现。功能数据表明,不同的HCN异构体可能聚集形成异质通道复合物,但很少有直接证据。亚基化学计量学也是未知的。虽然HCN通道的孔区含有K+选择性通道中发现的甘氨酸-t酪氨酸-甘氨酸(GYG)特征基元,但它们同时渗透Na+和K+。在本研究中,我们通过用丙氨酸(GYG349-351AAA或HCN1- aaa)取代HCN1中的GYG选择性基序,探讨了GYG选择性基序在起搏器通道中的功能重要性。HCN1-AAA不产生功能电流;HCN1-AAA与野生型(WT) HCN1的共表达以显性负向方式抑制正常通道活性(WT:AAA cRNA比例分别为4:1、3:1、2:1、1:1和1:2时,−140 mV电流降低分别为55.2±3.2%、68.3±4.3%、78.7±1.6%、91.7±0.8%和97.9±0.2%),而不影响门控(稳态激活、激活和失活动力学)或渗透(逆转电位)特性。然而,HCN1-AAA共表达并没有改变Kv1.4和Kv2.1通道的表达电流幅度,表明其抑制作用是通道特异性的。统计分析表明,单个HCN通道由4个单体亚基组成。有趣的是,HCN1-AAA也以显性阴性方式抑制HCN2,效果相同。我们得出结论,GYG基序是HCN通道离子渗透的关键决定因素,并且HCN1和HCN2很容易聚集形成异四聚体复合物。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Dominant-Negative Suppression of HCN1- and HCN2-Encoded Pacemaker Currents by an Engineered HCN1 Construct: Insights Into Structure-Function Relationships and Multimerization
If, a diastolic depolarizing current activated by hyperpolarization, is a key player in cardiac pacing. Despite the fact that If has been known for over 20 years, the encoding genes, namely HCN1 to 4, have only recently been identified. Functional data imply that different HCN isoforms may coassemble to form heteromeric channel complexes, but little direct evidence is available. Subunit stoichiometry is also unknown. Although the pore region of HCN channels contains the glycine-t yrosine-glycine (GYG) signature motif found in K+-selective channels, they permeate both Na+ and K+. In the present study, we probed the functional importance of the GYG selectivity motif in pacemaker channels by replacing this triplet in HCN1 with alanines (GYG349–351AAA or HCN1-AAA). HCN1-AAA did not yield functional currents; coexpression of HCN1-AAA with wild-type (WT) HCN1 suppressed normal channel activity in a dominant-negative manner (55.2±3.2%, 68.3±4.3%, 78.7±1.6%, 91.7±0.8%, and 97.9±0.2% current reduction at −140 mV for WT:AAA cRNA ratios of 4:1, 3:1, 2:1, 1:1, and 1:2, respectively) without affecting gating (steady-state activation, activation and deactivation kinetics) or permeation (reversal potential) properties. HCN1-AAA coexpression, however, did not alter the expressed current amplitudes of Kv1.4 and Kv2.1 channels, indicating that its suppressive effect was channel-specific. Statistical analysis reveals that a single HCN channel is composed of 4 monomeric subunits. Interestingly, HCN1-AAA also inhibited HCN2 in a dominant-negative manner with the same efficacy. We conclude that the GYG motif is a critical determinant of ion permeation for HCN channels, and that HCN1 and HCN2 readily coassemble to form heterotetrameric complexes.
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