Role of the voltage sensor module in Nav domain IV on fast inactivation in sodium channelopathies: The implication of closed-state inactivation

IF 3.3 3区 生物学 Q2 BIOCHEMISTRY & MOLECULAR BIOLOGY Channels Pub Date : 2019-01-01 DOI:10.1080/19336950.2019.1649521
T. Nakajima, Y. Kaneko, Tommy Dharmawan, M. Kurabayashi
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引用次数: 11

Abstract

ABSTRACT The segment 4 (S4) voltage sensor in voltage-gated sodium channels (Navs) have domain-specific functions, and the S4 segment in domain DIV (DIVS4) plays a key role in the activation and fast inactivation processes through the coupling of arginine residues in DIVS4 with residues of putative gating charge transfer center (pGCTC) in DIVS1-3. In addition, the first four arginine residues (R1-R4) in Nav DIVS4 have position-specific functions in the fast inactivation process, and mutations in these residues are associated with diverse phenotypes of Nav-related diseases (sodium channelopathies). R1 and R2 mutations commonly display a delayed fast inactivation, causing a gain-of-function, whereas R3 and R4 mutations commonly display a delayed recovery from inactivation and profound use-dependent current attenuation, causing a severe loss-of-function. In contrast, mutations of residues of pGCTC in Nav DIVS1-3 can also alter fast inactivation. Such alterations in fast inactivation may be caused by disrupted interactions of DIVS4 with DIVS1-3. Despite fast inactivation of Navs occurs from both the open-state (open-state inactivation; OSI) and closed state (closed-state inactivation; CSI), changes in CSI have received considerably less attention than those in OSI in the pathophysiology of sodium channelopathies. CSI can be altered by mutations of arginine residues in DIVS4 and residues of pGCTC in Navs, and altered CSI can be an underlying primary biophysical defect of sodium channelopathies. Therefore, CSI should receive focus in order to clarify the pathophysiology of sodium channelopathies.
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Nav结构域电压传感器模块在钠通道病变快速失活中的作用:闭合状态失活的含义
电压门控钠离子通道(Navs)中的4段(S4)电压传感器具有域特异性功能,而DIV域(DIVS4)中的S4段通过DIVS4中的精氨酸残基与DIVS1-3中假定的门控电荷转移中心(pGCTC)残基的耦合在激活和快速失活过程中起关键作用。此外,Nav DIVS4中的前四个精氨酸残基(R1-R4)在快速失活过程中具有位置特异性功能,这些残基的突变与Nav相关疾病(钠通道病)的多种表型相关。R1和R2突变通常表现为延迟的快速失活,导致功能获得,而R3和R4突变通常表现为延迟的失活恢复和严重的使用依赖的电流衰减,导致严重的功能丧失。相反,Nav DIVS1-3中pGCTC残基的突变也可以改变快速失活。这种快速失活的改变可能是由DIVS4与DIVS1-3的相互作用中断引起的。尽管nav的快速失活发生在开放状态(开放状态失活;OSI)和关闭状态(关闭状态失活;CSI),在钠通道病变的病理生理学中,CSI的变化比OSI的变化受到的关注要少得多。DIVS4中精氨酸残基和nav中pGCTC残基的突变可以改变CSI, CSI的改变可能是钠通道病潜在的原发性生物物理缺陷。因此,为了阐明钠通道病变的病理生理机制,CSI应受到重视。
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来源期刊
Channels
Channels 生物-生化与分子生物学
CiteScore
5.90
自引率
0.00%
发文量
21
审稿时长
6-12 weeks
期刊介绍: Channels is an open access journal for all aspects of ion channel research. The journal publishes high quality papers that shed new light on ion channel and ion transporter/exchanger function, structure, biophysics, pharmacology, and regulation in health and disease. Channels welcomes interdisciplinary approaches that address ion channel physiology in areas such as neuroscience, cardiovascular sciences, cancer research, endocrinology, and gastroenterology. Our aim is to foster communication among the ion channel and transporter communities and facilitate the advancement of the field.
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