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毛细胞机械换能器通道的渗透特性为其分子结构提供了深入了解。

Permeation properties of the hair cell mechanotransducer channel provide insight into its molecular structure.

机构信息

Department of Otolaryngology, Stanford University, 300 Pasteur Dr., Stanford, CA 94305, USA.

出版信息

J Neurophysiol. 2012 May;107(9):2408-20. doi: 10.1152/jn.01178.2011. Epub 2012 Feb 8.

DOI:10.1152/jn.01178.2011
PMID:22323630
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3362243/
Abstract

Mechanoelectric transducer (MET) channels, located near stereocilia tips, are opened by deflecting the hair bundle of sensory hair cells. Defects in this process result in deafness. Despite this critical function, the molecular identity of MET channels remains a mystery. Inherent channel properties, particularly those associated with permeation, provide the backbone for the molecular identification of ion channels. Here, a novel channel rectification mechanism is identified, resulting in a reduced pore size at positive potentials. The apparent difference in pore dimensions results from Ca(2+) binding within the pore, occluding permeation. Driving force for permeation at hyperpolarized potentials is increased because Ca(2+) can more easily be removed from binding within the pore due to the presence of an electronegative external vestibule that dehydrates and concentrates permeating ions. Alterations in Ca(2+) binding may underlie tonotopic and Ca(2+)-dependent variations in channel conductance. This Ca(2+)-dependent rectification provides targets for identifying the molecular components of the MET channel.

摘要

机械电换能器 (MET) 通道位于静纤毛尖端附近,通过使感觉毛细胞的毛束偏转而打开。该过程的缺陷会导致耳聋。尽管具有这种关键功能,但 MET 通道的分子身份仍然是个谜。通道的固有特性,特别是与渗透相关的特性,为离子通道的分子鉴定提供了基础。在这里,确定了一种新的通道整流机制,导致在正电势下孔径减小。表观孔径差异源于腔内 Ca(2+) 结合,阻碍了渗透。由于带负电的外部前庭使渗透离子脱水浓缩,因此在超极化电位下渗透的驱动力增加,因为 Ca(2+) 可以更容易地从腔内结合中被移除。Ca(2+) 结合的改变可能是音位和 Ca(2+) 依赖性通道电导变化的基础。这种 Ca(2+) 依赖性整流为确定 MET 通道的分子成分提供了靶标。

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