Taperin bundles F-actin at stereocilia pivot points enabling optimal lifelong mechanosensitivity.

IF 7.4 1区生物学 Q1 CELL BIOLOGY

Journal of Cell Biology Pub Date : 2025-08-04 Epub Date: 2025-06-05 DOI:10.1083/jcb.202408026

Inna A Belyantseva, Chang Liu, Abigail K Dragich, Takushi Miyoshi, Sayaka Inagaki, Ayesha Imtiaz, Risa Tona, Karen Sofia Zuluaga-Osorio, Shadan Hadi, Elizabeth Wilson, Eva Morozko, Rafal Olszewski, Rizwan Yousaf, Yuliya Sokolova, Gavin P Riordan, S Andrew Aston, Atteeq U Rehman, Cristina Fenollar Ferrer, Jan Wisniewski, Shoujun Gu, Gowri Nayak, Richard J Goodyear, Jinan Li, Jocelyn F Krey, Talah Wafa, Rabia Faridi, Samuel Mawuli Adadey, Meghan Drummond, Benjamin Perrin, Dennis C Winkler, Matthew F Starost, Hui Cheng, Tracy Fitzgerald, Guy P Richardson, Lijin Dong, Peter G Barr-Gillespie, Michael Hoa, Gregory I Frolenkov, Thomas B Friedman, Bo Zhao

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引用次数: 0

Abstract

Stereocilia are rod-like mechanosensory projections consisting of unidirectionally oriented actin filaments that extend into the inner ear hair cell cytoskeleton, forming dense rootlets. Taperin (TPRN) localizes to the narrowed-down base of stereocilia, where they pivot in response to sound and gravity. We show that TPRN-deficient mice have progressive deafness characterized by gradual asynchronous retraction and fusion of outer and inner hair cell stereocilia, followed by synaptic abnormalities. Stereocilia that lack TPRN develop warped rootlets with gradual loss of TRIOBP-5 and ANKRD24 from mechanosensory rows starting postnatally. In contrast, TPRN overexpression causes excessive F-actin bundling, extra rows, and over-elongation of stereocilia during development. Purified full-length mouse TPRN cross-links F-actin into bendable bundles reflecting in vivo data. This F-actin-bundling ability is attributed to the TPRN N-terminal region. TPRN interacts with the membrane receptor PTPRQ, connecting the F-actin core to the plasma membrane, stabilizing stereocilia. Thus, TPRN is a specialized F-actin bundler strategically located to augment stereocilia rootlet formation and their pivot point flexibility for sustained sound-induced deflections.

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锥形肽束f -肌动蛋白在立体纤毛支点实现最佳终身机械敏感性。

立体纤毛是杆状的机械感觉突起，由单向的肌动蛋白丝组成，延伸到内耳毛细胞骨架中，形成致密的细根。锥形蛋白（TPRN）定位于立体纤毛的狭窄基部，在那里它们对声音和重力做出反应。我们发现tprn缺陷小鼠具有进行性耳聋，其特征是外毛细胞和内毛细胞立体纤毛逐渐异步收缩和融合，随后是突触异常。缺乏TPRN的立体纤毛从出生后开始从机械感觉行逐渐丧失TRIOBP-5和ANKRD24，从而形成弯曲的根。相反，在发育过程中，TPRN过表达会导致过度的f -肌动蛋白捆绑、多行和立体纤毛过度伸长。纯化的全长小鼠TPRN将f -肌动蛋白交联成可弯曲束，反映了体内数据。这种f -肌动蛋白捆绑能力归因于TPRN n端区域。TPRN与膜受体PTPRQ相互作用，将f -肌动蛋白核心连接到质膜上，稳定立体纤毛。因此，TPRN是一种特殊的f -肌动蛋白束束器，战略性地定位于增强立体纤毛根的形成及其支点的灵活性，以维持声音诱导的偏转。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Cell Biology 生物-细胞生物学

CiteScore

12.60

自引率

2.60%

发文量

213

审稿时长

1 months

期刊介绍： The Journal of Cell Biology (JCB) is a comprehensive journal dedicated to publishing original discoveries across all realms of cell biology. We invite papers presenting novel cellular or molecular advancements in various domains of basic cell biology, along with applied cell biology research in diverse systems such as immunology, neurobiology, metabolism, virology, developmental biology, and plant biology. We enthusiastically welcome submissions showcasing significant findings of interest to cell biologists, irrespective of the experimental approach.