3D Morphology of an Outer-hair-cell Hair Bundle Increases Its Displacement and Dynamic Range

Overview

Journal Biophys J

Publisher Cell Press

Specialty Biophysics

Date 2024 Aug 20

PMID 39161094

Authors

Zenghao Zhu

Wisam Reid

Shefin Sam George

Victoria Ou

Daibhid O Maoileidigh

Affiliations

Soon will be listed here.

Abstract

In mammals, outer-hair-cell hair bundles (OHBs) transduce sound-induced forces into receptor currents and are required for the wide dynamic range and high sensitivity of hearing. OHBs differ conspicuously in morphology from other types of bundles. Here, we show that the 3D morphology of an OHB greatly impacts its mechanics and transduction. An OHB comprises rod-like stereocilia, which pivot on the surface of its sensory outer hair cell. Stereocilium pivot positions are arranged in columns and form a V shape. We measure the pivot positions and determine that OHB columns are far from parallel. To calculate the consequences of an OHB's V shape and far-from-parallel columns, we develop a mathematical model of an OHB that relates its pivot positions, 3D morphology, mechanics, and receptor current. We find that the 3D morphology of the OHB can halve its stiffness, can double its damping coefficient, and causes stereocilium displacements driven by stimulus forces to differ substantially across the OHB. Stereocilium displacements drive the opening and closing of ion channels through which the receptor current flows. Owing to the stereocilium-displacement differences, the currents passing through the ion channels can peak versus the stimulus frequency and vary considerably across the OHB. Consequently, the receptor current peaks versus the stimulus frequency. Ultimately, the OHB's 3D morphology can increase its receptor-current dynamic range more than twofold. Our findings imply that potential pivot-position changes owing to development, mutations, or location within the mammalian auditory organ might greatly alter OHB function.

Citing Articles

Gating-spring stiffness increases outer-hair-cell bundle stiffness, damping, and receptor current.

Zhu Z, Reid W, O Maoileidigh D Sci Rep. 2024; 14(1):29904.

PMID: 39622900 PMC: 11612202. DOI: 10.1038/s41598-024-81355-5.

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