Gravitational Change-induced Alteration of the Vestibular Function and Gene Expression in the Vestibular Ganglion of Mice

Overview

Journal J Physiol Sci

Specialty Physiology

Date 2024 Sep 18

PMID 39294564

Authors

Murat Bazek

Motoya Sawa

Kazuhiro Horii

Naotoshi Nakamura

Shingo Iwami

Chia-Hsien Wu

Tsuyoshi Inoue

Fumiaki Nin

Chikara Abe

Affiliations

Soon will be listed here.

Abstract

Gravity has profoundly influenced life on Earth, yet how organisms adapt to changes in gravity remains largely unknown. This study examines vestibular plasticity, specifically how the vestibular system responds to altered gravity. We subjected male C57BL/6J mice to hypergravity (2 G) followed by normal gravity (1 G) to analyze changes in vestibular function and gene expression. Mice showed significant vestibular dysfunction, assessed by righting reflex tests, which persisted for days but reversed at 1 G after exposure to 2 G. Gene expression analysis in the vestibular ganglion identified significant changes in 212 genes out of 49,585 due to gravitational changes. Specifically, 25 genes were upregulated under 2 G and recovered at 1 G after 2 G exposure, while one gene showed the opposite trend. Key neural function genes like Shisa3, Slc25a37, Ntn4, and Snca were involved. Our results reveal that hypergravity-induced vestibular dysfunction is reversible and highlight genes critical for adaptation.

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