Stereocilia are mechanosensitive protrusions on the surfaces of sensory hair cells in the inner ear that detect sound, gravity, and head movement. Their cores are composed of parallel actin filaments that are cross-linked and stabilized by several actin-binding proteins, including fascin-2, plastin-1, espin, and XIRP2. The actin filaments are the most stable known, with actin turnover primarily occurring at the stereocilia tips. While stereocilia actin dynamics has been well studied, little is known about the behavior of the actin cross-linking proteins, which are the most abundant type of protein in stereocilia after actin and are critical for stereocilia morphogenesis and maintenance. Here, we developed a novel transgenic mouse to monitor EGFP-fascin-2 incorporation . In contrast to actin, EGFP-fascin-2 readily enters the stereocilia core. We also compared the effect of EGFP-fascin-2 expression on developing and mature stereocilia. When it was induced during hair cell development, we observed increases in both stereocilia length and width. Interestingly, stereocilia size was not affected when EGFP-fascin-2 was induced in adult stereocilia. Regardless of the time of induction, EGFP-fascin-2 displaced both espin and plastin-1 from stereocilia. Altering the actin cross-linker composition, even as the actin filaments exhibit little to no turnover, provides a mechanism for ongoing remodeling and repair important for stereocilia homeostasis.
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| http://dx.doi.org/10.1091/mbc.E18-03-0196 | DOI Listing |
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Article Synopsis
- In the auditory and vestibular systems, stereocilia are specialized structures that convert sound and motion into electrical signals, with their growth involving the addition of actin filaments.
- Research focused on how stereocilia widen during development, finding that new actin filaments first incorporate at the tips before spreading along the shaft, indicating that the core structure remains stable.
- The study revealed a previously unrecognized population of short actin filaments at the tips of stereocilia, which are influenced by specific myosin motors (MYO3A/B and MYO15A) that play a crucial role in their growth and stabilization, suggesting these interactions are important for proper mechanosensory function.
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