Prestin-Dependence of Outer Hair Cell Survival and Partial Rescue of Outer Hair Cell Loss in PrestinV499G/Y501H Knockin Mice.

Mary Ann Cheatham,Peter Dallos,Kazuaki Homma,Emily L Leserman,Roxanne M Edge,Jing Zheng,Jonathan I Matsui

doi:10.1371/journal.pone.0145428

Mary Ann Cheatham, Peter Dallos + Show 5 more

Open Access

https://doi.org/10.1371/journal.pone.0145428

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Journal: PloS one	Publication Date: Dec 18, 2015
Citations: 13	License type: CC BY 4.0

Affiliation: Northwestern University, Knowles (United States)

Abstract

A knockin (KI) mouse expressing mutated prestin V499G/Y501H (499 prestin) was created to study cochlear amplification. Recordings from isolated outer hair cells (OHC) in this mutant showed vastly reduced electromotility and, as a consequence, reduced hearing sensitivity. Although 499 prestin OHCs were normal in stiffness and longer than OHCs lacking prestin, accelerated OHC death was unexpectedly observed relative to that documented in prestin knockout (KO) mice. These observations imply an additional role of prestin in OHC maintenance besides its known requirement for mammalian cochlear amplification. In order to gain mechanistic insights into prestin-associated OHC loss, we implemented several interventions to improve survival. First, 499 prestin KI’s were backcrossed to Bak KO mice, which lack the mitochondrial pro-apoptotic gene Bak. Because oxidative stress is implicated in OHC death, another group of 499 prestin KI mice was fed the antioxidant diet, Protandim. 499 KI mice were also backcrossed onto the FVB murine strain, which retains excellent high-frequency hearing well into adulthood, to reduce the compounding effect of age-related hearing loss associated with the original 499 prestin KIs. Finally, a compound heterozygous (chet) mouse expressing one copy of 499 prestin and one copy of KO prestin was also created to reduce quantities of 499 prestin protein. Results show reduction in OHC death in chets, and in 499 prestin KIs on the FVB background, but only a slight improvement in OHC survival for mice receiving Protandim. We also report that improved OHC survival in 499 prestin KIs had little effect on hearing phenotype, reaffirming the original contention about the essential role of prestin’s motor function in cochlear amplification.

Highlights

Prestin, the molecular motor essential for feedback amplification in the cochlea [1,5] is exclusively expressed in outer hair cells (OHCs) and is required for electromechanical transduction
499 prestin KI mice show accelerated, progressive OHC death when compared to both prestin KO and wildtype mouse models expressing age-related hearing loss genes (129/C57BL6)
We attempted to attenuate the effects of dysfunctional prestin in the 499 prestin KI mouse by administering a variety of treatments aimed to ameliorate OHC loss in order to make the 499 prestin KI mouse model more suitable for studying cochlear amplification

Summary

Introduction

The molecular motor essential for feedback amplification in the cochlea [1,5] is exclusively expressed in outer hair cells (OHCs) and is required for electromechanical (reverse) transduction. OHCs lacking prestin had no measureable motility, threshold shifts were ~50 dB [1] and tuning functions lacked sharp tip segments [6] These results indicate that prestin is required for OHC electromotility, it is difficult to determine on their bases the degree to which prestin contributes to cochlear amplification due to structural and mechanical changes in the KO organ of Corti. OHCs in prestin KO mice are only 60% of WT in length [7] and their stiffness is reduced [2] These changes in OHC properties influence the load seen by the amplifier with the result that the complex feedback loop including the basilar membrane, OHC and tectorial membrane is altered. These changes in physical/anatomical properties could well result in a loss of gain independent of whether prestin was responsible for amplification [8]

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