GPR156 is required in sensory hair cells for proper auditory and vestibular function.

Authors

• Amandine Jarysta, The Jackson LaboratoryFollow
• Brandie Morris Verdone
• Elli I Hartig, The Jackson LaboratoryFollow
• Kathleen E Cullen
• Basile Tarchini, The Jackson LaboratoryFollow

Document Type

Article

Publication Date

1-17-2026

Original Citation

Jarysta A, Verdone B, Hartig E, Cullen K, Tarchini B. GPR156 is required in sensory hair cells for proper auditory and vestibular function. Sci Rep. 2026;16(1):4276.

Keywords

JMG, SS1

JAX Source

Sci Rep. 2026;16(1):4276.

ISSN

2045-2322

PMID

41547998

DOI

https://doi.org/10.1038/s41598-025-34476-4

Abstract

Proper orientation of the apical cytoskeleton in auditory and vestibular hair cells is essential for their sensory function. A recently identified regulator of hair cell orientation is the G protein-coupled receptor GPR156, which signals through inhibitory heterotrimeric G proteins. In hair cells expressing the transcription factor EMX2, GPR156 is apically enriched and polarized at cell junctions. There, GPR156 signaling reverses the interpretation of tissue-level core planar cell polarity cues, effectively reversing the orientation of Emx2-positive compared to Emx2-negative hair cells. This mechanism establishes key anatomical features, such as the correct alignment of auditory outer hair cells and the line of polarity reversal in the otolith organs of the vestibular system. Null mice with constitutive Gpr156 inactivation exhibit severe hearing loss, mirroring congenital hearing impairment in human patients with homozygous GPR156 variants. These null mutants also display impaired swimming and vestibulo-ocular reflexes, although the nature of these vestibular deficits differs from those reported in Emx2 mutants. Here, to determine the extent to which functional deficits arise from hair cell misorientation, we conditionally inactivated Gpr156 in postmitotic hair cells in the inner ear. This targeted deletion approach recapitulated the misorientation phenotype observed in null mutants. Notably, 30–40% of cochlear and utricular hair cells affected in the null background retained normal orientation in conditional mutants, likely due to the later timing of Gpr156 inactivation. Despite reduced efficiency, conditional mutants exhibited similar, albeit predictably milder, auditory and vestibular dysfunction. As hair cells can carry out mechano-electrical transduction without GPR156, we conclude that sensory deficits mainly result from its essential role in hair cell orientation.

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