Single-cell transcriptomic atlas reveals increased regeneration in diseased human inner ear balance organs.
Tian WangAngela H LingSara E BillingsDavood K HosseiniYona VaisbuchGrace S KimPatrick J AtkinsonZahra N SayyidKsenia A AaronDhananjay WaghNicole PhamMirko ScheibingerRuiqi ZhouAkira IshiyamaLindsay S MoorePeter Santa MariaNikolas H BlevinsRobert K JacklerJennifer C AlyonoJohn KvetonDhasakumar NavaratnamStefan HellerIvan A LopezNicolas GrilletTaha A JanAlan G ChengPublished in: Nature communications (2024)
Mammalian inner ear hair cell loss leads to permanent hearing and balance dysfunction. In contrast to the cochlea, vestibular hair cells of the murine utricle have some regenerative capacity. Whether human utricular hair cells regenerate in vivo remains unknown. Here we procured live, mature utricles from organ donors and vestibular schwannoma patients, and present a validated single-cell transcriptomic atlas at unprecedented resolution. We describe markers of 13 sensory and non-sensory cell types, with partial overlap and correlation between transcriptomes of human and mouse hair cells and supporting cells. We further uncover transcriptomes unique to hair cell precursors, which are unexpectedly 14-fold more abundant in vestibular schwannoma utricles, demonstrating the existence of ongoing regeneration in humans. Lastly, supporting cell-to-hair cell trajectory analysis revealed 5 distinct patterns of dynamic gene expression and associated pathways, including Wnt and IGF-1 signaling. Our dataset constitutes a foundational resource, accessible via a web-based interface, serving to advance knowledge of the normal and diseased human inner ear.