Optogenetics reveals roles for supporting cells in force transmission to and from outer hair cells in the mouse cochlea

Abstract

ABSTRACTCochlear outer hair cells (OHCs), acting as bidirectional cellular mechanoelectrical-transducers, generate, receive, and exchange forces with other major elements of the cochlear partition, including inner hair cells (IHCs). Force exchange is mediated via a supporting cell scaffold, including Deiters’ (DC) and outer pillar cells (OPC), to enable the sensitivity and exquisite frequency selectivity of the mammalian cochlea. We conditionally expressed a hyperpolarizing halorhodopsin (HOP), a light-gated inward chloride ion pump in DCs and OPCs. We measured extracellular receptor potentials (ERPs) and their DC component (ERPDC) from the Cortilymph (CL) of HOP expressing mice and compared the responses with similar potentials from littermates without HOP expression. Compound action potentials (CAP) were measured as an indication of IHC activity. HOP laser activation suppressed cochlear amplification through changing timing of its feedback, altered basilar membrane (BM) responses to tones at all measured levels and frequencies, and reduced IHC excitation. Our HOP activation results here complement previous channelrhodopsin activation studies in exploiting optogenetics to measure and understand the roles of DCs and OPCsin vivoin controlling the mechanical and electrical responses of OHCs to sound and their contribution to timed and directed electromechanical feedback to the mammalian cochlea.SIGNIFICANCE STATEMENTOuter hair cells provide electromechanical feedback to the organ of Corti, mediated via a cellular scaffold of Deiters’ and outer pillar cells, that enables the sensitivity and fine frequency tuning of the cochlea. The role of this scaffold was explored by expressing the halorhodopsin HOP in Deiters’ and pillar cells which, when illuminated, hyperpolarized them. HOP activation suppressed cochlear amplification through altering the timing of outer hair cell forces to the Organ of Corti, altered basilar membrane responses to tones, including those at levels and frequencies not subject to amplification, and reduced neural excitation. The findings implicated roles for supporting cells in mediating force transmission to and from outer hair cells along all axes of the organ of Corti.