Abstract
BackgroundIntense endocytic activity at the apex of outer hair cells (OHCs)—the electromechanical cells of the cochlea—has been demonstrated using the vital plasma-membrane marker FM1-43 and confocal laser-scanning microscopy. Vesicular traffic toward the cell nucleus to distinct locations of the endoplasmic reticulum has also been shown.ObjectiveThe current study characterizes the dynamics of endocytic activity, as well as apicobasal and basoapical trafficking, using a local perfusion technique that we recently developed and published to visualize bidirectional trafficking in isolated bipolar cells.Materials and methodsThe fluorescent plasma-membrane markers FM1-43 (10 µM) and FM4-64 (10 µM), together with a fluid-phase marker, Lucifer yellow (50 µM), were used to label endocytosed vesicles in isolated OHCs of the guinea pig cochlea. Targets of endocytosed vesicles were examined with a fluorescent marker of subsurface cisternae, DiOC6 (0.87 µM). Single- and two-photon confocal laser-scanning microscopy was used to visualize labeled vesicles.ResultsThe plasma-membrane markers presented more intense vesicle internalization at the synaptic pole than at the apical pole of the OHC. Intracellular basoapical vesicle trafficking was faster than apicobasal trafficking. Vesicles endocytosed at the synaptic pole were transcytosed to the endoplasmic reticulum system. An intracellular Lucifer yellow signal was not detected.ConclusionThe larger endocytic fluorescent signals in the synaptic pole and the faster basoapical trafficking imply that membrane internalization and vesicle trafficking are more efficient at the synaptic pole than at the apical pole of the OHC.
Highlights
Outer hair cells (OHCs)—the electromotile elements of the organ of Corti—are responsible for the highfrequency selectivity as well as lowthreshold and broad dynamic range of hearing [2, 6, 20]
The efferents modulate the electromechanical response of the OHC via calcium-activated changes of the transmembrane potential and cell stiffness [17], which result in a conformation change of the electromotile protein, prestin [35], expressed in high density in the lateral plasma membrane (PM) of the OHC [19], as well as modulation of the electromechanical force produced by the cell
The current study characterizes the dynamics of endocytic activity, as well as apicobasal and basoapical trafficking, using a local perfusion technique that we recently developed and published to visualize bidirectional trafficking in isolated bipolar cells
Summary
Outer hair cells (OHCs)—the electromotile elements of the organ of Corti—are responsible for the highfrequency selectivity as well as lowthreshold and broad dynamic range of hearing [2, 6, 20]. The apical pole of the OHC is the site of mechanoelectrical transduction, where hair-bundle deflection causes ion influx accompa-. These data were presented at the 55th Inner Ear Biology Workshop, held in Berlin in September 2018. The (medial) efferents modulate the electromechanical response of the OHC via calcium-activated changes of the transmembrane potential and cell stiffness [17], which result in a conformation change of the electromotile protein, prestin [35], expressed in high density in the lateral plasma membrane (PM) of the OHC [19], as well as modulation of the electromechanical force produced by the cell. The current study characterizes the dynamics of endocytic activity, as well as apicobasal and basoapical trafficking, using a local perfusion technique that we recently developed and published to visualize bidirectional trafficking in isolated bipolar cells
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