Temperature Enhances Activation and Inactivation Kinetics of Potassium Currents in Inner Hair Cells Isolated from Guinea-Pig Cochlea

ObjectivesUntil recently, most patch-clamp recordings in inner hair cells (IHCs) have been performed at room temperature. The results acquired at room temperature should be corrected if they are to be related to in vivo findings. However, the temperature dependency to ion channels in IHCs is unknown. The aim of this study was to investigate the effect of temperature on the potassium currents in IHCs.MethodsIHCs were isolated from a mature guinea-pig cochlea and potassium currents were recorded at room temperature (around 25℃) and physiological temperatures (35℃-37℃).ResultsIHCs showed outwardly rectifying currents in response to depolarizing voltage pulses, with only a slight inward current when hyperpolarized. The amplitude of both outward and inward currents demonstrated no temperature dependency, however, activation and inactivation rates were faster at 36℃ than at room temperature. Half-time for activation was shorter at 36℃ than at room temperature at membrane potentials of -10, +10, +20, +30, and +40 mV. Q10 for the activation rate was 1.83. The inactivation time constant in outward tetraethylammonium-sensitive potassium currents was much smaller at 36℃ than at room temperature between the membrane potentials of -20 and +60 mV. Q10 for the inactivation time constant was 3.19.ConclusionThe results of this study suggest that the amplitude of potassium currents in IHCs showed no temperature dependence either in outward or inward-going currents, however, activation and inactivation accelerated at physiological temperatures

A role for Piezo2 in EPAC1-dependent mechanical allodynia

N.E. and J.W. designed and supervised experiments. N.E. performed most of the in vivo and in vitro experiments. J.L. performed experiments to characterize hPiezo2. G.H and G.L. supervised by U.O., and J.T. and J.C. cloned hPiezo. L.B. performed the in vivo electrophysiology under the supervision of A.D. M.G. helped with the overexpression studies.M.M. performed surgery. Y.I. provided the Epac1 / mice. F.Z. provided the Epac constructs. N.E. and J.W. wrote manuscript with contributions of all authors. N.E., J.L. and L.B. contributed to data analysis and all authors contributed to the discussionsAberrant mechanosensation has an important role in different pain states. Here we show that Epac1 (cyclic AMP sensor) potentiation of Piezo2-mediated mechanotransduction contributes to mechanical allodynia. Dorsal root ganglia Epac1 mRNA levels increase during neuropathic pain, and nerve damage-induced allodynia is reduced in Epac1 / mice. The Epac-selective cAMP analogue 8-pCPT sensitizes mechanically evoked currents in sensory neurons. Human Piezo2 produces large mechanically gated currents that are enhanced by the activation of the cAMP-sensor Epac1 or cytosolic calcium but are unaffected by protein kinase C or protein kinase A and depend on the integrity of the cytoskeleton. In vivo, 8-pCPT induces long-lasting allodynia that is prevented by the knockdown of Epac1 and attenuated by mouse Piezo2 knockdown. Piezo2 knockdown also enhanced thresholds for light touch. Finally, 8-pCPT sensitizes responses to innocuous mechanical stimuli without changing the electrical excitability of sensory fibres. These data indicate that the Epac1–Piezo2 axis has a role in the development of mechanical allodynia during neuropathic pain.Netherlands Organization for Scientific Research (NWO)Jose Castillejo fellowship JC2010-0196Spanish GovernmentMedical Research Council UK (MRC)WCU at SNU R31-2008-000-10103-0EU IMI Europain grantBBSRC LOLA grantWellcome TrustVersus Arthritis 20200Biotechnology and Biological Sciences Research Council (BBSRC) BB/F000227/1Medical Research Council UK (MRC) G0901905 G9717869 G110034