Voltage-dependent ionic conductances of type I spiral ganglion cells from the guinea pig inner ear

Type I spiral ganglion cells provide the afferent innervation to the inner hair cells of the mammalian organ of Corti and project centrally to the cochlear nucleus. While single-unit studies conducted over the past several decades have provided a wealth of information concerning the response characteristics of these neurons and, to some extent, their receptor targets, little is known about the neuron's intrinsic electrical properties. These properties undeniably will contribute to the firing patterns induced by acoustic stimuli. Type I spiral ganglion cell somata from the guinea pig inner ear were acutely isolated and the voltage-dependent conductances were analyzed with the whole-cell voltage clamp. Under conditions that mimic the normal intra- and extracellular ionic environments, type I spiral ganglion cells demonstrate fast inward TTX-sensitive Na currents (whose current density varied markedly among cells) and somewhat more slowly developing outward K currents. Resting potentials averaged -67.3 mV. Under current clamp, no spontaneous spike activity was noted, but short current injections produced graded action potentials with after hyperpolarizations lasting several milliseconds. The nondecaying outward K current activated at potentials near rest and was characterized by a pronounced rectification. The kinetics of the Na and K currents were rapid. Maximum peak inward Na currents occurred within 400 microseconds, between a voltage range of -10 and 0 mV, and inactivated within 4 msec. Recovery from inactivation was also rapid. At a holding potential of -80 mV, the time constant for recovery from an inactivating voltage step to -10 mV was 2.16 msec. Above -50 mV outward K currents reach half-maximal amplitude within 1.5 msec. In addition to these currents, a slow noninactivating TTX-sensitive inward current was observed that was blockable with Cd2+ or Gd3+. Problems encountered with blocking the tremendous outward K current hampered the characterization of this inward current. Similarities between the kinetics of ganglion cell currents and some of the rapid temporal characteristics of eighth nerve single-unit activity confirm the notion that intrinsic membrane properties help shape auditory neuron responses to sound.

[1]  L. A. Westerman,et al.  Rapid and short-term adaptation in auditory nerve responses , 1984, Hearing Research.

[2]  B. Frankenhaeuser,et al.  The effect of temperature on the sodium and potassium permeability changes in myelinated nerve fibres of Xenopus laevis , 1963, The Journal of physiology.

[3]  A. Palmer,et al.  Phase-locking in the cochlear nerve of the guinea-pig and its relation to the receptor potential of inner hair-cells , 1986, Hearing Research.

[4]  M. E. Wisgirda,et al.  Properties of Ca2+ currents in acutely dissociated neurons of the chick ciliary ganglion: Inhibition by somatostatin-14 and somatostatin-28 , 1991, Neuroscience.

[5]  A. Hodgkin,et al.  A quantitative description of membrane current and its application to conduction and excitation in nerve , 1952, The Journal of physiology.

[6]  J. M. Ritchie,et al.  On the physiological role of internodal potassium channels and the security of conduction in myelinated nerve fibres , 1984, Proceedings of the Royal Society of London. Series B. Biological Sciences.

[7]  D. Robertson Possible relation between structure and spike shapes of neurones in guinea pig cochlear ganglion , 1976, Brain Research.

[8]  M. G. Evans,et al.  Calcium currents in hair cells isolated from the cochlea of the chick. , 1990, The Journal of physiology.

[9]  A. King,et al.  Auditory function: Neurobiological bases of hearing G.M. Edelman W.E. , 1990, Neuroscience.

[10]  M. G. Evans,et al.  Potassium currents in hair cells isolated from the cochlea of the chick. , 1990, The Journal of physiology.

[11]  R A Levine,et al.  Auditory-Nerve Activity in Cats Exposed to Ototoxic Drugs and High-Intensity Sounds , 1976, The Annals of otology, rhinology, and laryngology.

[12]  P M Sellick,et al.  Intracellular studies of hair cells in the mammalian cochlea. , 1978, The Journal of physiology.

[13]  D. Tauck,et al.  Voltage‐dependent conductances of solitary ganglion cells dissociated from the rat retina. , 1987, The Journal of physiology.

[14]  P. Dallos,et al.  Spike activity recorded from the organ of Corti , 1986, Hearing Research.

[15]  E Neher,et al.  Sodium and calcium channels in bovine chromaffin cells , 1982, The Journal of physiology.

[16]  D. Oertel The role of intrinsic neuronal properties in the encoding of auditory information in the cochlear nuclei , 1991, Current Opinion in Neurobiology.

[17]  R. Kimura,et al.  Synapses and ephapses in the spiral ganglion. , 1987, Acta oto-laryngologica. Supplementum.

[18]  Alain Marty,et al.  Tight-Seal Whole-Cell Recording , 1983 .

[19]  J. Santos-Sacchi,et al.  Asymmetry in voltage-dependent movements of isolated outer hair cells from the organ of Corti , 1989, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[20]  D P Corey,et al.  Kinetics of the receptor current in bullfrog saccular hair cells , 1983, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[21]  E. Barrett,et al.  Evidence that action potentials activate an internodal potassium conductance in lizard myelinated axons. , 1992, The Journal of physiology.

[22]  J. Lynch,et al.  Slowly activating K+ channels in rat olfactory receptor neurons , 1991, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[23]  R. Keynes The ionic channels in excitable membranes. , 1975, Ciba Foundation symposium.

[24]  W. Gilly,et al.  Control of the spatial distribution of sodium channels in giant fiber lobe neurons of the squid , 1990, Neuron.

[25]  J. Lynch,et al.  Properties of transient K+ currents and underlying single K+ channels in rat olfactory receptor neurons , 1991, The Journal of general physiology.

[26]  C. Armstrong,et al.  Do voltage-dependent K+ channels require Ca2+? A critical test employing a heterologous expression system. , 1990, Proceedings of the National Academy of Sciences of the United States of America.

[27]  P. Dallos,et al.  Forward masking of auditory nerve fiber responses. , 1979, Journal of neurophysiology.

[28]  J. Santos-Sacchi,et al.  Reversible inhibition of voltage-dependent outer hair cell motility and capacitance , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[29]  D. Corey,et al.  Glial and neuronal forms of the voltage-dependent sodium channel: characteristics and cell-type distribution , 1989, Neuron.

[30]  P. Manis,et al.  Outward currents in isolated ventral cochlear nucleus neurons , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[31]  R J Docherty,et al.  Gadolinium selectively blocks a component of calcium current in rodent neuroblastoma x glioma hybrid (NG108‐15) cells. , 1988, The Journal of physiology.

[32]  P. Fuchs,et al.  The acquisition during development of Ca-activated potassium currents by cochlear hair cells of the chick , 1990, Proceedings of the Royal Society of London. Series B: Biological Sciences.

[33]  W. F. Sewell,et al.  The relation between the endocochlear potential and spontaneous activity in auditory nerve fibres of the cat. , 1984, The Journal of physiology.

[34]  P. Slesinger,et al.  Inactivation of calcium currents in granule cells cultured from mouse cerebellum. , 1991, The Journal of physiology.

[35]  S. Roper,et al.  Calcium Currents in Isolated Taste Receptor Cells of the Mudpuppy , 1989 .

[36]  J. Santos-Sacchi,et al.  On the frequency limit and phase of outer hair cell motility: effects of the membrane filter , 1992, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[37]  J R Huguenard,et al.  A fast transient potassium current in thalamic relay neurons: kinetics of activation and inactivation. , 1991, Journal of neurophysiology.

[38]  E. Barrett,et al.  Intracellular recording from vertebrate myelinated axons: mechanism of the depolarizing afterpotential , 1982, The Journal of physiology.

[39]  P. Grafe,et al.  Function and distribution of three types of rectifying channel in rat spinal root myelinated axons. , 1987, The Journal of physiology.

[40]  I. Whitfield Discharge Patterns of Single Fibers in the Cat's Auditory Nerve , 1966 .

[41]  T. F. Weiss,et al.  Mechanisms that degrade timing information in the cochlea , 1990, Hearing Research.

[42]  L. D. Partridge,et al.  Calcium-activated non-specific cation channels , 1988, Trends in Neurosciences.

[43]  G. Westbrook,et al.  Voltage-gated currents in identified rat olfactory receptor neurons , 1991, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[44]  S. Waxman,et al.  Ion channel organization of the myelinated fiber , 1990, Trends in Neurosciences.

[45]  R. Kimura,et al.  Ultrastructural study of the human spiral ganglion. , 1980, Acta oto-laryngologica.