Low Somatic Sodium Conductance Enhances Action Potential Precision in Time-Coding Auditory Neurons

Auditory nerve fibers encode sounds in the precise timing of action potentials (APs), which is used for such computations as sound localization. Timing information is relayed through several cell types in the auditory brainstem that share an unusual property: their APs are not overshooting, suggesting that the cells have very low somatic sodium conductance (gNa). However, it is not clear how gNa influences temporal precision. We addressed this by comparing bushy cells (BCs) in the mouse cochlear nucleus with T-stellate cells (SCs), which do have normal overshooting APs. BCs play a central role in both relaying and refining precise timing information from the auditory nerve, whereas SCs discard precise timing information and encode the envelope of sound amplitude. Nucleated-patch recording at near-physiological temperature indicated that the Na current density was 62% lower in BCs, and the voltage dependence of gNa inactivation was 13 mV hyperpolarized compared with SCs. We endowed BCs with SC-like gNa using two-electrode dynamic clamp and found that synaptic activity at physiologically relevant rates elicited APs with significantly lower probability, through increased activation of delayed rectifier channels. In addition, for two near-simultaneous synaptic inputs, the window of coincidence detection widened significantly with increasing gNa, indicating that refinement of temporal information by BCs is degraded by gNa. Thus, reduced somatic gNa appears to be an adaption for enhancing fidelity and precision in time-coding neurons. SIGNIFICANCE STATEMENT Proper hearing depends on analyzing temporal aspects of sounds with high precision. Auditory neurons that specialize in precise temporal information have a suite of unusual intrinsic properties, including nonovershooting action potentials and few sodium channels in the soma. However, it was not clear how low sodium channel availability in the soma influenced the temporal precision of action potentials initiated in the axon initial segment. We studied this using dynamic clamp to mimic sodium channels in the soma, which yielded normal, overshooting action potentials. Increasing somatic sodium conductance had major negative consequences: synaptic activity evoked action potentials with lower fidelity, and the precision of coincidence detection was degraded. Thus, low somatic sodium channel availability appears to enhance fidelity and temporal precision.

[1]  B. Grothe,et al.  Precise inhibition is essential for microsecond interaural time difference coding , 2002, Nature.

[2]  H. von Gersdorff,et al.  Fine-Tuning an Auditory Synapse for Speed and Fidelity: Developmental Changes in Presynaptic Waveform, EPSC Kinetics, and Synaptic Plasticity , 2000, The Journal of Neuroscience.

[3]  Bina Ramamurthy,et al.  High-speed dynamic-clamp interface. , 2015, Journal of neurophysiology.

[4]  Masakazu Konishi,et al.  Passive soma facilitates submillisecond coincidence detection in the owl's auditory system. , 2007, Journal of neurophysiology.

[5]  D. M. Soderlund,et al.  Functional Expression of Rat Nav1.6 Voltage-Gated Sodium Channels in HEK293 Cells: Modulation by the Auxiliary β1 Subunit , 2014, PloS one.

[6]  J. Borst,et al.  Short-term plasticity at the calyx of held , 2002, Nature Reviews Neuroscience.

[7]  J. Goldberg,et al.  Response of binaural neurons of dog superior olivary complex to dichotic tonal stimuli: some physiological mechanisms of sound localization. , 1969, Journal of neurophysiology.

[8]  J. Zook,et al.  Afferents to the medial nucleus of the trapezoid body and their collateral projections , 1991, The Journal of comparative neurology.

[9]  Nace L. Golding,et al.  Perisomatic Voltage-Gated Sodium Channels Actively Maintain Linear Synaptic Integration in Principal Neurons of the Medial Superior Olive , 2010, The Journal of Neuroscience.

[10]  William A Catterall,et al.  Overview of the voltage-gated sodium channel family , 2003, Genome Biology.

[11]  L. Kaczmarek,et al.  Contribution of the Kv3.1 potassium channel to high‐frequency firing in mouse auditory neurones , 1998, The Journal of physiology.

[12]  Jeffrey J. Clare,et al.  Electrophysiological and pharmacological properties of the human brain type IIA Na+ channel expressed in a stable mammalian cell line , 2000, Pflügers Archiv.

[13]  D. Oertel,et al.  Voltage-sensitive conductances of bushy cells of the Mammalian ventral cochlear nucleus. , 2007, Journal of neurophysiology.

[14]  Matthew A Xu-Friedman,et al.  Developmental Mechanisms for Suppressing the Effects of Delayed Release at the Endbulb of Held , 2010, The Journal of Neuroscience.

[15]  D. O. Kim,et al.  Responses of DCN-PVCN neurons and auditory nerve fibers in unanesthetized decerebrate cats to AM and pure tones: Analysis with autocorrelation/power-spectrum , 1990, Hearing Research.

[16]  M. Chahine,et al.  Regulation of Nav1.6 and Nav1.8 peripheral nerve Na+ channels by auxiliary β-subunits. , 2011, Journal of neurophysiology.

[17]  J. Rothman,et al.  Differential expression of three distinct potassium currents in the ventral cochlear nucleus. , 2003, Journal of neurophysiology.

[18]  A L Goldin,et al.  Functional Analysis of the Rat I Sodium Channel inXenopus Oocytes , 1998, The Journal of Neuroscience.

[19]  Philip H Smith,et al.  Coincidence Detection in the Auditory System 50 Years after Jeffress , 1998, Neuron.

[20]  I. Forsythe,et al.  Two voltage-dependent K+ conductances with complementary functions in postsynaptic integration at a central auditory synapse , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[21]  Joshua X. Gittelman,et al.  Kv1.1-containing channels are critical for temporal precision during spike initiation. , 2006, Journal of neurophysiology.

[22]  D. Oertel Synaptic responses and electrical properties of cells in brain slices of the mouse anteroventral cochlear nucleus , 1983, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[23]  Wade G Regehr,et al.  Dynamic-clamp analysis of the effects of convergence on spike timing. I. Many synaptic inputs. , 2005, Journal of neurophysiology.

[24]  S. Shore,et al.  Multisensory integration in the dorsal cochlear nucleus: unit responses to acoustic and trigeminal ganglion stimulation , 2005, The European journal of neuroscience.

[25]  H. Markram,et al.  Regulation of Synaptic Efficacy by Coincidence of Postsynaptic APs and EPSPs , 1997, Science.

[26]  H. Brew,et al.  Differential expression of voltage-gated potassium channel genes in auditory nuclei of the mouse brainstem , 2000, Hearing Research.

[27]  Nace L. Golding,et al.  Role of Intrinsic Conductances Underlying Responses to Transients in Octopus Cells of the Cochlear Nucleus , 1999, The Journal of Neuroscience.

[28]  K. Futai,et al.  High-Fidelity Transmission Acquired via a Developmental Decrease in NMDA Receptor Expression at an Auditory Synapse , 2001, The Journal of Neuroscience.

[29]  M. Liberman,et al.  Response properties of single auditory nerve fibers in the mouse. , 2005, Journal of neurophysiology.

[30]  Nace L. Golding,et al.  The relative contributions of MNTB and LNTB neurons to inhibition in the medial superior olive assessed through single and paired recordings , 2014, Front. Neural Circuits.

[31]  Altered sodium currents in auditory neurons of congenitally deaf mice , 2006, The European journal of neuroscience.

[32]  E. Ostapoff,et al.  Synaptic organization of globular bushy cells in the ventral cochlear nucleus of the cat: A quantitative study , 1991, The Journal of comparative neurology.

[33]  D. H. Johnson,et al.  The relationship between spike rate and synchrony in responses of auditory-nerve fibers to single tones. , 1980, The Journal of the Acoustical Society of America.

[34]  L. Kaczmarek,et al.  Acoustic environment determines phosphorylation state of the Kv3.1 potassium channel in auditory neurons , 2005, Nature Neuroscience.

[35]  R. Frisina,et al.  Differential encoding of rapid changes in sound amplitude by second-order auditory neurons , 2004, Experimental Brain Research.

[36]  Christoph Schmidt-Hieber,et al.  Fast Sodium Channel Gating Supports Localized and Efficient Axonal Action Potential Initiation , 2010, The Journal of Neuroscience.

[37]  C. Colbert,et al.  Ion channel properties underlying axonal action potential initiation in pyramidal neurons , 2002, Nature Neuroscience.

[38]  Anthony N. Burkitt,et al.  Analysis of Integrate-and-Fire Neurons: Synchronization of Synaptic Input and Spike Output , 1999, Neural Computation.

[39]  M. A. Xu-Friedman,et al.  Neuromodulation by GABA converts a relay into a coincidence detector. , 2010, Journal of neurophysiology.

[40]  Jeannette A. M. Lorteije,et al.  Reliability and Precision of the Mouse Calyx of Held Synapse , 2009, The Journal of Neuroscience.

[41]  Amanda M. Lauer,et al.  Activity-dependent, homeostatic regulation of neurotransmitter release from auditory nerve fibers , 2015, Proceedings of the National Academy of Sciences.

[42]  D. Oertel,et al.  Auditory nerve fibers excite targets through synapses that vary in convergence, strength, and short-term plasticity. , 2010, Journal of neurophysiology.

[43]  D. Ottoson,et al.  The site of impulse initiation in a nerve cell of a crustacean stretch receptor , 1958, The Journal of physiology.

[44]  Y. H. Chen,et al.  Functional modulation of human brain Nav1.3 sodium channels, expressed in mammalian cells, by auxiliary β1, β2 and β3 subunits , 2002, Neuroscience.

[45]  D. Oertel,et al.  Intracellular injection with horseradish peroxidase of physiologically characterized stellate and bushy cells in slices of mouse anteroventral cochlear nucleus , 1984, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[46]  B. Bean The action potential in mammalian central neurons , 2007, Nature Reviews Neuroscience.

[47]  T. Yin,et al.  Interaural time sensitivity in medial superior olive of cat. , 1990, Journal of neurophysiology.

[48]  G. Stuart,et al.  Direct measurement of specific membrane capacitance in neurons. , 2000, Biophysical journal.

[49]  D. Johnston,et al.  A Synaptically Controlled, Associative Signal for Hebbian Plasticity in Hippocampal Neurons , 1997, Science.

[50]  B. Grothe,et al.  New roles for synaptic inhibition in sound localization , 2003, Nature Reviews Neuroscience.

[51]  W. Catterall,et al.  Functional properties and differential neuromodulation of Nav1.6 channels , 2008, Molecular and Cellular Neuroscience.

[52]  P. Schwartzkroin,et al.  Localization of Kv1.1 and Kv1.2, two K channel proteins, to synaptic terminals, somata, and dendrites in the mouse brain , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[53]  Wade G Regehr,et al.  Dynamic-clamp analysis of the effects of convergence on spike timing. II. Few synaptic inputs. , 2005, Journal of neurophysiology.

[54]  E. Mugnaini,et al.  Distribution and dendritic features of three groups of rat olivocochlear neurons , 2004, Anatomy and Embryology.

[55]  Ramana Dodla,et al.  Subthreshold outward currents enhance temporal integration in auditory neurons , 2003, Biological Cybernetics.

[56]  I. Forsythe,et al.  Initial segment Kv2.2 channels mediate a slow delayed rectifier and maintain high frequency action potential firing in medial nucleus of the trapezoid body neurons , 2008, The Journal of physiology.

[57]  L H Carney,et al.  Enhancement of neural synchronization in the anteroventral cochlear nucleus. I. Responses to tones at the characteristic frequency. , 1994, Journal of neurophysiology.

[58]  Harunori Ohmori,et al.  Axonal site of spike initiation enhances auditory coincidence detection , 2006, Nature.

[59]  P. Joris,et al.  Detection of synchrony in the activity of auditory nerve fibers by octopus cells of the mammalian cochlear nucleus. , 2000, Proceedings of the National Academy of Sciences of the United States of America.

[60]  Andrew J Powell,et al.  Molecular cloning, distribution and functional analysis of the NA(V)1.6. Voltage-gated sodium channel from human brain. , 2002, Brain research. Molecular brain research.

[61]  Lu-Yang Wang,et al.  Coincident Activation of Metabotropic Glutamate Receptors and NMDA Receptors (NMDARs) Downregulates Perisynaptic/Extrasynaptic NMDARs and Enhances High-Fidelity Neurotransmission at the Developing Calyx of Held Synapse , 2007, The Journal of Neuroscience.

[62]  Philip H Smith,et al.  Projections of physiologically characterized globular bushy cell axons from the cochlear nucleus of the cat , 1991, The Journal of comparative neurology.

[63]  L. Trussell,et al.  Activation and deactivation of voltage-dependent K+ channels during synaptically driven action potentials in the MNTB. , 2006, Journal of neurophysiology.

[64]  D. Oertel,et al.  Morphology and physiology of cells in slice preparations of the dorsal cochlear nucleus of mice , 1989, The Journal of comparative neurology.

[65]  D. Schwarz,et al.  Firing properties of chopper and delay neurons in the lateral superior olive of the rat , 1999, Experimental Brain Research.

[66]  John Rinzel,et al.  Dynamic Interaction of Ih and IK-LVA during Trains of Synaptic Potentials in Principal Neurons of the Medial Superior Olive , 2011, The Journal of Neuroscience.

[67]  I. Forsythe,et al.  Lateral olivocochlear (LOC) neurons of the mouse LSO receive excitatory and inhibitory synaptic inputs with slower kinetics than LSO principal neurons , 2010, Hearing Research.

[68]  Y. H. Chen,et al.  Functional modulation of human brain Nav1.3 sodium channels, expressed in mammalian cells, by auxiliary beta 1, beta 2 and beta 3 subunits. , 2002, Neuroscience.

[69]  L. Isom,et al.  The role of non-pore-forming β subunits in physiology and pathophysiology of voltage-gated sodium channels. , 2014, Handbook of experimental pharmacology.

[70]  M. A. Xu-Friedman,et al.  Different pools of glutamate receptors mediate sensitivity to ambient glutamate in the cochlear nucleus. , 2015, Journal of neurophysiology.

[71]  Nace L. Golding,et al.  Recordings from slices indicate that octopus cells of the cochlear nucleus detect coincident firing of auditory nerve fibers with temporal precision , 1995, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[72]  Harunori Ohmori,et al.  Roles of axonal sodium channels in precise auditory time coding at nucleus magnocellularis of the chick , 2009, The Journal of physiology.

[73]  Nace L. Golding,et al.  Posthearing Developmental Refinement of Temporal Processing in Principal Neurons of the Medial Superior Olive , 2005, The Journal of Neuroscience.

[74]  G. Spirou,et al.  Recordings from cat trapezoid body and HRP labeling of globular bushy cell axons. , 1990, Journal of neurophysiology.

[75]  P. Manis,et al.  Short-term synaptic depression and recovery at the mature mammalian endbulb of Held synapse in mice. , 2008, Journal of neurophysiology.

[76]  Christian Leibold,et al.  Action Potential Generation in an Anatomically Constrained Model of Medial Superior Olive Axons , 2014, The Journal of Neuroscience.

[77]  J. Rothman,et al.  The roles potassium currents play in regulating the electrical activity of ventral cochlear nucleus neurons. , 2003, Journal of neurophysiology.

[78]  D. Oertel,et al.  Potassium currents in octopus cells of the mammalian cochlear nucleus. , 2001, Journal of neurophysiology.

[79]  M. A. Xu-Friedman,et al.  A low-affinity antagonist reveals saturation and desensitization in mature synapses in the auditory brain stem. , 2010, Journal of neurophysiology.

[80]  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.

[81]  A L Goldin,et al.  Primary structure and functional expression of the beta 1 subunit of the rat brain sodium channel. , 1992, Science.