Temporal Coding by Cochlear Nucleus Bushy Cells in DBA/2J Mice with Early Onset Hearing Loss

The bushy cells of the anterior ventral cochlear nucleus (AVCN) preserve or improve the temporal coding of sound information arriving from auditory nerve fibers (ANF). The critical cellular mechanisms entailed in this process include the specialized nerve terminals, the endbulbs of Held, and the membrane conductance configuration of the bushy cell. In one strain of mice (DBA/2J), an early-onset hearing loss can cause a reduction in neurotransmitter release probability, and a smaller and slower spontaneous miniature excitatory postsynaptic current (EPSC) at the endbulb synapse. In the present study, by using a brain slice preparation, we tested the hypothesis that these changes in synaptic transmission would degrade the transmission of timing information from the ANF to the AVCN bushy neuron. We show that the electrical excitability of bushy cells in hearing-impaired old DBA mice was different from that in young, normal-hearing DBA mice. We found an increase in the action potential (AP) firing threshold with current injection; a larger AP afterhyperpolarization; and an increase in the number of spikes produced by large depolarizing currents. We also tested the temporal precision of bushy cell responses to high-frequency stimulation of the ANF. The standard deviation of spikes (spike jitter) produced by ANF-evoked excitatory postsynaptic potentials (EPSPs) was largely unaffected in old DBA mice. However, spike entrainment during a 100-Hz volley of EPSPs was significantly reduced. This was not a limitation of the ability of bushy cells to fire APs at this stimulus frequency, because entrainment to trains of current pulses was unaffected. Moreover, the decrease in entrainment is not attributable to increased synaptic depression. Surprisingly, the spike latency was 0.46 ms shorter in old DBA mice, and was apparently attributable to a faster conduction velocity, since the evoked excitatory postsynaptic current (EPSC) latency was shorter in old DBA mice as well. We also tested the contribution of the low-voltage-activated K+ conductance (gKLV) on the spike latency by using dynamic clamp. Alteration in gKLV had little effect on the spike latency. To test whether these changes in DBA mice were simply a result of continued postnatal maturation, we repeated the experiments in CBA mice, a strain that shows normal hearing thresholds through this age range. CBA mice exhibited no reduction in entrainment or increased spike jitter with age. We conclude that the ability of AVCN bushy neurons to reliably follow ANF EPSPs is compromised in a frequency-dependent fashion in hearing-impaired mice. This effect can be best explained by an increase in spike threshold.

[1]  L. Trussell,et al.  Maturation of Synaptic Transmission at End-Bulb Synapses of the Cochlear Nucleus , 2001, The Journal of Neuroscience.

[2]  D. Frisina,et al.  Relationships among age-related differences in gap detection and word recognition. , 2000, The Journal of the Acoustical Society of America.

[3]  Donata Oertel,et al.  Correlation of AMPA Receptor Subunit Composition with Synaptic Input in the Mammalian Cochlear Nuclei , 2001, The Journal of Neuroscience.

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

[5]  M. C. Brown,et al.  Central trajectories of type II spiral ganglion cells from various cochlear regions in mice , 1994, Hearing Research.

[6]  P. Monsivais,et al.  Activity‐dependent regulation of the potassium channel subunits Kv1.1 and Kv3.1 , 2004, The Journal of comparative neurology.

[7]  R. Romand,et al.  Development of spiral ganglion cells in mammalian cochlea. , 1990, Journal of electron microscopy technique.

[8]  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.

[9]  J. Ison,et al.  A diminished rate of "physiological decay" at noise offset contributes to age-related changes in temporal acuity in the CBA mouse model of presbycusis. , 2003, The Journal of the Acoustical Society of America.

[10]  C. G. Benson,et al.  Synaptophysin immunoreactivity in the cochlear nucleus after unilateral cochlear or ossicular removal , 1997, Synapse.

[11]  Cornelia Kopp-Scheinpflug,et al.  Interaction of Excitation and Inhibition in Anteroventral Cochlear Nucleus Neurons That Receive Large Endbulb Synaptic Endings , 2002, The Journal of Neuroscience.

[12]  Marcus Müller,et al.  A physiological place–frequency map of the cochlea in the CBA/J mouse , 2005, Hearing Research.

[13]  H. Heffner,et al.  Focus: Sound-Localization Acuity Changes with Age in C57BL/6J Mice , 2001 .

[14]  B. Walmsley,et al.  Reduced low‐voltage activated K+ conductances and enhanced central excitability in a congenitally deaf (dn/dn) mouse , 2004, The Journal of physiology.

[15]  Paul J. Abbas,et al.  The effects of interpulse interval on stochastic properties of electrical stimulation: models and measurements , 2001, IEEE Transactions on Biomedical Engineering.

[16]  W. O'Neill,et al.  Age-Related Alteration in Processing of Temporal Sound Features in the Auditory Midbrain of the CBA Mouse , 1998, The Journal of Neuroscience.

[17]  Henry Simon,et al.  Age-related alterations in the neural coding of envelope periodicities. , 2002, Journal of neurophysiology.

[18]  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.

[19]  B. Walmsley,et al.  Counting quanta: Direct measurements of transmitter release at a central synapse , 1995, Neuron.

[20]  L. Trussell,et al.  Characterization of outward currents in neurons of the avian nucleus magnocellularis. , 1998, Journal of neurophysiology.

[21]  L. Trussell,et al.  Time Course and Permeation of Synaptic AMPA Receptors in Cochlear Nuclear Neurons Correlate with Input , 1999, The Journal of Neuroscience.

[22]  J. Willott,et al.  Genetics of age-related hearing loss in mice. IV. Cochlear pathology and hearing loss in 25 BXD recombinant inbred mouse strains , 1998, Hearing Research.

[23]  D. Oertel,et al.  Encoding of Timing in the Brain Stem Auditory Nuclei of Vertebrates , 1997, Neuron.

[24]  S. Waxman,et al.  Downregulation of Tetrodotoxin-Resistant Sodium Currents and Upregulation of a Rapidly Repriming Tetrodotoxin-Sensitive Sodium Current in Small Spinal Sensory Neurons after Nerve Injury , 1997, The Journal of Neuroscience.

[25]  B. Kachar,et al.  Asymmetric illumination contrast: a method of image formation for video light microscopy. , 1985, Science.

[26]  J. Rothman,et al.  Kinetic analyses of three distinct potassium conductances in ventral cochlear nucleus neurons. , 2003, Journal of neurophysiology.

[27]  L. Trussell,et al.  Long-Term Specification of AMPA Receptor Properties after Synapse Formation , 2000, The Journal of Neuroscience.

[28]  K. Henry Low-frequency acoustic modulations generated by the high-frequency portion of the cochlea, noninvasively recorded from the scalp of mice (Mus musculus). , 2000, Journal of comparative psychology.

[29]  J T Rubinstein,et al.  Threshold fluctuations in an N sodium channel model of the node of Ranvier. , 1995, Biophysical journal.

[30]  A. Burkitt,et al.  Temporal processing from the auditory nerve to the medial nucleus of the trapezoid body in the rat , 2001, Hearing Research.

[31]  Russell R. Pfeiffer,et al.  Classification of response patterns of spike discharges for units in the cochlear nucleus: Tone-burst stimulation , 2004, Experimental Brain Research.

[32]  J. Willott,et al.  Morphological changes in the anteroventral cochlear nucleus that accompany sensorineural hearing loss in DBA/2J and C57BL/6J mice. , 1996, Brain research. Developmental brain research.

[33]  Lu-Yang Wang,et al.  Developmental profiles of glutamate receptors and synaptic transmission at a single synapse in the mouse auditory brainstem , 2002, The Journal of physiology.

[34]  J. Willott The Auditory psychobiology of the mouse , 1983 .

[35]  David J. Christini,et al.  Real-Time Linux Dynamic Clamp: A Fast and Flexible Way to Construct Virtual Ion Channels in Living Cells , 2001, Annals of Biomedical Engineering.

[36]  P. Manis,et al.  Synaptic transmission at the cochlear nucleus endbulb synapse during age-related hearing loss in mice. , 2005, Journal of neurophysiology.

[37]  I. Raman,et al.  The kinetics of the response to glutamate and kainate in neurons of the avian cochlear nucleus , 1992, Neuron.

[38]  S. D. Thomas,et al.  Gap detection as a function of stimulus loudness for listeners with and without hearing loss. , 1997, Journal of speech, language, and hearing research : JSLHR.

[39]  K. Johnson,et al.  Assessment of hearing in 80 inbred strains of mice by ABR threshold analyses , 1999, Hearing Research.

[40]  S. Dib-Hajj,et al.  Sodium channels, excitability of primary sensory neurons, and the molecular basis of pain , 1999, Muscle & nerve.

[41]  Peter A. Smith,et al.  Changes in Na(+) channel currents of rat dorsal root ganglion neurons following axotomy and axotomy-induced autotomy. , 2002, Journal of neurophysiology.

[42]  J. Willott Handbook of Mouse Auditory Research: From Behavior to Molecular Biology , 2001 .

[43]  A. Reyes,et al.  Membrane properties underlying the firing of neurons in the avian cochlear nucleus , 1994, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[44]  K. Funabiki,et al.  The role of GABAergic inputs for coincidence detection in the neurones of nucleus laminaris of the chick , 1998, The Journal of physiology.

[45]  L. Trussell,et al.  Synaptic mechanisms for coding timing in auditory neurons. , 1999, Annual review of physiology.

[46]  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.

[47]  D. Oertel,et al.  Inhibitory circuitry in the ventral cochlear nucleus is probably mediated by glycine , 1986, The Journal of neuroscience : the official journal of the Society for Neuroscience.

[48]  Philip H Smith,et al.  Projections of physiologically characterized spherical bushy cell axons from the cochlear nucleus of the cat: Evidence for delay lines to the medial superior olive , 1993, The Journal of comparative neurology.

[49]  D. Born,et al.  Afferent influences on brainstem auditory nuclei of the chick: Nucleus magnocellularis neuronal activity following cochlea removal , 1991, Brain Research.

[50]  B. Walmsley,et al.  Amplitude and time course of spontaneous and evoked excitatory postsynaptic currents in bushy cells of the anteroventral cochlear nucleus. , 1996, Journal of neurophysiology.

[51]  Masaki Tanaka,et al.  Changes in the expression of tetrodotoxin-sensitive sodium channels within dorsal root ganglia neurons in inflammatory pain , 2004, Pain.

[52]  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.

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

[54]  H. Francis,et al.  Effects of deafferentation on the electrophysiology of ventral cochlear nucleus neurons , 2000, Hearing Research.

[55]  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.