Mechanisms underlying presynaptic facilitatory effect of cyclothiazide at the calyx of Held of juvenile rats.
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1. Excitatory postsynaptic currents (EPSCs) were recorded using the whole-cell patch-clamp technique at the calyx of Held synapse in the medial nucleus of the trapezoid body (MNTB) in auditory brainstem slices from juvenile rats. 2. Bath application of cyclothiazide (CTZ, 100 microM) significantly increased the amplitude of EPSCs mediated by alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-D-aspartate (NMDA) receptors. Cyclothiazide increased the magnitude of paired-pulse depression of both AMPA-EPSCs (intervals, 50 and 500 ms) and NMDA-EPSCs (interval, 20 ms). In low Ca(2+), high Mg(2+) solution, CTZ decreased the number of failures and increased the mean amplitude of AMPA-EPSCs more than three-fold. 3. Presynaptic Ca(2+) currents and K(+) currents were directly recorded from the calyceal nerve terminals. These currents were attenuated by CTZ in a reversible manner. The magnitude of inhibition of presynaptic K(+) currents by CTZ (100 microM) was comparable to that by 5 microM 4-aminopyridine (4-AP). Both CTZ and 4-AP slowed the repolarizing phase of presynaptic action potentials. 4. The inhibitory effects of CTZ on presynaptic ion channels were mimicked by a solution having reduced Ca(2+) concentration and 5 microM 4-AP. This solution facilitated EPSCs, but the magnitude of facilitation was significantly less than that caused by CTZ. 5. In the presence of tetrodotoxin (TTX), CTZ increased the mean frequency of miniature EPSCs three-fold. CTZ prolonged their decay time but had no effect on their amplitude. The facilitatory effect of CTZ on the miniature frequency was neither blocked by a protein kinase C inhibitor nor occluded by phorbol ester, suggesting that a distinct mechanism underlies the effect of CTZ. 6. We conclude that CTZ facilitates transmitter release through suppression of presynaptic potassium conductance and stimulation of exocytotic machinery downstream of Ca(2+) influx. (+info)
Physiological correlates of comodulation masking release in the mammalian ventral cochlear nucleus.
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Comodulation masking release (CMR) enhances the detection of signals embedded in wideband, amplitude-modulated maskers. At least part of the CMR is attributable to across-frequency processing, however, the relative contribution of different stages in the auditory system to across-frequency processing is unknown. We have measured the responses of single units from one of the earliest stages in the ascending auditory pathway, the ventral cochlear nucleus, where across frequency processing may take place. A sinusoidally amplitude-modulated tone at the best frequency of each unit was used as a masker. A pure tone signal was added in the dips of the masker modulation (reference condition). Flanking components (FCs) were then added at frequencies remote from the unit best frequency. The FCs were pure tones amplitude modulated either in phase (comodulated) or out of phase (codeviant) with the on-frequency component. Psychophysically, this CMR paradigm reduces within-channel cues while producing an advantage of approximately 10 dB for the comodulated condition in comparison with the reference condition. Some of the recorded units showed responses consistent with perceptual CMR. The addition of the comodulated FCs produced a strong reduction in the response to the masker modulation, making the signal more salient in the poststimulus time histograms. A decision statistic based on d' showed that threshold was reached at lower signal levels for the comodulated condition than for reference or codeviant conditions. The neurons that exhibited such a behavior were mainly transient chopper or primary-like units. The results obtained from a subpopulation of transient chopper units are consistent with a possible circuit in the cochlear nucleus consisting of a wideband inhibitor contacting a narrowband cell. A computational model was used to confirm the feasibility of such a circuit. (+info)
Mixed excitatory and inhibitory GABA-mediated transmission in chick cochlear nucleus.
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1. Neurons of the chick nucleus magnocellularis (NM) receive depolarizing GABAergic input from the superior olivary nucleus (SON). We examined the response to exogenous GABA or to stimulation of GABAergic fibres in order to identify the ionic basis of GABAergic synaptic transmission and its physiological implications. 2. Reversal potentials of GABA responses (E(GABA)) were determined exclusively by the Cl(-) gradient, measured using whole-cell recording. With gramicidin-perforated patch recording, E(GABA) was -25 +/- 5 mV (mean +/- S.D.), and was stable between embryonic day 17 and post-hatch day 10. With normal intracellular Cl(-), GABA depolarized neurons by 12 mV. 3. In current clamp, repetitive activation of the GABAergic axons reduced the probability of spiking in response to simultaneous stimulation of excitatory axons. However, IPSPs could themselves elicit action potentials, and facilitation of IPSPs by repetitive activation could lead to a characteristic pattern of spiking. 4. These data indicate that IPSPs with reversal potentials positive to spike threshold may have dual functions, depending on the context of their activation. (+info)
Development of primary axosomatic endings in the anteroventral cochlear nucleus of mice.
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The endbulb of Held is a large synaptic ending that arises from the myelinated auditory nerve fibers. Endbulbs exhibit an elaborate pattern of terminal branching and produce extensive contact with the postsynaptic cell body. These structural features appear to underlie the tight coupling between presynaptic activity and postsynaptic spike discharges. As a first step toward understanding the relationship between environmental sounds and the development of these neural elements, we examined the age-related changes in the morphology of endbulbs of Held in CBA/J mice, a strain known to retain good hearing throughout life. Neurobiotin was injected into the modiolus of the cochlea in CBA/J mice ranging in age from postnatal day 1 to 7 months. Light microscopic analyses suggest that endbulbs of the CBA/J mice develop from small bouton endings at birth into large, highly branched structures in adults. This increase in structural complexity occurs mostly during the second through eighth postnatal weeks, and general stages of development can be defined. In addition, we compared endbulb structure between adult CBA/J mice and adult shaker-2 mice (Myo15sh2/sh2) and heterozygous littermates (Myo15+/sh2). The shaker-2 mouse carries a mutated myosin 15 gene that results in congenital deafness, presumably due to abnormally short stereocilia in hair cell receptors. Neurobiotin was injected into the modiolus of adult CBA/J, Myo15sh2/sh2, and Myo15+/sh2 mice. Endbulbs of deaf adult Myo15sh2/sh2 mice exhibited a striking reduction in terminal branching compared with those of CBA/J and Myo15+/sh2 mice. Notably, the abnormal endbulbs of Myo15sh2/sh2 mice do not resemble immature endbulbs of normal-hearing mice, suggesting that deafness does not simply arrest development. (+info)
Tonotopic projections of the auditory nerve to the cochlear nucleus angularis in the barn owl.
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The nucleus angularis (NA), one of the two cochlear nuclei of birds, plays an important role in the processing of sound intensity. To begin investigating the NA in detail in the barn owl, which is a popular animal model for neural mechanisms of sound localization, a frequency map for this nucleus is presented here. Focal injections of horseradish peroxidase or neurobiotin were placed either in the NA or in the cochlear nucleus magnocellularis, labeling small groups of auditory nerve fibers of known characteristic frequency (CF) from 0.25 to 9.6 kHz. The courses of their axonal branches were used to construct a composite average map of the tonotopic frequency representation in the nucleus angularis. Nucleus angularis in the barn owl, as seen in frontal sections, resembles a sheet of cells bent approximately into an S shape. The lowest frequencies were found represented at the ventromedial extreme. The representation of increasingly higher frequencies then followed the S shape, with the highest frequencies located at the ventrolateral tip. Auditory nerve fibers of a given CF always entered the nucleus angularis within a well-restricted area and then traveled along their isofrequency band within the NA while branching off terminals. The isofrequency bands were typically slanted from caudo-ventro-medial to rostro-dorso-lateral. The basic tonotopic organization is comparable to that found in other birds, the major differences being the large size and unusual shape of the barn owl's nucleus angularis. (+info)
Cholinergic modulation of stellate cells in the mammalian ventral cochlear nucleus.
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The main source of excitation to the ventral cochlear nucleus (VCN) is from glutamatergic auditory nerve afferents, but the VCN is also innervated by two groups of cholinergic efferents from the ventral nucleus of the trapezoid body. One arises from collaterals of medial olivocochlear efferents, and the other arises from neurons that project solely to the VCN. This study examines the action of cholinergic inputs on stellate cells in the VCN. T stellate cells, which form one of the ascending auditory pathways to the inferior colliculus, and D stellate cells, which inhibit T stellate cells, are distinguished electrophysiologically. Whole-cell recordings from stellate cells in slices of the VCN of mice demonstrate that most T stellate cells are excited by cholinergic agonists through three types of receptors, whereas all D stellate cells tested were insensitive to cholinergic agonists. Nicotinic excitation in T stellate cells has two components. The faster component was blocked by alpha-bungarotoxin and methyllycaconitine, suggesting that receptors contained alpha7 subunits; the slower component was insensitive to both. Muscarinic receptors excite T stellate cells by blocking a voltage-insensitive, "leak" potassium conductance. Our results suggest that cholinergic efferent innervation enhances excitation by sounds of T stellate cells, opposing the inhibitory action of cholinergic innervation in the cochlea that is conveyed indirectly through the glutamatergic afferents. The inhibitory action of D stellate cells on their targets is probably not affected by cholinergic inputs. Excitation of T stellate cells by cholinergic efferents would be expected to enhance the encoding of spectral peaks in noise. (+info)
Correlation of AMPA receptor subunit composition with synaptic input in the mammalian cochlear nuclei.
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The composition of AMPA receptors in patches excised from somata and dendrites of six cell types in the mammalian cochlear nuclei was probed and compared electrophysiologically and pharmacologically with the rapid application of glutamate. Cells excited predominantly by auditory nerve fibers had AMPA receptors with exceptionally rapid gating (submillisecond deactivation and desensitization time constants). The nonlinear current-voltage relationship in the presence of spermine showed that few of these receptors had GluR2 subunits, and the insensitivity of desensitization to cyclothiazide indicated that they contained mostly flop splice variants. At synapses made by parallel fibers, AMPA receptors were slowly gating (time constants of deactivation and desensitization >1 msec) and contained higher levels of GluR2 and flip isoforms. However, receptors at auditory nerve synapses on cells that also receive parallel fiber input, the fusiform cells, had intermediate properties with respect to kinetics and contained GluR2 and flip isoforms. Given the diverse biophysical properties, patterns of innervation, patterns of electrical activity, and targets of each cell type in vivo, these data indicate that the kinetics and permeation properties of AMPA receptors are linked to factors associated with synaptic connectivity. (+info)
Accommodation enhances depolarizing inhibition in central neurons.
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Neurons in the avian cochlear nucleus are depolarized by GABAergic synaptic input. We recorded GABAergic synaptic currents using the gramicidin-perforated-patch method and found their reversal potential (V(rev)) to be depolarized relative to spike threshold, which is surprising given that these inputs are inhibitory. Depolarizing IPSPs (dIPSPs) are kept below spike generation threshold by the activation of a dendrotoxin-I-sensitive, voltage-gated K(+) conductance. We show experimentally that the polarity of IPSPs contributes to their efficacy; dIPSPs induce accommodation, the positive shift in spike threshold, and are therefore more strongly inhibitory than conventional, hyperpolarizing IPSPs in the same neurons. A similar inhibitory mechanism has been described in invertebrate sensory fibers and axons of dorsal root ganglion cells and may be a general means of amplifying the strength of inhibition in cases where the size of excitatory conductances greatly exceeds that of inhibitory conductances. (+info)