Differential expression of PKC beta II in the rat organ of Corti.

To investigate a possible involvement of protein kinase C (PKC) in cochlear efferent neurotransmission, we studied the expression of the calcium-dependent PKC beta II isoform in the rat organ of Corti at different postnatal ages using immunofluorescence and immunoelectron microscopy. We found evidence of PKC beta II as early as postnatal day (PND) 5 in efferent axons running in the inner spiral bundle and in Hensen cells. At PND 8, we also found PKC beta II in efferents targeting outer hair cells (OHCs), and a slight detection at the synaptic pole in the first row of the basal and middle cochlear turns. At PND 12, PKC beta II expression declined in the efferent fibres contacting OHCs, whereas expression was concentrated at the postsynaptic membrane, from the basal and middle turns. The adult-like pattern of PKC beta II distribution was observed at PND 20. Throughout the cochlea, we found PKC beta II expression in the Hensen cells, non-sensory cells involved in potassium re-cycling, and lateral efferent terminals of the inner spiral bundle. In addition, we observed expression in OHCs at the postsynaptic membrane facing the endings of the medial efferent system, with the exception of some OHCs located in the most apical region of the cochlea. These data therefore suggest an involvement of PKC beta II in both cochlear efferent neurotransmission and ion homeostasis. Among other functions, PKC beta II could play a role in the efferent control of OHC activity.

Synaptic repair mechanisms responsible for functional recovery in various cochlear pathologies.

In some cochlear pathologies, temporary hearing loss can be followed by complete or partial functional recovery. Our previous findings suggest the involvement of an excitotoxic (glutamate-related) disruption of inner hair cell (IHC)-auditory nerve synapses, followed by synaptic regeneration. It is essential to understand the molecular mechanisms responsible for this synaptic repair if new therapeutic strategies are to be developed. In guinea pig cochleas, acute synaptic excitotoxic damage (mimicking what occurs with acoustic trauma or local ischemia) is achieved by locally applying AMPA, a glutamate agonist. This results in a total disruption of all IHC-auditory dendrite synapses, together with a disappearance of cochlear potentials. Within the next 5 days, however, a recovery of both the normal pattern of IHC innervation and the physiological responses is observed. The fact that the blockage of the NMDA receptors during functional recovery delayed the regrowth of neurites and the restoration of hearing suggests that glutamate plays a neurotrophic role via activation of NMDA receptors. Experiments are in progress to investigate, among other factors, the role of other glutamate receptor subunits. A reversible in vivo antisense strategy is being developed to overcome the lack of specificity of some antagonists. First results bode well for future pharmacological therapies in cochlear pathologies where glutamatergic synapses are likely to be involved; i.e., noise trauma, ischemia-related sudden deafness, and neural presbycusis.

Protein kinase C may be involved in synaptic repair of auditory neuron dendrites after AMPA injury in the cochlea.

A suitable model of sudden deafness occurring after acoustic trauma or ischemia, is obtained in guinea pigs by an acute intracochlear perfusion of 200 microM alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA), a glutamate analog. By overloading the AMPA/kainate receptors, located post-synaptically to inner hair cells (IHCs), it induces a massive swelling of primary auditory neuron dendrites, which disconnects the IHCs. This synaptic uncoupling and the resulting hearing loss are followed by a progressive regrowth of dendrites, which make new synapses with IHCs, leading to a functional recovery of auditory responses that is completed after 5 days. Knowing the role of protein kinase C in neuroplastic events, we studied the expression of its isoforms alpha,beta(I,II) and gamma, respectively pre- and post-synaptic, in auditory neurons at various times after AMPA administration. In untreated cochleas, we observed an expression of PKC alpha,beta(I,II) and gamma in cell bodies of primary auditory neurons. After the intracochlear administration of AMPA, both isozymes were transiently overexpressed, with a peak at 3-6 h, followed by a decrease after about 24 h. At this point in time immuno-electron microscopy revealed some regrowing dendrites immunoreactive for PKCgamma. Five days after AMPA, when the auditory responses were restored, PKCgamma levels were still elevated in ganglion cell bodies.

Synaptic connections and putative functions of the dopaminergic innervation of the guinea pig cochlea.

We report our findings in the guinea pig involving dopamine in postsynaptic regulation of the activity of glutamatergic inner hair cells (IHCs) and in protection of primary auditory neurons during transient ischemia. Seven days after intracochlear perfusion of 6-hydroxydopamine, no immunoreactivity to tyrosine hydroxylase (TH) was demonstrable within the organ of Corti. TH and aromatic amino acid decarboxylase were immunolocalized at an ultrastructural level within lateral olivocochlear varicosities synapsing with radial auditory dendrites postsynaptic to the IHCs. The D2 agonist piribedil induced a dose-dependent decrease in the amplitude of the compound action potential of the auditory nerve. Piribedil also prevented appearance of ischemia-induced swelling of the radial dendrites.

Excitatory amino acid antagonists protect cochlear auditory neurons from excitotoxicity.

Since ischemic damage in the brain is linked to glutamate excitotoxicity, the effects of an acute exposure to glutamate, alpha-amino-3-hydroxy-5-methyl-4-isoxazole proprionic acid (AMPA) or N-methyl-D aspartate (NMDA) on the radial dendrites were compared with those occurring after a severe cochlear ischemia. Glutamate and AMPA, but not NMDA, produced a drastic swelling restricted to the radial dendrites below the inner hair cells (IHCs). At a concentration of 20 microM AMPA, a full electrophysiological recovery could be observed in some cochleas after washing the drug out. A prior perfusion of 6-7-dinitroquinoxaline-2,3-dione (DNQX, 50 microM) prevented the 25 microM AMPA-induced dendritic swelling. No protective effect of D-2-amino-5-phosphonopentanoate (D-AP5) could be observed. In the same way, ischemia (5-40 minutes) resulted in a clear swelling of the radial dendrites. While D-AP5 had no protective effects, 50 microM DNQX protected most of the radial dendrites from the ischemia-induced swelling, excepting those contacting the modiolar side of the IHCs. Finally, 50 microM DNQX + 50 microM D-AP5 resulted in a nearly complete protection of all the radial dendrites. Altogether, these results suggest that the acute swelling of radial dendrites primarily occurs via AMPA/kainate receptors. However, in radial dendrites contacting the inner hair cells on their modiolar side, NMDA receptors may be also involved.

Electrophysiological evidence for the presence of NMDA receptors in the guinea pig cochlea.

An excitatory amino acid, possibly L-glutamate, which probably acts as a neurotransmitter at the inner hair cell-afferent fiber synapses in the cochlea. In the present study, we have used an electrophysiological approach to investigate at this level the presence of a major type of excitatory amino acid receptor, namely the glutamatergic receptor for which N-methyl-D-aspartate is a selective agonist. Our results show that, when N-methyl-D-aspartate and the antagonist 2-amino-5-phosphonovalerate are perfused through the perilymphatic scalae, they induced, by different mechanisms, a significant reduction of the amplitude of the compound action potential and an increase of the N1 latency, both predominant at high intensity tone burst stimulations. No significant difference was found in the presence or absence of Mg2+ in the artificial perilymph used as a vehicle. A further slight N-methyl-D-aspartate-induced decrease of the amplitude of the compound action potential, although non significant, was observed when the Mg2(+)-free perilymph contained 100 or 1000 microM glycine. In all the experimental conditions, no effect was observed on the cochlear microphonic potential. This observation is consistent with an action of N-methyl-D-aspartate and 2-amino-5-phosphonovalerate at receptors located on the auditory nerve dendrites contacting the inner hair cells. In conclusion, our results suggest the presence of N-methyl-D-aspartate receptors in the cochlea.

Alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid electrophysiological and neurotoxic effects in the guinea-pig cochlea.

We have recorded cochlear potentials after perilymphatic perfusion of cumulative doses of the excitatory amino acid alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) which selectively recognizes the non-N-methyl-D-aspartate ionotropic receptor formerly known as the quisqualate receptor. Our results show that AMPA (1-80 microM) caused a significant suppression of the amplitude of the compound action potential evoked by acoustic stimulation. A total elimination of this potential at the 100 microM concentration was observed in all animals. In no case was the cochlear microphonic potential, a hair cell receptor potential, affected by AMPA. Histological examinations were performed either at the end of the physiological studies or on cochleas perfused for 10 min with a single dose of AMPA (50 or 100 microM). In both experimental conditions, a selective dendritic swelling or radial afferent nerve endings under the sensory inner hair cells was observed. No damage was found in both types of hair cells supporting cells, lateral and medial efferent fibers and spiral afferent nerve ending on the outer hair cells. The occurrence of the radial dendrite swelling was prevented when 6,7-dinitroquinoxaline-2,3-dione (500 microM) was perfused in the cochlea 10 min prior, then concomitantly with AMPA. The present study strongly suggests that non-N-methyl-D-aspartate receptors, possibly of the AMPA subtype, are involved in the synaptic transmission between the inner hair cells and the primary auditory neurons. They provide further support for the hypothesis that L-glutamate, or another excitatory amino acid, acts as an inner hair cell neurotransmitter.

The dissociation rate of estrogen receptor-ligand complexes is increased by high concentrations of steroids and antiestrogens.

The first-order dissociation rate constant, k-, of estradiol from uterine estrogen receptor, measured kin the presence of micromolar concentrations of diethylstilbestrol, increased linearly over a large concentration range (0-300 microM) of diethylstilbestrol. The experimental K- measured appears to be the sum of a basal dissociation rate constant corresponding to the spontaneous dissociation in the absence of diethylstilbestrol, and a diethylstilbestrol-induced dissociation rate constant, which is proportional to both the diethylstilbestrol concentration and the inverse of the cytosol concentration. Diethylstilbestrol induced the dissociation of estradiol in all species studied (lamb, calf and rat) and of estrone and 2 antiestrogens in lamb uterus. Various steroids and triphenylethylene antiestrogens also efficiently induced the dissociation of estradiol from the estrogen receptor. However, the potency of these inducers, which varied greatly, was not correlated with the binding affinity for the estrogen receptor. Structural characteristics and the hydrophobicity of the inducers, however, did appear to be important parameters. The relative efficiency of inducers varied depending on the ligand that was bound to the receptor. This induced dissociation allows the complete dissociation of estrogen receptor-[3H]-ligand complexes in a short time (less than 24 h) at low temperatures without alteration of the level of [3H] ligand bound non-specifically and can therefore be used to measure the [3H] ligand bound to the receptor by exchange at 0-4 degree C. From the specificity and the high doses of inducers required to make possible the observation of a significant effect, we conclude that the induced dissociation probably does not have a biological role.