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SUMMARY: The term "circling mouse" refers to an animal model of deafness, in which the mouse exhibits circling, head tossing, and hyperactivity, with pathological features including degenerated spiral ganglion cells in the cochlea, and the loss of the organ of Corti. The cochlear nuclear (CN) complex, a part of the auditory brain circuit, is essential to process both ascending and descending auditory information. Considering calcium's (Ca2+) importance in homeostasis of numerous biological processes, hearing loss by cochlear damage, either by ablation or genetic defect, could cause changes in the Ca2+ concentration that might trigger functional and structural alterations in the auditory circuit. However, little is known about the correlation of the central nervous system (CNS) pathology in circling mice, especially of the auditory pathway circuit and Ca2+ changes. This present study investigates the distribution of Ca2+- binding proteins (CaBPs), calbindin D-28k (CB), parvalbumin (PV), and calretinin (CR) by using a free floating immunohistochemical method inthe CN of the wild-type mouse (+/+), the heterozygous mouse (+/cir), and the homozygous (cir/cir) mouse. CaBPs are well known to be an important factor that regulates Ca2+ concentrations. Compared with the dorsal and ventral cochlear nuclei of +/+ and +/ cirmice, prominent decreases of CaBPs' immunoreactivity (IR) in cir/cirmice were observed in the somas, as well as in the neuropil. The present study reportson the overall distribution and changes in the immunoreactivity of CaBPs in the CN of cir/cirmice because ofa hearing defect. This data might be helpful to morphologically elucidate CNS disorders and their relation to CaBPs immunoreactivity related to hearing defects.

RESUMEN: El término "ratón circulante" se refiere a un modelo animal con sordera, en el que el ratón exhibe hiperactividad, movimientos circulares y movimientos de la cabeza, con características patológicas que incluyen células ganglionares espirales degeneradas en la cóclea, un canal de Rosenthal vacío y la pérdida del órgano de Corti. El complejo nuclear coclear (CN), una parte del circuito cerebral auditivo, es esencial para procesar la información auditiva tanto ascendente como descendente. Considerando la importancia del calcio (Ca2+) en la homeostasis de numerosos procesos biológicos, la hipoacusia por daño coclear, por ablación o por defecto genético, podría provocar cambios en la concentración de Ca2+que pueden desencadenar alteraciones funcionales y estructurales en el circuitoauditivo. Sin embargo, existe poca información de la correlación de la patología del sistema nervioso central (SNC) en ratones circulantes, especialmente del circuito de la víaauditiva y los cambios de Ca2+. Este estudio nvestiga la distribución de proteínas de unión a Ca2+ (CaBP), calbindina D-28k (CB), parvalbúmina (PV) y calretinina (CR) mediante el uso de un método inmunohistoquímico de flotaciónlibre en el CN del ratón de tiposalvaje (+/+), el ratón heterocigoto (+/cir) y el ratón homocigoto (cir/cir). Se sabe que los CaBP son un factor importante que regula las concentraciones de Ca2+. En comparación con los núcleos cocleares dorsal y ventral de los ratones +/+ y +/ cir, se observaron disminuciones prominentes de la inmunorreactividad (IR) de CaBPs en los ratonescir/cir en los somas, asícomo en el neuropilo. El presente estudio informa sobre la distribución general y los cambios en la inmunorreactividad de CaBP en el CN de ratones cir/cir debido a un defecto auditivo. Estos datos podrían ser útiles para dilucidar morfológicamente los trastornos del SNC y su relación con la inmunorreactividad de CaBP relacionada con los defectosauditivos.

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The Dorsal Cochlear Nucleus (DCN) is a region which has been traditionally linked to the genesis of tinnitus, the constant perception of a phantom sound. Sodium salicylate, a COX-2 inhibitor, can induce tinnitus in high doses. Hyperactivity of DCN neurons is observed in several animal models of tinnitus, including salicylate-induced tinnitus. The DCN presents several forms of endocannabinoid (EC)-dependent synaptic plasticity and COX-2 can also participate in the oxidative degradation of ECs. We recently demonstrated that short-term perfusion of sodium salicylate and other inhibitors of both oxidative and hydrolytic EC degradation did not affect depolarization-induced suppression of excitation (DSE), a form of EC-dependent short-term synaptic plasticity. Here, we show that prolonged incubation with high doses of sodium salicylate (1.4 mM) enhances DSE of synapses onto glycinergic DCN interneurons but not those innervating glutamatergic DCN fusiform neurons. This effect was not reproduced with lower doses of salicylate (140 µM) or with ibuprofen, another inhibitor of COX-2. This effect was not observed in the presence of AM251, an antagonist/inverse agonist of cannabinoid CB1 receptors, showing that it was dependent on EC release. Finally we demonstrated that incubation with salicylate potentiated the increase in intracellular calcium during the depolarization. Our results point to an increased inhibition of DCN inhibitory CW neuron during depolarizations, probably by an enhanced EC release during the depolarizations, which is potentially significant for DCN hyperactivity and tinnitus generation.

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Neurons from the dorsal cochlear nucleus (DCN) present endocannabinoid (EC) dependent short-term synaptic plasticity in the form of depolarization-induced suppression of excitation (DSE). Postsynaptic calcium influx promotes EC synthesis and depression of neurotransmission. ECs can be degraded by a hydrolytic and an oxidative pathway, the latter via the enzyme cyclooxygenase 2 (COX-2). Hyperactivity in the DCN is related to the development of tinnitus, which can be induced by high doses of salicylate, a COX-2 inhibitor. Since EC-dependent plasticity in the DCN can affect its excitation-inhibition balance, we investigated the impact of inhibitors of both oxidative and hydrolytic EC metabolism on the DSE from the synapses between the parallel fibers and cartwheel neurons (PF-CW) in the DCN. We found that inhibitors of COX-2 (ibuprofen and indomethacin) did not alter DSE at the PF-CW synapse. Salicylate also did not alter DSE. However, we found that inhibitors of the hydrolytic pathway did not affect DSE magnitude, but surprisingly speeded DSE decay. We conclude that oxidative EC degradation in the PF-CW synapse is not relevant for termination of DSE and are probably not important for controlling this form of synaptic plasticity in the DCN PF-CW synapse. The lack of effect on DSE of high doses of salicylate also suggests that it is not acting by increasing DSE in the PF-CWC synapse. However, the counter intuitive effect of the hydrolytic inhibitors shows that increasing EC on this synapse have more complex effects on DSE.

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High doses of salicylate induce reversible tinnitus in experimental animals and humans, and is a common tinnitus model. Salicylate probably acts centrally and induces hyperactivity in specific auditory brainstem areas like the dorsal cochlear nucleus (DCN). However, little is known about the effect of high doses of salicylate in synapses and neurons of the DCN. Here we investigated the effects of salicylate on the excitability and evoked and spontaneous neurotransmission in the main neurons (fusiform, cartwheel and tuberculoventral) and synapses of the DCN using whole cell recordings in slices containing the DCN. For this, we incubate the slices for at least 1 h in solution with 1.4 mM salicylate, and recorded action potentials and evoked and spontaneous synaptic currents in fusiform, cartwheel (CW) and putative tuberculoventral (TBV) neurons. We found that incubation with salicylate did not affect the firing of fusiform and TBV neurons, but decreased the spontaneous firing of cartwheel neurons, without affecting AP threshold or complex spikes. Evoked and spontaneous glutamatergic neurotransmission on the fusiform and CW neurons cells was unaffected by salicylate and evoked glycinergic neurotransmission on fusiform neurons was also unchanged by salicylate. On the other hand spontaneous glycinergic transmission on fusiform neurons was reduced in the presence of salicylate. We conclude that high doses of salicylate produces a decreased inhibitor drive on DCN fusiform neurons by reducing the spontaneous firing of cartwheel neurons, but this effect is not able to increase the excitability of fusiform neurons. So, the mechanisms of salicylate-induced tinnitus are probably more complex than simple changes in the neuronal firing and basal synaptic transmission in the DCN.

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