BACKGROUND AND PURPOSEBetahistine, the main histamine drug prescribed to treat vestibular disorders, is a histamine H3 receptor antagonist. Here, we explored the potential for modulation of the most recently cloned histamine receptor (H4 receptor) to influence vestibular system function, using a selective H4 receptor antagonist JNJ 7777120 and the derivate compound JNJ 10191584. EXPERIMENTAL APPROACHRT-PCR was used to assess the presence of H4 receptors in rat primary vestibular neurons. In vitro electrophysiological recordings and in vivo behavioural approaches using specific antagonists were employed to examine the effect of H4 receptor modulation in the rat vestibular system. KEY RESULTSThe transcripts of H4 and H3 receptors were present in rat vestibular ganglia. Application of betahistine inhibited the evoked action potential firing starting at micromolar range, accompanied by subsequent strong neuronal depolarization at higher concentrations. Conversely, reversible inhibitory effects elicited by JNJ 10191584 and JNJ 7777120 began in the nanomolar range, without inducing neuronal depolarization. This effect was reversed by application of the selective H4 receptor agonist 4-methylhistamine. Thioperamide, a H3/H4 receptor antagonist, exerted effects similar to those of H3 and H4 receptor antagonists, namely inhibition of firing at nanomolar range and membrane depolarization above 100 mM. H4 receptor antagonists significantly alleviated the vestibular deficits induced in rats, while neither betahistine nor thioperamide had significant effects. CONCLUSIONS AND IMPLICATIONSH4 receptor antagonists have a pronounced inhibitory effect on vestibular neuron activity. This result highlights the potential role of H4 receptors as pharmacological targets for the treatment of vestibular disorders. Abbreviations
Vestibular neuritis is a neuroinflammatory, peripheral vestibular pathology leading to chronic deficits and long-term disability. While current corticosteroid-based therapy does not appear to positively influence the long term outcome for the patient, a recent clinical pilot study suggested a functional vestibuloprotective effect of the anti-emetic ondansetron in the treatment of vestibular neuritis. We here demonstrate that systemic post-insult administration of ondansetron in a novel rat model of severe excitotoxic vestibular insult reproduces the clinically demonstrated functional benefits. This ondansetron-conferred reduction of functional deficits stems from the protection of synapses between sensory hair cells and primary neurons from excitotoxically induced lesion.
Damage to inner ear afferent terminals is believed to result in many auditory and vestibular dysfunctions. The sequence of afferent injuries and repair, as well as their correlation with vertigo symptoms, remains poorly documented. In particular, information on the changes that take place at the primary vestibular endings during the first hours following a selective insult is lacking. In the present study, we combined histological analysis with behavioral assessments of vestibular function in a rat model of unilateral vestibular excitotoxic insult. Excitotoxicity resulted in an immediate but transient alteration of the balance function that was resolved within a week. Concomitantly, vestibular primary afferents underwent a sequence of structural changes followed by spontaneous repair. Within the first two hours after the insult, a first phase of pronounced vestibular dysfunction coincided with extensive swelling of afferent terminals. In the next 24 h, a second phase of significant but incomplete reduction of the vestibular dysfunction was accompanied by a resorption of swollen terminals and fiber retraction. Eventually, within 1 week, a third phase of complete balance restoration occurred. The slow and progressive withdrawal of the balance dysfunction correlated with full reconstitution of nerve terminals. Competitive re-innervation by afferent and efferent terminals that mimicked developmental synaptogenesis resulted in full re-afferentation of the sensory epithelia. By deciphering the sequence of structural alterations that occur in the vestibule during selective excitotoxic impairment, this study offers new understanding of how a vestibular insult develops in the vestibule and how it governs the heterogeneity of vertigo symptoms.
In vertebrates, 14-3-3 proteins form a family of seven highly conserved isoforms with chaperone activity, which bind phosphorylated substrates mostly involved in regulatory and checkpoint pathways. 14-3-3 proteins are the most abundant protein in the brain and are abundantly found in the cerebrospinal fluid in neurodegenerative diseases, suggesting a critical role in neuron physiology and death. Here we show that 14-3-3eta-deficient mice displayed auditory impairment accompanied by cochlear hair cells' degeneration. We show that 14-3-3eta is highly expressed in the outer and inner hair cells, spiral ganglion neurons of cochlea and retinal ganglion cells. Screening of YWHAH, the gene encoding the 14-3-3eta isoform, in non-syndromic and syndromic deafness, revealed seven non-synonymous variants never reported before. Among them, two were predicted to be damaging in families with syndromic deafness. In vitro, variants of YWHAH induce mild mitochondrial fragmentation and severe susceptibility to apoptosis, in agreement with a reduced capacity of mutated 14-3-3eta to bind the pro-apoptotic Bad protein. This study demonstrates that YWHAH variants can have a substantial effect on 14-3-3eta function and that 14-3-3eta could be a critical factor in the survival of outer hair cells.
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