Histamine H4 receptor antagonists as potent modulators of mammalian vestibular primary neuron excitability.

BACKGROUND AND PURPOSE: Betahistine, the main histamine drug prescribed to treat vestibular disorders, is a histamine H(3) receptor antagonist. Here, we explored the potential for modulation of the most recently cloned histamine receptor (H(4) receptor) to influence vestibular system function, using a selective H(4) receptor antagonist JNJ 7777120 and the derivate compound JNJ 10191584. EXPERIMENTAL APPROACH: RT-PCR was used to assess the presence of H(4) 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 H(4) receptor modulation in the rat vestibular system. KEY RESULTS: The transcripts of H(4) and H(3) 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 H(4) receptor agonist 4-methylhistamine. Thioperamide, a H(3) /H(4) receptor antagonist, exerted effects similar to those of H(3) and H(4) receptor antagonists, namely inhibition of firing at nanomolar range and membrane depolarization above 100 µM. H(4) receptor antagonists significantly alleviated the vestibular deficits induced in rats, while neither betahistine nor thioperamide had significant effects. CONCLUSIONS AND IMPLICATIONS: H(4) receptor antagonists have a pronounced inhibitory effect on vestibular neuron activity. This result highlights the potential role of H(4) receptors as pharmacological targets for the treatment of vestibular disorders.

TRPV4 channels mediate the infrared laser-evoked response in sensory neurons.

Infrared laser irradiation has been established as an appropriate stimulus for primary sensory neurons under conditions where sensory receptor cells are impaired or lost. Yet, development of clinical applications has been impeded by lack of information about the molecular mechanisms underlying the laser-induced neural response. Here, we directly address this question through pharmacological characterization of the biological response evoked by midinfrared irradiation of isolated retinal and vestibular ganglion cells from rodents. Whole cell patch-clamp recordings reveal that both voltage-gated calcium and sodium channels contribute to the laser-evoked neuronal voltage variations (LEVV). In addition, selective blockade of the LEVV by micromolar concentrations of ruthenium red and RN 1734 identifies thermosensitive transient receptor potential vanilloid channels as the primary effectors of the chain reaction triggered by midinfrared laser irradiation. These results have the potential to facilitate greatly the design of future prosthetic devices aimed at restoring neurosensory capacities in disabled patients.

Evaluation of the chemical model of vestibular lesions induced by arsanilate in rats.

Several animal models of vestibular deficits that mimic the human pathology phenotype have previously been developed to correlate the degree of vestibular injury to cognate vestibular deficits in a time-dependent manner. Sodium arsanilate is one of the most commonly used substances for chemical vestibular lesioning, but it is not well described in the literature. In the present study, we used histological and functional approaches to conduct a detailed exploration of the model of vestibular lesions induced by transtympanic injection of sodium arsanilate in rats. The arsanilate-induced damage was restricted to the vestibular sensory organs without affecting the external ear, the oropharynx, or Scarpa's ganglion. This finding strongly supports the absence of diffusion of arsanilate into the external ear or Eustachian tubes, or through the eighth cranial nerve sheath leading to the brainstem. One of the striking observations of the present study is the complete restructuring of the sensory epithelia into a non sensory epithelial monolayer observed at 3months after arsanilate application. This atrophy resembles the monolayer epithelia observed postmortem in the vestibular epithelia of patients with a history of lesioned vestibular deficits such as labyrinthectomy, antibiotic treatment, vestibular neuritis, or Ménière's disease. In cases of Ménière's disease, aminoglycosides, and platinum-based chemotherapy, vestibular hair cells are destroyed, regardless of the physiopathological process, as reproduced with the arsanilate model of vestibular lesion. These observations, together with those presented in this study of arsanilate vestibular toxicity, suggest that this atrophy process relies on a common mechanism of degeneration of the sensory epithelia.

Three-dimensional culture of newborn rat utricle using an extracellular matrix promotes formation of a cyst.

The vestibule is the end organ devoted to sensing of head movements in space. To function properly, its mechano-receptors require the presence of a unique apical extracellular medium, the endolymph. Numerous studies have elucidated the mechanisms involved in the production and homeostasis of this unique medium and the responses of sensory cells to stimulation. However, anatomical constraints have prevented direct and simultaneous studies of their relationships. The aim of this study was the development of an in vitro model that would allow concomitant investigations on maturation and physiological properties of both the hair cells and their endolymphatic compartment. A three-dimensional (3D) culture of newborn rat utricles using an extracellular matrix sustaining 3D cellular growth was developed during 3, 6, or 10 days in vitro (DIV). Using morphological and electrophysiological techniques, we describe the de novo formation of a cyst. It was composed of the sensory epithelium and non-sensory cells-canalar, dark and intermediate cells-that polarized so that their apical surface faced its lumen. During the time of culture, the utricular potential (UP) was steady (-1.1+/-5.0 mV) in oxygenated condition, while in anoxia, the UP significantly decreased to -8.4+/-1.0 mV at 8 DIV. Over the same period, the K+ concentration in the cyst increased up to 86.1+/-33.9 mM (versus 5.6+/-1.5 mM in the bath). These observations indicated that the mechanisms generating the UP and the K-secretory activity were functional at this stage. Concomitantly, the hair cells acquired mature and functional properties: the type 1 and type 2 phenotypes, a mean resting membrane potential of -68.1+/-4.6 mV and typical electrophysiological responses. This preparation provides a powerful means to simultaneous access the hair cells and their endolymphatic compartment, with the possibility to use multi-technical approaches to investigate their interdependent relationships.

Detection and localization of BDNF in vestibular nuclei during the postnatal development of the rat.

The changes in expression and the subcellular localization of brain-derived neurotrophic factor (BDNF) protein in the rat vestibular nuclear complex (VNC), have been investigated at different postnatal stages. Immunoblotting and ELISA analyses showed a down-regulation of BDNF protein expression in VNC with age. In addition, observations by confocal microscopy revealed that BDNF is mainly located in neuronal somata at postnatal day 8 (P8) and restricted to processes by P15. These results support the idea that BDNF could have different roles in the VNC according to the stage of development The protein could act as a neurotrophic factor in embryonic and early postnatal stages whereas in later developmental stages of the VNC it could be involved in neuronal maturation and regulation of neuronal circuitry.

A role for BDNF in early postnatal rat vestibular epithelia maturation: implication of supporting cells.

The early development of the inner ear is largely determined by two members of the neurotrophic family: brain-derived neurotrophic factor (BDNF) and neurotrophin 3 (NT-3). Little information is available on the role of these neurotrophins during the late stages of vestibular development in the rat which take place during the first postnatal weeks. At this period where terminal synaptogenesis and maturation occur, we have investigated the expression and the activity of BDNF, the most important neurotrophin in the vestibular system. Using different experimental approaches, we show that BDNF is released by vestibular epithelia on postnatal day 3 (P3) and continues to have a trophic effect on vestibular neurones in vitro. Immunocytochemistry coupled to confocal microscopy revealed a remarkable evolution in BDNF localization during later stages of development. Whereas BDNF is present in both supporting cells and hair cells at P3, its distribution gradually changed and is highly compartmentalized within the upper part of supporting cells at P8 and P15. In parallel, we observed the presence of a truncated form of the BDNF receptor in sensory hair cells. These results suggest an original role for supporting cells, which could be involved in the release of BDNF during the late stages of synaptogenesis in mammalian vestibular epithelia. In particular, BDNF could participate to the set up of the calyx, a specific nerve structure surrounding type I vestibular hair cells.

Short-term response of postnatal rat vestibular neurons following brain-derived neurotrophic factor or neurotrophin-3 application.

The effects of the application of brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT-3) neurotrophins on the intracellular calcium level ([Ca2+]i) were studied in vestibular ganglion neurons (VGNs) from postnatal day 3 (P3) rats cultured for 50 hr. We first assessed the expression of trkB and trkC mRNA receptors in cultured VGNs. Immunobloting and immunocytochemistry confirmed the presence of the neurotrophin receptors on neurons. Both neurotrophins induced transient [Ca2+]i elevations in VGNs: BDNF-treated neurons responded in 65% and NT-3-treated neurons in 56%. The responses could be inhibited by anti-BDNF or anti-NT-3 antibodies. The [Ca2+]i elevation was dependent on extracellular calcium since it was abolished in calcium-free medium but also implicates the release of calcium from intracellular stores as tested by prior depletion with thapsigargin. Our results suggest the implication of a short-term calcium regulation in VGNs, which could reflect specific fast effects of neurotrophins in the early postnatal rat vestibular system.

Immunocytochemical localization of the GTP-binding protein G0 alpha in the vestibular epithelium and ganglion of the guinea-pig.

The guanine nucleotide binding protein G0 alpha was immunolocalized in the guinea-pig vestibular system by confocal and electron microscopy. The vestibular sensory epithelia consist of the macula utriculi, macula sacculi and cristae ampullaris of the semicircular canals. Two types of hair cells are present in these epithelia. Type I hair cells are surrounded by an afferent nerve calyx that receives efferent innervation and type II hair cells are innervated directly by the afferent and efferent nerves. G0 alpha protein was observed on the inner face of the afferent calyceal membrane surrounding type I hair cells and in nerve endings in contact with type II hair cells. No labelling was found in the stereocilia and cuticular plate of type I and type II hair cells whereas the cytoplasmic matrix displayed a diffuse labelling. The plasma membrane of the supporting cells showed discreet labelling in the confocal microscope that are still confirmed by electron microscopy. A positive reaction was also observed along the plasma membrane of the vestibular ganglion neurons. Immunoblotting with affinity-purified polyclonal rabbit antibodies selective for the 39 kDa alpha subunit of G0 indicated that G0 alpha protein was present in both the vestibular ganglion. That G0 alpha labelling was observed in the cytoplasm of vestibular hair cells and in nerve endings contacting hair cells suggests that G0 may be involved in the modulation of vestibular neurotransmission.

High sensitivity of hypertensive aortic myocytes to norepinephrine and angiotensin.

Single-mass primary cultures were used for as long as 5 wk as the source of subcultured vascular smooth muscle cells for the study of their change of shape on the addition of agonists. We have compared the responses to angiotensin II, vasopressin, norepinephrine, and serotonin of myocytes derived from three different areas or the thoracic aorta (aortic arch and midthoracic and diaphragm areas) of adult Wistar-Kyoto normotensive rats (WKY) and spontaneously hypertensive rats (SHR). Once in secondary culture, vascular myocytes displayed different mean sizes according to their origin along the organ, as previously described in freshly dispersed aortic myocyte suspensions. Responses of the cells from the area of the aortic arch of both strains had the maximal amplitude to all agonists. Angiotensin and norepinephrine were more potent on myocytes derived from the three areas in SHR than in WKY. As this hypersensitivity persisted even after 5 wk in culture, it is believed to be pressure independent and thus might have a genetic rather than an adaptive origin.

Responses of subcultured rat aortic smooth muscle myocytes to vasoactive agents and KCl-induced depolarization.

We have developed a culture system in which a single-mass primary culture can be used for as long as 6 wk as a source of subcultured smooth muscle myocytes for the study of the changes of their shape upon addition of vasoactive agents (angiotensin, vasopressin, norepinephrine, and serotonin) and KCl depolarization. Responses of subcultivated myocytes were shown to be reproducible with time in primary culture before subculture and consistent with responses of thoracic aorta to the same agents. Effect of KCl depolarization could be blocked with calcium antagonist PN 200-110. Consistently, the presence of calcium L-channels was shown using whole cell patch-clamp recordings. A comparative study of the responses of myocytes derived from two different segments of the thoracic aorta showed that these cells displayed responses with different maximal amplitudes and the same potencies according to their topological origin in the vessel.

A comparison of cyclic AMP signaling system in rat aortic myocytes in primary culture and aorta.

Cyclic AMP (cAMP) metabolism has been studied in rat aortic myocytes grown in primary culture to characterize this second messenger system in vascular smooth muscle cells that retain responses to vasoactive drugs. For comparison, cAMP metabolism was also studied in the aorta from donor rats. Adenylate cyclase activity from myocytes and from the aorta was stimulated to a similar degree by GTP, NaF, or forskolin, and the enzyme activation produced by isoproterenol or vasoactive intestinal polypeptide was observed only in the presence of GTP. A cAMP phosphodiesterase activity was found in homogenates from cultured myocytes and aorta as well, and it was similarly stimulated by calmodulin in both cases. The rates of cAMP production and degradation were about seven-fold higher in cultured myocytes than in aorta. Basal levels of cAMP were also higher in the cultured cells than in the aorta. Hormones and drugs acting on adenylate cyclase or cAMP-phosphodiesterase in cell-free preparations altered the cAMP content of undisrupted cultured myocytes and aorta in the expected manner. Differences between cultured myocytes and aorta resided in the courses of drug-induced cAMP increases and in the magnitude of the cAMP response to isoproterenol, which was markedly increased in cultured myocytes compared with aorta. It is concluded that, despite some quantitative differences, the cAMP system of rat aortic myocytes grown in primary culture has characteristics similar to those displayed in rat isolated aorta. These cells are therefore suitable for studying the effects of drugs involving cAMP as a second messenger.

Proteins solubilized from frog virus 3 particles: effect on transcription.

The treatment of KB cells with viral proteins solubilized from frog virus 3 particles (SVE) induced a rapid shutoff of host RNA synthesis. The RNA polymerase activities of SVE-treated cells were drastically depressed, corresonding, at least for RNA polymerase B, to a decrease in the number of enzyme molecules. In vitro, SVE had no direct effect on RNA polymerases but was capable of binding with calf thymus DNA to form an SVE-DNA complex modifying the template capacity. The effect of SVE on a transcription system consisting of cell lysates would suggest that cytoplasmic factors are necessary for expression of the inhibitory capacity of SVE.

Preparation and properties of an inhibitory extract from frog virus 3 particles.

The structural constituents of the frog virus 3 particle were solubilized by treatment with a nonionic detergent followed by the addition of a high salt concentration. This soluble viral extract (SVE) inhibits host nucleic acid synthesis. Its activity on RNA synthesis was studied in KB cells and found to be dependent on the presence of DEAE dextran. Inactivation of the inhibitory properties of SVE were obtained by trypsin digestion, treatment with urea, or heat denaturation. Neutralization of the activity of SVE was obtained by anti-frog virus 3 serum but not by anti-BHK serum. In vitro a complex may be formed between polynucleotides and the inhibitor indicating a possible mechanism for vivo inhibition.