Glucocorticoid-stimulated, transcription-independent release of annexin A1 by cochlear Hensen cells.

BACKGROUND AND PURPOSE: The current clinical strategy to protect the auditory organ against inflammatory damage by migrating leukocytes is the local delivery of glucocorticoids. However, the mechanism by which glucocorticoids confer this protection remains unknown. Therefore, we investigated the cellular and molecular targets of glucocorticoids in the cochlea that could be involved in preventing leukocyte migration. EXPERIMENTAL APPROACH: We used microscopy as well as immunocytochemical and microfluidic techniques to elucidate the effect of dexamethasone, hydrocortisone and prednisolone on the cellular and intracellular distribution of annexin A1 (ANXA1) - a glucocorticoid target known to inhibit leukocyte migration by receptor-mediated signalling - in the cochlea and isolated cochlear cells of guinea pigs. KEY RESULTS: All the cells lining the scala media - the cochlear compartment containing the auditory organ - express ANXA1 and the ANXA1 receptor FPR2/ALX is present in the scala media, as well as in other cochlear ducts. The majority of ANXA1 in the scala media is stored inside lipid droplets within cochlear Hensen cells. Glucocorticoids activate a myosin IIC-mediated mechanism that drives ANXA1 from the lipid droplets to the apical region of the Hensen cells, where ANXA1 is released to the external milieu by a process involving ABC transporters. CONCLUSIONS AND IMPLICATIONS: These findings suggest that ANXA1 could be a major mediator of the anti-inflammatory effects of glucocorticoids in the cochlea and identify new molecular targets for prevention of sudden sensorineural hearing loss.

Apoptosis in the OC-k3 immortalized cell line treated with different agents.

The aim of this study is to outline the mechanisms leading cochlear cells to die. We utilized an immortalized cell line (OC-k3 cells) derived from the organ of Corti of transgenic mice in order to perform in-depth biochemical studies with no limitations on sample size and number. We probed these cells with cisplatin and gentamicin, two drugs which display in vivo undesired ototoxic side-effects. We investigated cell viability, reactive oxygen species (ROS) production and glutathione (GSH) levels and tested the effects of different concentrations of cisplatin and gentamicin from 0 to 48 h. Results show that cells undergo a dose- and treatment-time-dependent apoptosis characterized by nuclear fragmentation, integrity of the cell membrane and mitochondria, and absence of DNA endonuclease activity. During the early part of treatment, ROS production increases and intracellular GSH decreases, probably due to the activation of protein kinase C alpha. Use of antioxidants such as N-acetylcysteine, GSH and vitamin C rescues cells from apoptosis almost completely. Overall, these data indicate that ROS generation might play a central role in inducing inner ear cell apoptosis and may have an additive role in the ageing process.

Rho GTPases mediate the regulation of cochlear outer hair cell motility by acetylcholine.

Outer hair cells are the mechanical effectors of the cochlear amplifier, an active process that improves the sensitivity and frequency discrimination of the mammalian ear. In vivo, the gain of the cochlear amplifier is regulated by the efferent neurotransmitter acetylcholine through the modulation of outer hair cell motility. Little is known, however, regarding the molecular mechanisms activated by acetylcholine. In this study, intracellular signaling pathways involving the small GTPases RhoA, Rac1, and Cdc42 have been identified as regulators of outer hair cell motility. Changes in cell length (slow motility) and in the amplitude of electrically induced movement (fast motility) were measured in isolated outer hair cells patch clamped in whole-cell mode, internally perfused through the patch pipette with different inhibitors and activators of these small GTPases while being externally stimulated with acetylcholine. We found that acetylcholine induces outer hair cell shortening and a simultaneous increase in the amplitude of fast motility through Rac1 and Cdc42 activation. In contrast, a RhoA- and Rac1-mediated signaling pathway induces outer hair cell elongation and decreases fast motility amplitude. These two opposing processes provide the basis for a regulatory mechanism of outer hair cell motility.

Establishment and characterization of conditionally immortalized organ of corti cell lines.

A culture of cells was isolated from the organ of Corti of 2-week-old H-2Kb-tsA58 (Immortomouse) transgenic mice. All cells of these mice harbor a mutant of the simian virus 40 A-gene, encoding a thermolabile large T-antigen (Tag) protein. At 33 degrees C the Tag protein is functional and induces cell proliferation, but at 39 degrees C it is rapidly denatured and inactivated. Isolated organ of Corti cells growing at 33 degrees C were predominantly small, rounded or fusiform and proliferated rapidly. When moved to 39 degrees C, the cells reduced their rate of proliferation and differentiated into specific morphological phenotypes. Four cell lines were cloned by limiting dilution and characterized by immunofluorescence microscopy and Western blot. The cell lines, named OC-k1, OC-k2, OC-k3 and OC-k4, have been passaged at least 50 times with retention of a stable phenotype. These cell lines were all positive for the neuroepithelial precursor cell marker nestin and for the inner ear cell marker OCP2. In addition, the cells showed reactivity to epithelial and neuronal cell markers, but with a pattern of protein expression different for each clone and different between cells of the same clone growing at 33 degrees C or 39 degrees C. Some of the clones exhibited asymmetric cell division which is a characteristic commonly ascribed to stem cells. These cell lines can be used advantageously to study mechanisms and signals involved in the control of cell differentiation and morphogenesis of the mammalian inner ear and to isolate inner ear specific proteins.

Cell and molecular basis of hearing.

The mammalian auditory organ is a specialized sensory epithelium capable of detecting subnanometer movements produced by sound and transducing them into electrical signals. It is a dual system consisting of two types of sensory cells: the inner hair cells, which provide afferent input to the central nervous system, and the outer hair cells, which provide frequency resolution and signal amplification. The critical element in mechano-reception is the hair bundle, a cluster of stereocilia located in the apical end of the sensory cells. Mechanical stimulation causes deflection of ciliary bundles that leads to the opening or closing of transduction channels located in the apical part of the plasma membrane of the stereocilia. The current concept of auditory function requires an active process of signal amplification within the cochlea. It is generally believed that outer hair cells, functioning as both sensor and motor elements, are responsible for this amplification process. The motor function consists of changes in cell length produced by the concerted action of a large number of independent molecular motors distributed along the length of the outer hair cell lateral plasma membrane. Although experimental evidence suggests its association with conformational changes in transmembrane proteins, the exact nature of the outer hair cell force generation mechanism on a molecular level is still unknown.

Cochlear outer hair cell bending in an external electric field.

We have used a high-resolution motion analysis system to reinvestigate shape changes in isolated guinea pig cochlear outer hair cells (OHCs) evoked by low-frequency (2-3 Hz) external electric stimulation. This phenomenon of electromotility is presumed to result from voltage-dependent structural changes in the lateral plasma membrane of the OHC. In addition to well-known longitudinal movements, OHCs were found to display bending movements when the alternating external electric field gradients were oriented perpendicular to the cylindrical cell body. The peak-to-peak amplitude of the bending movement was found to be as large as 0.7 microm. The specific sulfhydryl reagents, p-chloromercuriphenylsulfonic acid and p-hydroxymercuriphenylsulfonic acid, that suppress electrically evoked longitudinal OHCs movements, also inhibit the bending movements, indicating that these two movements share the same underlying mechanism. The OHC bending is likely to result from an electrical charge separation that produces depolarization of the lateral plasma membrane on one side of the cell and hyperpolarization on the other side. In the cochlea, OHC bending could produce radial distortions in the sensory epithelium and influence the micromechanics of the organ of Corti.

Immunolocalization of anion exchanger 2alpha in auditory sensory hair cells.

We have previously reported the isolation from a guinea pig organ of Corti cDNA library of a cDNA clone that encodes a novel isoform of the anion exchanger 2 (AE2) protein (Negrini, Rivolta, Kalinec and Kachar, 1995. Cloning of an organ of Corti anion exchanger 2 isoform with a truncated C-terminal domain. Biophys. Acta, 1236, 207-211). The deduced protein, named AE2alpha, has a conserved cytoplasmic domain and a short membrane domain with only two membrane spanning regions, as opposed to the fourteen present in the conventional AE2. Now, we are showing the immunolocalization and preliminary characterization of this protein using an antipeptide antibody specific for this novel AE2 isoform. In Western blots, this antibody binds to an approximately 89 kDa polypeptide that corresponds to a phosphorylated protein with serines as main phosphate acceptor residues. In immunofluorescence experiments, the antibody labels the stereocilia and the lateral wall of the outer hair cells and the stereocilia of the inner hair cells. Our results suggest that AE2alpha is a membrane-cytoskeletal linker in regions of the hair cell, where sensory transduction mechanisms take place.

Cloning of an organ of Corti anion exchanger 2 isoform with a truncated C-terminal domain.

We have isolated a cDNA clone from a guinea pig organ of Corti library encoding a new isoform of the Anion Exchanger 2 (AE2) protein. This cDNA clone shows an 83 bp deletion in the region that encodes the membrane domain of AE2. Analysis of the overlapping regions of genomic and cDNA clones indicates that the missing portion does not correspond exactly to a constitutive exon. The alternate splicing process that generates this transcript involves internal donor and acceptor sites which introduces a shift in the open reading frame. The resulting polypeptide has a conserved cytoplasmic N-terminal domain but the membrane C-terminal domain has only two of the fourteen membrane spanning regions. An affinity-purified antipeptide antibody to the novel C-terminus detects an 89 kDa polypeptide which agrees with the molecular mass predicted from the cDNA.

Inhibition of outer hair cell electromotility by sulfhydryl specific reagents.

Mammalian outer hair cells can change length at acoustic frequencies when they are electrically stimulated. It was postulated that these length changes depend on electromechanical transduction based on voltage dependent conformational changes in a membrane motor protein. In this report, we describe the effect of various sulfhydryl (SH)-specific reagents on the OHC electromotility. p-Chloromercuriphenylsulfonate (pCMPS), in addition to other mercurials that can react with well-protected SH-groups in proteins, inhibits this electromechanical transduction process. In contrast, N-ethylmaleimide and diamide, SH-reagents that only react with exposed SH-groups, showed no effect. These results suggest that one or more reactive SH-groups are present in a functionally important and protected region of the electromechanical transduction protein. Such reactivity can be utilized to identify and characterize this novel membrane motor.

A membrane-based force generation mechanism in auditory sensory cells.

Auditory outer hair cells can elongate and shorten at acoustic frequencies in response to changes of plasma membrane potential. We show that this fast bidirectional contractile activity consists of an electromechanical transduction process that occurs at the lateral plasma membrane and can be activated and analyzed independently in small membrane patches inside a patch electrode. Bidirectional forces are generated by increases and decreases in membrane area in response to hyperpolarization and depolarization, respectively. We suggest that the force generation mechanism is driven by voltage-dependent conformational changes within a dense array of large transmembrane proteins associated with the site of electromechanical transduction.

Structure of the cortical cytoskeleton in mammalian outer hair cells.

The cortical cytoskeletal lattice in outer hair cells is a two-dimensional actin-based structure, which can be labelled with rhodamine/phalloidin and disrupted by the enzyme deoxyribonuclease I. Structural information from thin sectioned, freeze-etched and negatively stained preparations shows that it is based upon two types of filament that form a cross-linked lattice of circumferential filaments. The cross-links are 70-80 nm long. Measurements of the spacing between circumferential filaments suggest that the lattice is stiffer circumferentially than it is longitudinally. Analysis of the orientation of circumferential filaments shows that it is composed of discrete domains of up to 10 microns 2. Relative movements between domains could allow substantial changes of cell shape without disrupting the unit structure of the lattice, thus allowing the cell cortex to retain its elastic responses to high-frequency deformations.

Ultrastructural variations of the urothelial membrane in essential fatty acid (EFA)-deficient rats. A digital densitometric study.

The present report deals with a densitometric study of the ultrastructural images of the urothelial membrane of rats in the following experimental conditions: (1) EFA-deficient (EFAD) rats; (2) EFA-sufficient (EFAS) rats; and (3) EFAD rats that were fed the EFAD diet for 30 weeks and received an EFAS diet for the following 10 weeks (EFAD/S group). On electron micrographs of the transitional epithelium of ureters and urinary bladder of these rats, optical density (OD) profiles of the urothelial unit membrane were recorded and digitized using a computer-controlled microdensitometer with a solid-state self-scanned photodiode array sensor. A Gaussian curve was adopted as a model for the distribution of electron-dense material in each osmiophilic leaflet. Gaussian parameters were used to estimate the thickness of the urothelial membrane and of each osmiophilic leaflet, and the amount of electron-dense material and the maximal electron density present in each leaflet. In EFAS rats, the thick urothelial membrane was asymmetric like that of the normal, resulting from a greater thickness of the outer leaflet and a greater electron density of the cytoplasmic one. In EFAD rats, a loss of the characteristic ultrastructural asymmetry and a decrease of the total thickness of the unit membrane were detected. These changes were partially reversed in the EFAD/S rats.

Ultrastructural changes of the luminal plasma membrane of the transitional epithelium of the rat urinary tract in essential fatty acid deficiency.

Rats fed an essential fatty acid deficient diet (EFAD) showed a statistically significant decrease in the thickness and ultrastructural asymmetry of the luminal membrane and cytoplasmic vesicles of transitional epithelium of the urinary tract, due to a marked thinning of the peculiar thick luminal leaflet. These changes were reversed by adding EFA to the diet. This indicates that the unusual EM appearance of urothelial membrane depends on its content in EFA.