Expression of Na+,K(+)-ATPase alpha 1 subunit mRNA in the developing rat cochlea

Expression of Na/K-ATPase subunits in the human cochlea: a confocal and super-resolution microscopy study with special reference to auditory nerve excitation and cochlear implantation

Background: For the first time the expression of the ion transport protein sodium/potassium-ATPase and its isoforms was analyzed in the human cochlea using light- and confocal microscopy as well as super-resolution structured illumination microscopy. It may increase our understanding of its role in the propagation and processing of action potentials in the human auditory nerve and how electric nerve responses are elicited from auditory prostheses. Material and methods: Archival human cochlear sections were obtained from trans-cochlear surgeries. Antibodies against the Na/K-ATPase β1 isoform together with α1 and α3 were used for immunohistochemistry. An algorithm was applied to assess the expression in various domains. Results: Na/K ATPase β1 subunit was expressed, mostly combined with the α1 isoform. Neurons expressed the β1 subunit combined with α3, while satellite glial cells expressed the α1 isoform without recognized association with β1. Types I and II spiral ganglion neurons and efferent fibers expressed the Na/K-ATPase α3 subunit. Inner hair cells, nerve fibers underneath, and efferent and afferent fibers in the organ of Corti also expressed α1. The highest activity of Na/K-ATPase β1 was at the inner hair cell/nerve junction and spiral prominence. Conclusion: The human auditory nerve displays distinct morphologic features represented in its molecular expression. It was found that electric signals generated via hair cells may not go uninterrupted across the spiral ganglion, but are locally processed. This may be related to particular filtering properties in the human acoustic pathway.

Expression of Pou3f3/Brn-1 and its genomic methylation in developing auditory epithelium

In the mammalian cochlea, both the sensory cells-called hair cells (HCs)-and nonsensory cells such as supporting cells (SCs) and mesenchymal cells participate in proper auditory function through the expression of various functional molecules. During development, expression of certain genes is repressed through genomic methylation, one of the major epigenetic regulatory mechanisms. We explored the genomic regions that were differentially methylated in rat auditory epithelium at postnatal day 1 (P1) and P14 using amplification of intermethylated sites (AIMS). An AIMS fragment was mapped to the 3'-flanking region of Pou3f3/Brn-1. Bisulfite-converted PCR and quantitative methylation-specific PCR showed that the methylation frequency of the AIMS region and the adjacent CpG island was increased at P14, when the expression of Pou3f3 and the noncoding RNAs nearby decreased. Expression of de novo DNA methyltransferases 3a and 3b also suggests a role of epigenetic regulation during postnatal inner ear development. Immunohistochemical analysis showed that Pou3f3 was expressed specifically in the SCs and mesenchymal cells in the cochlea and established that Pou3f3 is a new cell-type marker for studying inner ear development. Mice deficient in Pou3f3 or Pou3f2 plus Pou3f3 did not exhibit any abnormality in the embryonic cochlea. Absence of Pou3f3 affected neither the proliferation nor the differentiation activities of HC progenitor cells. Pou3f3 may, however, be important for the maintenance or functional development of the postnatal cochlea. This is the first report to study involvement of an epigenetic regulatory mechanism in the developing mammalian auditory epithelium.

Dynamic expression of FXYD6 in the inner ear suggests a role of the protein in endolymph homeostasis and neuronal activity

A key protein in the production and in the maintenance of the endocochlear potential is the Na,K-ATPase. Previously, we have shown that FXYD6 is a modulator of the Na,K-ATPase expressed in the inner ear (Delprat et al. [2007] J Biol Chem 282:7450-7456). To investigate the potential role of FXYD6 in inner ear function, we studied the developmental expression of FXYD6. Reverse transcriptase-polymerase chain reaction analysis demonstrates that FXYD6 is present as two splice variants. Both variants coimmunoprecipitate with Na,K-ATPase after expression in Xenopus oocytes. Immunohistochemistry of the cochlea (from birth to postnatal day 30) shows that FXYD6 is expressed in several epithelial cells important for endolymph homeostasis. Marked similarities were found in the developmental expression patterns of FXYD6 and Na,K-ATPase, suggesting functional cooperation between the two proteins in the generation and maintenance of the endocochlear potential and ion composition of the endolymph.

Molecular and physiological bases of the K+ circulation in the mammalian inner ear

Endolymph, the extracellular solution in cochlea, contains 150 mM K(+) and exhibits a potential of approximately +80 mV relative to neighboring extracellular spaces. This unique situation, essential for hearing, is maintained by K(+) circulation from perilymph to endolymph through the cochlear lateral wall. Recent studies have identified ion-transport molecules involved in the K(+) circulation and their pathophysiological relevance.

Expression of CLC-K chloride channels in the rat cochlea

Current models of the lateral K+ recycling pathway in the mammalian cochlea include two multicellular transport networks separated from one another by three interstitial gaps. The first gap is between outer hair cells and Deiters cells, the second is between outer sulcus cells and type II spiral ligament fibrocytes and the third is between intermediate and marginal cells in the stria vascularis. K+ taken up by cells bordering these interstitial spaces is accompanied by Cl-. Maintaining appropriate electrolyte balance and membrane potentials in these cells requires a mechanism for exit of the resorbed Cl-. One possible candidate for regulating this Cl- efflux is ClC-K, a chloride channel previously thought to be kidney specific. Here, we demonstrate the expression of both known isoforms of ClC-K in the organ of Corti, spiral ligament and stria vascularis of the rat cochlea by immunohistochemical, Western blot and RT-PCR analysis. These results indicate a role for ClC-K in mediating Cl- recycling in the cochlea. The widespread expression of both ClC-K isoforms in the cochlea may help to explain the symptoms of Bartter's syndrome Type III, a mutation in the hClC-Kb gene (human homologue of ClC-K2), which results in renal salt wasting without deafness. These data support the hypothesis that both isoforms of ClC-K are co-expressed in some cell membranes and account for the preservation of hearing in the presence of a mutation in only one channel isoform.

The emotional ear in stress

Stress of some kind is encountered everyday and release of stress hormones is essential for adaptation to change. Stress can be physical (pain, noise exposure, etc.), psychological (apprehension to impending events, acoustic conditioning, etc.) or due to homeostatic disturbance (hunger, blood pressure, inner ear pressure, etc.). Persistent elevated levels of stress hormones can lead to disease states. The aim of the present review is to bring together data describing morphological or functional evidence for hormones of stress within the inner ear. The present review describes possible multiple interactions between the sympathetic and the complex feed-back neuroendocrine systems which interact with the immune system and so could contribute to various inner ear dysfunctions such as tinnitus, vertigo, hearing losses. Since there is a rapidly expanding list of genes specifically expressed within the inner ear this clearly allows for possible genomic and non-genomic local action of steroid hormones. Since stress can be encountered at any time throughout the life-time, the effects might be manifested starting from in-utero. These are avenues of research which remain relatively unexplored which merit further consideration. Progress in this domain could lead towards integration of stress concept into the overall clinical management of various inner ear pathologies.

Cochlear distribution of Na,K-ATPase and corticosteroid receptors in two mouse strains with congenital hearing disorders

As corticosteroid hormones, via their receptors, and Na,K-ATPase are thought to be involved in the regulation of endolymph production, two mouse models were used to investigate whether degeneration of the stria vascularis (SV) and disturbed endolymph composition are correlated with changes in the amounts and distribution of corticosteroid receptors and Na,K-ATPase in the cochlea. Both the shaker-2 mouse and the newly discovered mix mouse are deaf at birth and show vestibular dysfunction. In both mouse strains, the SV is degenerated and endolymph production is severely disturbed. In the shaker-2 mouse, using the C57Bl mouse as a normal control, immunohistochemical staining of mineralo- and glucocorticoid receptors (MR and GR) and the Na,K-ATPase subunits alpha1, alpha3 and beta1 showed a weaker reaction in all structures of the cochlea. The inner ear morphology of the mix mouse is described and compared to that of asymptomatic littermates. Immunostaining of MR, GR and the different Na,K-ATPase subunits in this mouse was considerably weaker in the SV, while staining intensities were normal in the remaining cochlea. The reduced corticosteroid receptor levels may lead to a reduction in Na,K-ATPase expression in the same tissues, although this conclusion should be treated with caution. The conclusion that reduced Na,K-ATPase levels in both mouse strains may be an important mechanism of the disturbed endolymph production is less controversial.

Na,K-ATPase expression in the mouse cochlea is not dependent on the mineralocorticoid receptor

This study was performed in order to test the hypothesis that the mineralocorticoid hormone stimulates the expression of Na,K-ATPase in the cochlea of the mouse. Immunohistochemistry was used to investigate the distribution of the mineralocorticoid receptor (MR) in the cochlea of the C57Bl/J6 mouse at different ages between gestational day 19 and postnatal day 30, and the occurrence and distribution of Na,K-ATPase in the inner ear of a mouse with a null mutation of the MR. Adult patterns of staining for MR were found as early as on gestational day 19 in the cochlea, with small changes thereafter. MR was detected in the same structures in the cochlea as Na,K-ATPase in earlier studies, where the amount of Na,K-ATPase increased after postnatal day 4. Thus there is latency between the increase of MR and the increase of Na,K-ATPase. In the cochlea of the MR deficient mouse, antibody labelling of Na,K-ATPase showed no significant difference as compared to the control wild type mouse. The hypothesis that mineralocorticoid hormone alone via MR stimulates the formation of Na,K-ATPase in the inner ear could not be confirmed by this study, and other regulating mechanisms must be considered.

Alteration of 6-phosphofructo-1-kinase subunits during neonatal maturation of the rat cochlear cells

During postnatal development of rat cochlear cells and the onset of hearing (10-23 days), the increasing endocochlear potential and energy requirements are largely provided by increased glucose utilization. It is well established that the ability of maturing rat tissues to use glucose is directly related to alteration of 6-phosphofructo-1-kinase (PFK) subunits. To gain insight into the alteration of PFK subunit levels in the cochlea from 6 to 60 days of age, PFK subunit types were measured in sections of paraffin-embedded temporal bone using IgG specific for each type of PFK subunit and quantified by computer image analysis. Although the L-type and C-type subunits did not exhibit statistically significant changes in the cochlear structures during maturation, the levels of M-type subunit in the stria vascularis cells, spiral ligament cell types I, II, and III, outer hair cells, inner hair cells, and support cells significantly increased. Also, the type IV and V spiral ligament fibrocytes during this period did not exhibit significant alterations of the M-type subunit. These data suggest that during neonatal development of the cochlear, the elevated levels of the M-type subunit are associated with increased glucose utilization and the onset of hearing.

Development of monovalent ions in the endolymph in mouse cochlea

The present study was designed to clarify the chronological developmental process of monovalent ions (Na(+), K(+), Cl(-)) in the endolymph of the mouse in relation to the development of the endocochlear potential (EP). The EP and ionic concentrations were measured simultaneously with the ion-sensitive double-barreled microelectrodes from the scala media of the basal turn. The EP increased abruptly 7 days after birth (DAB) and reached approximately 80 mV 14 DAB. In the earliest postnatal days, the endolymphatic Na(+) concentration was significantly higher than that in adult mice, however, the K(+) and the Cl(-) concentrations were lower. The concentrations of all the monovalent ions in endolymph reached adult levels at 7 DAB when the EP was still under 20 mV. These data strongly suggest the presence of a different mechanism between the production of monovalent ions, especially of high K(+) in the endolymph and that of EP.

Intercellular junctional maturation in the stria vascularis: possible association with onset and rise of endocochlear potential

The postnatal maturation of intercellular junctions of marginal and basal cells of the stria vascularis was examined in the gerbil using thin sections and freeze fracture techniques. Immunohistochemical methods were used to determine the presence of Na,K-ATPase postnatally. The onset and growth of endocochlear potential (EP) was also measured. In marginal cells, the apical surface and junctional region around the apical pole of the cell was found to have adult-like characteristics by the time of onset of EP, whilst the increase in staining for Na.K-ATPase temporally coincided with an increasing density of intra-membrane protein particles on the infoldings of marginal cell lateral membranes. Maturation of the junctional specialisations of the basal cells was found to correspond temporally with the period of onset and rise of EP. Tight junctions between basal cells first appeared as small, broken strands composed of widely spaced particles at 6 days after birth (DAB). These junctional strands increased in number and in particle density until adult-like at 16 DAB when they covered large areas of the basal cell lateral membrane. Gap junctions on the apical membrane of basal cells first appeared as small patches of loosely packed junctional elements at 6 DAB. Between 8 and 16 DAB the area of membrane occupied by the gap junctions increased, reaching a mature conformation by 18 DAB. The results suggest that EP maturation is dependent upon the development of sealing between the basal cells by tight junctions and also the establishment and development of gap junctions in the apical plasma membrane of basal cells, associated with intermediate cells.

Identification of preferentially expressed cochlear genes by systematic sequencing of a rat cochlea cDNA library

107 expressed sequence tags (ESTs) from a rat cochlea cDNA library were identified by systematic sequencing coupled to database selection and RT-PCR analysis of novel sequences. This approach led us to select a clone, pCO8, showing no significant homology with any database sequence, that corresponds to a mRNA whose expression is restricted to the cochlea, except for traces detected in brain. Additional clones with novel sequences enriched in the cochlea were also found. ESTs bearing significant homologies with database sequences (63 out of 107) were classified according to the putatively encoded protein. They include tissue-specific genes not previously described in the cochlea as well as known genes from other species. We performed in situ hybridization in cochlear tissues to localize the pCO8 mRNA and that of clone pCO6 which is 100% homologous to the delayed rectifier potassium channel drk1. We found that both mRNAs were exclusively expressed in the cellular body of the primary auditory neurons from the spiral ganglion of the cochlea. These results indicate that this approach is an efficient way to identify novel genes that could be of importance in cochlear function.

An ATP-dependent inwardly rectifying potassium channel, KAB-2 (Kir4. 1), in cochlear stria vascularis of inner ear: its specific subcellular localization and correlation with the formation of endocochlear potential

Cochlear endolymph has a highly positive potential of approximately +80 mV. This so-called endocochlear potential (EP) is essential for hearing. Although pivotal roles of K+ channels in the formation of EP have been suggested, the types and distribution of K+ channels in cochlea have not been characterized. Because EP was depressed by vascular perfusion of Ba2+, an inhibitor of inwardly rectifying K+ (Kir) channels, but not by either 4-aminopyridine or tetraethylammonium, we examined the expression of Kir channel subunits in cochlear stria vascularis, the tissue that is supposed to play the central role in the generation of positive EP. Of 11 members of the Kir channel family examined with reverse transcription-PCR, we could detect only expression of KAB-2 (Kir4.1) mRNA in stria vascularis. KAB-2 immunoreactivity was specifically localized at the basolateral membrane of marginal cells but not in either basal or intermediate cells. Developmental expression of KAB-2 in marginal cells paralleled formation of EP. Furthermore, deaf mutant mice (viable dominant spotting; WV/WV) expressed no KAB-2 in their marginal cells. These results suggest that KAB-2 in marginal cells may be critically involved in the generation of positive EP.

Na,K-ATPase alpha- and beta-isoforms in the developing cochlea of the mouse

Immunohistochemistry was used to investigate the presence of Na,K-ATPase alpha- and beta-subunits isoforms (alpha 1, alpha 2, alpha 3, beta 1 and beta 2) in the cochlea of the mouse at different ages between embryological day (E) 19 and postnatal day (P) + 30. alpha 1 was mainly found in the stria vascularis and in the spiral ligament; it increased steadily from p+4. These data correlates well with the morphological and electrophysiological maturation of the cochlea. alpha 3 predominated in the spiral ganglia and the cochlear nerve. This finding is well in accordance with reports that alpha 3 seems to be associated with the nervous system. The beta-subunit was found mainly in those tissues where staining of the alpha-subunit also was seen. Both subunits were localized in tissue regions where fluid regulation is expected to play an important role. For some isoforms, the expression pattern of Na,K-ATPase during development in the mouse is different from that in the rat. The expression of Na,K-ATPase and that of glucocorticoid receptors during development in the inner ear of the mouse show a similar pattern, which may indicate that glucocorticoid receptors could be involved in regulating the expression of Na,K-ATPase.

Appearance of glucocorticoid receptors in the inner ear of the mouse during development

CBA mice were sacrificed at different ages of developments at embryonic day 13 (E13), E14, E16, E19, E20 and postnatal day 1 (P1), P2, P3, P4, P6, P8, P10, P14, P16, P18, P20 and P30. The temporal bones were quickly removed and deep frozen in order to prepare cryosections for immunohistochemical staining with polyclonal antibodies against glucocorticoid receptors. The avidin-biotin, ABC-method was used to visualize binding. Both the vestibular and the cochlear regions of the inner ear were analysed. A faint staining of the crista ampullaris, the utricle and the cochlear duct was seen at E19; and staining became clearly visible at P1. A decrease in labelling was found at day 2-5 post partum whereafter an increased staining was again noticed until postnatal day 14 when an adult pattern was observed. The appearance of glucocorticoid receptors in the inner ear during development does not follow a linear curve. Further, the labelling pattern may indicate an impact of glucocorticoid receptors on the embryologic maturation itself as well as a functional role in the adult ear.

Expression of Na+/myo-inositol cotransporter mRNA in the inner ear of the rat

We have demonstrated the cellular localization of Na+/myo-inositol cotransporter (SMIT) mRNA in the rat inner ear by in situ hybridization. In the cochlea, the most intense SMIT mRNA signals were observed in fibrocytes of the spiral ligament, moderate signals were found in the spiral limbus, inner hair cells and spiral ganglion cells, while the hybridization signals were almost undetectable in the marginal cells of the stria vascularis and outer hair cells. In the vestibular system, moderate hybridization signals were found in the sensory epithelium, fibrocytes and vestibular ganglion cells. These findings suggest that SMIT plays an important role in maintenance of intracellular ionic balance and cell volume in the inner ear, especially in the fibrocytes associated with generation of the ion gradients between the endolymph and perilymph.

Expression of Na, K-ATPase alpha and beta isoforms in the neonatal rat cochlea

The postnatal expression of five Na, K-ATPase alpha (alpha 1, alpha 2, alpha 3) and beta (beta 1, beta 2) subunit isoforms in the rat cochlea was investigated by immunocytochemistry. High levels of expression of the alpha 1 and beta 2 isoforms were observed in stria vascularis (SV) at all developmental stages. alpha 1 and beta 1 isoforms showed a distinct time-dependent developmental expression pattern in tissues of the spiral ligament (SL) and spiral limbus (SLi). Limited, temporary expression of alpha 2 and alpha 3 subunit isoforms were found in SV and SL. Expression of each isoform was also seen in organ of Corti (OC), spiral ganglion (SG), cochlear nerve (CN) and Kölliker's Organ (KO). These observations suggest that individual isoforms may exert specific actions postnatally during final cochlear maturation.

Glucocorticoid receptor expression in the postnatal rat cochlea

The glucocorticoid receptor (GR) expression in the neonatal rat cochlea was investigated by utilization of a polyclonal antibody against GR, the immunoreactivity of which exhibited a distinct, age-dependent developmental pattern in tissues of the spiral ligament (SL). Immunostaining of GR appeared initially at the 7th postnatal day (PND), increased rapidly between the 14th and 21st PND, and reached adult-like expression levels by the 21st PND. Less pronounced, developmentally regulated expression patterns of GR were observed in cells of the spiral limbus (SLi), spiral ganglion (SG), organ of Corti (OC), and cochlear nerve (CN). For example, high expression levels of GR were observed in the SLi, SG and OC at 3 PND; subsequently, GR immunoreactivity levels decreased from 7 to 14 PND, and then GR immunoreactivity intensified in these regions by 21 PND. No remarkable changes in GR expression were observed in stria vascularis (SV). These data indicate that GR expression in the inner ear is tissue and age-specific, and that GR expression parallels both Na,K-ATPase expression and endocochlear potential development.