Cochlear outer hair cells in a dominant-negative connexin26 mutant mouse preserve non-linear capacitance in spite of impaired distortion product otoacoustic emission.

Mutations in the connexin26 gene (GJB2) are the most common genetic cause of congenital bilateral non-syndromic sensorineural hearing loss. Transgenic mice were established carrying human Cx26 with the R75W mutation that was identified in a deaf family with autosomal dominant negative inheritance [Kudo T et al. (2003) Hum Mol Genet 12:995-1004]. A dominant-negative Gjb2 R75W transgenic mouse model shows incomplete development of the cochlear supporting cells, resulting in profound deafness from birth [Inoshita A et al. (2008) Neuroscience 156:1039-1047]. The Cx26 defect in the Gjb2 R75W transgenic mouse is restricted to the supporting cells; it is unclear why the auditory response is severely disturbed in spite of the presence of outer hair cells (OHCs). The present study was designed to evaluate developmental changes in the in vivo and in vitro function of the OHC, and the fine structure of the OHC and adjacent supporting cells in the R75W transgenic mouse. No detectable distortion product otoacoustic emissions were observed at any frequencies in R75W transgenic mice throughout development. A characteristic phenotype observed in these mice was the absence of the tunnel of Corti, Nuel's space, and spaces surrounding the OHC; the OHC were compressed and squeezed by the surrounding supporting cells. On the other hand, the OHC developed normally. Structural features of the lateral wall, such as the membrane-bound subsurface cisterna beneath the plasma membrane, were intact. Prestin, the voltage-dependent motor protein, was observed by immunohistochemistry in the OHC basolateral membranes of both transgenic and non-transgenic mice. No significant differences in electromotility of isolated OHCs during development was observed between transgenic and control mice. The present study indicates that normal development of the supporting cells is indispensable for proper cellular function of the OHC.

Postnatal development of the organ of Corti in dominant-negative Gjb2 transgenic mice.

Hereditary hearing loss is one of the most prevalent inherited human birth defects, affecting one in 2000. A strikingly high proportion (50%) of congenital bilateral nonsyndromic sensorineural deafness cases have been linked to mutations in the GJB2 coding for the connexin26. It has been hypothesized that gap junctions in the cochlea, especially connexin26, provide an intercellular passage by which K(+) are transported to maintain high levels of the endocochlear potential essential for sensory hair cell excitation. We previously reported the generation of a mouse model carrying human connexin26 with R75W mutation (R75W+ mice). The present study attempted to evaluate postnatal development of the organ of Corti in the R75W+ mice. R75W+ mice have never shown auditory brainstem response waveforms throughout postnatal development, indicating the disturbance of auditory organ development. Histological observations at postnatal days (P) 5-14 were characterized by i) absence of tunnel of Corti, Nuel's space, or spaces surrounding the outer hair cells, ii) significantly small numbers of microtubules in inner pillar cells, iii) shortening of height of the organ of Corti, and iv) increase of the cross-sectional area of the cells of the organ of Corti. Thus, morphological observations confirmed that a dominant-negative Gjb2 mutation showed incomplete development of the cochlear supporting cells. On the other hand, the development of the sensory hair cells, at least from P5 to P12, was not affected. The present study suggests that Gjb2 is indispensable in the postnatal development of the organ of Corti and normal hearing.

Ouabain application to the round window of the gerbil cochlea: a model of auditory neuropathy and apoptosis.

The physiological and morphological changes resulting from acute and chronic infusion of ouabain onto the intact round-window (RW) membrane were examined in the gerbil cochlea. Osmotic pumps fitted with cannulas allowed chronic (0.5-8 days) infusions of ouabain. Acute and short-term applications of ouabain (1-24 h) induced an increase in auditory-nerve compound action potential (CAP) thresholds at high frequencies with lower frequencies unaffected. The resulting threshold shifts were basically all (no response) or none (normal thresholds), with a sharp demarcation between high and low frequencies. Survival times of 2 days or greater after ouabain exposure resulted in complete auditory neuropathy with no CAP response present at any frequency. Distortion product otoacoustic emissions (DPOAEs) and the endocochlear potential (EP) were largely unaffected by the ouabain indicating normal function of the outer hair cells (OHC) and stria vascularis. One to 3 days after short-term applications, apoptosis was evident among the spiral ganglion neurons assessed both morphologically and with TdT-mediated dUTP-biotin nick end labeling (TUNEL). With 4-8 day survival times, most spiral ganglion cells were absent; however, a few cell bodies remained intact in many ganglia profiles. These surviving neurons had many of the characteristics of type II afferents. Our working hypothesis is that the ouabain induces a spreading depression among the type I ganglion cells by blocking the Na,K-ATPase pump. Because of the constant spike activity of these cells, the ouabain rapidly alters potassium concentrations within ([K+]i) and external to ([K+]o) the ganglion cells, thereby initiating an apoptotic cascade.

Enzyme-histochemical localization of carbonic anhydrase in the inner ear of the guinea pig and several improvements of the technique.

We have made several improvements in the method of fixation of the inner ear and the enzyme-histo-chemical technique for carbonic anhydrase (CA) detection. The results confirmed that CA is localized in the hair cells of the organ of Corti, Deiters' cells or nerve endings, inner pillar cells, Boettcher's cells, stria vascularis, spiral ligament, spiral limbus, and spiral ganglion cells. These results generally agree with previous histochemical observations but showed some differences. Our method preserved tissue morphology and showed more detailed localization of CA activity in the inner ear. In particular, the marginal zone of stria vascularis and the epithelial cells of spiral prominence, facing the endolymph, showed no CA activity, while the suprastrial region of the spiral ligament and the supralimbal region of the spiral limbus, juxtaposed to the perilymph, showed CA activity. In outer hair cells, the cuticular plate, which faces the endolymph showed CA activity, but the lateral membrane, which faces the perilymph showed no CA activity. In contrast, the inner hair cell cytoplasm showed diffuse CA activity. These results will be useful in considering ion exchange between endolymph and its adjacent cells, and between perilymph and its adjacent structures.