Zebrafish pax5 regulates development of the utricular macula and vestibular function.

The zebrafish otic vesicle initially forms with only two sensory epithelia, the utricular and saccular maculae, which primarily mediate vestibular and auditory function, respectively. Here, we test the role of pax5, which is preferentially expressed in the utricular macula. Morpholino knockdown of pax5 disrupts vestibular function but not hearing. Neurons of the statoacoustic ganglion (SAG) develop normally. Utricular hair cells appear to form normally but a variable number subsequently undergo apoptosis and are extruded from the otic vesicle. Dendrites of the SAG persist in the utricle but become disorganized after hair cell loss. Hair cells in the saccule develop and survive normally. Otic expression of pax5 requires pax2a and fgf3, mutations in which cause vestibular defects, albeit by distinct mechanisms. Thus, pax5 works in conjunction with fgf3 and pax2a to establish and/or maintain the utricular macula and is essential for vestibular function.

Ultrastructural analysis of [3H]thymidine-labeled cells in the rat utricular macula.

Ototoxic drugs stimulate cell proliferation in adult rat vestibular sensory epithelia, as does the infusion of transforming growth factor alpha (TGFalpha) plus insulin. We sought to determine whether new hair cells can be regenerated by means of a mitotic pathway. Previously, studies have shown that the nuclei of some newly generated cells are located in the lumenal half of the sensory epithelium, suggesting that some may be newly generated sensory hair cells. The aim of this study was to examine the ultrastructural characteristics of newly proliferated cells after TGFalpha stimulation and/or aminoglycoside damage in the utricular sensory epithelium of the adult rat. The cell proliferation marker tritiated-thymidine was infused, with or without TGFalpha plus insulin, into the inner ears of normal or aminoglycoside-damaged rats for 3 or 7 days by means of osmotic pumps. Autoradiographic techniques and light microscopy were used to identify cells synthesizing DNA. Sections with labeled cells were re-embedded, processed for transmission electron microscopy, and the ultrastructural characteristics of the labeled cells were examined. The following five classes of tritiated-thymidine labeled cells were identified in the sensory epithelium: (1) labeled cells with synaptic specializations that appeared to be newly generated hair cells, (2) labeled supporting cells, (3) labeled leukocytes, (4) labeled cells that we have classified as "active cells" in that they are relatively nondescript but contain massive numbers of polyribosomes, and (5) labeled degenerating hair cells. These findings suggest that new hair cells can be generated in situ by means of a mitotic mechanism in the vestibular sensory epithelium of adult mammals.

Extracellular matrices associated with the apical surfaces of sensory epithelia in the inner ear: molecular and structural diversity.

The ultrastructure and molecular composition of the extracellular matrices that are associated with the apical surfaces of the mechanosensory epithelia in the mouse inner ear are compared. A progressive increase in molecular and structural organization is observed, with the cupula being the simplest, the otoconial membrane exhibiting an intermediate degree of complexity, and the tectorial membrane being the most elaborate of the three matrices. These differences may reflect changes that occurred in the acellular membranes of the inner ear as a mammalian hearing organ arose during evolution from a simple equilibrium receptor. A comparison of the molecular composition of the acellular membranes in the chick inner ear suggests the auditory epithelium and the striolar region of the maculae are homologous, indicating the basilar papilla may have evolved from the striolar region of an otolithic organ. A comparison of the tectorial membranes in the chick cochlear duct and the mouse cochlea reveals differences in the structure of the noncollagenous matrix in the two species that may result from differences in the stochiometry of alpha- and beta-tectorin and/or differences in the post-translational modification of alpha-tectorin. This comparison also indicates that the appearance of collagen in the mammalian tectorial membrane may have been a major step in the evolution of an electromechanically tuned vertebrate hearing organ that operates over an extended frequency range.

Receptors for glucocorticoids in the human inner ear.

Glucocorticoid receptors were detected in the human inner ear. The highest concentration of glucocorticoid receptor protein was measured by enzyme-linked immunosorbent assay in the spiral ligament tissues; the lowest concentration of glucocorticoid receptors was measured in the macula of the saccule. The demonstration of the presence of glucocorticoid receptors in human Inner ear tissues provides a basis to consider the direct effects of glucocorticoid action on select inner ear cells, rather than assuming a systemic antiinflammatory or immunosuppressive effect during the therapeutic treatment of patients with given inner ear disorders.

Flavin adenine dinucleotide is a major endogenous fluorophore in the inner ear.

When illuminated with visible light, hair cells can exhibit autofluorescence (Lewis et al. [1982] Science 215, 1641-1643) concentrated in the basal pole near the synapses (Sento and Furukawa [1987] J. Comp. Neurol. 258, 352-367). The autofluorescence is enhanced by formaldehyde. The level of fluorescence is high enough to interfere with fluorescence microscopy of hair cells and to suggest that the fluorescent substance might have a particular role in hair-cell function. To identify this substance, we extracted a substance with formaldehyde-enhanced fluorescence from the inner ears of goldfish and purified it chromatographically. The substance copurified with FAD and had the same fluorescence emission spectrum. Two further results supported the identity of the endogenous fluorescent substance with FAD. First, as is the case with flavins, the autofluorescence in inner ear tissue examined within a few hours after fixation was reduced by addition of dithionite. Second, as is the case with the formaldehyde-enhanced fluorophore, the fluorescence of FAD was enhanced by formaldehyde. FAD accounted for 90% of flavins in goldfish inner ears; its concentration in the sensory epithelium was estimated to be about 30 nmol/g tissue weight, one of the highest tissue concentrations known. The FAD is probably associated with an unidentified flavoprotein concentrated in the basal, synaptic region of the hair cell.

Immunohistochemical examination of S-100 protein and substance P in the inner ear of the rat.

S-100 protein and substance P in the inner ear of the rats on decalcified specimens was investigated immunohistochemically. Immunoreactivity of S-100 protein and substance P was found in various parts of inner ear tissues. These results suggest the possibility of immunohistochemical study of decalcified and paraffinized inner ear tissues.