Sensory hair cells of a fish ear: evidence of multiple types based on ototoxicity sensitivity

Sensory hair cells from the striolar region (striolar hair cells) of the utricle and the lagena of the ear of a teleost fish Astronotus ocellatus (Cuvier) ear are sensitive to gentamicin sulphate, an ototoxic drug. In contrast, sensory hair cells from outside the striolar region (extra-striolar hair cells) are not sensitive to gentamicin. These data, combined with results from studies showing different ultrastructural features and different immunoreactivity to a calcium binding protein, S-100, lead to the suggestion that there are distinguishable types of hair cells in these endorgans. These results add to the increasing evidence that classifying the sensory hair cells of fish ears only as the traditional 'vestibular type II' may be inadequate for properly understanding structure and function of the fish ear.

Carbohydrates associated with the cell coat surrounding cells of the rainbow trout saccular macula as revealed by lectin probes

The luminal surface of the saccular macula in the rainbow trout is covered with a glycoconjugate-rich cell coat. The aim of this study was to identify specific carbohydrate moieties present in this coat, using biotinylated lectins as probes. Saccular tissues were fixed in Karnovsky's fixative for 2 h at 1-2 degrees C, followed by incubation with biotinylated lectins for 12-16 h at 25 degrees C. Lectin binding was visualized by performing avidin-biotin-peroxidase reactions. As controls, specimens were reacted with solutions of lectins preincubated with their specific inhibitory sugars. Staining was observed that was consistent with the presence of glucose, galactose, fucose, mannose, N-acetylglucosamine, N-acetylneuraminic acid, and N-acetylgalactosamine in the cell coat. The variability in the intensity of staining associated with the lectin-carbohydrate complexes suggests quantitative differences among the various carbohydrate moieties detected. The presence of these carbohydrates in the cell coat of the trout saccular macula also suggests biochemical similarities between cell coats in teleost and mammalian inner ear structures.

An ultrastructural study on vestibular sensory cells in a new-mutant mouse

The ultrastructural characteristics of the vestibular epithelium and light microscopical study of the central nervous system of a strain of new-mutant mice were analyzed. For the vestibular study, we used 72 homozygotes with ages ranging from 10 days to 18 months. The most striking findings observed in these mice were the disarray of the stereocilia of the utricular and saccular maculae and disintegration of the saccular otoconia. Many hair cells displayed abnormality of the stereocilia such as reduced number, disorganized distribution, and giant cilia, although the hair cell cytoplasm, including the nerve terminals, became fully developed. Demineralization of the saccular otoconia was age dependent, and a complete loss of the saccular hair cells was demonstrated. In conjunction with the disarray of the outer hair cells of the cochlea, morphological manifestation of the gene abnormality of these mice was related to immaturation of the stereociliary tufts. Because no morphological abnormality was observed in the central nervous system, the abnormal behavior in these mice was primarily correlated with morphological abnormalities of the vestibule.

Toadfish saccular hair cell bundle has a preferred orientation in the otolithic membrane

The macula of the saccule of the toadfish, Opsanus tau, is covered by an otolithic membrane containing sockets into which the stereocilia and kinocilia of the hair cells project. We have found that the hair cell bundle has a distinct eccentric orientation within this space of the otolithic socket. Although the sockets of the otolithic membrane are irregular in shape, all kinocilia are located closet to the same border of the sockets. Since the socket is a fluid or gel filled space through which the hair cell bundle moves, this orientation may have some significance for transduction since it leaves a larger space in the on direction for stereociliary movement.

Structural basis for mechanical transduction in the frog vestibular sensory apparatus: I. The otolithic membrane

The mechanical coupling of the otoliths to the hair cell sensory stereocilia at the surface of the vestibular sensory epithelium is mediated by two layers of extracellular matrix, each one with a specific role in the mechanical transduction process. The first is a rigid layer in direct contact with the otolithic mass and is known as the otolithic membrane or gelatin membrane. This structure consists of a dense, randomly cross linked filament network that uniformly distributes the force of inertia of the non-uniform otolithic mass to all stereocilia bundles. The second layer formed by a columnar organization of filaments secures the otolithic membrane above the surface of the epithelium. The long columnar filaments are organized in parallel to the stereocilia bundles and are anchored to the apical surface of the supporting cells. The zonula adherens at the apical region of each supporting cell displays a thick polygonal bundle of actin filaments forming at the surface of the epithelium a transcellular honeycomb organization that provides mechanical ground support for the columnar filament layer. The dominant aspect of this columnar filament layer indicates that it may also have an important role in attenuating the force of inertia of the large otolithic mass during acceleration, screening stresses that would be directed to an effective bending of the stereocilia bundles.

Immunoelectron microscopy of the human inner ear

The immediate fixation required for satisfactory morphologic preservation of the human inner ear has not only limited the ultrastructural study of this region, but has also limited the application of immunohistochemistry. The technique of postembedding protein A-colloidal gold immunoelectron microscopy was used on human inner ear tissue taken at operation and on celloidin-embedded temporal bone sections from a traditional temporal bone bank. We describe the utility of postembedding immunoelectron microscopy for studying the localization of a wide variety of antigens including type I collagen, S-100, and calcitonin gene-related peptide. The use of this method in material available in temporal bone banks or that has been routinely processed for transmission electron microscopy provides the potential for broad application to collections of otologic material.

Ultrastructural aspects of the human peripheral vestibular system

The sensory epithelia from the membranous labyrinths of 4 patients were examined by transmission electron microscopy. The distribution ratio of type 1 to type 2 cells was recorded, compared for each sensory area and correlated with age. An ultrastructural assessment confirmed generalized patterns consistent with autolytic and preparation artefact, viz. calyceal dilatation, cytoplasmic protrusions and some sensory hair loss. More specific features, i.e. lipofuscin accumulation, membrane-bound inclusions and neural degeneration were consistent with pre-mortem pathological change. In 2 patients, total nerve fibre counts of 15,766 and 19,741 were obtained. Total fibre counts correlated with the sensory cell density of the innervated areas. Differential counts of the superior and inferior vestibular nerves suggested that there was a reduced number of fibres in the superior division of both patients, in comparison with established normative data. Morphometric analysis of the constituent fibre diameters revealed a skewed distribution with a modal value of 6 microns for both patients.

High-voltage electron microscopic observations on the suprastructure of the macula utricle

Thick sections of the suprastructure of the utricular macula of the guinea pig were observed by high-voltage electron microscope. Whole views and the relationship of the otoconia, the otoconial membrane and the sensory ciliary bundles became very clear. In addition, stereo micrographs were even more helpful for simultaneously recognizing this three-dimensional relationship.

Ultrastructure of the vestibular sensory organs in delayed endolymphatic hydrops

Vestibular sensory organs were examined ultrastructurally in two cases of delayed endolymphatic hydrops. The patients, two women, 27 and 16 years of age, suffered profound sensory hearing loss in childhood and experienced severe, recurrent vertigo. Specimens were obtained by a translabyrinthial vestibular nerve transection. We studied the utricular macula and the lateral and posterior cristae in one case, and the utricular macula, the anterior and posterior cristae, and the vestibular ganglion in the other. The otoconia and the otoconial membrane, the sensory epithelia, and the vestibular ganglion appeared fairly normal. Although the entire vestibular end organs were not studied in these cases, it was surprising that the ultrastructural findings did not conclusively identify vestibular end organ pathology as the cause of the vertigo attacks.

[A study of the otolithic membranes of the saccule and utricle of the guinea pig]

By scanning electron microscopy the otolith membranes of the sacculus and utriculus of adult guinea-pigs were examined. The spatial arrangement of otoconia was found to differ from the standard scheme. New forms of imperfect otoconia were detected. Differences in morphological parameters of otoconia in the labyrinthine structures were revealed. Factors responsible for the development of imperfect otoconia on the otolith membrane are described and their relation to the potential changes in the sensitivity of otolith receptors is discussed.

Decreased adenosine triphosphatase activity in the absence of adrenocorticosteroids

Changes in adenosine triphosphatase activity and cellular integrity of rat inner-ear tissues were observed after removal of adrenal steroids via bilateral adrenalectomy. Statistical significance of total and magnesium ion-dependent adenosine triphosphatase activities of the stria vascularis, spiral ligament, and ampullar dark cells from adrenalectomized animals was detected when compared with those of controls as demonstrated by fluorometric microassay. Although there was a similar reduction of activity in utricular dark-cell tissues, no significant difference between the treated and control animals was observed. An increase of intercellular space and a decrease in basolateral infoldings of cells of the stria vascularis and dark cell regions of adrenalectomized animals were observed. Such data collectively provide indirect evidence that adrenal steroids are involved in the cellular regulation of inner-ear tissues that are concerned with fluid and ionic microhomeostasis.

Fine structure of guinea pig vestibular kinocilium

The fine structure of the utricular kinocilium of the guinea pig was examined with transmission electron microscopy after treatment with tannic acid to enhance resolution of internal morphology. The utricular kinocilium was devoid of inner dynein arms and a central pair of microtubules, while a set of outer dynein arms and radial spokes was found. This supports the hypothesis that the vestibular kinocilium is non-motile. Internal electron-dense particles at the attachment sites of the stereo-kinociliar bonds were situated in the immediate periphery of the outer dynein arms, although no visible connection existed between these structures. Findings obtained in the present study seem to give insight on the mechanism of mechanosensory transduction in the vestibular sensory cells.

The effect of gentamicin on the glycocalyx and the ciliary interconnections in vestibular sensory cells: a high resolution scanning electron microscopic investigation

Changes in glycocalyx structure and ciliary interconnections of the vestibular sensory cells are demonstrated after gentamicin administration. A special high resolution scanning electron microscope and a tannic acid-osmium staining technique giving an almost three dimensional view were used to achieve this purpose. Guinea pigs were injected with a single dose of 5 mg of gentamicin directly into the middle ear. Seven days after the injection, it was possible to observe the degenerative process of the glycocalyx and the ciliary interconnections. The first detectable change was a disarrangement of the cilia with a loosening of the interconnections. The ciliary membrane presented with an irregular appearance. The tip links connecting the tips of the stereocilia to their neighbours were also affected showing elongation or even disappearance. In the later stages of the degeneration process, the sensory hairs presented with different degrees of fusion whereafter they finally disappeared totally. These findings suggest that the glycocalyx acts to maintain a normal stability and shape of the ciliary membrane and to keep the regular distance between cilia in order to maintain the arrangement of the whole ciliary bundle. Gentamicin probably affects the glycocalyx and the ciliary interconnections resulting in a disarrangement, detachment and fusion of cilia. The tip links, which are suggested to be involved in sensory cell transduction, seem to be also affected by gentamicin.

Volume fraction and ultrastructure of age pigment in the saccular epithelium of old mice

Age pigment in the sensory and supporting cells was a prominent characteristic distinguishing old saccules from young. However, the pigment was not distributed uniformly throughout the sensory epithelium but displayed cell-specific patterns of accumulation. The highest cytoplasmic volume density was in the old supporting cells followed by type I hair cells and then type II hair cells. The most common form of pigmented inclusion seen in old type I hair cells was a cluster of granules resembling melanin. This form was never seen in type II hair cells or supporting cells where a form containing a lipid-like droplet was prevalent. The differences in the amount of age pigment and the forms accumulated probably reflects metabolic differences between the three cell types.

Functional aspects of carbohydrate complex of the statoconial membrane of the guinea pig utricular macula

A functional aspect of the carbohydrate complex of the statoconial membrane of the guinea pig utricular macula was observed by the use of the lectins as well as the ruthenium red staining techniques. The ruthenium red staining technique visualized the whole structure of the statoconial membrane as well as the contact zone between the sensory epithelium and the statoconial membrane. The statoconial membrane is composed of the otoconial layer, gelatinous layer, and subcupular meshwork. The otoconial layer was interconnected with sensory epithelium by the gelatinous layer and subcupular meshwork which formed honeycomb structure and housed the sensory hair bundle. This may allow the free movement of the sensory hair bundle. The gelatinous layer and the subcupular meshwork contain N-acetylglucosamine, mannose, and galactose which form acidic mucopolysaccharide and glycoprotein. It has been indicated that these carbohydrate complex may play an important role for the mechanical coupling not only between the statoconial membrane and the sensory epithelium but also between the sensory hair bundle and the statoconial membrane.

Transmission electron microscopic study of the saccule in the embryonic, larval, and adult toadfish Opsanus tau

The development of the sensory epithelium of the saccular macula of Opsanus tau was studied with transmission electron microscopy. In the 10-12 somite embryo all cells of the newly formed otocyst are morphologically undefined, having an apically placed cilium with an underlying basal body and parabasal body. Junctional complexes are characterized primarily by tight junctions and a few desmosomes. In the 17-somite embryo the sensory cells begin to differentiate and are definable by the development of microvilli, which lack a cuticular plate. When the embryo has approximately 25-30 somites, ganglion cells differentiate and send their nerve processes toward the thin, disrupted basal lamina and the developing rhombencephalon. Desmosomes are more definable in the sensory regions at this age. As the myotomes begin forming (approximately 5-8 days before hatching), the nerves invade the sensory epithelium, and the developing sensory cells contain dense bodies surrounded by clear, membrane-bound vesicles. Clear synapticlike vesicles are also found throughout the infranuclear region of the sensory cells. However, afferent fibers lack a postsynaptic density. Three to 6 days prior to hatching a cuticular plate begins forming under the ciliary bundles and support and peripheral cells begin to morphologically differentiate. Two to 4 days before hatching the cuticular plate is well formed, desmosomes are numerous, afferent synapses are complete, and the sensory cells are in the upper two-thirds of the epithelium. Seven to 10 days after hatching, sensory cells have efferent synapses and ganglion cells and nerves show a myelin coat. These results suggest that sensory cells begin their development prior to VIIIth nerve innervation, although the orientation and pattern development of these cells may be related to the formation of the cuticular plate, desmosomes, afferent innervation, and basal lamina formation.

Morphological evidence for parallel processing of information in rat macula

Study of montages, tracings and reconstructions prepared from a series of 570 consecutive ultrathin sections shows that rat maculas are morphologically organized for parallel processing of linear acceleratory information. Type II cells of one terminal field distribute information to neighboring terminals as well. The findings are examined in light of physiological data which indicate that macular receptor fields have a preferred directional vector, and are interpreted by analogy to a computer technology known as an information network.

[Structural resistance of receptor organs of the vestibular apparatus to the factors of space flight]

Observations made in ground-based simulation studies and in real orbital flights on fish and amphibian larvae as well as on adult rats show that exposure to different space flight factors, particularly microgravity, for as long as 20 days produces no pathological changes in the structural organization of vestibular receptors. However the possibility of functional or adaptive rearrangements in maculae and crystae as well as in the otolith organ cannot be excluded. It appears that bony fish (Teleostei) are most suitable for the study of adaptive changes in the otolith apparatus. When examining ultrastructural changes in maculae and crystae, it is important to take into consideration spatial and structural nonhomogeneity of the receptor epithelium of vestibular organs.

The response of structure and function of the gravireceptor in a vertebrate to near weightlessness

The paper sums up results of a 7-day space flight experiment (D-l-Mission-BW-STA 00-STATEX) using growing frog embryos and larvae (Xenopus laevis) as a model system. Evaluation of photographs taken from the surface of sectioned deep-frozen objects, and micrographs using TEM and SEM show no aberrations in the shape, size, position, or respective electron density of the otolith membranes in larvae developed for 154 h under near-zero g. The further evaluation of the "weightless larvae" revealed a probably not yet described otolith-like formation below the dorsal wall of the vestibulum. In the weightless larvae this formation outnumbers, also qualitatively, strongly the 1-g control samples. The swimming behavior of the tadpoles which was observed about one hour after landing of the Space Shuttle showed a typical anomaly (loop swimming), which is known from larvae developed on the clinostat or from fish flown aboard Apollo capsules. An extra result is the lack of striking effects of cosmic radiation on the embryonic development of the flown Xenopus eggs.

Gross and ultrastructural development of the saccule of the toadfish Opsanus tau

The development of the saccule of the inner ear in the toadfish was studied using light and scanning electron microscopy. Development was studied from the early embryo (2-3 days postfertilization), when the otocyst first forms, to the early-aged juvenile when the development of the inner ear approximates that of the adult (4 weeks postfertilization). The ultrastructural features examined included the morphological sequence of ciliary bundle growth, the development of orientation patterns of the ciliary bundles, and the relation of the ultrastructural development to overall gross development. Gross development may be divided into four distinct morphological stages. Stage I encompasses the time from initial formation of the otocyst until the start of stage II, which is the stage when the pars inferior begins migrating ventrally. In stage III the pars inferior continues to elongate ventrally. Stage IV starts when the pars inferior elongates in a rostral and caudal direction. The ear attains its adult shape in stage IV. The differentiation of the sensory cells begins during stage I. During the early part of stage I, a small cilium is found on the apical surface of each cell throughout the otocyst. In the middle and late periods of stage I, a few microvillous buds add to the surface of the cells that already have a kinocilium. These early ciliary bundles are clustered on the rostral-ventral and caudal walls of the otocyst. There is no clear patterning to the orientation of these ciliary bundles. In stage II the ventral stretching of the labyrinth wall causes a spreading of the clustered bundles along the ventral and medial walls of the pars inferior. The orientation of the ciliary bundles has no distinct pattern. In stage III the orientations of the ciliary bundles appear adultlike, although there are so few ciliary bundles that it is difficult to make a definite determination. During stage IV, hair cells with an adultlike horizontal and vertical orientation pattern are found on the rostral and caudal sections of the saccular macula, respectively. The transition region lying between these areas has ciliary bundles with various orientations.

The ultrastructure and innervation of the ear of the gar, Lepisosteus osseus

The endorgans of the inner ear of the gar were examined using transmission and scanning electron microscopy as well as nerve staining. The ultrastructure of the sensory hair cells and supporting cells of the gar ear are similar to cells in other bony fishes, whereas there are significant differences between the gar and other bony fishes in the orientations patterns of the sensory hair cells on the saccular and lagenar sensory epithelia. The saccular sensory epithelium has two regions, a main region and a secondary region ventral to the main region. The ciliary bundles on the main region are divided into two groups, one oriented dorsally and the other ventrally. Furthermore, as a result of curvature of the saccular sensory epithelium, the dorsal and ventral ciliary bundles on the rostral portion of the epithelium are rotated ninety degrees and are thus oriented on the animal's rostro-caudal axis. Hair cells on the secondary region are generally oriented ventrally. The lagenar epithelium has three groups of sensory hair cells. The groups on the rostral and caudal ends of the macula are oriented dorsally, whereas the middle group is oriented ventrally. Hair cell orientations on the utricular epithelium and macula neglecta are similar to those in other bony fishes. Nerve fiber diameters can be divided into three size classes, 1-8 microns, 9-13 microns, and 14 microns or more, with the smallest size class containing the majority of fibers. The distribution of the various classes of fiber diameters is not the same in nerve branches to each of the end organs. Similarly, the ratio of hair cells to axons differs in each end organ. The highest hair cell to axon ratio is in the utricle (23:1) and the smallest is in the macula neglecta (7:1). The number of sensory hair cells far exceed the number of eighth nerve axons in all sensory epithelia.

The morphological changes in the vestibular sensory epithelia following electrical stimulation

The morphological changes of the vestibular sensory epithelia of the guinea pig following electrical stimulation were investigated using scanning electron microscope. Positive and negative square wave pulse stimulation was given through a silver ball electrode placed on the round window membrane for one hour. The current intensities used were 100, 200 and 300 microA. While the direct current stimulation at intensities of 100 or 200 microA did not cause any significant changes, severe damage of the utricular macula and the ampullar crista of the lateral semicircular canal was observed at 300 microA. The degenerative changes such as fusion of sensory hairs, protrusion of the cuticular plate and loss of sensory cells were found on both the utricle and the semicircular canal. In the most severely damaged area, the sensory epithelial surface was badly torn apart. In the clinical application of direct current to the inner ear for relieving tinnitus, special attention should be paid to the vestibular organ.

Persistence of synaptic bodies in saccular hair cells of senescent mice

The morphology of the afferent synapse in type I (HCI) and type II (HCII) saccular hair cells was compared in juvenile and very old C57BL/6NNia mice. Normal membrane specializations and normal synaptic body (SB) form and organization were found to continue well beyond the expected life span. Although SB were found less frequently in HCI than in HCII, they were as readily found in old saccules as in juveniles. The elongated rod was the most common form in HCI and the spheroid was the most common in HCII. Large clusters of SB (greater than 5), found in both juvenile and old saccules, were unique to HCI. SB in HCII were generally found singly. A range of forms, including hollow and striated dense bodies, also occurred in both juvenile and very old saccules. Singular or clustered SB were found free in the cytoplasm as well as engaged at the membrane. No SB were seen at sites other than nerve terminal appositions. In rare instances a SB was observed engaged at a site that appeared to be opposite an efferent fiber.

Potassium-evoked release of endogenous primary amine-containing compounds from the trout saccular macula and saccular nerve in vitro

An in vitro preparation of the trout saccular macula, containing a large number of hair cells, served as a potential source of neurotransmitter(s) released at the acousticolateralis hair cell-afferent nerve synapse. An in vitro preparation of the saccular nerve, maintained in parallel, served to indicate the potential neural contribution to overall release from the macula. Efflux of 27 primary amine-containing compounds from the macula and nerve fractions was monitored by cation-exchange HPLC with fluorescence detection, and release by 53.5 mM potassium was determined at 1.45 mM calcium, 0.35 mM magnesium or 0 mM calcium, 10.1 mM magnesium. Taurine was released from the saccular macula in the greatest amount, accounting for 72% of the total evoked release of primary amine-containing compounds. Its release was calcium dependent and its time course prolonged. The contribution by myelinated nerve and associated Schwann cells within the macula to overall release of taurine from the macula in the presence of calcium, as determined from the saccular nerve preparation, was only 2%. Other components specifically released from the macula included ethanolamine, phosphoserine, beta-alanine, and glycine. Glutamate and aspartate were released from both the macula and saccular nerve fractions by potassium in the presence of calcium and in a ratio of 6:1 (glutamate:aspartate) for the macula and 7.5:1 for the nerve. The release of aspartate, but not that of glutamate, was lowered in saline containing 0 mM calcium, 10.1 mM magnesium. The calculated contribution from neural elements to overall release from the macula was 10% for aspartate and 18% for glutamate. These studies demonstrate that both the macula and saccular nerve fractions release the 'excitatory neurotransmitter' candidates aspartate and glutamate. Calcium-dependent, potassium-evoked release of taurine appears to be specific to the hair cell-supporting cell population of the saccular macula, and taurine may, therefore, be involved directly or indirectly in hair cell neurotransmission in labyrinthine organs. This study represents the first detailed biochemical characterization of efflux and release for an in vitro hair cell system of relatively high purity with respect to hair cells.