Sensory surface of the saccule and lagena in the ears of ostariophysan fishes

The inner ears of a few fishes in the teleost superorder Ostariophysi are structurally unlike those of most other teleosts. Scanning electron microscopy was used to determine if other ostariophysans share these unusual features. Examined were the families Cyprinidae, Characidae, and Gymnotidae (all of the series Otophysi), and Chanidae (of the sister series Anotophysi), representing the four major ostariophysan lineages, the auditory organs of which have not yet been well described. Among the Otophysi, the saccular and lagenar otolith organs are similar to those reported for other ostariophysans. The lagena is generally the larger of the two organs. The saccular sensory epithelium (macula) contains long ciliary bundles on the sensory hair cells in the caudal region, and short bundles in the rostral region. The saccule and the lagena each have hair cells organized into two groups having opposing directional orientations. In contrast, Chanos, the anotophysan, has a saccular otolith larger than the lagenar otolith, and ciliary bundles that are more uniform in size over most of its saccular macula. Most strikingly, its saccular macula has hair cells organized into groups oriented in four directions instead of two, in a pattern very similar to that in many nonostariophysan teleosts. We suggest that the bi-directional pattern seen consistently in the Otophysi is a derived development related to particular auditory capabilities of these species.     

Morphology of the macula neglecta in sharks of the genus Carcharhinus

Ears from several species of carcharhinid sharks were studied by gross dissection, light microscopy, transmission electron microscopy, and scanning electron microscopy. Structures along a possible sound transmission path to the ear are described, but main consideration is given to the structure of the macula neglecta. The macula neglecta is composed of two patches of sensory epithelium which line part of the posterior canal duct. In an adult shark the larger of these contains 224,000 sensory hair cells oriented so as to detect forces directed posteroventrolaterally in the duct. The smaller patch contains 43,000 hair cells oriented so as to detect oppositely directed forces. These receptor cells project through numerous small terminals to a total for both patches of 4,700 myelinated nerve fibers. Cytostructural variations throughout the hair cell population are also reported. Estimated acoustic properties of the tissues in this complex and the processing potential of the neural elements are interpreted as suggestive of auditory function. A mechanism based on the geometry of the receptor arrays is proposed to explain behaviorally observed instantaneous sound localization from the farfield. Evolution of the macula neglecta is reviewed, and evidence for homology of the macula neglecta and amphibian papilla is presented.     

On the Polarization and Innervation of the Pars Inferior Sensory Epithelia of the Herring Labyrinth

The macula sacculi and the macula lagenae of the herring, Clupea harengus L., were examined by light microscopy, the macula lagenae is large compared to what is normal among non-ostariophysan fishes, the morphological polarization of the hair cells in the inferior maculae shows a pattern which is similar to that usually seen in teleost fishes. The fibres in the nerves supplying the macula sacculi and the macula lagenae were counted and their diameters measured. The ramulus saccularis is divided in two separate ramuli innervating populations of hair cells with different morphological polarization. The saccular rostral nerve trunk contains 1800–2300 fibres, with 1300–1800 fibres in the caudal nerve trunk. The lagenar nerve is composed of 2100–4000 fibres. The fibre diameters are 1–14 μm in all ramuli. Silver staining of the nerve axoplasm reveals a unique differentiation of the maculae, which can be divided into a central area surrounded by a peripheral part. The hair cells in the central area are innervated by thick nerve fibres (5–14 μm diameter) as well as a few thin nerve fibres (about 1 μm diameter), while the receptor cells in the peripheral area are exclusively innervated by thin fibres having diameters of 2 μm or less.     

Structure and Innervation of the Inner Ear Sensory Organs in an Otophysine Fish,the Upside–down Catfish (Synodontis nigriventrisDavid)

All the sensory epithelia of the inner ear in the upside–down catfish (Synodontis nigriventrisDavid) were examined by light microscopy. The morphology of the membranous labyrinth and the orientation of the hair cells is similar to what has been found in other otophysine fishes. The sensory cells are of variable size both inter– and intraepithelially; particularly the macula sacculi is equipped with heterogeneous receptors. Regional differences in the hair cell density are presented for all the otolith organs plus the papilla neglecta. Nerve stainings reveal regional differentiation. The central areas are innervated by stout and stubbly nerve endings intermingled with a few thin nerve fibres while the peripheral parts are reached exclusively by thin axons. In the anterior region of the macula sacculi are found unique cup–shaped axon terminations which surround the basal parts of a single or a few sensory cells. The number and diameter range of the myelinated nerve fibres as well as the hair cell/axon ratio are presented. Electron microscopy demonstrates the presence of unmyelinated axons in all inner ear nerve ramuli.     

The polarization of hair cells from the inner ear of the lesser spotted dogfish Scyliorhinus canicula

The polarization of hair cells from the end organs of the inner ear from the lesser spotted dogfish Scyliorhinus canicula from the order Carcharhiniforms (ground sharks) was studied using a scanning electron microscope (SEM), revealing arrays of hair cells with diverse orientations on each of the sensory epithelia. The greatest numbers of hair cells were found on the utricular epithelium and orientated on the horizontal plane, whilst the smallest number were found on the anterior macula neglecta and orientated on the vertical plane. Examination of the posterior macula neglecta revealed a dense profusion of c. 500 000 individual elongate structures, each resembling long microvilli, a finding not previously described in elasmobranch auditory physiology.     

A study on the fine structure of the saccular macula of the gold fish

Summary The fine structure of the saccular macula of the gold fish has been studied by means of the electron microscope.The sensory epithelium of the macula consists of sensory cells and supporting cells. The surface of the sensory cell is studded with a group of sensory hairs consisting of one kino-cilium and 50–60 stereocilia. In the dorsal half of the macula, the kino-cilium is located at the dorsal end of the sensory hair group. In the ventral half of the macula, the kino-cilium is located at the ventral end of the sensory hair group. In the intermediary portion of the macula, the sensory cells with opposite polarities are situated side-by-side. The relation between the microphonic potential and the position of the kino-cilium has been discussed.Two types of nerve terminals are found situated on the basal surface of the receptor cells. The one contains no synaptic vesicle and the other contains a cluster of synaptic vesicles and a few cored vesicles. It is considered that the former corresponds to the afferent nerve terminal and the latter to the efferent one.This investigation was supported by NIH Grant NB-06052.The author is very grateful to Prof. Taro Furukawa, Osaka City University for his invaluable advice and discussion.     

Development of the inner ear of the brown trout (Salmo trutta fario): I. Gross morphology and sensory cell proliferation

The gross development of the trout inner ear between embryonic and juvenile stages was studied by light microscopy. The otocyst has already formed in 3–4 mm embryos. The semicircular canals begin to separate from the utriculo-saccular cavity in 6 mm embryos, the anterior canal first, then the posterior and the horizontal canal later. The formation of the saccular cavity begins in 7 mm embryos, whereas that of the lagena occurs in 18 mm fry. The first macular primordia appear before the separation of cavities. The anterior and horizontal crests arise from the primordium of the utricular macula, and the posterior crest, macula lagena, and macula neglecta arise from that of the saccular macula. The macula lagena and macula neglecta appear later. The sensory areas of the labyrinth and the number of receptor cells grow continuously between the embryonic and juvenile stages. © 1993 Wiley-Liss, Inc.     

Quantitative analyses of sex and size differences in the macula neglecta and ramus neglectus in the inner ear of the skate,Raja ocellata

Summary In Raja ocellata the macula neglecta is located in the posterior canal duct of the inner ear at the junction with the sacculus. The maximum length and width of a freeze-dried macula from a male skate of 61 cm width is 1035 m and 315 m respectively. Ultrastructural studies show that the hair cells of the macula are of two types. Orientation of hair cells is towards the periphery with a reverse direction of polarization in 5.0 to 6.5% of the cells. The axons of the associated nerve, the ramus neglectus, are myelinated, and include both efferent and afferent fibres.Electron-microscopic studies and quantitative analyses reveal significant sex differences in the macula neglecta and ramus neglectus. Hair cell and axon numbers, and total axon areas increase linearly with skate size, and are significantly different in males and females for any given representative size of skate, the females having the larger counts. Since the macula neglecta functions as a vibration detector of far-field localizations, the gender difference may be involved in the location of prey, or in mate detection. It is unknown whether such differences occur in any other vertebrate species.     

Hair Cell Polarization in the Flatfish Inner Ear

The hair cell polarization of the various sensory epithelia in the inner ear was examined in two species of flatfish, the Plaice (Pleuronectes platessa) and the Dab (Limanda limanda). The hair cells in the macula utriculi are polarized in the pattern usually seen for this macula in vertebrates. In the macula sacculi and macula lagenae the hair cell polarization is different from that hitherto described from bony fishes and other vertebrates. The polarization seen in these maculae in the flatfish explains their ability to sense movements in all directions, which is necessary if these sensory areas are the most important inner ear organs in the regulation of postural orientation.     

Ultrastructural study of the saccular epithelium of the inner ear of two teleosts, Oncorhynchus mykiss and Psetta maxima

The secretory cells and ionocytes of the saccular epithelium of the inner ear of trout (Oncorhynchus mykiss) and turbot (Psetta maxima) have been studied by electron microscopy. In these species, the saccular epithelium may be subdivided into four zones: the “macula”, the “meshwork area”, the “patches area”, and the “intermediate area”. In addition to the sensory “hair cells” and their supporting cells, the macula contains, at its periphery, “granular cells” that have the ultrastructural characteristics of secretory cells. The “meshwork area” around the macula contains large ionocytes endowed with pseudopods, many mitochondria, and three intracytoplasmic membrane systems (endoplasmic reticulum, tubular, and vesicular systems). The patches area, located at some distance from the macula, consists of groups of small mitochondria-rich ionocytes characterized by infoldings of their lateral plasma membrane. In the intermediate area, the size and organelle-content of cells decrease from the meshwork area to the patches area. There is no significant difference in cell composition or structure of the saccular epithelium between the trout and the turbot. The secreting cells might be involved in secretion of endolymph and formation of the otolith, whereas the ionocytes probably regulate the ionic composition of the endolymph.     

Ultrastructure of the sensory formations of the internal ear in the common frog

By means of scanning electron microscopy method, sensory formations of the membranous labyrinth has been studied in the frog (Rana temporaria). The form of sensory fields and morphological peculiarities of the hair cells are described. For the saccular macula, amphibian and basilar papillae, the number of the hair cells is calculated, orientation of the hair cell poles is demonstrated.     

Acoustic response properties of lagenar nerve fibers in the sleeper goby,<Emphasis Type="Italic"> Dormitator latifrons</Emphasis>

Auditory and vestibular functions of otolithic organs vary among vertebrate taxa. The saccule has been considered a major hearing organ in many fishes. However, little is known about the auditory role of the lagena in fishes. In this study we analyzed directional and frequency responses from single lagenar fibers of Dormitator latifrons to linear accelerations that simulate underwater acoustic particle motion. Characteristic frequencies of the lagenar fibers fell into two groups: 50 Hz and 80–125 Hz. We observed various temporal response patterns: strong phase-locking, double phase-locking, phase-locked bursting, and non-phase-locked bursting. Some bursting responses have not been previously observed in vertebrate otolithic nerve fibers. Lagenar fibers could respond to accelerations as small as 1.1 mm s^–2. Like saccular fibers, lagenar fibers were directionally responsive and decreased directional selectivity with stimulus level. Best response axes of the lagenar fibers clustered around the lagenar longitudinal axis in the horizontal plane, but distributed in a diversity of axes in the mid-sagittal plane, which generally reflect morphological polarizations of hair cells in the lagena. We conclude that the lagena of D. latifrons plays a role in sound localization in elevation, particularly at high stimulus intensities where responses of most saccular fibers are saturated.Abbreviations BRA best response axis/axes - BS best sensitivity - CF characteristic frequency - CV coefficient of variation - DI directionality index - ISIH inter-spike interval histogram - PSTH peri-stimulus time histogram - SR spontaneous rate     

Structure and Innervation of Inner Ear Sensory Epithelia in the European Eel (Anguilla anguilla L.)

Hair cell orientations of all inner ear sensory epithelia in glass eel, yellow eel and silver eel are presented. The patterns of hair cell orientation do not change with age. All sensory epithelia increase in area during growth of the eel. Examination of the hair cell population in macula utriculi show constant hair cell densities and increased hair cell population during development. Further, regional differences in hair cell densities and hair cell types are observed. The hair cells/axons ratio increases 3-fold from glass eel to silver eel stadium. Nerve stainings in silver eel reveal complex innervation patterns with large stubby fibres confined to restricted regions. Histograms of nerve fiber diameters show marked differences from glass eel to silver eel. Growth of sensory epithelia is discussed.     

Afferent Neurons of the Zebrafish Lateral Line Are Strict Selectors of Hair-Cell Orientation

Hair cells in the inner ear display a characteristic polarization of their apical stereocilia across the plane of the sensory epithelium. This planar orientation allows coherent transduction of mechanical stimuli because the axis of morphological polarity of the stereocilia corresponds to the direction of excitability of the hair cells. Neuromasts of the lateral line in fishes and amphibians form two intermingled populations of hair cells oriented at 180° relative to each other, however, creating a stimulus-polarity ambiguity. Therefore, it is unknown how these animals resolve the vectorial component of a mechanical stimulus. Using genetic mosaics and live imaging in transgenic zebrafish to visualize hair cells and neurons at single-cell resolution, we show that lateral-line afferents can recognize the planar polarization of hair cells. Each neuron forms synapses with hair cells of identical orientation to divide the neuromast into functional planar-polarity compartments. We also show that afferent neurons are strict selectors of polarity that can re-establish synapses with identically oriented targets during hair-cell regeneration. Our results provide the anatomical bases for the physiological models of signal-polarity resolution by the lateral line.     

Structural variation in the inner ears of four deep-sea elopomorph fishes

Deep-sea fishes have evolved in dark or dimly lit environments devoid of the visual cues available to shallow-water species. Because of the limited opportunity for visual scene analysis by deep-sea fishes, it is reasonable to hypothesize that the inner ears of at least some such species may have evolved structural adaptations to enhance hearing capabilities in lieu of vision. As an initial test of this hypothesis, scanning electron microscopy was used to examine the structure of the inner ears of four deep-sea elopomorph species inhabiting different depths: Synaphobranchus kaupii, Synaphobranchus bathybius, Polyacanthonotus challengeri, and Halosauropsis macrochir. The shape of the sensory epithelia and hair cell ciliary bundle orientation of the saccule, lagena, and utricle, the three otolithic organs associated with audition and vestibular function, are described. The saccules of all four species have a common, alternating ciliary bundle orientation pattern. In contrast, the lagena exhibits more interspecific diversity in shape and ciliary bundle orientation, suggesting that it has special adaptations in these species. The macula neglecta, a sensory epithelium of unknown function, is present in all four species.     

Differentiation of the inner ear sensory epithelia of Proteus anguinus (Urodela,amphibia)

The stages of differentiation of the inner ear sensory epithelia of the neotenous cave urodele, Proteus anguinus, was studied with light and electron microscopy. Comparative ultrastructural analysis among specimens of different sizes confirms that new sensory cells may be generated throughout life, particularly along the periphery of the saccular macula. The inner ear of Proteus contains at least four types of sensory cells that differ in their apical ciliary part. The lungs and air-filled buccal cavity may function as transducers of sound pressure in underwater conditions. Sound waves might be transmitted from the buccal cavity to the connected oval window. The very complex orientation of the sensory hair cells of the saccular macula and the large overlying saccular otoconial mass suggest that this macula facilitates orientation of Proteus in its underground aqueous habitat.     

STRUCTURE OF THE MACULA UTRICULI WITH SPECIAL REFERENCE TO DIRECTIONAL INTERPLAY OF SENSORY RESPONSES AS REVEALED BY MORPHOLOGICAL POLARIZATION

The anatomy of the labyrinth and the structure of the macula utriculi of the teleost fish (burbot) Lota vulgaris was studied by dissection, phase contrast, and electron microscopy. The innervating nerve fibers end at the bottom of the sensory cells where two types of nerve endings are found, granulated and non-granulated. The ultrastructure and organization of the sensory hair bundles are described, and the finding that the receptor cells are morphologically polarized by the presence of an asymmetrically located kinocilium in the sensory hair bundle is discussed in terms of directional sensitivity. The pattern of orientation of the hair cells in the macula utriculi was determined, revealing a complicated morphological polarization of the sensory epithelium. The findings suggest that the interplay of sensory responses is intimately related to the directional sensitivity of the receptor cells as revealed by their morphological polarization. The problem of efferent innervation is discussed, and it is concluded that the positional information signaled by the nerve fibers innervating the vestibular organs comprises an intricate pattern of interacting afferent and efferent impulses     

A scanning electron microscope study of the papilla basilaris of Gekko gecko

Summary The sensory hair cells of the ventral 2/3 of the papilla basilaris of Gekko gecko are divided into anterior (pre-axial) and posterior (post-axial) portions by a mid-axial gap or hiatus where there are no hair cells. There is no separation of the hair cells in the dorsal third of the papilla. There are three tectorial membrane modifications: an attached thickened membrane covering the pre-axial hair cells, sallets covering the post-axial hair cells, and an attached filamentous membrane covering the dorsal hair cells. The number of hair cells is greatest ventrally and decreases dorsally. There are approximately 2000 to 2100 hair cells. The kinocilia of the hair cells of the anterior halves of both the pre- and the post-axial vertical hair-cell rows are oriented posteriorly, while the kinocilia of the posterior halves are oriented anteriorly. The kinocilia of the hair cells of the dorsal third of the papilla are mostly oriented posteriorly. Thus, kinocilial orientation of the ventral 2/3 of the papilla is doubly bidirectional, and the dorsal 1/3, largely unidirectional.I would like to thank Ms. Maria Maglio for her skill in handling the technical aspects of the scanning electron microscopy as well as her artistry in achieving photographic excellence on the scope, David Akers for expert photographic assistance, and Wayne Emery for the drawings. Research sponsored by United States Public Health Service Grant NS-09231.