Neuron-specific enolase immunoreactivity in the developing mouse cochlea

Distribution of alpha-amino-3-hydroxy-5-methyl-4 isoazolepropionic acid and N-methyl-D-aspartate receptor subunits in the vestibular and spiral ganglia of the mouse during early development

We investigated the distribution of the glutamate receptor subunits, alpha-amino-3-hydroxy-5-methyl-4 isoazolepropionic acid (AMPA) GluR2 and GluR2/R3, and N-methyl-D-aspartate (NMDA) NR1, and the timing of their appearance during early development of the mouse vestibular and spiral ganglia. NMDA NR1 was the first to be expressed, in the statoacoustic ganglion neurons on E11. GluR2/R3 immunoreactivity was detected in these neurons on E12. This signal probably corresponded exclusively to GluR3, as no signal was obtained for GluR2 alone at this stage. The appearance of these proteins began much earlier than previously reported. GluR2 staining was observed later, on E14 in the vestibular neurons and on E17 in the spiral neurons. The sequence in which these three glutamate receptors appeared suggested possible differences in their roles in the establishment of neuronal circuitry in the inner ear sensory epithelia. The production of NR1 and GluR2/R3 began during the early period of neuron growth and fasciculation. GluR2 appeared later and its expression paralleled synaptogenesis in the vestibular sensory epithelia and in the organ of Corti.

Cochlear inner hair cells exist transiently in the fetal Bronx Waltzer (bv/bv) mouse

In the cochlea of the adult Bronx waltzer (bv/bv) mouse, the majority of inner hair cells are missing or deformed. As a result, Bronx waltzer mice are severely hearing impaired or deaf. Previous studies determined that most inner hair cells in these mice are missing by the time of birth, but no studies have resolved whether the missing inner hair cells ever exist in the mutant cochlea. The present study used light and electron microscopy to locate inner hair cells in the mutant mouse before birth. Most, and possibly all, inner hair cells exist in the embryonic day (E) 17 mouse. The shapes of the cells vary from normal and elongated in the youngest animals, to round and protruding through the reticular lamina a few days later. The density of sensory cells in the inner hair cell region (inner hair cells/millimeter) decreases in the basal turn between E17 and birth, and in the apical turn between birth and the third postnatal day. The initial presence of the full complement of inner hair cells, taken together with the temporospatial pattern of degeneration, suggests that the cause of inner hair cell death in the Bronx waltzer mouse is related to a differentiation event subsequent to cell birth.

Development of calretinin immunoreactivity in the mouse inner ear

Calretinin is a calcium-binding protein of the EF-hand family. It has been previously identified in particular cell types of adult guinea pig, rat, and chinchilla inner ear. Development of calretinin immunoreactivity in the mouse inner ear was investigated from embryonic day 13 (E13) to the adult stage. In the adult mouse vestibule, calretinin immunoreactivity was present in the same structures as described for the rat and guinea pig: the population of afferent fibers forming calyx units and a small number of ganglion neurons. The earliest immunoreactivity was found at E17 in vestibular hair cells (VHCs), then, at E19, in afferent fibers entering the sensory epithelia and in rare ganglion neurons. At postnatal day 4 (P4), a few vestibular nerve fibers and ganglion neurons were reactive. From this stage until P14, immunoreactivity developed in the calyx units and disappeared from VHCs. At P14, immunostaining was adult-like. In the adult mouse cochlea, immunoreactivity was present in the same cell populations as described in the rat: the inner hair cells (IHCs) and most of Corti's ganglion neurons. Calretinin immunoreactivity appeared at E19-P0 in IHCs and ganglion neurons of the basal turn. At P1, outer hair cells (OHCs) of the basal turn were positive. Calretinin immunoreactivity then appeared in IHCs, OHCs, and ganglion neurons of the medial turn, then of the apical turn. At P4, all IHCs and OHCs and most of the ganglion neurons were immunostained. Immunoreactivity gradually disappeared from the OHCs starting at P10 and, at P22, only IHCs and ganglion neurons were positive. The sequences of appearance of calretinin were specific to each cell type of the inner ear and paralleled their respective maturation. Calretinin was transiently expressed in VHCs and OHCs.

Characterization of different neuron populations in mouse statoacoustic ganglion cultures

Statoacoustic ganglion (SAG) cells were grown in primary culture and the appearance of different neuronal phenotypes was investigated. Analysis criteria were shape, size and staining for the immunocytochemical markers: neurofilament proteins (NF-200 kDa), neuron-specific enolase (NSE), calretinin, a calcium-binding protein and substance P, a neurotransmitter. Cultures were prepared from dissociated SAG cells of 13 gestation-day-old mouse embryos. Neurons were identified and counted after 7 days in vitro. At this stage, neurons were organized in small clusters forming an extensive network of neurites grown on a layer of fibroblasts and glia. Most neurons identified by NF or NSE immunoreactivity showed a typical adult-like bipolar profile. The diameters of the neurons were between 5.62 and 17.00 microns and displayed a normal distribution (mean: 10.6 microns). Two distinct subpopulations were identified by the expression of calretinin and substance P. Calretinin-immunoreactive neurons were large and very rare and had a mean diameter of 11.3 microns; the distribution of substance P was more extensive than that of calretinin and identified a population of small neurons with a mean diameter of 8.9 microns. The distributions of these two markers in SAG cultures were consistent with in vivo results. In conclusion, dissociated SAG cell cultures appear to be a suitable model for analyzing the development of the immunocytochemical and functional characteristics of the neurons of this inner ear ganglion.

Protein gene product 9.5 in the developing cochlea of the rat: cellular distribution and relation to the cochlear cytoskeleton

Protein gene product 9.5 was immunolocalized in the adult and early postnatal (P2-P15) rat cochlea, and its distribution compared with a 200 kDa highly phosphorylated neurofilament subunit (neurofilament 200) and alpha-tubulin. In the adult, Protein gene product 9.5 was expressed exclusively in cochlear nerve fibres and ganglion cells, a small percentage of these (Type II ganglion cells and olivocochlear bundle fibres) being intensely positive for both protein gene product and neurofilament 200. In postnatal development, pillar and Deiters' cells were at first (P2-P15) strongly positive for protein gene product 9.5, and hair cells moderately so. At P2, all nerve fibres and ganglion cells showed co-expression of protein gene product 9.5 and neurofilament 200, but at later stages, the subset of intensely co-labelled neurons appeared, nerve fibres at P7 onwards and ganglion cells from P12. There was no overt correlation between the onset of protein gene product 9.5 and alpha-tubulin expression in any cochlear component. Protein gene product 9.5 expression in ganglion cells was at first (P2 and P7) mainly nuclear, and later also cytoplasmic. It is concluded that there is a clear correlation of high levels of protein gene product 9.5 and neurofilament protein expression, and that protein gene product 9.5 is expressed in some non-neuronal cells of the cochlea during its early development, persisting until after hearing has commenced.

Neuronal influence on B and H human blood-group antigen expression in rat cochlear cultures

The presence of B and H human blood-group antigens was analyzed by immunocytochemistry in rat cochleas developing either in vivo or in vitro. Developing animals, on embryonic day (E) 18 and postnatal day (P) 3, were used for in vivo studies. For in vitro studies, cochleas were removed at E18 and placed for 3 or 8 days in organotypic culture either directly or after partial spiral ganglion removal. Results from epithelial regions from cochleas developing in vivo were similar to those observed in corresponding areas of direct organotypic cultures where the innervation from spiral ganglion neurons was present. Antibodies to human blood group antigens, anti B and anti AB, selectively labeled hair cells. The intensity of labeling was weak at E18, but increased at P3 in vivo or after 3-8 days in organotypic culture. Anti H antibodies showed weak labeling of the apical surface of hair cells and other epithelial cells at E18; this labeling also increased at P3 or after 3-8 days in culture. In contrast, the non-innervated regions from organotypic cultures, where ganglia were partially removed, exhibited an epithelial disorganization and no hair cell labeling with any of the antibodies studied. The present findings suggest that human blood-group antigen expression on developing cochlear hair cells of rats may be related to afferent nerve fiber influence.

Patterns of hair cell survival and innervation in the cochlea of the bronx waltzer mouse

A massive loss of inner hair cells typifies the cochleae of Bronx waltzer mutant mice. We have characterized the surviving inner hair cells and their modified innervation by immunocytochemistry using antibodies against neuron-specific enolase, with additional stains for neural cell adhesion molecule and neurofilaments, and by electron microscopy. The surviving inner hair cells vary in size, neuron-specific enolase content and innervation. All neuron-specific enolase-positive cells are innervated by neuron-specific enolase-positive endings. There is apparent correspondence between the neuron-specific enolase immunoreactivity of sensory cells and their innervation. Well-stained cells are richly innervated (and large) while lightly stained cells received fewer nerve endings. Neuron-specific enolase-negative inner hair cells innervated either by neuron-specific enolase-positive or -negative nerve endings are very rare. Ultrastructurally, the surviving inner hair cells vary from those of a normal morphological appearance to underdeveloped or vacuolated. Most of the apparently normal inner hair cells are associated with few nerve endings; instead nerve growth cones are abundant in the adjacent inner spiral sulcus epithelium. Cells forming ribbon synapses with afferent endings are rare. The contingent of efferent endings in the inner spiral bundle depends on the presence of afferent endings. The absence of inner hair cells and the uneven distribution of nerve endings on the surviving cells results in the disruption of normal innervation patterns, especially in the thinning out or discontinuation of the inner spiral bundle and an uneven distribution of tunnel fibres. We infer that the sprouting of nerve endings and their convergence on a selected population of the surviving inner hair cells represents a compensatory regenerative phenomenon in response to the loss and the genetic defect of the remaining inner hair cells.

Protein gene product 9.5 expression in the human fetal cochlea

The distribution of protein gene product (PGP) 9.5 was analyzed in the human fetal cochlea using the indirect immunofluorescence method. In the 12- and 14-week-old human fetuses, the cells of the greater epithelial ridge and the lesser epithelial ridge were overall labelled with PGP 9.5, while the stria vascularis and the Reissner's membrane did not exhibit any staining. Spiral ganglion cells and cochlear nerve fibers were labelled with PGP 9.5 and PGP 9.5-positive nerve fibers made contact with the basement membrane of the Corti primordium in the 12-week-old human fetus. These results suggest that PGP 9.5 might be used as a histological marker of maturation and innervation in the human cochlea.

Temporal pattern of innervation in the developing mouse inner ear: an immunocytochemical study of a 66-kD subunit of mammalian neurofilaments

We have examined the expression of a 66-kD neurofilament protein (NF-66) in the developing inner ear. Mouse embryos, fetuses, and neonates were fixed in Methacarn, embedded in paraffin, and sectioned. A polyclonal antiserum raised specifically to NF-66 and unreactive to NF-L, -M, -H, and peripherin was used for immunocytochemical staining. NF-66 immunostaining was first detectable in the rhombencephalon at embryonic day (E) 9.5. Immunoreactivity was first detected in the statoacoustic ganglion (SAG) early on E10.5. By late E10.5, the first SAG axons were detectable within the intraepithelial spaces of the otocyst. At E12, NF-66 positivity was detectable in neurites that projected into areas of presumptive vestibular sensory epithelium. Neurites projecting into the presumptive acoustic sensory epithelium were negative. However, at E13, the projections from both the vestibular and the acoustic ganglion (i.e, cochlear duct) were both NF-66 positive. In the cell bodies, NF-66 expression appeared earlier in the vestibular than in the auditory neurons. By E16, neuronal somas in both ganglia were NF-66 positive.

The development of laminar staining for neuron-specific enolase in the rat somatosensory cortex

The expression of the enzyme neuron-specific enolase (NSE) in the central nervous system (CNS) has been used as a developmental marker based on observations that it is expressed shortly after the arrival of afferent inputs. The immunostaining pattern of NSE was examined in the laminae of the somatosensory cortex of the rat and the relationship of this staining pattern with previous data on the timing of afferent and efferent arrival was determined. Male rat pups were sacrificed on postnatal days 1 (24 h after birth), 3, 5, 8, 10, 12, 15 and 20, and as an adult (over 90 days of age). Sections were stained with an anti-NSE antibody using the avidin-biotin immunocytochemical method. Sections from day 1 animals revealed stained cells in the subplate layer and cortical plate, presumably in cells destined to form layers VI and V. By day 8 there was staining in layers II, III, V and VI, the same layers that exhibited staining in the adult rat. This appears consistent with the arrival of afferents and efferents which is completed by approximately postnatal day 7. On day 10, there was a change in the staining pattern: cell staining in layer VI was decreased and then increased gradually up to adult levels by day 20. A stable pattern of NSE staining was not observed previous to day 20. These results suggest that changes in NSE expression following the initial arrival of afferents may relate to maturation of the neurons.

Appearance and distribution of neuron-specific enolase and calbindin (CaBP 28 kDa) in the developing human inner ear

The onset and development of neuron-specific enolase (NSE) and calbindin immunoreactivities were studied in the inner ear of human fetuses aged from 6-7 to 14 weeks of gestation. NSE occurred very early in ganglion neurons. Its appearance in vestibular sensory cells at 8 weeks coincided with the formation of the first afferent synapses, and showed an apex/base gradient in the cristae. Calbindin was found in vestibular ganglion neurons at 6-7 weeks and in the cochlear ganglion neurons at 8-9 weeks. Vestibular sensory cells and the whole ventral wall of the cochlear duct were stained from 8-9 weeks. At 14 weeks, calbindin staining occurred only in the sensory cells of the cochlear neuroepithelium. Non-neuronal secretory structures, i.e. Kölliker's organ and some cells of the transitional zone of the utricle, were also reactive. Staining appeared in Kölliker's organ with a base to apex gradient and disappeared from it with an internal to external gradient. Calbindin appeared in vestibular sensory cells later than NSE staining, synapse formation and sensory hair bundle differentiation. By contrast in the cochlea, calbindin staining appeared in the neuroepithelium before sensory cell differentiation, but remained only in the hair cells after they had differentiated and been contacted by the afferent fibers.

Calbindin (CaBP 28 kDa) appearance and distribution during development of the mouse inner ear

Previous reports of the distribution of calbindin, a 28 kDa vitamin D-induced calcium-binding protein, in the mammalian peripheral vestibular system postulated that this protein was involved in the calcium-dependent mechanisms occurring in the hair cells and ganglion cells. In this study, we examined the possibility of a relationship between the presence of calbindin and neurotransmission by comparing calbindin appearance in the inner ear to the sequence of synaptogenesis. Calbindin distribution was studied by immunocytochemistry, in the developing mouse inner ear from gestational day 12 to postnatal day 40. During the early development, calbindin was localized in non-neuronal structures: Kolliker's organ, spiral limbus and crista supporting cells; and in cochlear and vestibular ganglion neurons and sensory cells. At later stages and in the adult, no reactivity was observed in the non-neuronal cell populations and only certain sensory and nerve cells remained stained: inner hair cells, outer hair cells, vestibular hair cells of the apex of the cristae and of the striola in the maculae, all Corti's ganglion neurons and some vestibular ganglion neurons. The sequence of appearance of calbindin immunoreactivity in the sensory and nerve cells was not completely parallel to the maturation sequence of the inner ear, especially synaptogenesis. The dual distribution of calbindin during development and its expression in specific sensory and nerve cells opens new perspectives on its role in the inner ear.

Neuron-specific enolase during the development of the organ of Corti

NSE immunoreactivity has been studied in the organ of Corti of the developing mouse from birth to 21 days. NSE immunohistochemical stain is observed in spiral ganglion cells, in nerve fibers and in nerve endings of inner and outer hair cells, and in both populations of sensory cells. Spiral ganglion cells in lower and central parts of the ganglion stain for NSE at birth, but all nerve cells are stained by day 4. Radial and spiral fibers and the endings on inner hair cells stain at birth, but the nerve endings on outer hair cells develop NSE between days 3 and 6. The inner and outer hair cells are NSE-positive at day 2 but the NSE immunoreactivity in the outer hair cells decreases at the end of the second week until the cells become negative. The NSE stain in the neuronal pathways of the inner and outer hair cell regions increases for about 19 days, showing a predominant accumulation in neuronal endings. The data suggest that the development of NSE expression in the organ of Corti reflects the nascence and maturation of the synaptic contacts. Spiral neurons, their fibers and endings as well as inner and outer hair cells express NSE in the isolated organ of Corti in culture. Variability of stain among the different cell populations indicates a role of local factors in the regulation of NSE expression.

Appearance and development of neuron-specific enolase immunoreactivity in organotypic cultures of mouse embryo otocysts

The appearance of neuron-specific enolase (NSE) immunoreactivity was studied in sensory and vestibular ganglion cells during the development of mouse embryo otocysts grown in vitro from the 13th gestation day. NSE appeared sequentially in the ganglion and sensory cell populations of the inner ear with a pattern that paralleled their successive maturation. Comparison with NSE immunoreactivity profile during in vivo development shows that NSE appears earlier during organotypic in vitro maturation.

Immunohistochemical identification of neuron-specific enolase and calbindin in the vestibular receptors of human fetuses

Immunohistochemical techniques were used to identify neuron-specific enolase (NSE) and calbindin in the vestibular receptors and ganglia of human fetuses at 10 weeks of gestation. NSE was found in vestibular ganglion cells and in a few sensory cells. The pattern of immunoreactivity in the sensory epithelia was characteristic of the appearance of NSE in these structures. Calbindin was found in vestibular ganglion cells and sensory cells which displayed a strong immunoreactivity. These findings are discussed with regard to synaptogenesis and they indicate that the vestibular receptors show biochemical signs of maturation consistent with the possibility of synaptic activity.

Factors affecting the onset of inner ear function

The developing inner ear receptors have a very significant influence on the onset of stato-acoustic function and on its evolution. The factors which prevent the stato-acoustic system from functioning are called 'the limiting factors'. At present, it is possible to postulate that these factors are restricted to the inner ear cells and related structures. At least four places are particularly relevant for the onset of function: (1) connections of the apical part of hair cell with the tectorial membrane; (2) the internal structure of hair cell; (3) connections between the base of the hair cell and nerve fibers; (4) the ganglion cell with its processes. Special emphasis is devoted to the apical part of the inner hair cell and its connections to the tectorial membrane which are considered as very important for the onset of the cochlear function. For the labyrinth, it is technically difficult to determine precisely the onset of function because of its early prenatal onset. Nevertheless, it is postulated that the limiting factors for the onset of function are also related to certain components of hair cells.

Expression of intermediate filaments and actin in the embryonic human inner ear

The immunoreactivity for intermediate filaments (IF) and F-actin was documented in serially cryosectioned human inner ears aged 14-19 gestational weeks. An individual immunoreactivity for IF was documented for different cell types in both the cochlear and vestibular parts of the labyrinth. All secretory epithelia showed a similar expression of the cytoskeleton. In outer hair cells, immunoreactivity for vimentin was documented, but not for other IF types. The cytoskeletal composition is similar in the tectorial membrane and in supporting cells of the great epithelial ridge. Strong immunoreactivity for F-actin occurs close to the surface of all vestibular organs and Kölliker's organ, but not to the same extent in other epithelia lining the endolymphatic space.