In vitro differentiation of mouse embryo statoacoustic ganglion and sensory epithelium

Culture media-based selection of endothelial cells, pericytes, and perivascular-resident macrophage-like melanocytes from the young mouse vestibular system

The vestibular blood-labyrinth barrier (BLB) is comprised of perivascular-resident macrophage-like melanocytes (PVM/Ms) and pericytes (PCs), in addition to endothelial cells (ECs) and basement membrane (BM), and bears strong resemblance to the cochlear BLB in the stria vascularis. Over the past few decades, in vitro cell-based models have been widely used in blood-brain barrier (BBB) and blood-retina barrier (BRB) research, and have proved to be powerful tools for studying cell-cell interactions in their respective organs. Study of both the vestibular and strial BLB has been limited by the unavailability of primary culture cells from these barriers. To better understand how barrier component cells interact in the vestibular system to control BLB function, we developed a novel culture medium-based method for obtaining EC, PC, and PVM/M primary cells from tiny explants of the semicircular canal, sacculus, utriculus, and ampullae tissue of young mouse ears at post-natal age 8-12 d. Each phenotype is grown in a specific culture medium which selectively supports the phenotype in a mixed population of vestibular cell types. The unwanted phenotypes do not survive passaging. The protocol does not require additional equipment or special enzyme treatment. The harvesting process takes less than 2 h. Primary cell types are generated within 7-10 d. The primary culture ECs, PCs, and PVM/M shave consistent phenotypes more than 90% pure after two passages (∼ 3 weeks). The highly purified primary cell lines can be used for studying cell-cell interactions, barrier permeability, and angiogenesis.

Hair cell development in vivo and in vitro: analysis by using a monoclonal antibody specific to hair cells in the chick inner ear

The purpose of this study was to establish a hair cell-specific marker and a convenient explant culture system for developing chick otocysts to facilitate in vivo and in vitro studies focusing on hair cell genesis in the inner ear. To achieve this, a hair cell-specific monoclonal antibody, 2A7, was generated by immunizing chick inner ear tissues to a mouse. Through the use of immunofluorescence and immunoelectron microscopy, it was shown that 2A7 immunoreactivity (2A7-IR) was primarily restricted to the apical region of inner ear hair cells, including stereocilia, kinocilia, apical membrane amongst the extending cilia, and superficial layer of the cuticular plate. Although the 2A7 antibody immunolabeled basically all of the hair cells in the posthatch chick inner ear, two different patterns of 2A7-IR were observed; hair cells located in the striolar region of the utricular macula, which consist of two distinct cell types identifiable on the basis of the type of nerve ending, Type I and II hair cells, showed labeling restricted to the basal end of the hair bundles. On the other hand, hair cells in the extrastriolar region, which are exclusively of Type II, showed labeling extending over virtually the entire length of the bundles. These findings raised the possibility that chick vestibular Type II hair cells, characterized by their bouton-type afferent nerve endings, can be divided into two subpopulations. Analysis of developing inner ear by using the 2A7 antibody revealed that this antibody also recognizes newly differentiated immature hair cells. Thus, the 2A7 antibody is able to recognize both immature and mature hair cells in vivo. The developmental potential of embryonic otocysts in vitro was then assessed by using explant cultures as a model. In this study, conventional otocyst explant cultures were modified by placing the tissues on floating polycarbonate filters on culture media, thereby allowing the easy manipulation of explants. In these cultures, 2A7-positive hair cells were differentiated from dividing precursor cells in vitro on the same schedule as in vivo. Furthermore, it was found that hair cells with both types of 2A7-IR were generated in culture as in vivo, indicating that a maturational process of hair cells also occurred. All these results as presented here suggest that the 2A7 monoclonal antibody as a hair cell-specific marker together with the culture system could be a potential tool in analysis of mechanisms underlying hair cell development.

Effect of gravity on vestibular neural development

The timing, molecular basis, and morphophysiological and behavioral consequences of the interaction between external environment and the internal genetic pool that shapes the nervous system over a lifetime remain important questions in basic neuroscientific research. Space station offers the opportunity to study this interaction over several life cycles in a variety of organisms. This short review considers past work in altered gravity, particularly on the vestibular system, as the basis for proposing future research on space station, and discusses the equipment necessary to achieve goals. It is stressed that, in keeping with the international investment being made in this research endeavor, both the questions asked and the technologies to be developed should be bold. Advantage must be taken of this unique research environment to expand the frontiers of neuroscience.

Postnatal development of type I and type II hair cells in the mouse utricle: acquisition of voltage-gated conductances and differentiated morphology

The type I and type II hair cells of mature amniote vestibular organs have been classified according to their afferent nerve terminals: calyx and bouton, respectively. Mature type I and type II cells also have different complements of voltage-gated channels. Type I cells alone express a delayed rectifier, gK,L, that is activated at resting potential. We report that in mouse utricles this electrophysiological differentiation occurs during the first postnatal week. Whole-cell currents were recorded from hair cells in denervated organotypic cultures and in acutely excised epithelia. From postnatal day 1 (P1) to P3, most hair cells expressed a delayed rectifier that activated positive to resting potential and a fast inward rectifier, gK1. Between P4 and P8, many cells acquired the type I-specific conductance gK,L and/or a slow inward rectifier, gh. By P8, the percentages of cells expressing gK,L and gh were at mature levels. To investigate whether the electrophysiological differentiation correlated with morphological changes, we fixed utricles at different times between P0 and P28. Ultrastructural criteria were developed to classify cells when calyces were not present, as in cultures and neonatal organs. The morphological and electrophysiological differentiation followed different time courses, converging by P28. At P0, when no hair cells expressed gK,L, 33% were classified as type I by ultrastructural criteria. By P28, approximately 60% of hair cells in acute preparations received calyx terminals and expressed gK,L. Data from the denervated cultures showed that neither electrophysiological nor morphological differentiation depended on ongoing innervation.

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.

Histochemical and scanning electron microscopic studies of supernumerary hair cells in embryonic rat cochlea in vitro

In the embryonic organ of Corti supernumerary hair cells were observed when developed in organotypic cultures. Hair cells ranging in up to two rows of inner hair cells (IHCs) and up to nine rows of outer hair cells (OHCs), were observed by phalloidin histochemistry. The total number of hair cells may double in some explanted cochleae compared to control ones. Cuticular plates of hair cells displayed an actin-free zone corresponding to the kinocilium location, differently located and indicating different degrees of differentiation and maturation. Moreover, some hair cells had a small apical surface area and a centrally located kinocilium, revealing immaturity. Under scanning electron microscopy, stereocilia appeared to differentiate normally, as compared to the in vivo development. The staircase pattern of the stereociliary bundles was reached on most of the hair cells with a 'V' shape on the OHCs and hemispherical one on the IHCs. Hair cell polarity was not homogeneous along the length of the tissue. Organs of Corti explanted at birth developed a weaker number of supernumerary hair cells showing a decrease of supernumerary hair cells with the developmental stage of the explant. These results provide evidence for supernumerary hair cells in the mammalian cochlea in culture, without loss or injury to preexisting hair cells.

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.

Neurotrophins and the development of cochlear innervation

The rapid progress in the past few years concerning neurotrophic factor research, has greatly stimulated advances in developmental neurobiology of hearing. We have summarized evidence that neurotrophins are expressed by auditory sensory epithelia during the time at which ganglion cells with neurotrophin receptors send their processes to these epithelia. Recent findings have led to the identification of BDNF and NT3 as responsible substances. Since no NGF mRNA nor the NGF high affinity receptor component trkA mRNA were detectable during the development of cochlear structures, this factor is not likely to be an important neurotrophin at this level. By their biological activity, neurotrophins could be responsible for chemotrophic, differentiation, survival, and maintenance functions at the afferent as well as at the efferent level of the inner ear development.

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.

Spatiotemporal development of cochlear innervation and hair cell differentiation in the rat

The apical cytoskeleton of cochlear hair cells is largely comprised of actin microfilaments and actin-associated proteins, of which fodrin is one of the most prominent. We studied the development of this mechanosensory apical portion of cochlear hair cells of the rat by fluorescence microscopy using rhodamine conjugated phalloidin to detect F-actin and an antibody against alpha-fodrin. An antibody against the 160 kDa neurofilament polypeptide was used for tracing nerve fibers. The first sign of differentiation of the mechanosensory region, actin-containing stereocilia, was observed on the 19th gestational day in the inner hair cells of the basal coil. The appearance of expression of cytoskeletal actin in the cochlear hair cells proceeded gradientally from basal to apical coil and from inner to outer hair cells. Corresponding maturation sequences were observed in the development of fodrin immunoreactivity in the cuticular plates, but the first evidence of this reactivity was found one day later than the appearance of stereocilia in the hair cells at the same location. Also the penetration of neurofilament-positive neurites into the sensory epithelium followed the same kind of longitudinal and radial maturation gradients throughout the cochlea. Fibers were revealed beneath the sensory cells shortly before the first appearance of differentiation of their mechanosensory region. The results suggest that ingrowing nerve fibers may influence the timing of the apical cytoskeleton differentiation in cochlear hair cells or that both these processes could be controlled by the same external signals that are gradientally expressed throughout the cochlea.

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.

Afferent nerve ending development and synaptogenesis in the vestibular epithelium of human fetuses

Synaptogenesis has been investigated in the vestibular epithelium of human fetuses aged from 7 to 14 weeks of gestation. The arrival of afferent nerve endings in the epithelium preceded hair cell differentiation. Synaptogenesis involved the proliferation of synaptic bodies. It was concomitant with the formation of contacts between microtubules and the presynaptic membrane, and the presence of numerous coated vesicles within the presynaptic area.