Retardation of cochlear maturation and impaired hair cell function caused by deletion of all known thyroid hormone receptors.

The deafness caused by early onset hypothyroidism indicates that thyroid hormone is essential for the development of hearing. We investigated the underlying roles of the TRalpha1 and TRbeta thyroid hormone receptors in the auditory system using receptor-deficient mice. TRalpha1 and TRbeta, which act as hormone-activated transcription factors, are encoded by the Thra and Thrb genes, respectively, and both are expressed in the developing cochlea. TRbeta is required for hearing because TRbeta-deficient (Thrb(tm1/tm1)) mice have a defective auditory-evoked brainstem response and retarded expression of a potassium current (I(K,f)) in the cochlear inner hair cells. Here, we show that although TRalpha1 is individually dispensable, TRalpha1 and TRbeta synergistically control an extended array of functions in postnatal cochlear development. Compared with Thrb(tm1/tm1) mice, the deletion of all TRs in Thra(tm1/tm1)Thrb(tm1/tm1) mice produces exacerbated and novel phenotypes, including delayed differentiation of the sensory epithelium, malformation of the tectorial membrane, impairment of electromechanical transduction in outer hair cells, and a low endocochlear potential. The induction of I(K,f) in inner hair cells was not markedly more retarded than in Thrb(tm1/tm1) mice, suggesting that this feature of hair cell maturation is primarily TRbeta-dependent. These results indicate that distinct pathways mediated by TRbeta alone or by TRbeta and TRalpha1 together facilitate control over an extended range of functions during the maturation of the cochlea.

A mutation in the Lunatic fringe gene suppresses the effects of a Jagged2 mutation on inner hair cell development in the cochlea.

Recent studies have demonstrated that the Notch signaling pathway regulates the differentiation of sensory hair cells in the vertebrate inner ear [1] [2] [3] [4] [5] [6] [7] [8] [9]. We have shown previously that in mice homozygous for a targeted null mutation of the Jagged2 (Jag2) gene, which encodes a Notch ligand, supernumerary hair cells differentiate in the cochlea of the inner ear [7]. Other components of the Notch pathway, including the Lunatic fringe (Lfng) gene, are also expressed during differentiation of the inner ear in mice [6] [7] [8] [9] [10]. In contrast to the Jag2 gene, which is expressed in hair cells, the Lfng gene is expressed in non-sensory supporting cells in the mouse cochlea [10]. Here we demonstrate that a mutation in the Lfng gene partially suppresses the effects of the Jag2 mutation on hair cell development. In mice homozygous for targeted mutations of both Jag2 and Lfng, the generation of supernumerary hair cells in the inner hair cell row is suppressed, while supernumerary hair cells in the outer hair cell rows are unaffected. We also demonstrate that supernumerary hair cells are generated in mice heterozygous for a Notch1 mutation. We suggest a model for the action of the Notch signaling pathway in regulating hair cell differentiation in the cochlear sensory epithelium.

Type 2 iodothyronine deiodinase expression in the cochlea before the onset of hearing.

Thyroid hormone signaling during a postnatal period in the mouse is essential for cochlear development and the subsequent onset of hearing. To study the control of this temporal dependency, we investigated the role of iodothyronine deiodinases, which in target tissues convert the prohormone thyroxine into triiodothyronine (T3), the active ligand for the thyroid hormone receptor (TR). Type 2 5'-deiodinase (D2) activity rose dramatically in the mouse cochlea to peak around postnatal day 7 (P7), after which activity declined by P10. This activity peak a few days before the onset of hearing suggests a role for D2 in amplifying local T3 levels at a critical stage of cochlear development. A mouse cochlear D2 cDNA was isolated and demonstrated near identity to rat D2. In situ hybridization localized D2 mRNA in periosteal connective tissue in the modiolus, the cochlear outer capsule and the septal divisions between the turns of the cochlea. Surprisingly, D2 expression in these regions that give rise to the bony labyrinth was complementary to TR expression in the sensory epithelium. Thus, the connective tissue may control deiodination of thyroxine and release of T3 to confer a paracrine-like control of TR activation. These results suggest that temporal and spatial control of ligand availability conferred by D2 provides an unexpectedly important level of regulation of the TR pathways required for cochlear maturation.

Expression of Math1 and HES5 in the cochleae of wildtype and Jag2 mutant mice.

The sensory epithelium within the mammalian cochlea (the organ of Corti) is a strictly ordered cellular array consisting of sensory hair cells and nonsensory supporting cells. Previous research has demonstrated that Notch-mediated lateral inhibition plays a key role in the determination of cell types within this array. Specificallly, genetic deletion of the Notch ligand, Jagged2, results in a significant increase in the number of hair cells that develop within the sensory epithelium, presumably as a result of a decrease in Notch activation. In contrast, the downstream mediators and targets of the Notch pathway in the inner ear have not been determined but they may include genes encoding the proneural gene Math1 as well as the HES family of inhibitory bHLH proteins. To determine the potential roles of these genes in cochlear development, in situ hybridization for Math1 and HES5 was performed on the cochleae of wild-type vs. Jagged2 mutants (Jag2deltaDSL). Results in wild-type cochleae show that expression of Math1 transcripts in the duct begins on E13 and ultimately becomes restricted to hair cells in the sensory epithelium. In contrast, expression of HES5 begins on E15 and becomes restricted to supporting cells in the epithelium. Results in Jag2 mutant cochleae suggest that Math1 transcripts are ultimately maintained in a larger number of cells as compared with wild-type, while transcripts for HES5 are dramatically reduced throughout the epithelium. These results are consistent with the hypothesis that activation of Notch via Jagged2 acts to inhibit expression of Math1 in cochlear progenitor cells, possibly through the activity of HES5.

Retinoic acid signaling is necessary for the development of the organ of Corti.

The cellular mosaic of the mammalian organ of Corti represents one of the most highly ordered structures in any vertebrate system. A single row of inner hair cells and three or four rows of outer hair cells extend along the basal-to-apical axis of the cochlea. The factors that play a role in the development of specific cell types within the cochlea are largely unknown; however, the results of previous studies have strongly suggested that retinoic acid plays a role in the development of cells as hair cells. To determine whether cochlear progenitor cells can respond directly to retinoic acid, the expression patterns for each of the RAR and RXR receptors within the embryonic cochlear duct were determined by in situ hybridization. Results indicate that RARalpha, RXRalpha, and RXRgamma are initially expressed throughout the cochlear duct. As development continues, the expression of each receptor becomes more intense in cells that will develop as hair cells. At the same time, receptor expression is down-regulated in cells that will develop as nonsensory cell types. To determine the effects of retinoic acid signaling during the development of the organ of Corti, activation of retinoid receptors was blocked in cultures of the embryonic cochlea through receptor-specific antagonism or inhibition of retinoic acid synthesis. Results indicate that inhibition of retinoic acid signaling induces a significant decrease in the number of cells that develop as hair cells and a disruption in the development of the organ of Corti. These results demonstrate that cells within the developing cochlea can respond to retinoic acid and that signaling by retinoic acid is necessary for the normal development of the organ of Corti.

Retinoic acid promotes rod photoreceptor differentiation in rat retina in vivo.

Previous studies have indicated that retinoic acid (RA) promotes rod photoreceptor differentiation in dissociated cultures of rat retina and in zebrafish embryos. To determine whether RA will have the same affect in the mammalian retina in vivo, pregnant rats were given single i.p. injections of RA on the 18th and 20th days of gestation, and the retinas of the pups were analyzed for rods. HPLC showed that i.p. injections of RA substantially increased levels of retinal RA in the embryos. Embryonic exposure to RA caused an increase in the number of cells that differentiated as rod photoreceptors. There was a comparable decrease in the number of cells that differentiated as amacrine cells. These results demonstrate that RA promotes the differentiation of rods in vivo and further support the hypothesis that differentiation of rods is normally controlled partly by the RA concentration in the developing retina or RPE.

Notch signalling pathway mediates hair cell development in mammalian cochlea.

The mammalian cochlea contains an invariant mosaic of sensory hair cells and non-sensory supporting cells reminiscent of invertebrate structures such as the compound eye in Drosophila melanogaster. The sensory epithelium in the mammalian cochlea (the organ of Corti) contains four rows of mechanosensory hair cells: a single row of inner hair cells and three rows of outer hair cells. Each hair cell is separated from the next by an interceding supporting cell, forming an invariant and alternating mosaic that extends the length of the cochlear duct. Previous results suggest that determination of cell fates in the cochlear mosaic occurs via inhibitory interactions between adjacent progenitor cells (lateral inhibition). Cells populating the cochlear epithelium appear to constitute a developmental equivalence group in which developing hair cells suppress differentiation in their immediate neighbours through lateral inhibition. These interactions may be mediated through the Notch signalling pathway, a molecular mechanism that is involved in the determination of a variety of cell fates. Here we show that genes encoding the receptor protein Notch1 and its ligand, Jagged 2, are expressed in alternating cell types in the developing sensory epithelium. In addition, genetic deletion of Jag2 results in a significant increase in sensory hair cells, presumably as a result of a decrease in Notch activation. These results provide direct evidence for Notch-mediated lateral inhibition in a mammalian system and support a role for Notch in the development of the cochlear mosaic.

Expression of proneural and neurogenic genes in the embryonic mammalian vestibular system.

One of the most striking aspects of all auditory and vestibular sensory epithelia is the mosaic pattern of hair cells and supporting cells. The factors that are required for the development of this mosaic have not been determined, however the results of recent studies have demonstrated that components of the neurogenic (Notch) signaling pathway are expressed in the developing inner ears of a number of different vertebrate species. To examine whether this signaling pathway may play a similar role in the development of the hair cell mosaic in the mammalian vestibular system, the expression patterns of proneural (Math1) and neurogenic (Notch1, Jagged2, HES5) genes were examined in the developing mouse inner ear. Results indicate that Notch1 is initially expressed throughout the developing inner ear and becomes restricted to non-sensory cells within the developing sensory epithelia. In contrast, initial expression of Math1 and Jagged2 is localized to the developing sensory epithelia and ultimately becomes restricted to hair cells. Interestingly, transcripts for HES5, a target of Notch activation, are expressed in the developing cristae but not in the saccule or utricle. These results are consistent with the hypothesis that formation of the hair cell mosaic is regulated through the neurogenic pathway. However the differential expression of HES5 within the ear indicates that the downstream targets of Notch1 activation are not consistent across all of the sensory epithelia and suggests that the effects of activation of Notch1 in the saccule and utricle must be regulated through alternate target genes.

Cellular commitment and differentiation in the cochlea: potential advances using gene transfer.

The development of individual cells as hair cells and supporting cells is a key step during the embryonic formation of the auditory system. However, at present the factors that play a role in the commitment and differentiation of cells as hair cells and supporting cells have not been identified. Recent advances in molecular biological techniques have led to the identification of candidate genes that may be involved in hair cell and supporting cell development, however it has been difficult to determine the specific effects of these genes. The development of new methods for gene transfer into post-mitotic cells should provide powerful new techniques for examining the specific effects of candidate genes. Virally mediated vectors, such as adenovirus and herpes simplex virus, and non-virally mediated vectors, such as lipofectins and biolistics, have been shown to efficiently transfer candidate genes into many different cell types, including hair cells, supporting cells, and spiral ganglion neurons. In addition, studies in other developing systems have demonstrated that these techniques can be used to determine the effects of expression of candidate genes during the specification of individual cell phenotypes. These results suggest that these vectors can be used effectively to study the role of specific genes during the development of the auditory system.

Growth factors in the treatment of degenerative retinal disorders.

There are currently a number of degenerative conditions, both inherited and acquired, that affect the retina and lead to blindness. Retinal photoreceptors degenerate from inherited conditions, such as retinitis pigmentosa or as a result of light damage or normal ageing; retinal ganglion cells degenerate from optic nerve injury or glaucoma. Current research in this field includes the use of growth factors to: (1) inhibit the degenerative processes; (2) promote regeneration of the retina from the pigmented epithelium; and (3) improve the conditions for transplantation of new cells to the retina by expanding the photoreceptor cell populations in vitro. The results to date have shown that a number of different growth factors promote survival of retinal cells in vitro and in vivo. In addition, some of the same factors can stimulate regeneration in the developing retina and act as mitogens for the retinal progenitor cells. It is likely that a combination of these approaches will ultimately be important for the treatment of the various retinal degenerations.

Ligands of steroid/thyroid receptors induce cone photoreceptors in vertebrate retina.

The mechanisms by which multipotent progenitor cells are directed to alternative cell identities during the histogenesis of the vertebrate central nervous system are likely to involve several different types of signaling systems. Recent evidence indicates that 9-cis retinoic acid, which acts through members of the steroid/thyroid superfamily of receptors, directs progenitor cells to the rod photoreceptor cell fate. We now report that another effector of this family of receptors, thyroid hormone, induces an increase in the number of cone photoreceptors that develop in embryonic rat retinal cultures, and that combinations of 9-cis retinoic acid and triiodothyronine cause isolated progenitor cells to differentiate as either rods or cones, depending on the relative concentrations of the ligands. These results implicate thyroid hormone in CNS cell fate determination, and suggest that different photoreceptor phenotypes may be modulated through the formation of thyroid/retinoid receptor heterodimers.

Regulation of proliferation and photoreceptor differentiation in fetal human retinal cell cultures.

PURPOSE: To examine whether fetal human retinal cells can be maintained in vitro over long time periods and to determine whether exogenous growth factors can be used to generate large numbers of photoreceptors within these cultures. METHODS: Fetal human retinas (6 to 13 weeks after conception) were dissected, dissociated, and plated into culture wells. Specific growth factors and steroid/thyroid hormones, which have been shown to influence retinal progenitor cell proliferation and differentiation in rats, were added to the culture medium to determine whether any of these factors had similar effects on human retinal cells. RESULTS: Fetal human retinal cells survived and continued to proliferate for up to 300 days in vitro. Under control conditions, 15 million cells were generated from an initial plating of 100,000 cells; however, the addition of either epidermal growth factor or basic fibroblast growth factor stimulated proliferation and resulted in the generation of more than 100 million cells. A percentage of these cells was induced to differentiate as photoreceptors by adding either retinoic acid or triiodo-thyronine to the culture medium. CONCLUSIONS: Fetal human retinal cells can be maintained and expanded in vitro, indicating that this technique may be useful for generating large numbers of retinal cells. The number and types of cells generated can be influenced by adding exogenous factors to the culture medium. The response of human retinal cells to growth factors and hormones is similar to the response of rodent retinal cells to the same factors, suggesting that the effects of these factors are conserved across species.

Replacement of hair cells after laser microbeam irradiation in cultured organs of corti from embryonic and neonatal mice.

This study examined the potential for hair cell regeneration in embryonic and neonatal mouse organs of Corti maintained in vitro. Small numbers of hair cells were killed by laser microbeam irradiation and the subsequent recovery processes were monitored by differential interference contrast (DIC) microscopy combined with continuous time-lapse video recordings. Replacement hair cells were observed to develop in lesion sites in embryonic cochleae and on rare occasions in neonatal cochleae. In embryonic cochleae, replacement hair cells did not arise through renewed proliferation, but instead developed from preexisting cells that changed from their normal developmental fates in response to the loss of adjacent hair cells. In cochleae established from neonates, lost hair cells usually were not replaced, but 11 apparently regenerated hair cells and a single hair cell labeled by 3H-thymidine were observed as rare responses to the creation of hair cell lesions in these organs. The results indicate that the organ of Corti can replace lost hair cells during embryonic and on rare occasions during early neonatal development. The ability of preexisting cells to change their developmental fates in response to hair cell death is consistent with the hypothesis that during embryonic development hair cells may inhibit neighboring cells from specializing as hair cells. In neonatal cultures, the rare occurrence of apparently regenerated hair cells indicates that some cells in the postembryonic organ of Corti retain response mechanisms that can lead to self-repair.

Retinoic acid promotes differentiation of photoreceptors in vitro.

The results of several recent studies have demonstrated that cell commitment and differentiation in the developing vertebrate retina are influenced by cell-cell interactions within the microenvironment. Retinoic acid has been shown to influence cell fates during development of the nervous system, and retinoic acid has been detected in the embryonic retina. To determine whether retinoic acid mediates the differentiation of specific neuronal phenotypes during retinal histogenesis, we treated dissociated cell cultures of embryonic and neonatal rat retina with varying concentrations of all-trans or 9-cis retinoic acid and analyzed the effects on cell fate using neuron and photoreceptor-specific antibodies. Addition of exogenous retinoic acid caused a dose-dependent, specific increase in the number of cells that developed as photoreceptors in culture throughout the period of retinal neurogenesis. In the same cultures, retinoic acid also caused a dose-dependent decrease in the number of cells that developed as amacrine cells. Also, results of double-labeled immunohistochemical studies using bromodeoxyuridine demonstrated that the primary effect of retinoic acid was to influence progenitor cells to develop as newly generated rod photoreceptors. Since retinoic acid and at least one of the retinoic acid receptors (RAR alpha) have been localized to the developing neural retina, these results suggest that retinoic acid may play a role in the normal development of photoreceptor cells in vivo.

The developing organ of Corti contains retinoic acid and forms supernumerary hair cells in response to exogenous retinoic acid in culture.

The mammalian organ of Corti has one of the most highly ordered patterns of cells in any vertebrate sensory epithelium. A single row of inner hair cells and three or four rows of outer hair cells extend along its length. The factors that regulate the formation of this strict pattern are unknown. In order to determine whether retinoic acid plays a role during the development of the organ of Corti, exogenous retinoic acid was added to embryonic mouse cochleae in vitro. Exogenous retinoic acid significantly increased the number of cells that developed as hair cells and resulted in large regions of supernumerary hair cells and supporting cells containing two rows of inner hair cells and up to 11 rows of outer hair cells. The effects of retinoic acid were dependent on concentration and on the timing of its addition. Western blot analysis indicated that cellular retinoic acid binding protein (CRABP) was present in the sensory epithelium of the embryonic cochlea. The amount of CRABP apparently increased between embryonic day 14 and postnatal day 1, but CRABP was not detectable in sensory epithelia from adults. A retinoic acid reporter cell line was used to demonstrate that retinoic acid was also present in the developing organ of Corti between embryonic day 14 and postnatal day 1, and was also present in adult cochleae at least in the vicinity of the modiolus. These results suggest that retinoic acid is involved in the normal development of the organ of Corti and that the effect of retinoic acid may be to induce a population of prosensory cells to become competent to differentiate as hair cells and supporting cells.

Hair cell development.

Neurobiologists have been challenged by the desire to understand how the highly specialized ultrastructure of the sensory hair cells of the ear develops, how patterns of phenotypically distinct hair cells are formed and regenerate, and how their specific neural connections are formed. Recent research has addressed some of these challenges at the level of cell and molecular biology, focusing on cell proliferation in hair cell epithelia, the mechanisms that control hair cell differentiation, and the developmental interdependencies between hair cells and neurons. The initial identification of some of the homeobox genes and growth factors that are involved in hair cell development has occurred during the past year.

Maturation of kinocilia in amphibian hair cells: growth and shortening related to kinociliary bulb formation.

New hair cells are added to the amphibian sacculus throughout life, primarily at its outer edge. The stereociliary bundles near that edge are heterogeneous, but eventually develop the more homogeneous morphology of the overwhelming majority of mature cells near the center of the epithelium. During their development the kinocilium grows and a kinociliary bulb forms. It has been proposed that initial elongation of the kinocilium is followed by shortening, and that the bulb may form during shortening. To test those hypotheses, amphibian sacculi were examined by scanning electron microscopy and the length of the kinocilium, the width of the kinociliary bulb, and the length of the tallest stereocilia were measured for 159 hair cells. The length of the tallest stereocilia on each hair cell was used as an indicator of the relative maturity of that cell, so that changes in the structure of each cell's kinocilium could be related to that cell's stage of development. Results indicate that initial elongation of the kinocilium is followed by shortening. Kinociliary bulbs first appear and increase in volume as shortening proceeds. These findings support the hypotheses. Models are proposed to explain how the formation of the bulb could result from depolymerization of apical cytoskeletal elements, and how kinocilium growth and shortening may contribute to hair bundle reorientation in the developing ear.

Hair cell regeneration: the identities of progenitor cells, potential triggers and instructive cues.

Hair cells are produced and accumulate in the ears of fish and amphibians as they grow during postembryonic life; hair cell regeneration occurs in lateral line organs in those groups and in the cochlea in birds. Continuous time-lapse microscopy has directly demonstrated that supporting cells divide to give rise to hair cells during regeneration in lateral line neuromasts. Supporting cells also appear to give rise to hair cells during regeneration in the avian ear, but additional cell types have been proposed as hair cell progenitors. Alternative interpretations of current evidence are discussed in relation to the possibility that supporting cells may be the common progenitor in all cases of hair cell regeneration. The regenerative proliferation of hair cells in birds occurs in populations of cells that are mitotically quiescent in undamaged ears. Evidence suggests that the extrusion of damaged hair cells and the breaking of intercellular junctional adhesions may be a trigger for regenerative proliferation. The potential triggering influence of phagocytes is also discussed. The differentiation of replacement cells during regeneration in the cochlea may be regulated by surface interactions between cells. A model that could account for the reconstitution of the mosaic pattern of hair cells and supporting cells is proposed.