Nonsyndromic hearing impairment is associated with a mutation in DFNA5

Nonsyndromic hearing impairment is one of the most heterogeneous hereditary conditions, with more than 40 loci mapped on the human genome, however, only a limited number of genes implicated in hearing loss have been identified. We previously reported linkage to chromosome 7p15 for autosomal dominant hearing impairment segregating in an extended Dutch family (DFNA5). Here, we report a further refinement of the DFNA5 candidate region and the isolation of a gene from this region that is expressed in the cochlea. In intron 7 of this gene, we identified an insertion/deletion mutation that does not affect intron-exon boundaries, but deletes five G-triplets at the 3' end of the intron. The mutation co-segregated with deafness in the family and causes skipping of exon 8, resulting in premature termination of the open reading frame. As no physiological function could be assigned, the gene was designated DFNA5.

Mutations in the human alpha-tectorin gene cause autosomal dominant non-syndromic hearing impairment

The tectorial membrane is an extracellular matrix of the inner ear that contacts the stereocilia bundles of specialized sensory hair cells. Sound induces movement of these hair cells relative to the tectorial membrane, deflects the stereocilia, and leads to fluctuations in hair-cell membrane potential, transducing sound into electrical signals. Alpha-tectorin is one of the major non-collagenous components of the tectorial membrane. Recently, the gene encoding mouse alpha-tectorin (Tecta) was mapped to a region of mouse chromosome 9, which shows evolutionary conservation with human chromosome 11q (ref. 3), where linkage was found in two families, one Belgian (DFNA12; ref. 4) and the other, Austrian (DFNA8; unpublished data), with autosomal dominant non-syndromic hearing impairment. We determined the complete sequence and the intron-exon structure of the human TECTA gene. In both families, mutation analysis revealed missense mutations which replace conserved amino-acid residues within the zona pellucida domain of TECTA. These findings indicate that mutations in TECTA are responsible for hearing impairment in these families, and implicate a new type of protein in the pathogenesis of hearing impairment.

Mapping of the alpha-tectorin gene (TECTA) to mouse chromosome 9 and human chromosome 11: a candidate for human autosomal dominant nonsyndromic deafness

alpha-Tectorin is one of the major noncollagenous components of the mammalian tectorial membrane in the inner ear. We have mapped the gene encoding alpha-tectorin to mouse chromosome 9 and human chromosome 11 in a known region of conserved synteny. Human YAC clones containing alpha-tectorin have been identified, demonstrating physical linkage to the anonymous marker D11S925. This places alpha-tectorin within the genetic interval that contains both the human nonsyndromic autosomal dominant deafness DFNA12 and the proximal limit of a subset of deletions within Jacobsen syndrome. Thus both DFNA12 and the hearing loss in some cases of Jacobsen syndrome may be due to haploinsufficiency for TECTA.

Myosin VIIA is required for aminoglycoside accumulation in cochlear hair cells

Myosin VIIA is expressed by sensory hair cells and has a primary structure predicting a role in membrane trafficking and turnover, processes that may underlie the susceptibility of hair cells to aminoglycoside antibiotics. [3H]Gentamicin accumulation and the effects of aminoglycosides were therefore examined in cochlear cultures of mice with different missense mutations in the myosin VIIA gene, Myo7a, to see whether myosin VIIA plays a role in aminoglycoside ototoxicity. Hair cells from homozygous mutant Myo7ash1 mice, with a mutation in a nonconserved region of the myosin VIIA head, respond rapidly to aminoglycoside treatment and accumulate high levels of gentamicin. Hair cells from homozygous mutant Myo7a6J mice, with a mutation at a highly conserved residue close to the ATP binding site of the myosin VIIA head, do not accumulate [3H]gentamicin and are protected from aminoglycoside ototoxicity. Hair cells from heterozygotes of both alleles accumulate [3H]gentamicin and respond to aminoglycosides. Although aminoglycoside uptake is thought to be via apical surface-associated endocytosis, coated pit numbers on the apical membrane of heterozygous and homozygous Myo7a6J hair cells are similar. Pulse-chase experiments with cationic ferritin confirm that the apical endocytotic pathway is functional in homozygous Myo7a6J hair cells. Transduction currents can be recorded from both heterozygous and homozygous Myo7a6J hair cells, suggesting it is unlikely that the drug enters via diffusion through the mechanotransducer channel. The results show that myosin VIIA is required for aminoglycoside accumulation in hair cells. Myosin VIIA may transport a putative aminoglycoside receptor to the hair cell surface, indirectly translocate it to sites of membrane retrieval, or retain it in the endocytotic pathway.

Extracellular matrix and cell adhesion molecules in the developing inner ear

The inner ear is a complex sensory organ that forms from a simple epithelial placode. The expression patterns of cell adhesion molecules and extracellular matrix components that have been described in the developing inner ear to date are summarized. Whilst our knowledge of the distribution of some of the known elements involved in cell-cell and cell-matrix interactions is in some instances quite limited, these studies generally suggest many potential roles for cell-cell and cell-matrix interactions in various aspects of inner ear development. However, there is a serious need for experimental studies to assess these possibilities.

A quantitative comparison of mechanoelectrical transduction in vestibular and auditory hair cells of neonatal mice

Vestibular hair cells (VHCs) and cochlear outer hair cells (OHCs) of neonatal mice were stimulated by a fluid jet directed at their stereociliary bundles. Relations between the force exerted by the jet, bundle displacement, and the resulting transducer current were studied. The mean maximum transducer conductance in VHCs (2.6 nS) was about half that of the OHCs (5.5 nS), with the largest recorded values being 4.1 nS and 9.2 nS, respectively. In some OHCs activity of a single, 112 pS transducer channel was observed, allowing an estimate of the maximum number of channels: up to 36 in VHCs and 82 in OHCs, corresponding to about one transducer channel per tip link. The VHC bundles required about 330 nm of tip displacement to activate 90% of the maximum transducer conductance, compared to 150 nm for the OHC bundles. This corresponded to 2 deg of rotation about their pivots for both, due to the greater length of the VHC bundles. The VHC bundles' translational stiffness was one-seventh of that of the OHCs. Conversion to rotational stiffness almost abolished this difference. Rotation of the hair bundle rather than translation determines the gating of the transducer channels, independent of bundle height or origin of the cells.

The mouse tectorins. Modular matrix proteins of the inner ear homologous to components of the sperm-egg adhesion system

The cDNA and derived amino acid sequences for the two major non-collagenous proteins of the mouse tectorial membrane, alpha- and beta-tectorin, are presented. The cDNA for alpha-tectorin predicts a protein of 239,034 Da with 33 potential N-glycosylation sites, and that of beta-tectorin a smaller protein of 36,074 Da with 4 consensus N-glycosylation sites. Southern and Northern blot analysis indicate alpha- and beta-tectorin are single copy genes only expressed in the inner ear, and in situ hybridization shows they are expressed by cells both in and surrounding the mechanosensory epithelia. Both sequences terminate with a hydrophobic COOH terminus preceded by a potential endoproteinase cleavage site suggesting the tectorins are synthesized as glycosylphosphatidylinositol-linked, membrane bound precursors, targeted to the apical surface of the inner ear epithelia by the lipid and proteolytically released into the extracellular compartment. The mouse beta-tectorin sequence contains a single zona pellucida domain, whereas alpha-tectorin is composed of three distinct modules: an NH2-terminal region similar to part of the entactin G1 domain, a large central segment with three full and two partial von Willebrand factor type D repeats, and a carboxyl-terminal region which, like beta-tectorin, contains a single zona pellucida domain. The central, high molecular mass region of alpha-tectorin containing the von Willebrand factor type D repeats has homology with zonadhesin, a sperm membrane protein that binds to the zona pellucida. These results indicate the two major non-collagenous proteins of the tectorial membrane are similar to components of the sperm-egg adhesion system, and, as such may interact in the same manner.

Antibodies to the sulphated, high molecular mass mouse tectorin stain hair bundles and the olfactory mucus layer

Polyclonal antibodies were raised in chickens to the glycosylated forms of the high (H), medium (M) and low (L) molecular mass (MM) mouse tectorins. In the mouse cochlea, all three antibodies stained the tectorial membrane. Antibodies raised to HMM tectorin also stained the hair bundles of both inner and outer hair cells. A number of other mouse tissues were screened with the anti-tectorin antibodies to look for similar or antigenically related molecules. Staining was not observed in any other tissue type with the antibodies directed against the MMM and LMM tectorins. In the nose, the anti-HMM tectorin antibodies stained Bowman's glands and the mucus layer overlying the olfactory epithelium. The surface of the adjacent respiratory epithelium was not stained by these antibodies. HMM tectorin can be specifically radiolabelled by injecting neonatal mice with 35SO4 and undergoes a shift in electrophoretic mobility following treatment with keratanase, an endo-beta-galactosidase from Pseudomonas. However, when centrifuged on shallow CsCl gradients HMM tectorin has a buoyant density similar to that of glycoproteins and does not behave as a typical cartilage type proteoglycan. HMM tectorin does not react with mab 5D4, a monoclonal antibody that recognises keratan sulphate glycosaminoglycan from corneal and skeletal muscle proteoglycan. Unlike antibodies to HMM tectorin, mab 5D4 selectively stains the upper surface of the tectorial membrane, Hensen's stripe and the mucus layer overlying the respiratory epithelium. These studies indicate that the MMM and LMM tectorins may be unique to the cochlea, and that HMM may be a "light' keratan sulphate proteoglycan that is antigenically related to either the mucins or a more specific component of the olfactory mucus layer.

Distribution of beta-tectorin mRNA in the early posthatch and developing avian inner ear

Expression of beta-tectorin mRNA in the inner ear of the embryonic and early posthatch (PH) chick was studied by in situ hybridisation. In the PH chick, beta-tectorin mRNA is expressed in the basilar papilla, in the clear and the cuboidal cells that lie either side of the papilla, in the striolar regions of the maculae, and in two small groups of cells lying adjacent to the midline in the cristae of the anterior and posterior ampullae. Expression of beta-tectorin is not observed in the lateral ampulla. In the sensory epithelia of the PH chick in which beta-tectorin mRNA is detected, expression is restricted to the supporting cell population. During development of the cochlear duct, beta-tectorin expression begins between embryonic (E) days 5 and 6. At E6, expression is observed throughout the length of the duct but is highest at the distal end. By E7, the pattern of expression is reversed and is highest at the proximal end of the cochlea, suggesting that a wave of high beta-tectorin expression passes disto-proximally along the papilla during E6 and E7. Expression of beta-tectorin mRNA is not detected in the homogene cells at any stage during the development of the cochlear duct, indicating that these cells do not synthesise one of the two major proteins of the avian tectorial membrane. The distribution of supporting cells expressing beta-tectorin mRNA in the different epithelia was compared with the distribution of sensory cells that have type B hair bundles, those with shaft links restricted to basal regions of their stereocilia, and sensory cells that have type A bundles, those with shaft links all over the entire surface of their stereocilia. Hair cells with type A hair bundles are never found in association with supporting cells expressing beta-tectorin. Although there is a correspondence in the basilar papilla and the maculae of the utriculus and lagena between the distribution of supporting cells expressing beta-tectorin mRNA and hair cells with type B bundles, this correlation does not generalise to the other sensory epithelia.

Molecular cloning of chick beta-tectorin, an extracellular matrix molecule of the inner ear

The tectorial membrane is an extracellular matrix lying over the apical surface of the auditory epithelium. Immunofluorescence studies have suggested that some proteins of the avian tectorial membrane, the tectorins, may be unique to the inner ear (Killick, R., C. Malenczak, and G. P. Richardson. 1992. Hearing Res. 64:21-38). The cDNA and deduced amino acid sequences for chick beta-tectorin are presented. The cDNA encodes a protein of 36,902.6 D with a putative signal sequence, four potential N-glycosylation sites, 13 cysteines, and a hydrophobic COOH terminus. Western blots of two-dimensional gels using antibodies to a synthetic peptide confirm the identity of the cDNA. Southern and Northern analysis suggests that beta-tectorin is a single-copy gene only expressed in the inner ear. The predicted COOH terminus is similar to that of glycosylphosphatidylinositol-linked proteins, and antisera raised to this region react with in vitro translation products of the cDNA clone but not with mature beta-tectorin. These data suggest beta-tectorin is synthesized as a glycosylphosphatidyl-inositol-linked precursor, targeted to the apical surface of the sensory epithelium by the lipid moiety, and then further processed. Sequence analysis indicates the predicted protein possesses a zona pellucida domain, a sequence that is common to a limited number of other matrix-forming proteins and may be involved in the formation of filaments. In the cochlear duct, beta-tectorin is expressed in the basilar papilla, in the clear cells and the cuboidal cells, as well as in the striolar region of the lagena macula. The expression of beta-tectorin is associated with hair cells that have an apical cell surface specialization known as the 275-kD hair cell antigen restricted to the basal region of the hair bundle, suggesting that matrices containing beta-tectorin are required to drive this hair cell type.

Ototoxicity in vitro: effects of neomycin, gentamicin, dihydrostreptomycin, amikacin, spectinomycin, neamine, spermine and poly-L-lysine

The effects that the aminoglycoside-aminocyclitol antibiotics amikacin, dihydrostreptomycin, gentamicin, neomycin, and spectinomycin, the neomycin fragment neamine, and the polybasic compounds spermine and poly-L-lysine, have on outer hair cells in cochlear cultures prepared from the early post-natal mouse have been assessed using both scanning and transmission electron microscopy (SEM and TEM). The antibiotics were used at concentrations ranging from 0.25-1.0 mM, spermine from 10 microM to 3.0 mM, and poly-L-lysine from 0.05-2 microM. Qualitative assessment of apical surface damage allows the antibiotics to be ranked in the following order: neomycin > gentamicin > dihydrostreptomycin > amikacin > neamine > spectinomycin. At a concentration of 1 mM spectinomycin is essentially non-toxic and the effects of neamine are marginal. Poly-L-lysine and spermine also cause surface damage, with poly-L-lysine being substantially more toxic than any of the antibiotics, and spermine ranking, on the basis of SEM observations, between dihydrostreptomycin and amikacin. TEM indicates that although all toxic compounds cause damage to the apical surface of the hair cell, only neomycin, poly-L-lysine and spermine induce the formation of whorls of tightly packed membrane resembling myelin within the apical surface lesions to any great extent. Apical-surface changes induced by dihydrostreptomycin and amikacin are simply large distensions of the cell filled with cytoplasmic organelles of normal appearance. Although the effects of the aminoglycoside antibiotics are largely limited to the apical surface of the cell, poly-L-lysine induces complete necrosis of the cell, and spermine causes a dramatic increase in cytoplasmic electron density and condensation of the nuclear chromatin.

Monoclonal antibodies specific for endoplasmic membranes of mammalian cochlear outer hair cells

Monoclonal antibodies were raised in vitro against an antigen associated with the lateral cisternal membranes of outer hair cells. Two of the antibodies were class IgM and one of these retained its specific reactivity in tissue fixed with aldehydes and embedded in the resin LR White. Immunogold labelling for electron microscopy showed that the antigen was closely associated with the membranes rather than the cytoplasmic or lumenal regions of the cisternae. The third antibody was an IgG. All three weakly labelled a protein band with an apparent molecular weight of about 60 kD on a Western blot. The antibodies did not cross-react with any other cell in the organ of Corti, including the inner hair cells. Furthermore, they showed no cross-reactivity with skeletal muscle, kidney, gut, brain, skin, blood or retina from the guinea pig. The results suggest that the lateral cisternae in outer hair cells may be functionally different from those of inner hair cells. The antibodies may provide useful markers for outer hair cells in studies of hair cell regeneration.

Block by amiloride and its derivatives of mechano-electrical transduction in outer hair cells of mouse cochlear cultures

1. The effects of amiloride and amiloride derivatives on mechano-electrical transducer currents in outer hair cells of the cultured neonatal mouse cochlea were examined under whole-cell voltage clamp. 2. At -84 mV transducer currents were reversibly blocked by the extracellular application of the pyrazinecarboxamides amiloride, benzamil, dimethylamiloride, hexamethyleneiminoamiloride, phenamil and methoxynitroiodobenzamil with half-blocking concentrations of 53, 5.5, 40, 4.3, 12 and 1.8 microM, respectively. Hill coefficients were determined for all but the last of these compounds and were 1.7, 1.6, 1.0, 2.2 and 1.6, respectively, suggesting that two drug molecules co-operatively block the transducer channel. 3. Both the structure-activity sequence for amiloride and its derivatives and the mechanism of the block of the transducer channel appear to be different from those reported for the high-affinity amiloride-sensitive epithelial Na+ channels but similar to those of stretch-activated channels in Xenopus oocytes. 4. The block by all pyrazinecarboxamides was voltage dependent with positive membrane potentials releasing the block. The form of the voltage dependence is consistent with a voltage-independent binding of the drug to a site that is accessible at hyperpolarized but not at depolarized potentials, suggesting that the transducer channel undergoes a voltage-dependent conformational change. The channel was not blocked by 1 mM amiloride from the intracellular side at either negative or positive membrane potentials. 5. The kinetics of the block were studied using force steps or voltage jumps. The results suggest that the drug binding site is only accessible when the transducer channel is open (open-channel block) and that the channel cannot close when the drug molecules are bound. 6. The time dependence and voltage dependence of the block together reveal that the transducer channel has at least two open conformational states, the transition between which is voltage dependent.

Nonlinear mechanical responses of mouse cochlear hair bundles

The stiffness of sensory hair bundles of both inner (IHC) and outer (OHC) hair cells was measured with calibrated silica fibres in mouse cochlear cultures to test the hypothesis that the mechanical properties of the hair bundle reflect processes underlying mechanotransduction. For OHCs, the displacement of the hair bundle relaxed with time constants of 6 ms for displacements which open transducer channels and 4 ms for displacements which close the channels. The corresponding values of the time constants for IHCs were 10 ms and 8 ms, respectively. A displacement-dependent change in the stiffness of the hair bundle was not observed when the bundle was displaced orthogonally to the direction of excitation. The stiffness of the hair bundle as a function of nanometre displacements from the resting position was remarkably nonlinear. The stiffness declined to a minimum from the resting stiffness by about 12% for OHCs and 20% for IHCs when the hair bundle was displaced by about 20 nm in the excitatory direction, and it increased by a similar amount when the bundle was displaced by 20 nm in the inhibitory direction. The displacement at which the stiffness reached a minimum was within the most sensitive region of the hair-cell transducer function (receptor potential as a function of hair-bundle displacement), and the displacement at which the stiffness reached a maximum was at the point of saturation of the transducer function in the inhibitory direction. The nonlinear displacement-dependent compliance change is reversibly abolished, and the time constant of relaxation of the bundle for excitatory displacements is reversibly reduced, when mechanotransduction is blocked by the addition of either neomycin sulphate or cobalt chloride to the solution bathing the hair cells. The displacement-dependent compliance change was not apparently reduced when the receptor potential was attenuated through the substitution of sodium in the bathing solution with a less permeant cation, tetraethylammonium. These findings suggest that the nonlinear mechanical properties of the hair bundle are associated with aspects of the hair-cell mechanotransducer process. The mechanical properties of the hair bundle are discussed in relation to the 'gating-spring' hypothesis of hair-cell transduction.

The protein composition of the avian tectorial membrane

Gel electrophoretic analysis of the avian tectorial membrane under non-reducing conditions reveals the presence of 2 major proteins with apparent molecular masses of 195 and 41 kDa on 8.25% gels. Under reducing conditions, 6 polypeptides with apparent molecular masses of 146, 60, 56, 43, 35 and 31 kDa are consistently observed. None of these six polypeptides observed under reducing conditions are sensitive to digestion with collagenase, and all, except for the 43 kDa component, are degraded by treatment with cold acidic pepsin. The 60, 56 and 43 kDa polypeptides bind the peroxidase conjugated lectins from Canavalia ensiformis and Triticum vulgaris, indicating the presence of mannose, N-acetyl glucosamine and/or sialic acid. The 146, 60 and 56 kDa bands undergo a shift in electrophoretic mobility after treatment of native tectorial membranes with the enzyme neuroaminidase. Fibronectin and Type II collagen cannot be detected in the avian tectorial membrane by either immunoblotting or immunofluorescence techniques. Polyclonal antisera raised against the different polypeptides after partial purification by one dimensional gel electrophoresis confirm that these proteins are all components of the tectorial membrane, and show that they are restricted to the otolithic and tectorial membranes within the inner ear. Analysis of a wide variety of other tissue types indicates that the 60, 43 and 35 kDa components can only be detected within the inner ear, and that the antisera recognising the 146 and 31 kDa components only show cross-reactivity within the head, with the anti-146 kDa antibodies staining the mucus ducts supplying the olfactory epithelium and the anti-31 kDa antibodies staining granular elements in the cells of the respiratory epithelium. The results suggest that certain of the tectorial membrane components may be novel matrix molecules unique to the inner ear, and that some of the other proteins may be antigenically related to mucins.

Mechano-electrical transducer currents in hair cells of the cultured neonatal mouse cochlea

The first step towards the generation of the receptor potential in hair cells is the gating of the transducer channels and subsequent flow of transducer current, induced by deflection of the stereocilia. We describe properties of the transducer current in outer hair cells of neonatal mice. Less extensive observations on inner hair cells suggest that their transducer currents have similar characteristics. The hair bundles were stimulated by force from a fluid jet. The transducer currents in outer hair cells are the largest found so far in any hair cell, with a chord conductance of up to 9.2 nS at -84 mV. The transfer function suggests that the channel has at least two closed states and one open state. The permeabilities for sodium, potassium and caesium are similar, consistent with the channel being a fairly non-selective cation channel. At negative potentials the currents adapt in most cells, although never as completely as in hair cells of lower vertebrates. If the unit conductance of the transducer channel is similar to that of the turtle's auditory hair cells (100 pS), then there are about 90 channels per hair bundle, or one channel between every pair of adjacent stereocilia in neighbouring rows.

A cell surface-associated centrosomal layer of microtubule-organizing material in the inner pillar cell of the mouse cochlea

This investigation provides evidence that pericentriolar material is divorced from the immediate vicinities of centrioles and becomes functionally associated with the plasmalemma during the differentiation of a mammalian cell type. Such events occur prior to the assembly of large transcellular microtubule bundles in columnar epithelial cells called inner pillar cells in the mouse organ of Corti. The microtubules do not radiate from a typical centrosome and its centrioles. They elongate from a microtubule-organizing centre (MTOC), which is deployed as a subapical cell surface-associated layer in each cell. Most of the dense material of this layer, and the tops of most of the microtubules, are initially concentrated around the sides of a cell about 1 microns below its apical surface. In addition, a pair of centrioles is located above the layer, which acts as if it is a pericellular concentration of the pericentriolar material of a modified centrosome. Although microtubule nucleation takes place in a centrosome-like region, 13 protofilament fidelity is not exercised. Most of the microtubules have 15 protofilaments. Microtubule assembly progresses in these cells after the organ of Corti has been isolated for in vitro culture. However, large numbers of microtubules elongate from pericentriolar material juxtaposed against the centrioles. Hence, there is some reversion by the centrosomes of cultured cells to the operational configuration regarded as typical for animal tissue cells in general.

Cochlear cultures as a model system for studying aminoglycoside induced ototoxicity

Light and electron microscopy have been used to evaluate the effects of treating mouse cochlear cultures with the ototoxic aminoglycoside antibiotic neomycin sulphate at concentrations of 0.2 mM and greater for periods of up to 1 hour. Neomycin rapidly induces the formation of numerous, membrane filled blisters on the apical surfaces of the sensory hair cells. Such morphological damage is restricted to the hair cells, and is not observed on the surfaces of supporting cells within the organ of Corti. Hair cells in apical-coil cultures are less sensitive than those in basal-coil cultures, and, at any given point along the cochlea, outer hair cells appear to be more extensively damaged by neomycin than inner hair cells. These morphological effects of neomycin are considerably more severe when the drug is applied in calcium/magnesium free saline, and can be blocked by elevating the saline concentration of either calcium or magnesium. The effects can also be blocked by lowering the temperature to 4 degrees C, but not by either K+ depolarization or the lectin Concanavalin A. The potential value of this culture system as a model for studying aminoglycoside induced ototoxicity is discussed.

Transient expression of neurofilament protein during hair cell development in the mouse cochlea

A polyclonal antiserum raised against the 145 kDa neurofilament protein (NFM) has been used to study the distribution of neurofilaments both in organotypic cultures of the early postnatal mouse cochlea and during development of the mouse cochlea in vivo. In the cultures, both the inner hair cells and the outer hair cells are stained by the antibodies, as well as the innervating afferent fibres from the spiral ganglion. In cultures denervated at the time of preparation, neurofilament positive hair cells can still be detected after 7 days in vitro. NFM can also be detected by immunoblotting in such denervated cultures. Characteristic 10 nm diameter, cytoplasmic filaments can also be observed in cultured hair cells using transmission electron microscopy. Immunostaining of cryosections prepared from cochleas at embryonic days 17 and 19, and days 1, 2, 5, 10 and 21 post-partum reveals that hair cells transiently express NFM during their development in vivo. Expression of NFM in hair cells is first detected at embryonic day 19 in the basal region of the cochlea and, by 2 days post-partum, neurofilament positive hair cells are found throughout the entire length of the cochlea. By 10 days post-partum, staining of hair cells begins to diminish and, by 21 days post-partum, NFM can no longer be detected in hair cells.

Identification of a 275-kD protein associated with the apical surfaces of sensory hair cells in the avian inner ear

Immunological techniques have been used to generate both polyclonal and monoclonal antibodies specific for the apical ends of sensory hair cells in the avian inner ear. The hair cell antigen recognized by these antibodies is soluble in nonionic detergent, behaves on sucrose gradients primarily as a 16S particle, and, after immunoprecipitation, migrates as a polypeptide with a relative molecular mass of 275 kD on 5% SDS gels under reducing conditions. The antigen can be detected with scanning immunoelectron microscopy on the apical surface of the cell and on the stereocilia bundle but not on the kinocilium. Double label studies indicate that the entire stereocilia bundle is stained in the lagena macula (a vestibular organ), whereas in the basilar papilla (an auditory organ) only the proximal region of the stereocilia bundle nearest to the apical surface is stained. The monoclonal anti-hair cell antibodies do not stain brain, tongue, lung, liver, heart, crop, gizzard, small intestine, skeletal muscle, feather, skin, or eye tissues but do specifically stain renal corpuscles in the kidney. Experiments using organotypic cultures of the embryonic lagena macula indicate that the antibodies cause a significant increase in the steady-state stiffness of the stereocilia bundle but do not inhibit mechanotransduction. The antibodies should provide a suitable marker and/or tool for the purification of the apical sensory membrane of the hair cell.

Stereocilia bundle stiffness: effects of neomycin sulphate, A23187 and concanavalin A

The effects that the aminoglycoside antibiotic neomycin sulphate, the ionophore A23187 and the lectin Concanavalin A (Con A) have on the steady state stiffness of the hair-cell stereocilia bundle have been studied using organotypic cultures of the early postnatal mouse cochlea. In normal saline, stereocilia bundle stiffness is increased 1.5-2.0 fold by neomycin sulphate, 1.3-1.7 fold by the ionophore A23187 and 3.0-5.0 fold by Con A. In low-calcium saline neither neomycin sulphate nor A23187 cause increases in stiffness, and the stiffness increases elicited by these two agents in normal saline are reversed on washout with low-calcium saline. In normal saline neomycin sulphate has two independent effects on hair cells; one effect is a reversible inhibition of transduction and the other effect is to cause an irreversible increase in bundle stiffness. Neither Con A nor the ionophore A23187 block transduction. No obvious changes in stereocilia bundle morphology are associated with the increases in stiffness caused by neomycin sulphate, A23187 and Con A. Succinylated Con A binds to stereocilia bundles but does not cause an increase in stiffness, suggesting that the stiffness increase caused by native Con A results from receptor cross-linking. The effects of Con A and neomycin are non-additive, saturating concentrations of neomycin sulphate block the effects of low doses of Con A, and pretreatment of cells with succinylated Con A prevents subsequent neomycin sulphate treatment from causing an increase in stiffness suggesting that neomycin sulphate and Con A are acting via a similar mechanism at the cell surface. Ionophore treatment prevents the subsequent application of neomycin sulphate from causing a further increase in stiffness, but when cells are treated with neomycin sulphate followed by ionophore the effects of the two drugs are additive indicating that they are operating via different mechanisms. The possible nature of these mechanisms and their role in the control of steady state stereocilia bundle stiffness are discussed.

The responses of cochlear hair cells to tonic displacements of the sensory hair bundle

Hair bundle displacements and receptor potentials were recorded from outer hair cells (OHCs) in organotypic cultures of the mouse cochlea during force steps applied to the bundles with a silica probe of known stiffness. The receptor potentials of some OHCs adapt for excitatory displacements and the time constants of receptor potential adaptation and hair bundle force relaxation for excitatory displacements are very similar. Thus in these OHCs, the receptor potentials correspond to the applied force for excitatory displacements. For inhibitory displacements, the receptor potentials correspond to hair bundle displacement. Some OHC receptor potentials are nonadapting and follow displacement in both the excitatory and inhibitory directions. The hair bundles of nonadapting OHCs are less stiff than those of adapting OHCs and nonadapting OHCs are an order of magnitude less sensitive to hair bundle displacement than adapting OHCs. In response to a combination of excitatory, tonic, hair bundle displacement and current injection, the receptor potentials of nonadapting OHCs decline as the membrane potential is made more positive and reverse near 0 mV. When the receptor potentials of adapting OHCs measured during current injection are compensated for constant input resistance and driving voltage across the transducer conductance, the receptor potential amplitude at the offset of the step displacement is independent of the level and polarity of the injected current. Before adaptation, at the onset of the step displacement of the hair bundle, the amplitude of the receptor potential increases as the injected current becomes more positive. For adapting OHCs, the receptor potential amplitude is a linear function of excitatory bundle displacement for amplitudes less than 50 nm. With negative, but not positive, current injection the receptor potentials at the onset of the displacement tend to saturate and the slope of the function decreases. This voltage dependent control of OHC transducer operating range is proposed to have a role in regulating the sensitivity of the cochlea.

Tubulin and microtubules in cochlear hair cells: comparative immunocytochemistry and ultrastructure

The distribution of tubulin has been investigated in surface preparations of the guinea pig organ of Corti using indirect immunofluorescence microscopy. Two different monoclonal antibodies to tubulin produce similar distinct patterns of labelling in hair cells. Labelling is greater in inner hair cells than outer hair cells. It occurs in rings around the cell apex, and in a meshwork below and channels through, the cuticular plate. In outer hair cells from the apical region of the cochlea, labelling occurs around the location of a basalward protrusion of the cuticular plate. These patterns correlate with the location of microtubules observed using transmission electron microscopy. A large patch of labelling occurs on the strial side of the cell corresponding to the largest channel through the cuticular plate and the kinociliary basal body. Strands of labelling are seen running parallel to the long axis of the cell between the subcuticular and synaptic region. Many more of these strands are seen in the inner hair cell than the outer hair cell and may correspond to tracks of microtubules transporting neurotransmitter vesicles or other organelles. In outer hair cells, intense labelling and many microtubules are seen in the subnuclear region. The possible roles of the different microtubule arrangements are discussed.

Stereociliary bundle morphology in organotypic cultures of the mouse cochlea

Organotypic cultures of the neonatal mouse cochlea have a band of hair cells consisting of 3-5 rows of outer hair cells and a single row of inner hair cells. The outer hair cell stereociliary bundles show progressive differentiation from the apical to the basal ends of the band. Undifferentiated apical bundles have a disk-like array of short stereocilia resembling microvilli. Partially differentiated bundles are hemispherical with poorly organized rows of thickly clustered stereocilia, which gradually increase in height in the direction of the kinocilium. More differentiated bundles remain hemispherical with many microvilli-like stereocilia, but have highly organized rows of sterocilia along the side nearest to the kinocilium, and well-defined height increments between the rows. Highly-differentiated, basal bundles usually have a 'V' or 'W' shape, although some can be almost polygonal. The basal bundles have 4-5 regular rows of stereocilia with a well-defined gradient in height across the rows, and very few microvilli-like stereocilia. Cross-links are only consistently observed in more differentiated bundles, where the rows of stereocilia are regular and have significant height increments across them. The links show a wide variety of forms and orientations not previously observed in other preparations. Spoke-like arrays of links project from the upper regions of many stereocilia and other stereocilia appear to bear distinct tip-to-side links, although with a variety of orientations. A similar variety of cross-links is observed in early postnatal cochleae in vivo, but not in the cochleae of adult mice, indicating that this variety may be a transient feature of sterociliary bundle development. In vitro, inner hair cell stereociliary bundles are often covered by overlying material from the developing tectorial membrane. The variations in morphology of inner hair cell bundles and their cross-links are similar to those of the outer hair cell bundles.