Donnan equilibrium in the tectorial membrane

Basic properties of the isolated tectorial membrane were investigated. Pieces of the membrane were equilibrated in various bathing fluids and the potential difference between the matrix of the membrane and the bathing fluid was measured, using micropipette electrodes. A negative potential was recorded within the membrane, and the magnitude of the potential was dependent upon the pH and ionic strength of the bathing fluid. These observations suggest that a Donnan equilibrium is established under these experimental conditions, and demonstrate that the tectorial membrane acts as a separate phase in vitro. It may not be valid, therefore, to assume that the membrane is electrically and ionically transparent in vivo.     

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.     

Tectorial membrane. II: Stiffness measurements in vivo

The tectorial membrane is assumed to play a crucial role in the stimulation of the cochlear hair cells and was thought for decades to serve as a stiff anchor for the tips of the hair-cell stereocilia, particularly those belonging to the OHCs. Yet, its stiffness has never been measured under conditions approximating its normal environment in live animals. We have developed a method for doing this. The tectorial membrane is approached through the lateral wall of scala media. The bony cochlear capsule is removed along scala media over somewhat less than 1/4 turn, and the underlying spiral ligament and stria vascularis are carefully reflected. With the help of a three axial hydraulic manipulator, a flexible micropipette filled with isotonic KCl is inserted into the tectorial membrane at one of two different angles and moved either transversally, away from the basilar membrane, or radially, toward or away from the modiolus. This causes the tectorial membrane to be deformed and the micropipette to bend. The micropipette stiffness is calibrated on an instrument of a new kind, so as to convert the bend into force. The calibration allows us to determine the point stiffness of the tectorial membrane from the amount of micropipette bend. The stiffness of the tectorial membrane per unit length has been calculated from the point stiffness with the help of the deformation pattern. Transversal and radial stiffness magnitudes have been determined in the second cochlear turn in Mongolian gerbils. Both are smaller by almost an order of magnitude than the corresponding aggregate stiffness of the OHC stereocilia. As a consequence, the tectorial membrane cannot act as a stiff anchor for the stereocilia but only as a mass load, except at relatively low sound frequencies where mass effects are negligible. This means that the classical model of shear motion between the tectorial membrane and the reticular lamina must be replaced.     

Acoustic overstimulation alters the morphology of the tectorial membrane

After a permanent threshold shift was induced by exposing guinea pigs to a 1 kHz pure tone at 105 dB(A) for 72 h, light microscopic observations of freshly dissected and stained tectorial membranes showed an increased waviness and clumping of the fibers of the middle zone. Hensen's stripe was not seen as a continuous dense structure running through the middle zone but was at times discontinuous and curved. As measured from cross-sections of the cochlea, the thickness of the tectorial membrane was decreased after acoustic overstimulation. The stereocilia of the inner and outer hair cells lie directly under the middle zone. Visual detection levels of threshold of tectorial membrane movement was determined by stimulating the marginal zone of the tectorial membrane of isolated cochlear coils by an oscillating water jet. After acoustic overstimulation the tectorial membrane became more compliant. The tectorial membrane abnormalities were restricted to the regions of the cochlea that demonstrated a 40–50 dB hearing loss.     

The ultrastructural organization and properties of the mouse tectorial membrane matrix

The polyphenolic compound tannic acid and the cationic stains ruthenium red, Alcian blue and lanthanum chloride have been used to reinvestigate the ultrastructural organization of the tectorial membrane matrix. Tannic acid treatment reveals that the matrix both in between and within the Type A protofibril bundle system has a high degree of structural organization. The basic unit of this matrix is best described as a 'striated sheet'. These striated sheets are formed by alternating 'dark' and 'light' fibrils which run parallel to one another and lie within the plane of each sheet. In sodium based buffers both light and dark fibrils have diameters of approximately 7 nm and the distance between each dark fibril in a sheet varies from 30 to 46 nm. Dark and light fibrils are coupled by periodic, staggered cross-bridges which occur at approximately 12 nm intervals along the fibrils. Fibril diameters in tectorial membranes prepared and fixed in potassium based buffers are from 10-20% greater than they are in tectorial membranes prepared and fixed in sodium based buffers. Fine fibrils can also be resolved in the matrix with the cationic stains lanthanum chloride and ruthenium red, but the organization of these fibrils into a regular matrix structure is most clearly resolved with tannic acid treatment. The striated sheets are largely destroyed by treating the tectorial membranes with neutral trypsin and are insensitive to treatment with bacterial collagenase. In contrast, the Type A protofibril system is trypsin resistant and collagenase sensitive. Treatment of tectorial membranes with salt solutions containing either 5 nM EDTA or 5 mM EGTA and 2 mM MgCl2 results in a complete loss of organized striated sheets and the appearance of randomly dispersed fibrillar material and small particles. Re-addition of Ca2+ ions causes the striated sheets to reform, indicating that the structure can undergo at least one cycle of depolymerization and polymerization in vitro. Reduction of disulphide bonds with beta-mercaptoethanol causes a loss of structural organization similar to that observed after EDTA or EGTA treatment. The results demonstrate that the non-collagenous components of the tectorial form a matrix with a degree of organization that has been previously unrecognised.     

Regeneration of the tectorial membrane in the chick cochlea following severe acoustic trauma

Damage to the tectorial membrane caused by acoustic trauma was examined with scanning and transmission electron microscopy immediately after exposure and at selected time points over a 10 day recovery period. At 0 h of recovery the structure of the tectorial membrane overlying the region of hair cell damage was severely disrupted and connections between the membrane and the basilar papilla were lost. By 24 h of recovery, regeneration of the tectorial membrane was evident in the secretion of new matrix materials by the supporting cells of the basilar papilla. By 10 days of recovery a new honeycomb-like matrix had replaced the segment of damaged tectorial membrane, re-established connections with hair cell stereocilia and become fused with adjacent regions of undamaged tectorial membrane. However, the regenerated segment included only the honeycomb-like structure of the lower layer of the normal tectorial membrane. The laterally-oriented fibers which form the upper layer of the membrane were not regenerated over the damaged region. These findings indicate that the tectorial membrane is regenerated in parallel with the hair cells during recovery from acoustic trauma but the full extent of this recovery and its effect on cochlear function are not yet clear.     

Localization of the marginal zone of the tectorial membrane in situ, unfixed, and with in vivo-like ionic milieu.

In order to determine the normal positional relationship between the tectorial membrane and the organ of Corti, a preparation method was developed which made it possible to study the unfixed tectorial membrane in its normal position in relation to the cochlea and with in vivo-like ionic conditions. With this method, post-mortem changes visible with the light microscope were detectable after 60 to 90 min instead of the normal 30 min. When endolymph of artifical endolymph are present in the scala media, the marginal zone lies in close contact with the surface of the organ of Corti. If the endolymph is replaced by artificial perilymph, first the marginal zone of the tectorial membrane, and later the whole membrane shrinks. At this stage, latex particles suspended in the perilymph are free to enter the subtectorial space.     

Structural relationships of the unfixed tectorial membrane

Although the tectorial membrane has a key role in the function of the organ of Corti, its structural relationship within the cochlear partition is still not fully characterised. Being an acellular structure, the tectorial membrane is not readily stained with dyes and is thus difficult to visualise. We present here detailed observations of the unfixed tectorial membrane in an in vitro preparation of the guinea pig cochlea using confocal microscopy. By perfusing the fluid compartments within the cochlear partition with fluorochrome-conjugated dextran solutions, the tectorial membrane stood out against the bright background. The tectorial membrane was seen as a relatively loose structure as indicated by the dextran molecules being able to diffuse within its entire volume. There were, however, regions showing much less staining, demonstrating a heterogeneous organisation of the membrane. Especially Hensen's stripe and regions facing the outer hair cell bundles appeared more condensed. Whereas no connections between Hensen's stripe and the inner hair cell bundles could be observed, there was clearly a contact zone between the stripe and the reticular lamina inside of the inner hair cell.     

Guinea pig tectorial membrane profile in an in vitro cochlear preparation

The guinea pig cochlea was examined under high-magnification light microscopy in an in vitro preparation. After extraction of the otic capsule, the bulla was opened widely and a small hole made into the fourth turn of the scala vestibuli. The organ of Corti was visualized under artificial endolymph at 600 X magnification. Added 1-micron titanium dioxide particles settled on the upper surface of the transparent tectorial membrane. Particle positions showed that much of this upper surface lay in a flat sheet that extended centrifugally almost to the Hensen's cells, giving the impression it was attached there. The sheet extended at least to the level of the inner hair cells, where a tectorial membrane thickness of about 40 micron was reached. Titanium dioxide particles were seen regularly in immediate proximity to the hair cell cilia, indicating that scala media is continuous with the subtectorial space. Upon mechanical manipulation, Hensen's cells proved to be extremely cohesive and elastic. It is suggested that hair cell stereocilia provide major mechanical connections for the tectorial membrane.     

Imprints of the inner sensory cell hairs on the human tectorial membrane

Summary Imprints indicating possible direct inner sensory cell hair contact with the tectorial membrane were observed in the cochlea of a 77-year-old woman under a scanning electron microscope (SEM). The imprints were seen in the lower and upper basal cochlear turns but not in the apical and middle turns. The small dot of imprints numbered from a few up to 12 and were arranged in various forms rather than straight lines. Contact between the tectorial membrane and inner and outer sensory cell hairs of the human cochlea was discussed from the SEM findings found in this case.     

The surface morphology of the avian tectorial membrane

The structure of the tectorial membrane of the chick was evaluated by scanning electron microscopy (SEM), using standard techniques, and, for the first time, by studying unfixed tectorial membranes with video-enhanced light microscopy techniques (AVEC-DIC). The SEM pictures show a widely varying morphology, ranging from a fully perforated tectorial membrane to a completely closed upper boundary, with a smooth surface. Based on several indicators, it is concluded that the latter presents the more natural state. This was confirmed by the results of the AVEC-DIC technique, which show a highly homogeneous structure. In contrast to the bulk of the tectorial membrane, its lower surface shows discrete structures, especially regularly oriented fibril bundles.     

A newly identified surface coat on cochlear hair cells

Routine electron microscope methods do not well preserve or stain the surface coat or glycocalyx on cochlear hair cells. In other tissues, enhanced preservation and staining of these glycoconjugates was obtained following fixation with glutaraldehyde containing a cationic dye (e.g., Alcian blue and ruthenium red). When cochleas were fixed with glutaraldehyde containing Alcian blue, the endolymphatic surface of hair cells, but not the supporting cells, displayed an extensive (approximately 90 nm thick) surface coat. Alcian blue positive material was also observed in the tectorial and basilar membranes and in a portion of the spiral ligament. In addition, acellular bands of Alcian blue positive material were observed between the tectorial membrane and the reticular lamina or inner sulcus cells. Although the function of these cochlear glycoconjugates is not yet known, it is proposed that they serve to attach the tectorial membrane to the organ of Corti, and they are involved in stereocilia fusion following sound exposure and ototoxic drug administration.     

豚鼠耳蜗盖膜下面的超微结构

目的 利用扫描电镜技术详细地观察豚鼠盖膜下的超微结构,为耳蜗的感音机制提供新的认识.方法 用S-4800型超高分辨率扫描电子显微镜观察了6只豚鼠12只耳蜗的盖膜.结果 (1)耳蜗各圈盖膜下面均可观察到外毛细胞静纤毛压迹,这种压迹多半与静纤毛最高排的形态一致,第一圈呈“W”型,由基底圈到顶圈,逐渐由“W”型渐变为“V”型及不规则的簇状.压迹为一排圆形的小凹,将盖膜下表面表层辐射状纤维断开,只有最高排的静纤毛才与盖膜接触形成压迹,压迹排列呈串珠一样.(2)盖膜下内毛细胞相应的位置有一条较深的波浪状沟槽,呈线性结构,沟槽比外毛细胞静纤毛的压迹浅而宽,由耳蜗的基底圈到顶圈这种压迹逐渐呈带状.(3)盖膜下的纤维由盖膜的外缘到盖膜与内毛细胞静纤毛压迹之间以蜗轴呈辐射状排列,但在外毛细胞静纤毛压迹的位置被这些压迹所阻断,而总的辐射方向和纤维走行并没有改变,纤维非常的精细,每根纤维之间又相互交错相连.内、外毛细胞压迹之间,柱细胞顶部的盖膜纤维很细,均匀呈细丝状.而内毛细胞与螺旋缘之间,即内沟上方的盖膜下方的纤维更加细长.结论 通过对盖膜超微结构的观察,盖膜下内外毛细胞静纤毛的压迹充分说明毛细胞静纤毛与盖膜的接触.盖膜下的纤维由盖膜的外缘到柱细胞和柱细胞到盖膜下内毛细胞静纤毛带状压迹之间也就是内、外毛细胞压迹之间,柱细胞顶部的盖膜的纤维与内毛细胞顶部盖膜带状结构到螺旋缘之间的纤维的粗细都不一样.这种纤维的分布特点,可能与盖膜在声音调谐方面所起的作用有一定的关系.     

Mechanical properties of the tectorial membrane in situ

According to the classical model of cochlear hair-cell stimulation, the tectorial membrane moves in cross-section like a stiff beam, rotating around the lip of the spiral limbus. This produces a shearing motion against the reticular lamina and, as a result, a radial deflection of the hair-cell stereocilia. The deflection can be effectively produced by the tectorial membrane only if its stiffness in the radial direction is greater than that of the stereocilia. We were able to manipulate the tectorial membrane through a scala-media access in live Mongolian gerbils and to measure its transverse and radial stiffness. We found the membrane to behave like a rubber band and to be much less stiff than the stereocilia. This is incompatible with the classical model. The tectorial membrane must act on the stereocilia as a mass load rather than a stiff anchor.     

Histochemical analysis of glycoconjugates in gelatinous membranes of the gerbil's inner ear.

The gelatinous membranes of the gerbil inner ear were analyzed histochemically for glycoconjugates with a battery of twenty horseradish peroxidase-conjugated lectins. Glycoconjugates with mannose (Man) and/or glucose (Glc), galactose (Gal), fucose (Fuc), N-acetylglucosamine (GlcNAc), N-acetylgalactosamine (GalNAc) and N-acetylneuraminic acid (NeuAc) were detected in the tectorial and otolithic membranes and cupula. Differences in lectin reactivity were observed between tectorial and vestibular membranes and also among zones and between the medial and lateral regions of the middle zone of the tectorial membrane. The distribution of staining differed markedly for several lectins that bind specifically to GalNAc or to GlcNAc but vary in affinity for oligosaccharides containing these sugars in different sequences or linkages. The findings suggest presence of the terminal disaccharides GalNAc alpha 1,3Gal in tectorial membrane and Gal beta 1,3GalNAc in vestibular membranes. Lectin binding profiles provided evidence that the limbal zone's fibrous and attachment layers contain mainly O-glycosidically linked oligosaccharides whereas the middle zone's medial fibrous layer contains both O- and N-linked chains. The remaining regions of the tectorial membrane contain mainly N-linked oligosaccharides with bisected biantennary type chains predominating. Additionally, the marginal band and the middle zone's basal layer contain abundant N-linked oligosaccharides with a triantennary structure.     

Polypeptide composition of the mammalian tectorial membrane

The effects of the enzymes collagenase, pepsin, chondroitinase ABC and keratanase on the polypeptide composition of the mammalian tectorial membrane have been analysed using one dimensional SDS-polyacrylamide gel electrophoresis (SDS-PAGE). After reduction at least ten polypeptides can be consistently and clearly recognized in SDS gels with molecular weights relative to globular protein standards of 245, 235, 190, 165, 155, 145, 100, 93, 60-73 and 35-49 kDa. With the exception of the 60-73 and 35-49 kDa bands all these polypeptides are sensitive to digestion with bacterial collagenase. The 235, 165, 155, 145 and 93 kDa bands also resist degradation by cold, acidic pepsin. Amino acid analysis of whole tectorial membranes demonstrates that glycine accounts for nearly 25% of the total amino acid content, that proline, hydroxyproline and hydroxylysine are present and that amine sugars can be detected in fairly high concentrations. Estimates based on hydroxyproline content suggest that collagens account for 25-50% of the total tectorial membrane protein. Immunoblotting techniques demonstrate the presence of polypeptides cross reacting with antisera to Type II collagen, Type IX collagen and Type V collagen. Results from immunohistochemical studies confirm that these polypeptides are present in the tectorial membrane and are not contaminants of the isolation procedure. Collagenase treatment of tectorial membranes reveals the presence of an additional non-collagenous polypeptide with an apparent molecular weight of 173 kDa on 7.5% polyacrylamide gels, and polydisperse high molecular weight material spreading over a broad range at the top of the gels. This high molecular weight material and the 173, 60-73 and 35-49 kDa non-collagenous polypeptides are pepsin sensitive and all bind wheat germ agglutinin (WGA) suggesting that they contain N-acetyl glucosamine. The 173 kDa band also binds soybean agglutinin (SBA) suggesting the presence of N-acetyl galactosamine. In the absence of reducing agent the 173 and 60-73 kDa bands are no longer observed and high molecular weight material forming a broad band at the top of the separating gel is seen. The electrophoretic behaviour of this non-collagenous, glycosylated, disulphide bonded, high molecular weight material is altered by treatment with keratanase but not by chondroitinase ABC. The results of this study indicate the tectorial membrane contains at least three different collagen types and, in addition to these collagenous proteins, several non-collagenous, glycosylated polypeptides that may account for as much as 50% of the total tectorial membrane protein.     

Histopathology of the temporal bones of deaf dogs

Histopathological studies were done in 22 deaf dogs consisting of 10 Dalmatians, 5 English setters, 2 Great Danes, 2 foxhounds, 1 shepherd, 1 bulldog and 1 Australian sheep dog. Hypoplasia or aplasia of the sensory cells of the organ of Corti, stria vascularis and macula sacculi (pars inferior) was noted in all deaf dogs examined, indicating the pathology of inner ear malformation in these dogs to be of Scheibe's type. A solidified and calcified tectorial membrane was noted in 19 out of the 22 deaf dogs. A calcified sclerosis of the tectorial membrane is thought to be a characteristic finding of genetically inherited anomaly of the inner ear in deaf dogs. Distortion of the tectorial membrane, absence of the sensory cells in the organ of Corti, agenesis of the stria vascularis and abnormalities of the saccule described Scheibe's dysgenesis of the pars inferior as the pathological correlate for deafness in these dogs as assessed functionally.     

Morphological changes in the tectorial and basilar membranes of aged rats

Using both light and transmission electron microscopy presbycusic degeneration of the cochlea was observed in particular in the tectorial and basilar membranes, in naturally aged rats. These animals showed a descending auditory pattern as determined by auditory brainstem response. Ultrastructurally, the number of collagen fibers in the tectorial membrane was reduced and straight type A fibers were increased relative to branched, coiled type B fibers. The basilar membrane in the basal turn was also thickened by an increased homogeneous ground substance. These findings indicate that the specificity of vibration of the tectorial and basal membranes is very different in aged and young rats.     

Frequency dependence of synchronization of cochlear nerve fibers in the alligator lizard: evidence for a cochlear origin of timing and non-timing neural pathways

The dependence of synchronization of spike discharges on tone frequency was measured in cochlear nerve fibers of anesthetized alligator lizards at 21 degrees C. Synchronization measures were based on the fundamental component of a Fourier analysis of the instantaneous discharge rate in response to tone bursts. Measurements were obtained from fibers innervating hair cells in both the region of the cochlea that contains a tectorial membrane (tectorial fibers) and the region where hair-cell stereocilia are free-standing in scala media (free-standing fibers). Both rate and synchronization tuning-curves were measured automatically as a function of tone frequency. For tectorial fibers, the shapes of synchronization tuning-curves are roughly similar to the shapes of rate tuning-curves: the characteristic frequencies (CF's) of both curves are approximately equal. For free-standing fibers, the shape of synchronization tuning-curves differ markedly from those of rate tuning-curves. The CF's of synchronization and rate tuning-curves differ - the ranges are 0.2-0.6 kHz and 1-4 kHz, respectively - and the two CF's are uncorrelated. Synchronization filter-functions, which are contours of synchronization index at constant average discharge rate, were measured as a function of tone frequency for both tectorial and free-standing fibers. These synchronization filter-functions have the shapes of lowpass filters. For the populations of tectorial fibers and of free-standing fibers taken separately, these functions are independent of CF. The corner frequency of these functions is 0.50 +/- 0.038 kHz for tectorial fibers and 0.37 +/- 0.037 kHz for free-standing fibers. We conclude that these populations are characterized by different synchronization filters. For free-standing fibers, synchronization filter-functions measured at average driven discharge rates of about 20 and 40 spikes/s do not differ appreciably, and the high-frequency slope is -80 to -115 dB/decade. The results show that tectorial fibers encode timing information for low-level stimuli, whereas free-standing fibers do not. It is proposed that in the alligator lizard, neural pathways that encode timing information originate in the tectorial region and those that encode non-timing information originate in the free-standing region.     

Neural tuning in the granite spiny lizard

Scanning electron microscopy was used to examine the basilar papilla of the granite spiny lizard. The papilla contains three distinct hair cell populations: an apical and a basal population with free-standing cilia, and a central population with a tectorial membrane. In the free-standing populations, stereocilium length decreases towards the ends of the papilla. Ciliary tuft morphology differs in the free-standing and the tectorial membrane populations, except that several of the free-standing hair cells with the shortest stereocilia have a tuft morphology like the hair cells in the tectorial membrane population. On the basis of single-fiber physiology, auditory nerve fibers can be divided into a low characteristic frequency (CF) and a high CF population. Mappings of the tonotopic organization of the nerve demonstrated two groups of high CF fibers that correspond to the two free-standing hair cell populations. The low CF fibers are associated with the tectorial membrane hair cell population. Fiber CF correlated with hair cell cilium length, not position on basilar membrane, for hair cells with free-standing cilia. Tonotopic organization of high CF fibers could be predicted reasonably well from the histogram of fiber CFs.