A voltage- and Ca2+-dependent big conductance K channel in cochlear spiral ligament fibrocytes.

Evidence is accruing that spiral ligament fibrocytes (SLFs) play an important role in cochlear K(+) homeostasis, but little direct physiological data is available to support this concept. Here we report the presence and characterization of a voltage- and Ca(2+)-dependent big-conductance K (BK) channel in type I SLFs cultured from the gerbil cochlea. A single-channel conductance of 298+/-5.6 pS (n=28) was measured under symmetrical K(+). Membrane potentials for half-maximal open probability (P(o)) were -67, -45 and 85 mV with cytosolic free-Ca(2+) levels of 0.7 mM, 10 microM and 1 microM, respectively (n=8-14). The Hill coefficient for Ca(2+) affinity was 1.9 at a membrane potential of 60 mV (n=6). The BK channel showed very low activity (P(o)=0.0019, n=5) under normal physiological conditions, suggesting a low resting intracellular free [Ca(2+)]. Pharmacological results fit well with the profile of classic BK channels. The estimated half-maximal inhibitory concentration and Hill coefficient for tetraethylammonium were 0.086+/-0.021 mM and 0.99, respectively (n=4-9). In whole cell recordings, the voltage-activated outward K current was inhibited 85.7+/-4.5% (n=6) by 0.1 microM iberiotoxin. A steady-state kinetic model with two open and two closed stages best described the BK gating process (tau(o1) 0.23+/-0.08 ms, tau(o2) 1.40+/-0.32 ms; tau(c1) 0.26+/-0.09 ms, tau(c2) 3.10+/-1.2 ms; n=11). RT-PCR analyses revealed a splice variant of the BK channel alpha subunit in cultured type I SLFs and freshly isolated spiral ligament tissues. The BK channel is likely to play a major role in regulating the membrane potential of type I SLFs, which may in turn influence K(+) recycling dynamics in the mammalian cochlea.

Effects of gap junction uncoupling in the gerbil cochlea.

OBJECTIVE: To gain insight into molecular and cellular mechanisms regulating cochlear potassium (K+) recycling, including the possible effects of mutations in the gene, which encodes the gap junction protein connexin 26. Intercellular K+ flux was manipulated in vivo by infusion of the gap junction uncoupler proadifen (SKF-525A) into perilymph. Functional and structural alterations induced by gap junction blockade were assessed by electrophysiological and morphologic analysis. STUDY DESIGN: Laboratory study using an animal model. METHODS: Physiological effects of acute and chronic uncoupling of gap junctions in the Mongolian gerbil inner ear were evaluated by measurement of compound action potential (CAP) thresholds and input-output (I/O) functions, distortion product otoacoustic emissions (DPOAE), and the endocochlear potential (EP). Morphologic changes were assessed by electron microscopy. RESULTS: Acute exposures to proadifen resulted in large decreases in EP values, DPOAE magnitudes, and CAP I/O maximum amplitudes and an increase in high-frequency CAP thresholds. These physiological changes were accompanied by vacuolization of type II and type V fibrocytes in the lateral wall of the cochlea. Chronic treatments revealed some recovery in EP values and CAP thresholds, which showed a relatively flat 15- to 20-dB elevation across frequencies. CONCLUSIONS: Gap junctions play a significant role in normal cochlear function. In particular they appear to be essential for maintaining the EP, an activity that could be related to their participation in K+ recycling. Thus, hearing losses associated with mutations in the gene that alter the expression or function of connexin 26 may result from a diminished capacity to recycle K+ from perilymph back to the stria vascularis and a consequent decline in the EP.

Developmental expression of monocarboxylate transporter in the gerbil inner ear.

The expression of H+-monocarboxylate cotransporters (MCTs) that facilitate cell uptake of lactate, pyruvate and other monocarboxylates was investigated in the adult and postnatally developing gerbil inner ear. In the mature cochlea, immunoreactive MCT1 was present in marginal cells of the stria vascularis and in type II, suprastrial and limbal fibrocytes. In the adult vestibular system, dark cells and a subpopulation of fibrocytes immediately underlying maculae and cristae stained strongly for MCT1. Satellite cells surrounding mature spiral and vestibular ganglia neurons also expressed MCT1. MCT1 immunoreactivity was present at birth in marginal and dark cells, at 8 days after birth in fibrocytes and at 12 days after birth in satellite cells, and coincided precisely with the developmental expression of Na,K-ATPase in these sites. The coexpression of MCT1 and Na,K-ATPase in these cell types points to MCT1 as an important source of energy to drive inner ear Na,K-ATPase activity. In the adult inner ear, MCT2 was detectable only in tectal cells of the cochlea and supporting cells of the crista ampullaris. Immunostaining was first observed at 16 days after birth in tectal and at 20 days after birth in supporting cells, and at the same time immunoreactive aquaporin 4 appeared in these cells. The coexpression of MCT2 and aquaporin 4 suggests a possible role for MCT2 in regulating transcellular water movement. Because MCT2 facilitates the transport of acidic intermediates, its biological significance also could relate to modulation of cell pH and volume. Maintenance of the inner ear's unique ion and fluid gradients is essential to normal hearing and balance and requires the expenditure of large amounts of energy. The cellular distribution of MCT1 and MCT2 points to their participation in generating these electrochemical gradients and their potential involvement in sensory deficits associated with various inner ear disorders.

Immunohistochemical localization of phospholipase C isozymes in mature and developing gerbil cochlea.

The possibility that phospholipase C contributes to intracellular signaling in the cochlea was investigated by immunostaining for eight different isoforms of the enzyme. In the mature gerbil cochlea, expression of the isozymes varied widely among different cell types. The phospholipase C-beta1 isoform was detected in inner and outer hair cells, and spiral ganglion neurons where it may participate in regulating Ca(2+) flux. The beta3 isozyme was expressed in epithelial cells thought to mediate lateral and medial circulation of potassium. The beta2 isozyme was present in border, inner phalangeal and Hensen cells, the stria vascularis, and suprastrial and supralimbal fibrocytes where it also may be involved in regulating ion transport activities. The phospholipase C-gamma isozymes were expressed in supporting cells, the stria vascularis, and certain fibrocytes where they possibly participate in activating tyrosine kinase and modulating ion conductances. The delta2 isoform was found in pillar, outer sulcus and strial marginal cells as well as spiral ganglion neurons and their radial processes. Documentation of changes in the expression pattern of phospholipase C isoforms during postnatal development and knowledge of their distribution in several positive control tissues provided further data for speculation about the biologic significance of the cochlear reactivity. The results demonstrate a wide diversity of isozyme distribution in the cochlea and suggest that the enzymes affect activities of various cochlear cell types in different ways.

Ultrastructural changes in the spiral limbus associated with carboplatin-induced ablation of inner hair cells.

Four months after the selective ablation of inner hair cells by carboplatin, the interdental cell epithelium exhibited dilated intercellular spaces and cytosolic vacuoles not seen in controls. In addition, the wide, often electron-lucent phalanges observed in the interdental cells of the normal chinchilla collapsed into a dense stratum that projected enlarged polypoid profiles into the limbal zone of the tectorial membrane. Carboplatin treatment also resulted in the restructuring of the tectorial membrane overlying the limbus. Changes in this membrane included a variable accumulation of the basal matrix, the rearrangement of intermediate lucent spaces, and the disappearance of a superimposed filamentous mesh. These three strata are, under normal conditions, apparently involved in events underlying tectorial membrane renewal. The post-carboplatin changes in the interdental cells and tectorial membrane occurred exclusively in the proposed medial pathway for K+ diffusion from inner hair cells and presumably resulted from a reduced flow of ions and fluid secondary to the ablation of these cells.

Canalicular reticulum in vestibular hair cells.

A membrane limited system referred to as canalicular reticulum (CR) has been demonstrated in the apical cytosol of the cochlea's inner and outer hair cells. Similarities between cochlear and vestibular hair cells prompted investigation of the presence of CR in hair cells of the gerbil vestibular labyrinth. A method of fixation with glutaraldehyde followed by an osmium-ferrocyanide mixture demonstrated abundant CR in the apex of both type I and type II hair cells. The CR was closely associated with numerous Golgi zones in the apex of the vestibular hair cells, indicating its genesis from Golgi cisternae. Also preserved in upper cytosol were discrete complexes of mitochondria with granular reticulum. These complexes offered a possible site for generating the membrane in Golgi zones and CR. Single and parallel cisternae of granular reticulum were observed in the basal half of the hair cells together with numerous synaptic-like vesicles. These cisternae with their terminal blebbing and accompanying canaliculi were interpreted as novel structures mediating synaptic vesicle genesis in vestibular hair cells in a manner comparable to that postulated for cochlear inner hair cells.

Structural evidence for ion transport and tectorial membrane maintenance in the gerbil limbus.

Cells medial to the tunnel of Corti were examined to assess fine structural features relevant to their proposed role in cochlear K(+) homeostasis. A dense network of canaliculi referred to as canalicular reticulum (CR) resided in the foot body of inner pillar cells, where it bordered and could resorb ions released from inner radial and spiral nerves. Lateral interdental cells (IDCs) formed columns which connected the inner sulcus epithelium with the base of the tectorial membrane's (TM) middle zone. A spout-like neck in cells at the top of lateral IDC columns housed a dense concentration of CR which resembled that characteristic of ion transporting epithelia and appeared to be located here for transporting ions and fluid toward the TM. Clustered IDCs in the center of the limbus connected underlying limbal stroma with the TM's limbal zone and appeared capable of transporting ions from stroma to TM. Abundant CR in limbal stellate fibrocytes evidenced their capacity to transport ions and fluid, presumably from inner sulcus epithelium toward central IDCs. The most medial IDCs possibly function as the terminus of an ion cycling path from scala vestibuli to endolymph. Light fibrocytes situated between supralimbal fibrocytes and medial IDCs appeared to serve as a link in this pathway. The limbal zone of the TM overlying central IDCs consisted of three distinct regions which offered a structural basis for transformation of an amorphous matrix supplied by central IDCs into the protofibrils of the membrane's middle zone.

Distribution of IkappaB proteins in gastric mucosa and other organs of mouse and gerbil.

The NF-kappaB/IkappaB complex is a major transcription regulator of inflammatory and immune responses. Helicobacter pylori infection causes chronic inflammation in gastric mucosa by inducing dissociation of the inhibitory IkappaB protein from the complex with a resulting increased expression of interleukin (IL)-8. To clarify which of several known IkappaB proteins could be involved in this inflammatory response, we undertook immunohistochemical examination of normal mouse stomach as well as other murine tissues for comparison, using polyclonal antibodies specific for alpha-, beta-, gamma-, and in-isoforms of IkappaB. The results showed strong immunoreactivity for the alpha-isoform in parietal cells and for the beta-isoform in pit cells of the stomach, along with the presence of these proteins in various other sites. Comparative staining revealed a similar but not identical distribution of IkappaB proteins in the Mongolian gerbil, a rodent model for H. pylori infection. The findings suggest that the alpha- and beta-isoforms are dominant IkappaB proteins in gastric parietal and foveolar cells, respectively, and point to a role for these transcription regulators in modulating pathological responses in stomach and other organs. (J Histochem Cytochem 48:191-199, 2000)

Ablation of inner hair cells by carboplatin alters cells in the medial K(+) flow route and disrupts tectorial membrane.

The thesis that K(+) effluxing from inner hair cells (IHCs) cycles medially back to endolymph through inner sulcus and interdental cells (IDCs) was tested by comparing control chinchilla cochleas with those in which IHCs were selectively destroyed by carboplatin. By light microscopy inner sulcus cells appeared tall and nearly empty in control ears, but 4 months after the carboplatin treatment many showed vacuolization and shrinkage. Inner pillar cells also consistently developed abnormal vacuoles after carboplatin treatment. Control cochleas exhibited lateral columns and central clusters of IDCs which at their apex possessed expanded presumably hydrated phalanges. Four months after carboplatin, the IDC epithelium enclosed empty looking spaces and the apical phalangeal compartment collapsed into a thin, apparently dehydrated layer. This alteration was accompanied by changes in the tectorial membrane (TM) whereby the membrane's limbal zone thickened progressively to form a tall hollow mound in advanced lesions. The clear spaces in the epithelium and collapse of the phalanges are thought to reflect diminished flow of ions and fluid through IDCs. The accumulation of limbal TM supports the premise that IDCs secrete macromolecules for TM turnover as well as ions and fluid for promoting lateral migration of its precursor constituents. Occurring after ablation of IHCs by carboplatin, the changes in inner pillar, inner sulcus and IDCs and limbal TM can be viewed as a secondary effect of the interrupted ion efflux from IHCs and as further evidence that this effluent follows a medial route.

Novel membranous structures in apical and basal compartments of inner hair cells.

Postfixation with a ferrocyanide-osmium tetroxide solution preserved a dense network of canaliculi extending from the apical to the upper lateral plasma membrane in cochlear inner hair cells (IHCs). Numerous Golgi bodies intermingled with this apical canalicular reticulum (CR). Osmium-ferrocyanide treatment also disclosed several previously unreported structures below the IHC nucleus. The first consisted of stacks of six or eight and sets of three parallel cisternae of rough endoplasmic reticulum spanning between clustered mitochondria. Some parallel cisternae ended with segmentation where they contacted mitochondria, and others terminated by transforming into blebs or continuing into canaliculi. A second feature was comprised of a complex of segmented cisternae and branching canaliculi with clustered mitochondria. Branching minicanaliculi with associated vesicles neighbored the complexes. A fourth entity consisted of synaptic-like vesicles that largely filled the subnuclear cytosol and congregated at synapses. An additional infranuclear structure was composed of slender canaliculi that collected near or streamed to plasmalemma, often next to a synapse. A paradoxical absence of rough endoplasmic reticulum above and Golgi zones below the nucleus provided evidence of atypical mechanisms for generating the membrane in CR and forming synaptic vesicles. The observations offer the view that IHCs are compartmentalized into an apical mechanoreceptor half and a basal half that affects neurotransmission. The apical CR provided a possible structural basis for sequestering the K+ known to influx apically and for directing its diffusion to the site of known efflux across the lateral plasmalemma. The codistribution of parallel cisternae, canalicular-mitochondrial complexes, and synaptic-like vesicles, all of which are unique to IHCs, implicated the cisternae and complexes in the genesis of the vesicles.

Distribution of canalicular reticulum in Deiters cells and pillar cells of gerbil cochlea.

Postfixation with an osmium tetroxide-potassium ferrocyanide solution revealed in supporting cells in the organ of Corti a network of canaliculi termed canalicular reticulum (CR). In Deiters cells (DCs), the CR filled cytosol at the base of the phalanx and under plasmalemma apposed to either the outer hair cells' (HCs) basal surface or nerve terminals. From these locations the CR, accompanied by dense fibrillar substance, descended along microtubule bundles and terminated by surrounding the rosette complex in the apical cytosol. Canalicular profiles protruding from the reticulum penetrated the loose meshwork comprising the periphery of the rosette complex to contact at intervals branches of the dense trabeculae that make up the core of the complex. This arrangement disclosed a structural and presumably functional relationship between outer HCs and the CR and rosette complex. Inner pillar cells (PCs) exhibited moderately abundant to sparse profiles of CR interspersed between microtubule bundles of the microtubule stalk that connected head and foot regions. More elaborate CR extended as a network upward from the top of the microtubule stalk part was into the head body and downward into a conical expansion of the stalk at the base of the cell. Cytosol on the medial side of the basal microtubule expansion contained abundant CR which in conjunction with CR between basal microtubule bundles lay situated for possible uptake of ions or neurotransmitter released from numerous adjoining nerves. CR in outer PCs resembled that in inner PCs but appeared less prevalent in the head and foot regions and did not occur in cytosol beside the basal microtubule stalk. Characteristically small Golgi complexes accompanied the reticulum in DCs and were prevalent in the upper regions but absent in the mid and lower part of inner PCs. Short cisternae in the Golgi stacks associated with CR contrasted with the lengthier cisternae in the complexes infrequently observed in cytosol outside the microtubule stalk of inner PCs.

Immunohistochemical localization of Ca2+/Calmodulin-dependent protein kinase IV in outer hair cells.

A smooth membrane system consisting of subsurface cisternae (SSC) underlies the lateral plasmalemma of auditory outer hair cells (OHCs). The SSC contain Ca-ATPase and are regarded as an intracellular Ca2+ reservoir like the sarcoplasmic reticulum of myocytes. Recently, it has been demonstrated that Ca-ATPase activity in sarcoplasmic reticulum is regulated by Ca2+/calmodulin-dependent protein kinases (CaM kinases). Here we investigated the presence of CaM kinases in OHCs and their possible association with the SSC. Inner ears collected from adult gerbils and from neonates at 2-day intervals between 0 and 20 days after birth were immunostained with antibodies specific for different CaM kinases. A polyclonal antiserum against CaM kinase IV yielded a strong immunostaining reaction along the lateral wall of OHCs. The staining appeared after the tenth postnatal day and continued into adulthood. No other site in the inner ear, including cochlear inner hair cells and vestibular hair cells, was reactive. The kinase's apparent association with the SSC strongly supports its involvement in intracellular Ca2+ homeostasis and suggests a role in regulating the OHCs' slow motile responses.

Cytologic evidence for mechanisms of K+ transport and genesis of Hensen bodies and subsurface cisternae in outer hair cells.

UNLABELLED: A system commonly termed the tubulocisternal endoplasmic reticulum (TCER), but designated here the canalicular reticulum (CR), occurs selectively in ion-transporting epithelia, in which it is interpreted as facilitating the transcellular diffusion of ions. Mechanoelectrical transduction in the cochlear outer hair cells (OHCs) depends on the apical influx and the subsequent basolateral efflux of K+. Cytologic structures that possibly mediate K+ transport in gerbil OHCs were investigated here. METHODS: Cochleas were fixed primarily with glutaraldehyde and secondarily with reagents for demonstrating TCER or were fixed with a ferrocyanide-osmium tetroxide solution to preserve intracellular membranes. The distribution of membranous structures retained with these techniques was examined by using electron microscopy. RESULTS: Secondary fixation with osmium tetroxide-ferrocyanide permitted ultrastructural demonstration in OHCs of increased numbers of Hensen bodies and newly detected membranous systems, including CR, linear cisternae, small clusters of cytosolic vesicles and complexes of canaliculi, segmented cisternae, and mitochondria. CR filling an apical stratum beside and below the cuticular plate and contacting laterally the uppermost subsurface cisternae (SSC) was situated to sequester and transport the apical K+ influx that attends the acoustically generated receptor potential and the silent current. The close association of CR with numerous, highly developed Golgi bodies exclusively in the apex of the cell suggested genesis of CR from Golgi cisternae. Nonbranching, linear cisternae occupied a lower cell stratum and spread from CR laterally to a more inferior region of the SSC. Small clusters of vesicles in the central cytosol resembled Hensen bodies in their envelopment by branching canaliculi and segmented cisternae in close association with mitochondria. Viewing the vesicles in Hensen bodies and the small clusters as functioning like most other cytoplasmic vesicles in transport of cell membrane permitted the interpretation that these vesicles move nascent membrane from the canalicular-mitochondrial complex to the SSC. Other small clusters of vesicles contacted the innermost layer of the SSC, often at cisterna-depleted foci in which the vesicles appeared to either replenish the SSC or arise in the course of its turnover. Proximity of multivesicular bodies and lysosomes to small vesicle clusters in foci of depleted SSC implicated the lysosomes in digesting vesicles released from the SCC. Populations of unique, large, lysosome-like bodies and of small, dense bodies in the upper cytosol of OHCs appeared to be involved in different catabolic pathways mediating the turnover ofSSC, CR, and other structures. CONCLUSIONS: Cochlear OHCs contain previously unrecognized membranous organelles that facilitate ion transport and presumably contribute thereby to mechanoelectrical transduction. Vesicles in small clusters and Hensen bodies arise from complexes of canaliculi, cisternae, and mitochondria and contribute membrane to the genesis of the SSC.

Evidence for a medial K+ recycling pathway from inner hair cells.

K+ effluxed from outer hair cells and their nerves is thought to flow laterally to strial marginal cells for recycling into scala media. Observations reported here provide evidence that K+ effluxed from inner hair cells and inner radial nerves travels medially through border cells, inner sulcus cells (ISCs), limbal fibrocytes and interdental cells (IDCs) for return to endolymph. Morphologic features of ISCs in the medial route resembled those of Hensen and Claudius cells in the lateral indicating an ion transport role for ISCs like that of Hensen and Claudius cells. Na,K-ATPase in plasmalemma of IDCs testified to their capacity to resorb and transport K+ through their known gap junctions. IDCs were differentiated into three subgroups. The most lateral IDCs formed short and long columns. Long columns contacted the medialmost ISC inferiorly and the undersurface of the tectorial membrane superiorly providing thereby a potential transcellular route for K+ transit from ISCs to endolymph. Short columns faced inner sulcus below and tectorial membrane above and accordingly possessed cells with opposite polarity at the bottom and top of the column. Short columns thus appeared situated to resorb electrolytes from limbal stroma for release into inner sulcus and beneath tectorial membrane at opposite ends of the column. The central IDCs were positioned for resorbing and transporting K+ effluxing from the Na,K-ATPase-rich stellate fibrocytes which spread toward the IDCs from near the inner sulcus. The most medial IDCs lined cuplike invaginations near the attachment of Reissner's membrane and lay apposed to light fibrocytes located between supralimbal fibrocytes and the medial IDCs. Content of Na,K-ATPase and position in the K+ transport route likened the limbal stellate fibrocytes to the spiral ligament type II fibrocytes and supralimbal fibrocytes to suprastrial fibrocytes in the lateral wall. From content of creatine kinase and position in the transport path, limbal light fibrocytes appeared analogous to spiral ligament type I fibrocytes. The additional finding that limbal fibrocytes showed unchanged or upregulated Na,K-ATPase immunoreactivity in aged gerbils with strial atrophy provided further evidence for an independent medial transport route and for the survival of inner hair cells in presbyacusis.

Age-related thickening of basement membrane in stria vascularis capillaries.

Ultrastructural examination was undertaken to investigate the pathogenesis of age-related atrophy of the stria vascularis (StV). Basement membrane (BM) thickness was increased in 65-85% of strial capillaries in gerbils aged 33 months or older and often exceeded by several-fold that observed in young controls. In an early stage of thickening the BM expanded slightly around the full capillary profile, after which nodular expansions of BM encircling slender cell processes were often observed at or near one or both poles of the elliptical vessel profile. As widening progressed, the BM consisted of 2-3 layers separated by cell processes in the nodules but fewer strata elsewhere. Association of slender processes of both endothelial cells and pericytes with focal thickening outside the process suggested their participation in genesis of the capillary lesion. In later stages of atrophy, pericytes degenerated and disappeared, while endothelial cells remained intact. Eventually, thick multilayered BM devoid of endothelial cells surrounded a narrow lumen occluded by debris. The age-related change in BM in the inner ear was confined to StV capillaries. Degenerative changes in StV epithelial cells occurred apparently as a secondary consequence of the capillary lesion. The pathologic alterations in marginal cells included extrusion of blebs from the luminal surface, separation and loss of basolateral interfoldings, alteration and depletion of mitochondria and nuclear pyknosis. At the end-stage of degeneration, the StV consisted of a simple or multiple layer of squamous cells lining the scala media.

Expression patterns of ion transport enzymes in spiral ligament fibrocytes change in relation to strial atrophy in the aged gerbil cochlea.

Fibrocytes of the lateral wall function in conjunction with the stria vascularis (StV) to mediate cochlear ion homeostasis. Age-related changes in the expression patterns of ion transport enzymes in spiral ligament fibrocytes were investigated to ascertain their relation to metabolic presbyacusis in the gerbil. Immunoreactivity of fibrocytes for Na,K-ATPase (Na,K), carbonic anhydrase isozyme II (CA) and creatine kinase isozyme BB (CK) varied among and within cochleas from aged but not from young gerbils. The variable immunostaining was related to the extent and location of StV atrophy. Age-dependent degeneration and loss of Na,K in the StV occurred predominantly in the apex and lower base and hook of the cochlea, largely sparing more central regions. Immunostaining intensity for Na,K, CK, and CA in fibrocytes changed in relation to declines in strial marginal cell Na,K initially showing upregulation followed by downregulation. Spiral ligament fibrocytes in cochleas with more than two remaining normal turns often disclosed overexpression of CK in regions of strial atrophy. Conversely, CA in such cochleas was often increased in regions of normal StV adjacent to foci of atrophic StV. Senescent cochleas with two or fewer functional turns generally contained fibrocytes with diminished CK or CA immunoreactivity in regions of atrophic StV but in isolated instances exhibited fibrocytes with enhanced staining. Heightened staining for CK in type Ia fibrocytes underlying regions of complete or partial strial atrophy indicated an increased metabolic demand in fibrocytes in response to strial insufficiency. The findings provide further support for the role of spiral ligament fibrocytes in cochlear fluid and ion homeostasis.

Golgi-canalicular reticulum system in ion transporting fibrocytes and outer sulcus epithelium of gerbil cochlea.

BACKGROUND: Five types of highly specialized fibrocytes have been identified in the spiral ligament of the gerbil cochlea. Type I, II, and IV fibrocytes function in cycling back to the stria vascularis K+ effluxed from outer hair cells and nerves during auditory transduction. Thus, evidence exists for a transcellular path of K+ movement from outer sulcus cells through fibrocytes to the strial interstitial space, but a mechanism for facilitating such ion flow within the cells has not been elucidated. METHODS: The spiral ligament of glutaraldehyde-osmium tetroxide-fixed and Epon-embedded gerbil cochlea was examined by transmission electron microscopy. RESULTS: Ultrastructural examination disclosed an extensive membrane limited reticulum in the cytoplasm of type I, II, IV, and V fibrocytes of the lateral wall and in outer sulcus cells and their root processes. This system resembled the tubulocisternal endoplasmic reticulum present in some ion-transporting epithelia but appeared more to constitute a network of canaliculi and is referred to as the canalicular reticulum (CR). Many typical small Golgi complexes invariably accompanied the CR in the fibrocytes and sulcus cells, as we have found to be true of other epithelia known to contain CR and function in ion transport. Numerous mitochondria populated cytosol-containing CR. CONCLUSIONS: The data support the concept of transcellular K+ flux in type I, II, IV, and V fibrocytes and outer sulcus cells in the cochlea and lend credence to the view of CR as functioning in the movement of ions through cells. The constant and precise association of Golgi complexes with CR in the different cell types implies a functional relationship possibly concerned with biosynthesis of CR by Golgi elements, and the abundance of mitochondria near CR indicates an energy requirement for function of the reticulum or its biosynthesis.

Immunoglobulin deposition in thickened basement membranes of aging strial capillaries.

The presence of immunoglobulins in the thickened basement membrane (BM) of aging strial capillaries was investigated as a possible indicator of autoimmunity in the genesis of atypical BM. Cochleas from young and old Mongolian gerbils raised in quiet were examined by immunostaining at the light microscopic level for IgG and IgM and for the BM components laminin (La) and type IV collagen (IV-C). Another age-graded series of cochleas was stained for IgG at the ultrastructural level. No immunoreactive IgG was detected in specimens from animals less than 6 months old. In contrast, 2 of 12 cochleas from 20- to 28-month-old gerbils and 11 of 20 cochleas from gerbils 30 months or older showed positive staining for IgG in strial capillary BM. IgM was not detected at any age. At the electron microscope level, no immunoreactive IgG was detected in the stria of cochleas younger than 30 months. However, labeling demonstrative of IgG was observed in the thickened BM of some strial capillaries in all six cochleas from gerbils older than 33 months. Lysosome-like granules in endothelial cells and the superiormost marginal cells also stained for content of IgG as did fibrillar material in edematous regions in the intrastrial space. In addition to showing accumulation of IgG, the findings confirm our prior demonstration of increased La deposition in the thickened strial capillary BM of all cochleas from old gerbils. The BM alterations appear confined to strial capillaries in old gerbils, since morphological observations and immunostaining for La and IgG failed to detect changes in BMs at any other site in a wide survey of aged gerbil organs including vessels in other regions of the affected cochleas. The results point more towards the development of an age-dependent permeability to IgG selectively in strial capillaries than to autoimmunity as an explanation of the IgG in BM.

Increased laminin deposition in capillaries of the stria vascularis of quiet-aged gerbils.

The distribution of laminin (LA) and type IV collagen (IV-C) in the gerbil inner ear was investigated by light and electron microscopic immunohistochemistry. Changes in protein expression were assessed from birth to old age to determine the relation of these constituents to maturation of the cochlea and development of presbyacusis. The distribution of LA paralleled that of IV-C during postnatal development, and both were visualized in the basement membrane (BM) of endothelial, epithelial and spiral ganglion cells in neonatal and young adult gerbils. Immunopositive BM underlying the stria vascularis disappeared at 8-12 days after birth coincident with the development and maturation of the strial capillaries. Immunoreactivity for LA afforded an index to the thickness of the BM and was found to increase with age only in the BM of strial capillaries. At 6 months of age, occasional strial capillaries in the apex of the cochlea showed thickening of the LA-positive BM. Abnormal deposition of LA in strial capillary BM spread to lower turns and increased in prevalence with advancing age, affecting apical and basal more than middle cochlear turns. Thickening of the capillary BM appeared to precede capillary obstruction which eventuated in complete strial atrophy. Staining for IV-C in the walls of the strial capillaries did not increase with age. The data show that LA and IV-C play important roles in postnatal development of the cochlea and that LA deposition increases with age only in the BM of strial capillaries.

The fine structure of spiral ligament cells relates to ion return to the stria and varies with place-frequency.

Ultrastructural analysis of cells in the cochlea's lateral wall was undertaken to investigate morophologic features relevant to the route of K+ cycling from organ of Corti (OC) to stria vascularis (StV) and to the question of a transcellular versus an extracellular path. The fine structure of outer sulcus cells (OSCs) evidenced their capacity for uptake of K+ from Claudius cells and from perilymph in inferior spiral ligament. Plasmalemmal amplification and mitochondrial density together with known content of Na,K-ATPase testified to activity of type II, IV and V fibrocytes in resorbing K+. Location and fine structure afforded a basis for distinguishing subtypes among the type I, II and IV cells. The type II, IV and V fibrocytes can be viewed as drawing K+ from surrounding perilymph and from OSCs and generating an intracellular downhill diffusion gradient for K+ flow through gap junctions to subtype Ib and Ia fibrocytes and strial basal cells. Pumping action enabled by extreme structural specialization of type II fibrocytes is considered to mediate K+ translocation across the interruption between the gap junction connected epithelial and gap junction connected fibrocyte systems and to explain ion flow directed toward StV through OSCs and fibrocytes despite their lack of polarity. The OSC bodies shrank, their root bundles expanded and the gap junction contact between OSCs and Claudius cells increased toward the base of the cochlea. Expanding root bundles and type I and IIb fibrocyte populations contrasted with shrinking OHCs and Deiters and tectal cells from the apex to the base of the cochlea. These differences indicated an increased magnitude and alternate route of K+ transport toward the StV in high as compared to low-frequency regions. The augmented K+ transport through spiral ligament in basal cochlea correlates with and provides a possible basis for the larger endocochlear potential in the base. The findings appear consistent with current flow extracellularly through scalae tympani and vestibuli and transcellularly through OC, OSCs and class I, II, IV and V fibrocytes.