内耳免疫反应诱导Fas和FasL表达与凋亡的关系

目的研究内耳免疫反应过程中是否存在细胞凋亡,以及细胞凋亡是否与Fas和FasL信号转导有关.方法选用雌性白色豚鼠16只,随机分为实验组和对照组各8只,以钥孔虫戚血蓝蛋白(keyhole limpet hemocyanin,KLH)全身免疫后,实验组以相同抗原进行内耳免疫,对照组内耳注射等量的磷酸盐缓冲生理盐水(phosphate buffered saline,PBS),在内耳免疫5d后处死动物,取内耳免疫侧耳蜗做石蜡切片.通过脱氧核糖核苷酸末端转移酶介导的缺口末端标记技术(terminal-deoxynucleotidyl transferase mediated nick end labeling,TUNEL)检测内耳凋亡细胞,免疫组化检测内耳Fas和FasL的表达.结果实验组豚鼠内耳Corti器毛细胞,血管纹的缘细胞和螺旋神经节细胞存在TUNEL染色阳性细胞,而对照组动物切片仅在支持细胞、血管纹和螺旋神经节细胞中发现极少数TUNEL染色阳性细胞.免疫组化染色实验组Corti器、螺旋神经节细胞、血管纹和螺旋韧带Fas和FasL蛋白表达阳性,而对照组只有螺旋神经节细胞和血管纹有较弱的Fas蛋白表达,FasL蛋白表达阴性.结论内耳免疫反应可诱导细胞凋亡的发生,Fas-FasL途径是参与此过程重要的信号转导途径之一.     

Enzyme-histochemical localization of carbonic anhydrase in the inner ear of the guinea pig and several improvements of the technique

We have made several improvements in the method of fixation of the inner ear and the enzyme-histochemical technique for carbonic anhydrase (CA) detection. The results confirmed that CA is localized in the hair cells of the organ of Corti, Deiters' cells or nerve endings, inner pillar cells, Boettcher's cells, stria vascularis, spiral ligament, spiral limbus, and spiral ganglion cells. These results generally agree with previous histochemical observations but showed some differences. Our method preserved tissue morphology and showed more detailed localization of CA activity in the inner ear. In particular, the marginal zone of stria vascularis and the epithelial cells of spiral prominence, facing the endolymph, showed no CA activity, while the suprastrial region of the spiral ligament and the supralimbal region of the spiral limbus, juxtaposed to the perilymph, showed CA activity. In outer hair cells, the cuticular plate, which faces the endolymph showed CA activity, but the lateral membrane, which faces the perilymph showed no CA activity. In contrast, the inner hair cell cytoplasm showed diffuse CA activity. These results will be useful in considering ion exchange between endolymph and its adjacent cells, and between perilymph and its adjacent structures.     

Developmental expression patterns of connexin26 and -30 in the rat cochlea

Connexin proteins form transmembranous gap junction channels that connect adjacent cells. Connexin26 and connexin30 have been previously shown to be strongly expressed in the inner ear of adult rats and to be mainly colocalized. Because intercellular connections by gap junction proteins are crucial for maturation of different tissues, we investigated the developmental expression of connexin26 and connexin30 in pre- and postnatal rats using immunocytochemistry. In the rat otocyst, staining for connexin26 as well as for connexin30 appeared at the 17th day of gestation. However, at this stage, expression of connexin30 was low and restricted to the neurosensory epithelium. Beginning from the 3rd postnatal day connexin26 and -30 were expressed with highest immunoreaction in the spiral limbus, the neurosensory epithelium, and between the stria vascularis and the spiral ligament. Beginning from postnatal day 12 the staining pattern resembled that of adult animals, with additional strong staining between all fibrocytes of the spiral ligament. Double labeling experiments demonstrated strongest colocalization of both connexins between the stria vascularis and the spiral ligament. These results demonstrate that development of the cochlear gap junction system precedes the functional maturation of the rat inner ear, which takes place between the 2nd and 3rd postnatal week. In the cochlea of a 22-week-old human embryo, connexin26 and connexin30 could be detected in the lateral wall, suggesting that both connexins also play a crucial role in function of the human inner ear.     

Fine structure and permeability of capillaries in the stria vascularis and spiral ligament of the inner ear of the guinea pig

Summary The blood capillaries in the stria vascularis and the spiral ligament of guinea pigs were studied by electron microscopy with freeze-fracture and thin section methods, including tracer experiments with horseradish peroxidase (HRP) and microperoxidase (MP). The endothelial cells of the capillaries of both tissues are connected by tight junctions, and contain about the same number of micropinocytotic vesicles. In cases of intravascular administration before fixation, both of the tracers stained the perivascular space and almost all endothelial vesicles in the stria vascularis. On the other hand, the perivascular space and many vesicles in the spiral ligament were unstained. The endothelial tight junctions in the stria vascularis prevented the penetration of HRP, but sometimes allowed the penetration of MP. Those of the spiral ligament were impermeable to both tracers. In cases of tracer administration after fixation, leakage spots of HRP from capillaries were sparsely located all over the stria vascularis. Transendothelial channels and isolated fenestrae formed by micropinocytotic vesicles were detected. It is concluded that the capillaries of the stria vascularis are similar to the muscle capillaries and to the capillaries of the elasmobranch brain, whereas those in the spiral ligament are similar to the brain capillaries of higher vertebrates.     

Developmental expression patterns of connexin26 and ‐30 in the rat cochlea

Connexin proteins form transmembranous gap junction channels that connect adjacent cells. Connexin26 and connexin30 have been previously shown to be strongly expressed in the inner ear of adult rats and to be mainly colocalized. Because intercellular connections by gap junction proteins are crucial for maturation of different tissues, we investigated the developmental expression of connexin26 and connexin30 in pre‐ and postnatal rats using immunocytochemistry. In the rat otocyst, staining for connexin26 as well as for connexin30 appeared at the 17th day of gestation. However, at this stage, expression of connexin30 was low and restricted to the neurosensory epithelium. Beginning from the 3rd postnatal day connexin26 and ‐30 were expressed with highest immunoreaction in the spiral limbus, the neurosensory epithelium, and between the stria vascularis and the spiral ligament. Beginning from postnatal day 12 the staining pattern resembled that of adult animals, with additional strong staining between all fibrocytes of the spiral ligament. Double labeling experiments demonstrated strongest colocalization of both connexins between the stria vascularis and the spiral ligament. These results demonstrate that development of the cochlear gap junction system precedes the functional maturation of the rat inner ear, which takes place between the 2nd and 3rd postnatal week. In the cochlea of a 22‐week‐old human embryo, connexin26 and connexin30 could be detected in the lateral wall, suggesting that both connexins also play a crucial role in function of the human inner ear. Dev. Genet. 25:306–311, 1999. © 1999 Wiley‐Liss, Inc.     

Involvement of calpain-I and microRNA34 in kanamycin-induced apoptosis of inner ear cells

Inner ear cells, including hair cells, spiral ganglion cells, stria vascularis cells and supporting cells on the basilar membrane, play a major role in transducing hearing signals and regulating inner ear homoeostasis. However, their functions are often damaged by antibiotic-induced ototoxicity. Apoptosis is probably involved in inner ear cell injury following aminoglycoside treatment. Calpain, a calcium-dependent protease, is essential for mediating and promoting cell death. We have therefore investigated the involvement of calpain in the molecular mechanism underlying ototoxicity induced by the antibiotic kanamycin in mice. Kanamycin (750 mg/kg) mainly induced cell death of cochlear cells, including stria vascularis cells, supporting cells and spiral ganglion cells, but not hair cells within the organ of Corti. Cell death due to apoptosis occurred in a time-dependent manner with concomitant up-regulation of calpain expression. Furthermore, the expression levels of two microRNAs, mir34a and mir34c, were altered in a dose-dependent manner in cochlear cells. These novel findings demonstrated the involvement of both calpain and microRNAs in antibiotic-induced ototoxicity.     

Immunolocalization of P2Y4 and P2Y2 Purinergic Receptors in Strial Marginal Cells and Vestibular Dark Cells

K+ secretion by strial marginal cell and vestibular dark cell epithelia is regulated by UTP and ATP at both the apical and basolateral membranes, suggesting control by P2Y2 and/or P2Y4 purinergic receptors. Immunolocalization was used to determine the identity and distribution of these putative receptors. Membrane proteins from gerbil brain, gerbil vestibular labyrinth and gerbil stria vascularis were isolated and analyzed by Western blot. P2Y2 antibody stained one band at 42 kDa for each tissue, whereas P2Y4 antibody stained 3 bands on gerbil brain (75, 55 and 36 kDa), one band on gerbil stria vascularis (55 kDa) and two bands on vestibular labyrinth (42 and 56 kDa). All bands were absent when the antibodies were blocked with their respective antigenic peptide. P2Y4 was immunolocalized by fluorescence confocal microscopy to only the apical membrane of strial marginal cells and vestibular dark cells and was similar to apical immunostaining of KCNE1 in the same cells. By contrast, P2Y2 was observed on the basolateral but not the apical membrane of dark cells. Similarly, in the stria vascularis P2Y2 was observed in the basolateral region but not the apical membrane of marginal cells. Additional staining was observed in the spiral ligament underlying the stria vascularis. These findings identify the molecular bases of the regulation of K+ secretion by apical and basolateral UTP in the inner ear.     

Dye-coupling of melanocytes with endothelial cells and pericytes in the cochlea of gerbils

Intercellular connections via gap junctions in the stria vascularis, which constitutes the lateral wall of the cochlear duct, were investigated by the Lucifer yellow microinjection method with the aid of a confocal laser microscope. The dye injected into an intermediate cell (melanocyte) diffused into capillary endothelial cells and pericytes as well as other intermediate cells, basal cells, and fibrocytes in the spiral ligament; whereas the dye injected into a marginal cell (epithelial cell) was confined to the injected cell. The observation of dye-coupling between intermediate cells and endothelial cells and pericytes makes likely the possibility that these cells work together to play a role in the specific function of the stria vascularis (i.e., production of the positive endocochlear potential and the endolymph) and adds endothelial cells and pericytes to the current “two-cell model” of the stria vascularis.     

Pou3f4 deficiency causes defects in otic fibrocytes and stria vascularis by different mechanisms

DFN3, the most prevalent X-linked hearing loss, is caused by mutations in the POU3F4 gene. Previous studies in Pou3f4 knockout mice suggest that defective otic fibrocytes in the spiral ligament of the cochlear lateral wall may underlie the hearing loss in DFN3. To better understand the pathological mechanisms of the DFN3 hearing loss, we analyzed inner ears of Pou3f4-deficient mice during development. Our results indicate that compartmentalization of the spiral ligament mesenchyme setting up boundaries for specific otic fibrocytes occurs normally in Pou3f4-deficient cochlea. However, differentiation of the compartmentalized mesenchyme into specific otic fibrocytes was blocked in the absence of Pou3f4 function. In addition, we found that stria vascularis in the cochlear lateral wall was also affected in Pou3f4-deficient cochlea. Unlike the otic fibrocytes, differentiation of stria vascularis was completed in the absence of Pou3f4 function, yet expression of Kir4.1 channels in the strial intermediate cells, essential for the sound transduction, was lost afterwards. These results suggest that Pou3f4 deficiency causes defects in both otic fibrocytes and stria vascularis at different developmental stages and by different pathological mechanisms, which may account for the progressive nature of DFN3 hearing loss.     

Deafness and stria vascularis defects in S1P2 receptor-null mice

The S1P(2) receptor is a member of a family of G protein-coupled receptors that bind the extracellular sphingolipid metabolite sphingosine 1-phosphate with high affinity. The receptor is widely expressed and linked to multiple G protein signaling pathways, but its physiological function has remained elusive. Here we have demonstrated that S1P(2) receptor expression is essential for proper functioning of the auditory and vestibular systems. Auditory brainstem response analysis revealed that S1P(2) receptor-null mice were deaf by one month of age. These null mice exhibited multiple inner ear pathologies. However, some of the earliest cellular lesions in the cochlea were found within the stria vascularis, a barrier epithelium containing the primary vasculature of the inner ear. Between 2 and 4 weeks after birth, the basal and marginal epithelial cell barriers and the capillary bed within the stria vascularis of the S1P(2) receptor-null mice showed markedly disturbed structures. JTE013, an S1P(2) receptor-specific antagonist, blocked the S1P-induced vasoconstriction of the spiral modiolar artery, which supplies blood directly to the stria vascularis and protects its capillary bed from high perfusion pressure. Vascular disturbance within the stria vascularis is a potential mechanism that leads to deafness in the S1P(2) receptor-null mice.     

Expression of Growth Factors and Their Receptors in the Postnatal Rat Cochlea

RT-PCR was used to assay for growth factors and receptors from seven different protein families in cochlea tissues of the juvenile rat. There was a broad representation of the growth factor families in all the cochlea tissues examined, though the organ of Corti and stria vascularis expressed a greater variety than the spiral ganglion. This broad expression suggests that a variety of known growth factors play significant roles in the development, maintenance, and repair of the inner ear. The results of this survey serve as a basis for the design of future in vitro experiments that will address the ability of growth factors to protect hair cells from damage and to evoke a repair-regeneration response by injured hair cells.     

Malformation of stria vascularis in the developing inner ear of the German waltzing guinea pig

Auditory function and cochlear morphology have previously been described in the postnatal German waltzing guinea pig, a strain with recessive deafness. In the present study, cochlear histopathology was further investigated in the inner ear of the developing German waltzing guinea pig (gw/gw). The lumen of the cochlear duct diminished progressively from embryonic day (E) 35 to E45 and was absent at E50 because of the complete collapse of Reissner's membrane onto the hearing organ. The embryonic stria vascularis, consisting of a simple epithelium, failed to transform into the complex trilaminar tissue seen in normal animals and displayed signs of degeneration. Subsequent degeneration of the sensory epithelium was observed from E50 and onwards. Defective and insufficient numbers of melanocytes were observed in the developing gw/gw stria vascularis. A gene involved in cochlear melanocyte development, Pax3, was markedly reduced in lateral wall tissue of the cochlea of both E40 and adult gw/gw individuals, whereas its expression was normal in the skin and diaphragm muscle of adult gw/gw animals. The Pax3 gene may thus be involved in the pathological process but is unlikely to be the primary mutated gene in the German waltzing guinea pig. TUNEL assay showed no signs of apoptotic cell death in the developing stria vascularis of this type of guinea pig. Thus, malformation of the stria vascularis appears to be the primary defect in the inner ear of the German waltzing guinea pig. Defective and insufficient numbers of melanocytes might migrate to the developing stria vascularis but fail to provide the proper support for the subsequent development of marginal and basal cells, thereby leading to stria vascularis malformation and dysfunction in the inner ear of the German waltzing guinea pig.     

Cellular distribution of myosin-V in the guinea pig cochlea

The importance of unconventional myosins to hearing has recently been revealed by the identification of myosins-VI and -VII as the defective genes in mouse mutations and in a human syndrome which lead to profound hearing loss. Another class of novel myosins (V) has been implicated in the trafficking of intracellular vesicles in neurons and other secretory cells. We used affinity-purified antibodies to determine the localization of myosin-V in the guinea pig inner ear. In the sensory epithelium of the cochlea, myosin-V epitopes were recognized in neuronal and supporting cells. Neuronal labelling was most intense in the afferent innervation of inner and outer hair cells. Supporting cells labelled were cells of Hensen and Deiters, and inner border, inner phalangeal, inner sulcus and interdental cells. In the vascular tissue of the cochlea, we observed staining of intermediate cells of the stria vascularis and of border cells between the stria and the spiral prominence. Staining of afferent chalice nerve endings was observed on type I vestibular hair cells. The results suggest that, like myosins VI and VII, myosin-V is localized in positions that may be critical to auditory function.     

Fine structure of the intracochlear potential field. I. The silent current.

Field potentials were recorded along radial tracks in scala tympani and scala vestibuli of the guinea-pig cochlea. A current density analysis revealed standing current density profiles that were qualitatively similar between animals and between the second and third cochlear turns. Radial standing current densities were greatest at or near the spiral ligament. All the scala vestibuli current density profiles were scaled versions of one another while the scala tympani current density profiles showed more variability. Acoustic stimuli modulated the standing current and there was a cochlear microphonic current density peak in scala tympani near the organ of Corti. The results are summarized with a current-density field line model, the key element of which is a constant current pumped into scale media by the stria vascularis. The standing potential gradients drive current from each perilymphatic chamber into the spiral ligament en route to the lateral surface of the stria vascularis. The strial current is divided between the receptor cell pathway and leakage pathways. The standing current through the leakage pathways is indirectly modulated by acoustic stimulation through the modulation of the endocochlear potential. The reciprocal modulation of current between hair cell and leakage pathways suggests that the stria vascularis maintains a constant current during acoustic stimulation. The cochlear standing current is similar to the retinal dark current in its importance for sensory transduction but the fact that the silent current is generated by the stria vascularis and not the receptor cells provides significant benefits for the detection of mechanical stimuli.     

Elongated pericyte-like cells connect discrete capillaries in the cochlear stria vascularis of gerbils and rats

 Bridging structures between discrete capillaries in the stria vascularis of the cochlea were studied morphologically in gerbils and rats. Serial thin sections for transmission electron microscopy revealed (1) that elongated cells surrounded by the basal lamina provided the structural basis for the bridging structure, (2) that the basal lamina surrounding the elongated cell extended to the basal lamina around the capillary endothelial cell, (3) that the electron density of the cytoplasm was similar to that of the pericytes around the capillaries, and (4) that the cell was attached to the capillaries at both ends only. Visualization of the basal lamina by immunofluorescent methods revealed (1) that capillaries were often bent at the site of attachment of the bridging cell, (2) that the bridging cell bifurcated occasionally, and (3) that the density of the bridging cell was much higher in the stria vascularis than in the underlying spiral ligament. Filamentous actin visualized by fluorescent phalloidin was not apparent in the bridging cell. We propose that the bridging cell provides mechanical strength to the tortuous capillary network in the stria vascularis and participates in the specific function of the stria vascularis in cooperation with other types of cells. Received: 26 October 1998 / Accepted: 8 January 1999     

A mutation in CCDC50, a gene encoding an effector of epidermal growth factor-mediated cell signaling, causes progressive hearing loss

We previously mapped a novel autosomal dominant deafness locus, DFNA44, by studying a family with postlingual, progressive, nonsyndromic hearing loss. We report here on the identification of a mutation in CCDC50 as the cause of hearing loss in the family. CCDC50 encodes Ymer, an effector of epidermal growth factor (EGF)-mediated cell signaling that is ubiquitously expressed in different organs and has been suggested to inhibit down-regulation of the EGF receptor. We have examined its expression pattern in mouse inner ear. Western blotting and cell transfection results indicate that Ymer is a soluble, cytoplasmic protein, and immunostaining shows that Ymer is expressed in a complex spatiotemporal pattern during inner ear development. In adult inner ear, the expression of Ymer is restricted to the pillar cells of the cochlea, the stria vascularis, and the vestibular sensory epithelia, where it shows spatial overlap with the microtubule-based cytoskeleton. In dividing cells, Ymer colocalizes with microtubules of the mitotic apparatus. We suggest that DFNA44 hearing loss may result from a time-dependent disorganization of the microtubule-based cytoskeleton in the pillar cells and stria vascularis of the adult auditory system.