Your search keyword '"Hiroshi Hibino"' showing total 8 results

1. Electrochemical properties of the non‐excitable tissue stria vascularis of the mammalian cochlea are sensitive to sounds

Author

Fumiaki Nin, Hiroshi Hibino, Arata Horii, Mitsuo P. Sato, Daisuke Ino, Takeru Ota, Katsumi Doi, Takamasa Yoshida, and Qi Zhang

Subjects

Physiology, Endolymph, Chemistry, Guinea Pigs, Stria Vascularis, Depolarization, Cochlea, Electrophysiology, medicine.anatomical_structure, Hair Cells, Auditory, Potassium, otorhinolaryngologic diseases, medicine, Biophysics, Animals, Mechanosensitive channels, sense organs, Hair cell, Ion transporter, Ion channel

Abstract

Excitable cochlear hair cells convert the mechanical energy of sounds into the electrical signals necessary for neurotransmission. The key process is cellular depolarization via K+ entry from K+ -enriched endolymph through hair cells' mechanosensitive channels. Positive 80 mV potential in endolymph accelerates the K+ entry, thereby sensitizing hearing. This potential represents positive extracellular potential within the epithelial-like stria vascularis; the latter potential stems from K+ equilibrium potential (EK ) across the strial membrane. Extra- and intracellular [K+ ] determining EK are likely maintained by continuous unidirectional circulation of K+ through a putative K+ transport pathway containing hair cells and stria. Whether and how the non-excitable tissue stria vascularis responds to acoustic stimuli remains unclear. Therefore, we analysed a cochlear portion for the best frequency, 1 kHz, by theoretical and experimental approaches. We have previously developed a computational model that integrates ion channels and transporters in the stria and hair cells into a circuit and described a circulation current composed of K+ . Here, in this model, mimicking of hair cells' K+ flow induced by a 1 kHz sound modulated the circulation current and affected the strial ion transport mechanisms; the latter effect resulted in monotonically decreasing potential and increasing [K+ ] in the extracellular strial compartment. Similar results were obtained when the stria in acoustically stimulated animals was examined using microelectrodes detecting the potential and [K+ ]. Measured potential dynamics mirrored the EK change. Collectively, because stria vascularis is electrically coupled to hair cells by the circulation current in vivo too, the strial electrochemical properties respond to sounds. KEY POINTS: A highly positive potential of +80 mV in K+ -enriched endolymph in the mammalian cochlea accelerates sound-induced K+ entry into excitable sensory hair cells, a process that triggers hearing. This unique endolymphatic potential represents an EK -based battery for a non-excitable epithelial-like tissue, the stria vascularis. To examine whether and how the stria vascularis responds to sounds, we used our computational model, in which strial channels and transporters are serially connected to those hair cells in a closed-loop circuit, and found that mimicking hair cell excitation by acoustic stimuli resulted in increased extracellular [K+ ] and decreased the battery's potential within the stria. This observation was overall verified by electrophysiological experiments using live guinea pigs. The sensitivity of electrochemical properties of the stria to sounds indicates that this tissue is electrically coupled to hair cells by a radial ionic flow called a circulation current.

Published

2021

2. Molecular architecture of the stria vascularis membrane transport system, which is essential for physiological functions of the mammalian cochlea

Author

Tadashi Kitahara, Shushi Nagamori, Shizuo Komune, Noriyoshi Isozumi, Takamasa Yoshida, Genki Ogata, Hiroshi Hibino, Hidenori Inohara, Yoshiaki Kikkawa, Satoru Uetsuka, Yoshikatsu Kanai, and Fumiaki Nin

Subjects

Male, Proteomics, Endolymph, Molecular Sequence Data, Deafness, Biology, Mice, Databases, Genetic, otorhinolaryngologic diseases, medicine, Animals, Humans, Protein kinase A, Cochlea, Ion channel, General Neuroscience, Membrane Transport Proteins, Stria Vascularis, Transporter, Anatomy, Membrane transport, Rats, Cell biology, medicine.anatomical_structure, Membrane protein

Abstract

Stria vascularis of the mammalian cochlea transports K(+) to establish the electrochemical property in the endolymph crucial for hearing. This epithelial tissue also transports various small molecules. To clarify the profile of proteins participating in the transport system in the stria vascularis, membrane components purified from the stria of adult rats were analysed by liquid chromatography tandem mass spectrometry. Of the 3236 proteins detected in the analysis, 1807 were membrane proteins. Ingenuity Knowledge Base and literature data identified 513 proteins as being expressed on the 'plasma membrane', these included 25 ion channels and 79 transporters. Sixteen of the former and 62 of the latter had not yet been identified in the stria. Unexpectedly, many Cl(-) and Ca(2+) transport systems were found, suggesting that the dynamics of these ions play multiple roles. Several transporters for organic substances were also detected. Network analysis demonstrated that a few kinases, including protein kinase A, and Ca(2+) were key regulators for the strial transports. In the library of channels and transporters, 19 new candidates for uncloned deafness-related genes were identified. These resources provide a platform for understanding the molecular mechanisms underlying the epithelial transport essential for cochlear function and the pathophysiological processes involved in hearing disorders.

Published

2015

3. The mechanism underlying maintenance of the endocochlear potential by the K+transport system in fibrocytes of the inner ear

Author

Fumiaki Nin, Hiroshi Hibino, Yoshihisa Kurachi, Takamasa Yoshida, Naoko Adachi, Soichiro Yamaguchi, Genki Ogata, S. Komune, Toshihiro Suzuki, and Yasuo Hisa

Subjects

Syncytium, Physiology, Endolymph, Endocochlear potential, Cochlear duct, Anatomy, Biology, Perilymph, medicine.anatomical_structure, otorhinolaryngologic diseases, Extracellular, medicine, Biophysics, Inner ear, Ion transporter

Abstract

Key points • The endocochlear potential (EP) of +80 mV in cochlear endolymph is essential for audition and controlled by K+ transport across the lateral cochlear wall composed of two epithelial barrier layers, the syncytium containing the fibrocytes and the marginal cells. • The EP depends upon the diffusion potential elicited by a large K+ gradient across the apical surface of the syncytium. • We examined by electrophysiological approaches an involvement of Na+,K+-ATPase, which occurs at the syncytium's basolateral surface comprising the fibrocytes’ membranes and would mediate K+ transport across the lateral wall, in maintenance of the EP. • We show that the Na+,K+-ATPase sustains the syncytium's high [K+] that is crucial for the K+ gradient across the apical surface of the syncytium. • The results help us better understand the mechanism underlying the establishment of the EP as well as the pathophysiological process for deafness induced by dysfunction of the ion transport apparatus. Abstract The endocochlear potential (EP) of +80 mV in the scala media, which is indispensable for audition, is controlled by K+ transport across the lateral cochlear wall. This wall includes two epithelial barriers, the syncytium and the marginal cells. The former contains multiple cell types, such as fibrocytes, which are exposed to perilymph on their basolateral surfaces. The apical surfaces of the marginal cells face endolymph. Between the two barriers lies the intrastrial space (IS), an extracellular space with a low K+ concentration ([K+]) and a potential similar to the EP. This intrastrial potential (ISP) dominates the EP and represents the sum of the diffusion potential elicited by a large K+ gradient across the apical surface of the syncytium and the syncytium's potential, which is slightly positive relative to perilymph. Although a K+ transport system in fibrocytes seems to contribute to the EP, the mechanism remains uncertain. We examined the electrochemical properties of the lateral wall of guinea pigs with electrodes sensitive to potential and K+ while perfusing into the perilymph of the scala tympani blockers of Na+,K+-ATPase, the K+ pump thought to be essential to the system. Inhibiting Na+,K+-ATPase barely affected [K+] in the IS but greatly decreased [K+] within the syncytium, reducing the K+ gradient across its apical surface. The treatment hyperpolarized the syncytium only moderately. Consequently, both the ISP and the EP declined. Fibrocytes evidently use the Na+,K+-ATPase to achieve local K+ transport, maintaining the syncytium's high [K+] that is crucial for the K+ diffusion underlying the positive ISP.

Published

2013

4. Distinct detergent-resistant membrane microdomains (lipid rafts) respectively harvest K+ and water transport systems in brain astroglia

Author

Yoshihisa Kurachi and Hiroshi Hibino

Subjects

Water transport, General Neuroscience, Cell, HEK 293 cells, Biology, Cell biology, Cell membrane, Immunolabeling, Membrane, medicine.anatomical_structure, medicine, sense organs, Signal transduction, Lipid raft

Abstract

The detergent-resistant microdomains (DRM) of cell membranes scaffold different molecules and regulate cell functions by orchestrating various signaling pathways including G-proteins and tyrosine kinase. Here we report a novel role for DRM in astroglial cells. K(+)-buffering inwardly rectifying Kir4.1 channels and the water channel AQP4 are expressed in astrocytes and they may be functionally coupled to maintain ionic and osmotic homeostasis in the brain. Kir4.1 and AQP4 channel proteins were abundant in noncaveloar DRM in the brain and also in HEK293T cells when exogenously expressed. In HEK293T cells, depletion of membrane cholesterol by methyl-beta-cyclodextrin (MbetaCD) resulted in loss of Kir4.1 association with DRM and its channel activity but did not affect either the distribution or the function of AQP4. Immunolabeling showed that Kir4.1 and AQP4 were occasionally distributed in close proximity but in distinct compartments of the astroglial cell membrane. Astroglial noncaveolar DRM may therefore be made up of at least two distinct compartments, MbetaCD-sensitive and MbetaCD-resistant microdomains, which control localization and function of, respectively, Kir and AQP4 channels on the cell membrane.

Published

2007

5. Expression of an inwardly rectifying K+ channel, Kir5.1, in specific types of fibrocytes in the cochlear lateral wall suggests its functional importance in the establishment of endocochlear potential

Author

Kaori Iwai, Masaru Ishii, Kayoko Higashi-Shingai, Yoshihisa Kurachi, Akikazu Fujita, and Hiroshi Hibino

Subjects

Male, Endolymph, Spiral limbus, Endocochlear potential, Mechanotransduction, Cellular, Membrane Potentials, Hearing, otorhinolaryngologic diseases, medicine, Animals, Potassium Channels, Inwardly Rectifying, Rats, Wistar, Mechanotransduction, Cochlea, Chemistry, General Neuroscience, Gene Expression Regulation, Developmental, Stria Vascularis, Cell Differentiation, Anatomy, Fibroblasts, Perilymph, Immunohistochemistry, Potassium channel, Rats, Cell biology, Microscopy, Electron, medicine.anatomical_structure, Animals, Newborn, Spiral ligament, Potassium, sense organs

Abstract

Cochlear endolymph contains 150 mm K+ and has a highly positive potential of approximately +80 mV. The specialized ionic composition and high potential in endolymph are essential for hearing and maintained by circulation of K+ from perilymph to endolymph through the cochlear lateral wall. Various types of K+ channel such as Kir4.1 and KCNQ1/KCNE1 are expressed in stria vascularis of the lateral wall and play essential roles in K+ circulation. In this study, we examined a distribution of another K+ channel, Kir5.1, and found it specifically expressed in the spiral ligament of the cochlear lateral wall. Specific immunoreactivity for Kir5.1 was detected in type II, IV and V fibrocytes of the ligament and spiral limbus, all of which are directly involved in K+ circulation. Kir5.1 was not found in either type I or III fibrocytes. Although Kir5.1 assembles with Kir4.1 to form a functional Kir channel in renal epithelia and retinal Müller cells, double-immunolabelling revealed that they were expressed in distinct regions in the cochlea lateral wall, i.e. Kir4.1 only in stria vascularis vs. Kir5.1 in spiral ligament. During development, the expression of Kir5.1 subunits started significantly later than Kir4.1 and was correlated with the 'rapid' phase of the elevation of endocochlear potential (EP). Kir5.1 and Kir4.1 channel-subunits may therefore play distinct functional roles in K+ circulation in the cochlear lateral wall.

Published

2004

6. Successful Cochlear Implantation in Prelingual Profound Deafness Resulting From the Common 233delC Mutation of the GJB2 Gene in the Japanese

Author

Takako Iwaki, Katsumi Doi, Takayuki Kawashima, Naoki Matsushiro, Hiroshi Hibino, Ayako Sawada, Ken-ichi Nagai, Koichi Yamamoto, Takeshi Kubo, and Yuka Fuse

Subjects

Male, medicine.medical_specialty, Speech perception, medicine.medical_treatment, Molecular Sequence Data, Deafness, Audiology, Language Development, Polymerase Chain Reaction, Risk Assessment, Connexins, Audiometry, Japan, Cochlear implant, Prevalence, otorhinolaryngologic diseases, medicine, Humans, Point Mutation, Auditory system, Prelingual deafness, Allele, Retrospective Studies, Base Sequence, business.industry, Cochlear Implantation, Connexin 26, Treatment Outcome, medicine.anatomical_structure, Auditory brainstem response, Otorhinolaryngology, Child, Preschool, Mutation (genetic algorithm), Speech Perception, Mutation testing, Female, business, Follow-Up Studies

Abstract

Objectives Recently, we identified three novel mutations of the GJB2 gene in Japanese families with autosomal-recessive non-syndromic deafness. 1 Seven of 11 mutated chromosomes (63.6%) contained a 233delC allele, suggesting that the 233delC mutation is the most common mutation of the GJB2 gene in the Japanese population. After it was recognized that cochlear implantation (CI) is of benefit to children with prelingual deafness, we have had a number of prelingual pediatric CI patients. Because children carrying the homozygous 233delC mutation show bilateral prelingual profound deafness, they could be enrolled in the CI program at Osaka University Graduate School of Medicine. The purposes of this study were 1) to analyze the occurrence of the GJB2 mutations in our 15 prelingual pediatric CI patients in whom the cause of non-syndromic deafness was unknown, and 2) to evaluate the auditory function and postoperative speech perception with CI of those GJB2-related deaf subjects. Study Design Retrospective analysis. Methods Mutation analysis of the GJB2 gene by direct sequencing was performed with genomic DNA from 15 children born profoundly deaf as a result of unknown causes and implanted with CI. Intraoperative electrically evoked auditory brainstem response (EABR) and intra-/postoperative EAP were measured. The speech perception was evaluated with Infants and Toddlers Meaningful Auditory Integration Scale (IT-MAIS). Results and Conclusions We identified 4 CI patients (26.7%) out of 15 children carrying the homozygous 233delC mutation. Intra- and postoperative evaluation of the auditory system revealed almost intact cochlear and retrocochlear auditory function in these 4 patients. Postoperative auditory testing indicates that their speech perception had become significantly higher in comparison with that of other prelingual CI patients. These results suggest that prelingual deaf children carrying the homozygous 233delC mutation of the GJB2 gene can benefit from CI.

Published

2002

7. Anchoring proteins confer G protein sensitivity to an inward-rectifier K+ channel through the GK domain

Author

Akikazu Fujita, Yoshimi Takai, Takeshi Kubo, Yoshihisa Kurachi, Katsumi Doi, Masayuki Tanemoto, Yutaka Hata, Atsushi Inanobe, and Hiroshi Hibino

Subjects

Potassium Channels, GTPase-activating protein, G protein, Xenopus, PDZ domain, Nerve Tissue Proteins, General Biochemistry, Genetics and Molecular Biology, Discs Large Homolog 1 Protein, Mice, GTP-binding protein regulators, GTP-Binding Proteins, KCNJ5, Animals, Humans, Potassium Channels, Inwardly Rectifying, Molecular Biology, Ion channel, Adaptor Proteins, Signal Transducing, G protein-coupled receptor kinase, Binding Sites, General Immunology and Microbiology, biology, Inward-rectifier potassium ion channel, General Neuroscience, Membrane Proteins, Rats, SAP90-PSD95 Associated Proteins, Cell biology, biology.protein, Guanylate Kinases, Research Article

Abstract

Anchoring proteins cluster receptors and ion channels at postsynaptic membranes in the brain. They also act as scaffolds for intracellular signaling molecules including synGAP and NO synthase. Here we report a new function for intracellular anchoring proteins: the regulation of synaptic ion channel function. A neuronal G protein-gated inwardly rectifying K(+) channel, Kir3.2c, can not be activated either by M(2)-muscarinic receptor stimulation or by G(betagamma) overexpression. When coexpressed with SAP97, a member of the PSD/SAP anchoring protein family, the channel became sensitive to G protein stimulation. Although the C-terminus of Kir3. 2c bound to the second PDZ domain of SAP97, functional analyses revealed that the guanylate kinase (GK) domain of SAP97 is crucial for sensitization of the Kir3.2c channel to G protein stimulation. Furthermore, SAPAP1/GKAP, which binds specifically to the GK domain of membrane-associated guanylate kinases, prevented the SAP97-induced sensitization. The function of a synaptic ion channel can therefore be controlled by a network of various intracellular proteins.

Published

2000

8. Immunolocalization of an inwardly rectifying K+ channel, KAB -2 (Kir4.1), in the basolateral membrane of renal distal tubular epithelia

Author

Hiroyuki Ito, Minoru Ito, Atsushi Inanobe, Akira Tonosaki, Yoshihisa Kurachi, Shojiro Isomoto, Yoshiyuki Horio, Hiroshi Hibino, Hitonobu Tomoike, and Keiji Mori

Subjects

Male, Kidney Cortex, Potassium Channels, Molecular Sequence Data, Biophysics, KCNJ10, Biochemistry, Epithelium, Cell membrane, Antibody Specificity, Structural Biology, Genetics, EAST syndrome, medicine, Animals, Amino Acid Sequence, Potassium channel, Potassium Channels, Inwardly Rectifying, Rats, Wistar, Kidney Tubules, Distal, Molecular Biology, Immunogold electron microscopy, Epithelial polarity, Membrane potential, Messenger RNA, biology, Chemistry, Cell Membrane, Cell Biology, medicine.disease, Immunohistochemistry, Basolateral membrane, Rats, Cell biology, medicine.anatomical_structure, Kidney tubule, distal, biology.protein, Rabbits, Oligopeptides

Abstract

Immunolocalization of K(AB)-2 (Kir4.1), an inwardly rectifying K+ channel with a putative ATP-binding domain, was examined in rat kidney where expression of K(AB)-2 mRNA was previously shown. Anti-K(AB)-2 antibody was raised in rabbit and then affinity-purified. An immunohistochemical study revealed that K(AB)-2 immunoreactivity was detected specifically in the basolateral membrane of distal tubular epithelia. Therefore, K(AB)-2 is the first K+ channel shown to be localized in the basolateral membrane of renal epithelia. The finding suggests that K(AB)-2 may contribute to supplying K+ to the Na(+)-K+ pump, which is abundant in the basolateral membrane of distal tubular epithelia, as well as to maintenance of the deep negative membrane potential of these cells.

Published

1996