Your search keyword '"Beyer LA"' showing total 6 results

1. Hearing dysfunction in heterozygous Mitf(Mi-wh) /+ mice, a model for Waardenburg syndrome type 2 and Tietz syndrome.

Author

Ni C, Zhang D, Beyer LA, Halsey KE, Fukui H, Raphael Y, Dolan DF, and Hornyak TJ

Subjects

Action Potentials physiology, Albinism, Oculocutaneous genetics, Albinism, Oculocutaneous pathology, Animals, Animals, Newborn, Deafness genetics, Deafness pathology, Disease Models, Animal, Embryo, Mammalian metabolism, Embryo, Mammalian pathology, Evoked Potentials, Auditory, Brain Stem physiology, Hair Cells, Auditory, Outer metabolism, Hair Cells, Auditory, Outer pathology, Humans, Melanocytes metabolism, Melanocytes pathology, Mice, Mice, Inbred C57BL, Mice, Transgenic, Otoacoustic Emissions, Spontaneous physiology, Stria Vascularis metabolism, Stria Vascularis pathology, Waardenburg Syndrome genetics, Waardenburg Syndrome pathology, Albinism, Oculocutaneous physiopathology, Deafness physiopathology, Hearing physiology, Heterozygote, Microphthalmia-Associated Transcription Factor genetics, Waardenburg Syndrome physiopathology

Abstract

The human deafness-pigmentation syndromes, Waardenburg syndrome (WS) type 2a, and Tietz syndrome are characterized by profound deafness but only partial cutaneous pigmentary abnormalities. Both syndromes are caused by mutations in MITF. To illuminate differences between cutaneous and otic melanocytes in these syndromes, their development and survival in heterozygous Microphthalmia-White (Mitf(Mi-wh) /+) mice were studied and hearing function of these mice characterized. Mitf(Mi-wh) /+ mice have a profound hearing deficit, characterized by elevated auditory brainstem response thresholds, reduced distortion product otoacoustic emissions, absent endocochlear potential, loss of outer hair cells, and stria vascularis abnormalities. Mitf(Mi-wh) /+ embryos have fewer melanoblasts during embryonic development than their wild-type littermates. Although cochlear melanocytes are present at birth, they disappear from the Mitf(Mi-wh) /+ cochlea between P1 and P7. These findings may provide insight into the mechanism of melanocyte and hearing loss in human deafness-pigmentation syndromes such as WS and Tietz syndrome and illustrate differences between otic and follicular melanocytes., (© 2012 John Wiley & Sons A/S.)

Published

2013

2. BDNF gene therapy induces auditory nerve survival and fiber sprouting in deaf Pou4f3 mutant mice.

Author

Fukui H, Wong HT, Beyer LA, Case BG, Swiderski DL, Di Polo A, Ryan AF, and Raphael Y

Subjects

Adenoviridae genetics, Animals, Brain-Derived Neurotrophic Factor metabolism, Cell Survival, Cochlear Implantation, Cochlear Nerve metabolism, Cochlear Nerve pathology, Genetic Therapy, Homeodomain Proteins metabolism, Mice, Mutation, Nerve Fibers physiology, Spiral Ganglion cytology, Spiral Ganglion physiology, Transcription Factor Brn-3C metabolism, Brain-Derived Neurotrophic Factor genetics, Deafness therapy, Homeodomain Proteins genetics, Transcription Factor Brn-3C genetics

Abstract

Current therapy for patients with hereditary absence of cochlear hair cells, who have severe or profound deafness, is restricted to cochlear implantation, a procedure that requires survival of the auditory nerve. Mouse mutations that serve as models for genetic deafness can be utilized for developing and enhancing therapies for hereditary deafness. A mouse with Pou4f3 loss of function has no hair cells and a subsequent, progressive degeneration of auditory neurons. Here we tested the influence of neurotrophin gene therapy on auditory nerve survival and peripheral sprouting in Pou4f3 mouse ears. BDNF gene transfer enhanced preservation of auditory neurons compared to control ears, in which nearly all neurons degenerated. Surviving neurons in treated ears exhibited pronounced sprouting of nerve fibers into the auditory epithelium, despite the absence of hair cells. This enhanced nerve survival and regenerative sprouting may improve the outcome of cochlear implant therapy in patients with hereditary deafness.

Published

2012

3. Transgenic BDNF induces nerve fiber regrowth into the auditory epithelium in deaf cochleae.

Author

Shibata SB, Cortez SR, Beyer LA, Wiler JA, Di Polo A, Pfingst BE, and Raphael Y

Subjects

Adenoviridae genetics, Animals, Animals, Genetically Modified, Basilar Membrane physiology, Deafness physiopathology, Epithelial Cells physiology, Epithelium physiology, Green Fluorescent Proteins genetics, Guinea Pigs, Hair Cells, Auditory physiology, Hair Cells, Auditory ultrastructure, Male, Nerve Fibers physiology, Spiral Ganglion physiology, Basilar Membrane cytology, Brain-Derived Neurotrophic Factor genetics, Deafness therapy, Genetic Therapy methods, Nerve Regeneration physiology, Spiral Ganglion cytology

Abstract

Sensory organs typically use receptor cells and afferent neurons to transduce environmental signals and transmit them to the CNS. When sensory cells are lost, nerves often regress from the sensory area. Therapeutic and regenerative approaches would benefit from the presence of nerve fibers in the tissue. In the hearing system, retraction of afferent innervation may accompany the degeneration of auditory hair cells that is associated with permanent hearing loss. The only therapy currently available for cases with severe or complete loss of hair cells is the cochlear implant auditory prosthesis. To enhance the therapeutic benefits of a cochlear implant, it is necessary to attract nerve fibers back into the cochlear epithelium. Here we show that forced expression of the neurotrophin gene BDNF in epithelial or mesothelial cells that remain in the deaf ear induces robust regrowth of nerve fibers towards the cells that secrete the neurotrophin, and results in re-innervation of the sensory area. The process of neurotrophin-induced neuronal regeneration is accompanied by significant preservation of the spiral ganglion cells. The ability to regrow nerve fibers into the basilar membrane area and protect the auditory nerve will enhance performance of cochlear implants and augment future cell replacement therapies such as stem cell implantation or induced transdifferentiation. This model also provides a general experimental stage for drawing nerve fibers into a tissue devoid of neurons, and studying the interaction between the nerve fibers and the tissue., (Copyright (c) 2009 Elsevier Inc. All rights reserved.)

Published

2010

4. Characterization of two transgene insertional mutations at pirouette, a mouse deafness locus.

Author

Odeh H, Hagiwara N, Skynner M, Mitchem KL, Beyer LA, Allen ND, Brilliant MH, Lebart MC, Dolan DF, Raphael Y, and Kohrman DC

Subjects

Actins analysis, Alleles, Animals, Cell Line, Evoked Potentials, Auditory, Brain Stem genetics, Genotype, Hair Cells, Auditory chemistry, Hair Cells, Auditory ultrastructure, Humans, Immunohistochemistry, Membrane Glycoproteins, Mice, Mice, Mutant Strains, Microfilament Proteins analysis, Microscopy, Electron, Scanning, Phosphoproteins analysis, Deafness genetics, Mutagenesis, Insertional, Mutation, Transgenes

Abstract

The mouse mutant 'pirouette' (pi) exhibits profound hearing loss and vestibular defects due to inheritance of a recessive mutation on chromosome 5. Dysfunction has been correlated with defects during maturation of sensory cells in the inner ear. As an initial step in characterizing pirouette at the genetic level, we have localized the candidate interval to a small region on central chromosome 5 by analysis of a congenic strain of pirouette mice. This region exhibits conserved synteny with human chromosome 4 and suggests that pirouette may be a genetic model of the human nonsyndromic deafness disorder DFNB25, which has been localized to 4p15.3-q12. In addition to the original spontaneous pirouette strain, we have identified and characterized 2 additional mouse strains with allelic mutations at the same locus. Analysis of the morphology in each of the 3 pirouette alleles indicated very similar early postnatal alterations in maturation of stereocilia and suggests that the gene affected in pirouette normally plays a role in building or maintaining these structures that are critical for sensory mechanotransduction., (Copyright 2004 S. Karger AG, Basel)

Published

2004

5. Claudin 14 knockout mice, a model for autosomal recessive deafness DFNB29, are deaf due to cochlear hair cell degeneration.

Author

Ben-Yosef T, Belyantseva IA, Saunders TL, Hughes ED, Kawamoto K, Van Itallie CM, Beyer LA, Halsey K, Gardner DJ, Wilcox ER, Rasmussen J, Anderson JM, Dolan DF, Forge A, Raphael Y, Camper SA, and Friedman TB

Subjects

Animals, Animals, Newborn, Cell Membrane Permeability genetics, Claudins, Cochlea cytology, Cochlea metabolism, Deafness pathology, Ear, Inner metabolism, Female, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Nerve Degeneration pathology, Organ of Corti ultrastructure, Sequence Deletion, Deafness genetics, Hair Cells, Auditory pathology, Membrane Proteins genetics, Organ of Corti chemistry, Tight Junctions physiology

Abstract

Tight junctions (TJs) create ion-selective paracellular permeability barriers between extracellular compartments. In the organ of Corti of the inner ear, TJs of the reticular lamina separate K(+)-rich endolymph and Na(+)-rich perilymph. In humans, mutations of the gene encoding claudin 14 TJ protein cause profound deafness but the underlying pathogenesis is unknown. To explore the role of claudin 14 in the inner ear and in other tissues we created a mouse model by a targeted deletion of Cldn14. In the targeted allele a lacZ cassette is expressed under the Cldn14 promoter. In Cldn14-lacZ heterozygous mice beta-galactosidase activity was detected in cochlear inner and outer hair cells and supporting cells, in the collecting ducts of the kidney, and around the lobules of the liver. Cldn14-null mice have a normal endocochlear potential but are deaf due to rapid degeneration of cochlear outer hair cells, followed by slower degeneration of the inner hair cells, during the first 3 weeks of life. Monolayers of MDCK cells expressing claudin 14 show a 6-fold increase in the transepithelial electrical resistance by decreasing paracellular permeability for cations. In wild type mice, claudin 14 was immunolocalized at hair cell and supporting cell TJs. Our data suggest that the TJ complex at the apex of the reticular lamina requires claudin 14 as a cation-restrictive barrier to maintain the proper ionic composition of the fluid surrounding the basolateral surface of outer hair cells.

Published

2003

6. Hair cells in the inner ear of the pirouette and shaker 2 mutant mice.

Author

Beyer LA, Odeh H, Probst FJ, Lambert EH, Dolan DF, Camper SA, Kohrman DC, and Raphael Y

Subjects

Actin Cytoskeleton pathology, Actin Cytoskeleton ultrastructure, Animals, Animals, Newborn abnormalities, Animals, Newborn growth & development, Animals, Newborn physiology, Cilia pathology, Cilia ultrastructure, Deafness physiopathology, Disease Models, Animal, Evoked Potentials, Auditory, Brain Stem physiology, Hair Cells, Auditory pathology, Mice, Mice, Inbred C57BL, Mice, Neurologic Mutants genetics, Mice, Neurologic Mutants metabolism, Microscopy, Electron, Microscopy, Electron, Scanning, Organ of Corti abnormalities, Organ of Corti pathology, Organ of Corti ultrastructure, Phalloidine, Vestibular Diseases physiopathology, Vestibule, Labyrinth abnormalities, Vestibule, Labyrinth pathology, Vestibule, Labyrinth ultrastructure, Deafness genetics, Deafness pathology, Hair Cells, Auditory abnormalities, Hair Cells, Auditory ultrastructure, Mice, Neurologic Mutants abnormalities, Vestibular Diseases genetics, Vestibular Diseases pathology

Abstract

The shaker 2 (sh2) and pirouette (pi) mouse mutants display severe inner ear dysfunction that involves both auditory and vestibular manifestation. Pathology of the stereocilia of hair cells has been found in both mutants. This study was designed to further our knowledge of the pathological characteristics of the inner ear sensory epithelia in both the sh2 and pi strains. Measurements of auditory brainstem responses indicated that both mutants were profoundly deaf. The morphological assays were specifically designed to characterize a pathological actin bundle that is found in both the inner hair cells and the vestibular hair cells in all five vestibular organs in these two mutants. Using light microscope analysis of phalloidin-stained specimens, these actin bundles could first be detected on postnatal day 3. As the cochleae matured, each inner hair cell and type I vestibular hair cell contained a bundle that spans from the region of the cuticular plate to the basal end of the cell, then extends along with cytoplasm and membrane, towards the basement membrane. Abnormal contact with the basement membrane was found in vestibular hair cells. Based on the shape of the cellular extension and the actin bundle that supports it, we propose to name these extensions "cytocauds." The data suggest that the cytocauds in type I vestibular hair cells and inner hair cells are associated with a failure to differentiate and detach from the basement membrane.

Published

2000