Search

Your search keyword '"Kiernan, Amy E."' showing total 47 results
Start Over Author "Kiernan, Amy E."
47 results on '"Kiernan, Amy E."'

2. Using genetic mouse models to gain insight into glaucoma: Past results and future possibilities

Author

Fernandes, Kimberly A, Harder, Jeffrey M, Williams, Pete A, Rausch, Rebecca L, Kiernan, Amy E, Nair, K Saidas, Anderson, Michael G, John, Simon WM, Howell, Gareth R, and Libby, Richard T

Subjects
Biomedical and Clinical Sciences, Ophthalmology and Optometry, Human Genome, Eye Disease and Disorders of Vision, Aging, Neurosciences, Neurodegenerative, Genetics, 2.6 Resources and infrastructure (aetiology), Aetiology, Eye, Animals, Disease Models, Animal, Glaucoma, Humans, Intraocular Pressure, Mice, Retinal Ganglion Cells, Neuroinflammation, IOP, Axonal degeneration, Trabecular meshwork, Mouse genetics, Genomics, Neurodegeneration, DBA/2J, Medical Biochemistry and Metabolomics, Opthalmology and Optometry, Ophthalmology & Optometry, Ophthalmology and optometry
Abstract

While all forms of glaucoma are characterized by a specific pattern of retinal ganglion cell death, they are clinically divided into several distinct subclasses, including normal tension glaucoma, primary open angle glaucoma, congenital glaucoma, and secondary glaucoma. For each type of glaucoma there are likely numerous molecular pathways that control susceptibility to the disease. Given this complexity, a single animal model will never precisely model all aspects of all the different types of human glaucoma. Therefore, multiple animal models have been utilized to study glaucoma but more are needed. Because of the powerful genetic tools available to use in the laboratory mouse, it has proven to be a highly useful mammalian system for studying the pathophysiology of human disease. The similarity between human and mouse eyes coupled with the ability to use a combination of advanced cell biological and genetic tools in mice have led to a large increase in the number of studies using mice to model specific glaucoma phenotypes. Over the last decade, numerous new mouse models and genetic tools have emerged, providing important insight into the cell biology and genetics of glaucoma. In this review, we describe available mouse genetic models that can be used to study glaucoma-relevant disease/pathobiology. Furthermore, we discuss how these models have been used to gain insights into ocular hypertension (a major risk factor for glaucoma) and glaucomatous retinal ganglion cell death. Finally, the potential for developing new mouse models and using advanced genetic tools and resources for studying glaucoma are discussed.

Published
2015

8. Increased central auditory gain in 5xFAD Alzheimer's disease mice as an early biomarker candidate for Alzheimer's disease diagnosis.

Author

Daxiang Na, Jingyuan Zhang, Beaulac, Holly J., Piekna-Przybylska, Dorota, Nicklas, Paige R., Kiernan, Amy E., and White, Patricia M.

Subjects
ALZHEIMER'S disease, AUDITORY processing disorder, DIAGNOSIS, INFERIOR colliculus, HEARING disorders, APOLIPOPROTEIN E4, PRESBYCUSIS
Abstract

Alzheimer's Disease (AD) is a neurodegenerative illness without a cure. All current therapies require an accurate diagnosis and staging of AD to ensure appropriate care. Central auditory processing disorders (CAPDs) and hearing loss have been associated with AD, and may precede the onset of Alzheimer's dementia. Therefore, CAPD is a possible biomarker candidate for AD diagnosis. However, little is known about how CAPD and AD pathological changes are correlated. In the present study, we investigated auditory changes in AD using transgenic amyloidosis mouse models. AD mouse models were bred to a mouse strain commonly used for auditory experiments, to compensate for the recessive accelerated hearing loss on the parent background. Auditory brainstem response (ABR) recordings revealed significant hearing loss, a reduced ABR wave I amplitude, and increased central gain in 5xFAD mice. In comparison, these effects were milder or reversed in APP/PS1 mice. Longitudinal analyses revealed that in 5xFAD mice, central gain increase preceded ABR wave I amplitude reduction and hearing loss, suggesting that it may originate from lesions in the central nervous system rather than the peripheral loss. Pharmacologically facilitating cholinergic signaling with donepezil reversed the central gain in 5xFAD mice. After the central gain increased, aging 5xFAD mice developed deficits for hearing sound pips in the presence of noise, consistent with CAPD-like symptoms of AD patients. Histological analysis revealed that amyloid plaques were deposited in the auditory cortex of both mouse strains. However, in 5xFAD but not APP/PS1 mice, plaque was observed in the upper auditory brainstem, specifically the inferior colliculus (IC) and the medial geniculate body (MGB). This plaque distribution parallels histological findings from human subjects with AD and correlates in age with central gain increase. Overall, we conclude that auditory alterations in amyloidosis mouse models correlate with amyloid deposits in the auditory brainstem and may be reversed initially through enhanced cholinergic signaling. The alteration of ABR recording related to the increase in central gain prior to AD-related hearing disorders suggests that it could potentially be used as an early biomarker of AD diagnosis. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

12. Deletion of Notch1 during Cochlear Maturation Leads to Rapid Supporting Cell Death and Profound Deafness.

Author

Heffer, Alison, Gilels, Felicia A., and Kiernan, Amy E.

Subjects
CELL death, HAIR cells, DEAFNESS, CELL survival
Abstract

The sensory region of the mammalian hearing organ contains two main cell types—hair cells and supporting cells. During development, Notch signaling plays an important role in whether a cell becomes either a hair cell or supporting cell by mediating lateral inhibition. However, once the cell fate decisions have been determined, little is understood about the role Notch plays in cochlear maturation. Here, we report that deletion of Notch1 from the early postnatal mouse cochlea in both male and female animals resulted in profound deafness at 6 weeks of age. Histologic analyses at 6 weeks revealed significant hair cell and supporting cell loss throughout the Notch1-deficient cochlea. Early analyses revealed a reduction in supporting cells in the outer hair cell region between postnatal day (P) 2 and P6, without a comparable increase in outer hair cell number, suggesting a mechanism other than lateral inhibition. Consistent with this, we found apoptotic cells in the outer supporting cell region of the cochlea at P1 and P2, indicating that Notch1 is required for outer supporting cell survival during early cochlear maturation. Interestingly, inner supporting cell types were not lost after Notch1 deletion. Surprisingly, we do not detect outer hair cell loss in Notch1 mutants until after the onset of hearing, around P14, suggesting that hair cell loss is caused by loss of the supporting cells. Together, these results demonstrate that Notch1 is required for supporting cell survival during early maturation and that loss of these cells causes later loss of the hair cells and cochlear dysfunction. [ABSTRACT FROM AUTHOR]

Published
2023
Full Text
View/download PDF

14. Genetic background modifies inner ear and eye phenotypes of Jag1 heterozygous mice

Author

Kiernan, Amy E., Li, Renhua, Hawes, Norman L., Churchill, Gary A., and Gridley, Thomas

Subjects
Phenotype -- Properties, Labyrinth (Ear) -- Genetic aspects, Eye -- Genetic aspects, Heterozygosis -- Properties, Biological sciences
Abstract

Mice heterozygous for missense mutations of the Notch ligand Jagged1 (Jag1) exhibit head-shaking behavior indicative of an inner ear vestibular defect. In contrast, mice heterozygous for a targeted deletion of the Jag1 gene ([Jag1.sup.del1]) do not demonstrate obvious head-shaking behavior. To determine whether the differences in inner ear phenotypes were due to the types of Jag1 mutations or to differences in genetic background, we crossed [Jag1.sup.del1] heterozygous mice onto the same genetic background as the missense mutants. This analysis revealed that variation of the Jag1 mutant inner ear phenotype is caused by genetic background differences and is not due to the type of Jag1 mutation. Genome scans of N2 backcross mice identified a significant modifier locus on chromosome 7, as well as a suggestive locus on chromosome 14. We also analyzed modifiers of an eye defect in [Jag1.sup.del1] heterozygous mice from this same cross.

Published
2007

15. Sox2 is required for sensory organ development in the mammalian inner ear

Author

Kiernan, Amy E., Pelling, Anna L., Leung, Keith K. H., Tang, Anna S. P., Bell, Donald M., Tease, Charles, Lovell-Badge, Robin, Steel, Karen P., and Cheah, Kathryn S. E.

Subjects
Environmental issues, Science and technology, Zoology and wildlife conservation
Abstract

Author(s): Amy E. Kiernan [1, 5, 6]; Anna L. Pelling [2, 5]; Keith K. H. Leung [2]; Anna S. P. Tang [2]; Donald M. Bell [3]; Charles Tease [4, 6]; [...]

Published
2005
Full Text
View/download PDF

20. Contributors

Author

Anderson, Robert, primary, Ang, Siew-Lan, additional, Asakura, Atsushi, additional, Behringer, Richard R., additional, Burrows, Heather, additional, Byrne, Carolyn, additional, Camper, Sally, additional, Chen, Freida H., additional, Cross, James C., additional, Cushman, Lisa, additional, de Crombrugghe, Benoit, additional, De Vries, Wilhelmine N., additional, Depew, Michael J., additional, Douglas, Kristin, additional, Dressler, Gregory R., additional, Dzierzak, Elaine, additional, Evsikov, Alexi V., additional, Fekete, Donna M., additional, Gage, Phil, additional, Gardner, R.L., additional, Gossler, Achim, additional, Hamada, Hiroshi, additional, Hardman, Matthew, additional, Harvey, Richard P., additional, Hogan, Brigid L.M., additional, Joyner, Alexandra L., additional, Kiernan, Amy E., additional, Knowles, Barbara B., additional, Kondoh, Hisato, additional, Lefebvre, Veronique, additional, Loughna, Siobhan, additional, Lovell-Badge, Robin, additional, Marin, Oscar, additional, Martin, Donna, additional, Morrison, Sean J., additional, Nakashima, Kazuhisa, additional, Nasonkin, Igor, additional, Peaston, Anne E., additional, Peeters, Marlan, additional, Raetzman, Lori, additional, Rossant, Janet, additional, Rubenstein, John L.R., additional, Rudnicki, Michael A., additional, Sato, Thomas N., additional, Sharpe, Paul T., additional, Solter, Davor, additional, Speck, Nancy, additional, Steel, Karen P., additional, Suh, Hoonkyo, additional, Swain, Amanda, additional, Tam, Patrick P.L., additional, Tucker, Abigail S., additional, Wylie, Chris, additional, and Zaret, Kennneth S., additional

Published
2002
Full Text
View/download PDF

21. The expression domain of two related homeobox genes defines a compartment in the chicken inner ear that may be involved in semicircular canal formation

Author

Kiernan, Amy E., Nunes, Fabio, Wu, Doris K., and Fekete, Donna M.

Subjects
Homeobox genes -- Research, Labyrinth (Ear) -- Research, Chickens -- Genetic aspects, Developmental biology -- Research, Gene expression -- Research, Biological sciences
Abstract

Homeobox-containing genes encode a class of proteins that control patterning in developing systems, in some cases by acting as selector genes that define compartment identity. In an effort to demonstrate a similar role for such genes during ear development in the chicken, we present a detailed expression study of two related homeobox-containing genes, SOHo-1 and GH6, using in situ hybridization. At otocyst stages the two genes define a broad lateral domain of expression, which may represent a developmental compartment. Three-dimensional computer reconstructions of SOHo-1 expression at these and later stages revealed that the lateral domain becomes progressively restricted to the three semicircular canals. Thus, SOHo-1 and GH6 are among a small group of markers for a specific structural component of the inner ear. The gene expression domain initially includes the sensory regions of the semicircular canals, known as the cristae ampullaris, but none of the other four sensory organs which were recognizable by BMP4 expression during early morphogenesis (stages 19-94). Significantly, two of the sensory organs (the superior and posterior cristae) were found at the limits, or boundaries, of the SOHo-1/GH6 expression domain, suggesting that compartment boundaries may be involved in specifying sensory organ location as well as identity. Maintained expression at the boundaries may aid in specifying the location of canal outgrowth. These concepts are presented as a formal model which emphasizes that patterning information could be provided at the boundaries of gene expression domains in the inner ear.

Published
1997

27. SOX2 is required for inner ear growth and cochlear nonsensory formation before sensory development.

Author

Steevens, Aleta R., Glatzer, Jenna C., Kellogg, Courtney C., Low, Walter C., Santi, Peter A., and Kiernan, Amy E.

Subjects
HAIR cells, INNER ear, COCHLEA, CELL cycle, CELL aggregation, TRANSCRIPTION factors, EAR
Abstract

The transcription factor sex determining region Y-box 2 (SOX2) is required for the formation of hair cells and supporting cells in the inner ear and is a widely used sensory marker. Paradoxically, we demonstrate via fate mapping that, initially, SOX2 primarily marks nonsensory progenitors in the mouse cochlea, and is not specific to all sensory regions until late otic vesicle stages. SOX2 fate mapping reveals an apical-to-basal gradient of SOX2 expression in the sensory region of the cochlea, reflecting the pattern of cell cycle exit. To understand SOX2 function, we undertook a timed-deletion approach, revealing that early loss of SOX2 severely impaired morphological development of the ear, whereas later deletions resulted in sensory disruptions. During otocyst stages, SOX2 shifted dramatically from a lateral to medial domain over 24-48 h, reflecting the nonsensory-to-sensory switch observed by fate mapping. Early loss or gain of SOX2 function led to changes in otic epithelial volume and progenitor proliferation, impacting growth and morphological development of the ear. Our study demonstrates a novel role for SOX2 in early otic morphological development, and provides insights into the temporal and spatial patterns of sensory specification in the inner ear. [ABSTRACT FROM AUTHOR]

Published
2019
Full Text
View/download PDF

28. The Wheels Mutation in the Mouse Causes Vascular, Hindbrain, and Inner Ear Defects

Author

Alavizadeh, Alireza, Kiernan, Amy E., Nolan, Patrick, Lo, Cecilia, Steel, Karen P., and Bucan, Maja

Subjects
Developmental biology -- Research, Mutation (Biology) -- Observations, Mice as laboratory animals -- Genetic aspects, Embryology -- Research, Labyrinth (Ear) -- Analysis, Biological sciences
Abstract

In a screen for mouse mutations with dominant behavioral anomalies, we identified Wheels, a mutation associated with circling and hyperactivity in heterozygotes and embryonic lethality in homozygotes. Mutant Wheels embryos die at E10.5-E11.5 and exhibit a host of morphological anomalies which include growth retardation and anomalies in vascular and hindbrain development. The latter includes perturbation of rhombomeric boundaries as detected by Krox20 and Hoxb1. PECAM-1 staining of embryos revealed normal formation of the primary vascular plexus. However, subsequent stages of branching and remodeling do not proceed normally in the yolk sac and in the embryo proper. To obtain insights into the circling behavior, we examined development of the inner ear by paint-filling of membranous labyrinths of Wh1/+ embryos. This analysis revealed smaller posterior and lateral semicircular canal primordia and a delay in the canal fusion process at E12.5. By E13.5, the lateral canal was truncated and the posterior canal was small or absent altogether. Marker analysis revealed an early molecular phenotype in heterozygous embryos characterized by perturbed expression of Bmp4 and Msx1 in prospective lateral and posterior cristae at E11.5. We have constructed a genetic and radiation hybrid map of the centromeric portion of mouse Chromosome 4 across the Wheels region and refined the position of the Wheels locus to the ~1.1-cM region between D4Mit104 and D4Mit181. We have placed the locus encoding Epha7, in the Wheels candidate region; however, further analysis showed no mutations in the Epha7-coding region and no detectable changes in mRNA expression pattern. In summary, our findings indicate that Wheels, a gene which is essential for the survival of the embryo, may link diverse processes involved in vascular, hindbrain, and inner ear development, [C] 2001 Academic Press Key Words: mouse; ENU mutagenesis; vascular development; angiogenesis; inner ear; Bmp4; Eph.

Published
2001

31. Deletion of a Long-Range Dlx5Enhancer Disrupts Inner Ear Development in Mice

Author

Johnson, Kenneth R, Gagnon, Leona H, Tian, Cong, Longo-Guess, Chantal M, Low, Benjamin E, Wiles, Michael V, and Kiernan, Amy E

Abstract

Distal enhancers are thought to play important roles in the spatiotemporal regulation of gene expression during embryonic development, but few predicted enhancer elements have been shown to affect transcription of their endogenous genes or to alter phenotypes when disrupted. Here, we demonstrate that a 123.6-kb deletion within the mouse Slc25a13gene is associated with reduced transcription of Dlx5, a gene located 660 kb away. Mice homozygous for the Slc25a13deletion mutation [named hyperspin (hspn)] have malformed inner ears and are deaf with balance defects, whereas previously reported Slc25a13knockout mice showed no phenotypic abnormalities. Inner ears of Slc25a13hspn/hspnmice have malformations similar to those of Dlx5−/−embryos, and Dlx5expression is severely reduced in the otocyst but not the branchial arches of Slc25a13hspn/hspnembryos, indicating that the Slc25a13hspndeletion affects otic-specific enhancers of Dlx5. In addition, transheterozygous Slc25a13+/hspnDlx5+/−mice exhibit noncomplementation with inner ear dysmorphologies similar to those of Slc25a13hspn/hspnand Dlx5−/−embryos, verifying a cis-acting effect of the Slc25a13hspndeletion on Dlx5expression. CRISPR/Cas9-mediated deletions of putative enhancer elements located within the Slc25a13hspndeleted region failed to phenocopy the defects of Slc25a13hspn/hspnmice, suggesting the possibility of multiple enhancers with redundant functions. Our findings in mice suggest that analogous enhancer elements in the human SLC25A13gene may regulate DLX5expression and underlie the hearing loss that is associated with split-hand/-foot malformation 1 syndrome. Slc25a13hspn/hspnmice provide a new animal model for studying long-range enhancer effects on Dlx5expression in the developing inner ear.

Published
2018
Full Text
View/download PDF

39. LMO4 Functions As a Negative Regulator of Sensory Organ Formation in the Mammalian Cochlea.

Author

Min Deng, Xiong-jian Luo, Ling Pan, Hua Yang, Xiaoling Xie, Guoqing Liang, Liang Huang, Fang Hu, Kiernan, Amy E., and Lin Gan

Subjects
COCHLEA, SENSE organs, PROTEINS, HAIR cells, PHENOTYPES
Abstract

In mammals, formation of the auditory sensory organ (the organ of Corti) is restricted to a specialized area of the cochlea. However, the molecular mechanisms limiting sensory formation to this discrete region in the ventral cochlear duct are not well understood, nor is it known whether other regions of the cochlea have the competence to form the organ of Corti. Here we identify LMO4, a LIM-domain-only nuclear protein, as a negative regulator of sensory organ formation in the cochlea. Inactivation of Lmo4 in mice leads to an ectopic organ of Corti (eOC) located in the lateral cochlea. The eOC retains the features of the native organ, including inner and outer hair cells, supporting cells, and other nonsensory specialized cell types. However, the eOC shows an orientation opposite to the native organ, such that the eOC appears as a mirror-image duplication to the native organ of Corti. These data demonstrate a novel sensory competent region in the lateral cochlear duct that is regulated by LMO4 and may be amenable to therapeutic manipulation. [ABSTRACT FROM AUTHOR]

Published
2014
Full Text
View/download PDF

41. Ectopic Expression of Activated Notch or SOX2 Reveals Similar and Unique Roles in the Development of the Sensory Cell Progenitors in the Mammalian Inner Ear.

Author

Wei Pan, Ying Jin, Jing Chen, Rottier, Robbert J., Steel, Karen P., and Kiernan, Amy E.

Subjects
NOTCH genes, PROGENITOR cells, CELL growth, HEARING disorders, INNER ear diseases, TRANSCRIPTION factors
Abstract

Hearing impairment or vestibular dysfunction in humans often results from a permanent loss of critical cell types in the sensory regions of the inner ear, including hair cells, supporting cells, or cochleovestibular neurons. These important cell types arise from a common sensory or neurosensory progenitor, although little is known about how these progenitors are specified. Studies have shown that Notch signaling and the transcription factor Sox2 are required for the development of these lineages. Previously we and others demonstrated that ectopic activation of Notch can direct nonsensory cells to adopt a sensory fate, indicating a role for Notch in early specification events. Here, we explore the relationship between Notch and SOX2 by ectopically activating these factors in nonsensory regions of the mouse cochlea, and demonstrate that, similar to Notch, SOX2 can specify sensory progenitors, consistent with a role downstream of Notch signaling. However, we also show that Notch has a unique role in promoting the proliferation of the sensory progenitors. We further demonstrate that Notch can only induce ectopic sensory regions within a certain time window of development, and that the ectopic hair cells display specialized stereocilia bundles similar to endogenous hair cells. These results demonstrate that Notch and SOX2 can both drive the sensory program in nonsensory cells, indicating these factors may be useful in cell replacement strategies in the inner ear. [ABSTRACT FROM AUTHOR]

Published
2013
Full Text
View/download PDF

42. Notch2 regulates BMP signaling and epithelial morphogenesis in the ciliary body of the mouse eye.

Author

Yi Zhou, Tanzie, Christopher, Zhipeng Yan, Shuyi Chen, Duncan, Michael, Gaudenz, Karin, Hua Li, Seidel, Christopher, Lewis, Brandy, Moran, Andrea, Libby, Richard T., Kiernan, Amy E., and Ting Xie

Subjects
CILIARY body, INTRAOCULAR pressure, AQUEOUS humor, BONE morphogenetic proteins, ANIMAL models in research, MICE
Abstract

The ciliary body (CB) of the mammalian eye is responsible for secreting aqueous humor to maintain intraocular pressure, which is elevated in the eyes of glaucoma patients. It contains a folded two-layered epithelial structure comprising the nonpigmented inner ciliary epithelium (ICE), the pigmented outer ciliary epithelium (OCE), and the underlying stroma. Although the CB has an important function in the eye, its morphogenesis remains poorly studied. In this study, we show that conditional inactivation of the Jagged 1 (Jag1)-Notch2 signaling pathway in the developing CB abolishes its morphogenesis. Notch2 is expressed in the OCE of the CB, whereas Jag1 is expressed in the ICE. Conditional inactivation of Jag1 in the ICE or Notch2 in the OCE disrupts CB morphogenesis, but neither affects the specification of the CB region. Notch2 signaling in the OCE is required for promoting cell proliferation and maintaining bone morphogenetic protein (BMP) signaling, both of which have been suggested to be important for CB morphogenesis. Although Notch and BMP signaling pathways are known to cross-talk via the interaction between their downstream transcriptional factors, this study suggests that Notch2 maintains BMP signaling in the OCE possibly by repressing expression of secreted BMP inhibitors. Based on our findings, we propose that Jag1-Notch2 signaling controls CB morphogenesis at least in part by regulating cell proliferation and BMP signaling. [ABSTRACT FROM AUTHOR]

Published
2013
Full Text
View/download PDF

43. Notch signaling is required for the generation of hair cells and supporting cells in the mammalian inner ear.

Author

Wei Pan, Ying Jin, Stanger, Ben, and Kiernan, Amy E.

Subjects
EAR diseases, HAIR cells, HEARING disorders, CELL death, EPITHELIUM
Abstract

Sensorineural deafness and balance dysfunction are common impairments in humans frequently caused by defects in the sensory epithelium of the inner ear, composed of hair cells and supporting cells. Lineage studies have shown that hair cells and supporting cells arise from a common progenitor, but how these progenitors are generated remains unknown. Although various molecules have been implicated in the development of the sensory progenitors. none has been shown to be required for the specification of these progenitors in the mammalian inner ear. Here, using both loss-of- function and gain-of-function approaches, we show that Jaggedi (JAG1)-mediated Notch signaling is both required and sufficient for the generation of the sensory progenitors. Specifically, we find that loss of JAG1 signaling leads to smaller sensory progenitor regions without initial effects on proliferation or cell death, indicating that JAG1 is involved in initial specification events. To further test whether Notch signaling is involved in specification of the sensory progenitors, we transiently expressed an activated form of the Notchi receptor (NICD) using a combined Tet-On/Cre induction system in the mouse. NICD expression resulted in ectopic hair cells and supporting cells in the nonsensory regions of the cochlea and vestibule. These data indicate that Notch specifies sensory progenitors in the inner ear, and that induction of Notch may be important for regenerating or replacing hair cells and supporting cells in the mammalian inner ear. [ABSTRACT FROM AUTHOR]

Published
2010
Full Text
View/download PDF

44. The WheelsMutation in the Mouse Causes Vascular, Hindbrain, and Inner Ear Defects

Author

Alavizadeh, Alireza, Kiernan, Amy E., Nolan, Patrick, Lo, Cecilia, Steel, Karen P., and Bucan, Maja

Abstract

In a screen for mouse mutations with dominant behavioral anomalies, we identified Wheels, a mutation associated with circling and hyperactivity in heterozygotes and embryonic lethality in homozygotes. Mutant Wheelsembryos die at E10.5–E11.5 and exhibit a host of morphological anomalies which include growth retardation and anomalies in vascular and hindbrain development. The latter includes perturbation of rhombomeric boundaries as detected by Krox20and Hoxb1. PECAM-1 staining of embryos revealed normal formation of the primary vascular plexus. However, subsequent stages of branching and remodeling do not proceed normally in the yolk sac and in the embryo proper. To obtain insights into the circling behavior, we examined development of the inner ear by paint-filling of membranous labyrinths of Whl/+embryos. This analysis revealed smaller posterior and lateral semicircular canal primordia and a delay in the canal fusion process at E12.5. By E13.5, the lateral canal was truncated and the posterior canal was small or absent altogether. Marker analysis revealed an early molecular phenotype in heterozygous embryos characterized by perturbed expression of Bmp4and Msx1in prospective lateral and posterior cristae at E11.5. We have constructed a genetic and radiation hybrid map of the centromeric portion of mouse Chromosome 4 across the Wheelsregion and refined the position of the Wheelslocus to the ∼1.1-cM region between D4Mit104and D4Mit181. We have placed the locus encoding Epha7, in the Wheelscandidate region; however, further analysis showed no mutations in the Epha7-coding region and no detectable changes in mRNA expression pattern. In summary, our findings indicate that Wheels, a gene which is essential for the survival of the embryo, may link diverse processes involved in vascular, hindbrain, and inner ear development.

Published
2001
Full Text
View/download PDF

45. Notch1 is required to maintain supporting cell identity and vestibular function during maturation of the mammalian balance organs.

Author

Heffer A, Lee C, Holt JC, and Kiernan AE

Abstract

The inner ear houses two sensory modalities: the hearing organ, located in the cochlea, and the balance organs, located throughout the vestibular regions of the ear. Both hearing and vestibular sensory regions are composed of similar cell types, including hair cells and associated supporting cells. Recently, we showed that Notch1 is required for maintaining supporting cell survival postnatally during cochlear maturation. However, it is not known whether Notch1 plays a similar role in the balance organs of the inner ear. To characterize the role of Notch during vestibular maturation, we conditionally deleted Notch1 from Sox2 -expressing cells of the vestibular organs in the mouse at P0/P1. Histological analyses showed a dramatic loss of supporting cells accompanied by an increase in type II hair cells without cell death, indicating the supporting cells are converting to hair cells in the maturing vestibular regions. Analysis of 6-week old animals indicate that the converted hair cells survive, despite the reduction of supporting cells. Interestingly, measurements of vestibular sensory evoked potentials (VsEPs), known to be generated in the striolar regions of the vestibular afferents in the maculae, failed to show a response, indicating that NOTCH1 expression is critical for striolar function postnatally. Consistent with this, we find that the specialized type I hair cells in the striola fail to develop the complex calyces typical of these cells. These defects are likely due to the reduction in supporting cells, which have previously been shown to express factors critical for the striolar region. Similar to other mutants that lack proper striolar development, Notch1 mutants do not exhibit typical vestibular behaviors such as circling and head shaking, but do show difficulties in some vestibular tests, including the balance beam and forced swim test. These results indicate that, unlike the hearing organ in which the supporting cells undergo cell death, supporting cells in the balance regions retain the ability to convert to hair cells during maturation, which survive into adulthood despite the reduction in supporting cells.

Published
2024
Full Text
View/download PDF

46. LMO4 functions as a negative regulator of sensory organ formation in the mammalian cochlea.

Author

Deng M, Luo XJ, Pan L, Yang H, Xie X, Liang G, Huang L, Hu F, Kiernan AE, and Gan L

Subjects
Adaptor Proteins, Signal Transducing antagonists & inhibitors, Adaptor Proteins, Signal Transducing physiology, Animals, Cochlea growth & development, Female, Gene Knock-In Techniques, LIM Domain Proteins antagonists & inhibitors, LIM Domain Proteins physiology, Male, Mice, Mice, Knockout, Mice, Transgenic, Sense Organs growth & development, Adaptor Proteins, Signal Transducing genetics, LIM Domain Proteins genetics, Organ of Corti growth & development
Abstract

In mammals, formation of the auditory sensory organ (the organ of Corti) is restricted to a specialized area of the cochlea. However, the molecular mechanisms limiting sensory formation to this discrete region in the ventral cochlear duct are not well understood, nor is it known whether other regions of the cochlea have the competence to form the organ of Corti. Here we identify LMO4, a LIM-domain-only nuclear protein, as a negative regulator of sensory organ formation in the cochlea. Inactivation of Lmo4 in mice leads to an ectopic organ of Corti (eOC) located in the lateral cochlea. The eOC retains the features of the native organ, including inner and outer hair cells, supporting cells, and other nonsensory specialized cell types. However, the eOC shows an orientation opposite to the native organ, such that the eOC appears as a mirror-image duplication to the native organ of Corti. These data demonstrate a novel sensory competent region in the lateral cochlear duct that is regulated by LMO4 and may be amenable to therapeutic manipulation., (Copyright © 2014 the authors 0270-6474/14/3410072-06$15.00/0.)

Published
2014
Full Text
View/download PDF

47. Ectopic expression of activated notch or SOX2 reveals similar and unique roles in the development of the sensory cell progenitors in the mammalian inner ear.

Author

Pan W, Jin Y, Chen J, Rottier RJ, Steel KP, and Kiernan AE

Subjects
Animals, Ear, Inner metabolism, Immunohistochemistry, Mice, Mice, Transgenic, Microscopy, Electron, Scanning, Signal Transduction physiology, Cell Differentiation physiology, Ear, Inner cytology, Neural Stem Cells cytology, Neural Stem Cells metabolism, Receptors, Notch metabolism, SOXB1 Transcription Factors metabolism
Abstract

Hearing impairment or vestibular dysfunction in humans often results from a permanent loss of critical cell types in the sensory regions of the inner ear, including hair cells, supporting cells, or cochleovestibular neurons. These important cell types arise from a common sensory or neurosensory progenitor, although little is known about how these progenitors are specified. Studies have shown that Notch signaling and the transcription factor Sox2 are required for the development of these lineages. Previously we and others demonstrated that ectopic activation of Notch can direct nonsensory cells to adopt a sensory fate, indicating a role for Notch in early specification events. Here, we explore the relationship between Notch and SOX2 by ectopically activating these factors in nonsensory regions of the mouse cochlea, and demonstrate that, similar to Notch, SOX2 can specify sensory progenitors, consistent with a role downstream of Notch signaling. However, we also show that Notch has a unique role in promoting the proliferation of the sensory progenitors. We further demonstrate that Notch can only induce ectopic sensory regions within a certain time window of development, and that the ectopic hair cells display specialized stereocilia bundles similar to endogenous hair cells. These results demonstrate that Notch and SOX2 can both drive the sensory program in nonsensory cells, indicating these factors may be useful in cell replacement strategies in the inner ear.

Published
2013
Full Text
View/download PDF

Catalog

Books, media, physical & digital resources
See catalog results