Your search keyword '"Alan G. Cheng"' showing total 5 results

1. Editorial: Epidemiology and Genetics of Vestibular Disorders

Author

Jose A. Lopez-Escamez, Alan G. Cheng, Eva Grill, and Tien-Chen Liu

Subjects

Meniere disease, vestibular migraine, heritability, exome sequencing, RNA seq, familial aggregation, Neurology. Diseases of the nervous system, RC346-429

Published

2021

2. Gpr125 Marks Distinct Cochlear Cell Types and Is Dispensable for Cochlear Development and Hearing

Author

Haiying Sun, Tian Wang, Patrick J. Atkinson, Sara E. Billings, Wuxing Dong, and Alan G. Cheng

Subjects

Gpr125, cochlea, lesser epithelial ridge, hair cell, spiral ganglion neurons, Biology (General), QH301-705.5

Abstract

The G protein-coupled receptor (GPR) family critically regulates development and homeostasis of multiple organs. As a member of the GPR adhesion family, Gpr125 (Adgra3) modulates Wnt/PCP signaling and convergent extension in developing zebrafish, but whether it is essential for cochlear development in mammals is unknown. Here, we examined the Gpr125lacZ/+ knock-in mice and show that Gpr125 is dynamically expressed in the developing and mature cochleae. From embryonic day (E) 15.5 to postnatal day (P) 30, Gpr125-β-Gal is consistently expressed in the lesser epithelial ridge and its presumed progenies, the supporting cell subtypes Claudius cells and Hensen’s cells. In contrast, Gpr125-β-Gal is expressed transiently in outer hair cells, epithelial cells in the lateral cochlear wall, interdental cells, and spiral ganglion neurons in the late embryonic and early postnatal cochlea. In situ hybridization for Gpr125 mRNA confirmed Gpr125 expression and validated loss of expression in Gpr125lacZ/lacZ cochleae. Lastly, Gpr125lacZ/+ and Gpr125lacZ/lacZ cochleae displayed no detectable loss or disorganization of either sensory or non-sensory cells in the embryonic and postnatal ages and exhibited normal auditory physiology. Together, our study reveals that Gpr125 is dynamically expressed in multiple cell types in the developing and mature cochlea and is dispensable for cochlear development and hearing.

Published

2021

3. Towards the Prevention of Aminoglycoside-Related Hearing Loss

Author

Mary E. O’Sullivan, Adela Perez, Randy Lin, Autefeh Sajjadi, Anthony J. Ricci, and Alan G. Cheng

Subjects

aminoglycoside antibiotics, mechanotransducer channel, ribosome, ototoxicity, mRNA misreading, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Aminoglycosides are potent antibiotics deployed worldwide despite their known side-effect of sensorineural hearing loss. The main etiology of this sensory deficit is death of inner ear sensory hair cells selectively triggered by aminoglycosides. For decades, research has sought to unravel the molecular events mediating sensory cell demise, emphasizing the roles of reactive oxygen species and their potentials as therapeutic targets. Studies in recent years have revealed candidate transport pathways including the mechanotransducer channel for drug entry into sensory cells. Once inside sensory cells, intracellular targets of aminoglycosides, such as the mitochondrial ribosomes, are beginning to be elucidated. Based on these results, less ototoxic aminoglycoside analogs are being generated and may serve as alternate antimicrobial agents. In this article, we review the latest findings on mechanisms of aminoglycoside entry into hair cells, their intracellular actions and potential therapeutic targets for preventing aminoglycoside ototoxicity.

Published

2017

4. Gpr125 Marks Distinct Cochlear Cell Types and Is Dispensable for Cochlear Development and Hearing

Author

Wuxing Dong, Sara E Billings, Patrick J. Atkinson, Tian Wang, Haiying Sun, and Alan G. Cheng

Subjects

0301 basic medicine, Cell type, QH301-705.5, cochlea, In situ hybridization, Gpr125, hair cell, 03 medical and health sciences, Cell and Developmental Biology, 0302 clinical medicine, medicine, otorhinolaryngologic diseases, Biology (General), Zebrafish, Spiral ganglion, Cochlea, Original Research, biology, Wnt signaling pathway, spiral ganglion neurons, Cell Biology, biology.organism_classification, Embryonic stem cell, Cell biology, 030104 developmental biology, medicine.anatomical_structure, lesser epithelial ridge, Hair cell, sense organs, 030217 neurology & neurosurgery, Developmental Biology

Abstract

The G protein-coupled receptor (GPR) family critically regulates development and homeostasis of multiple organs. As a member of the GPR adhesion family, Gpr125 (Adgra3) modulates Wnt/PCP signaling and convergent extension in developing zebrafish, but whether it is essential for cochlear development in mammals is unknown. Here, we examined the Gpr125lacZ/+ knock-in mice and show that Gpr125 is dynamically expressed in the developing and mature cochleae. From embryonic day (E) 15.5 to postnatal day (P) 30, Gpr125-β-Gal is consistently expressed in the lesser epithelial ridge and its presumed progenies, the supporting cell subtypes Claudius cells and Hensen’s cells. In contrast, Gpr125-β-Gal is expressed transiently in outer hair cells, epithelial cells in the lateral cochlear wall, interdental cells, and spiral ganglion neurons in the late embryonic and early postnatal cochlea. In situ hybridization for Gpr125 mRNA confirmed Gpr125 expression and validated loss of expression in Gpr125lacZ/lacZ cochleae. Lastly, Gpr125lacZ/+ and Gpr125lacZ/lacZ cochleae displayed no detectable loss or disorganization of either sensory or non-sensory cells in the embryonic and postnatal ages and exhibited normal auditory physiology. Together, our study reveals that Gpr125 is dynamically expressed in multiple cell types in the developing and mature cochlea and is dispensable for cochlear development and hearing.

Published

2021

5. Making sense of Wnt signaling – linking hair cell regeneration to development

Author

Lina eJansson, Grace eKim, and Alan G Cheng

Subjects

Cochlea, beta-Catenin, LGR5, planar cell polarity, supporting cells, Axin2, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Wnt signaling is a highly conserved pathway crucial for development and homeostasis of multicellular organisms. Secreted Wnt ligands bind Frizzled receptors to regulate diverse processes such as axis patterning, cell division, and cell fate specification. They also serve to govern self-renewal of somatic stem cells in several adult tissues. The complexity of the pathway can be attributed to the myriad of Wnt and Frizzled combinations as well as its diverse context-dependent functions. In the developing mouse inner ear, Wnt signaling plays diverse roles, including specification of the otic placode and patterning of the otic vesicle. At later stages, its activity governs sensory hair cell specification, cell cycle regulation, and hair cell orientation. In regenerating sensory organs from non-mammalian species, Wnt signaling can also regulate the extent of proliferative hair cell regeneration. This review describes the current knowledge of the roles of Wnt signaling and Wnt-responsive cells in hair cell development and regeneration. We also discuss possible future directions and the potential application and limitation of Wnt signaling in augmenting hair cell regeneration.

Published

2015