Transcriptomic and epigenetic regulation of hair cell regeneration in the mouse utricle and its potentiation by Atoh1

H. -I Jen; M. C. Hill; L. Tao; K. Sheng; W. Cao; H. Zhang; H. V. Yu; J. Llamas; C. Zong; J. F. Martin; N. Segil; A. K. Groves

doi:10.7554/eLife.44328

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Transcriptomic and epigenetic regulation of hair cell regeneration in the mouse utricle and its potentiation by Atoh1

Journal article

Open access

Transcriptomic and epigenetic regulation of hair cell regeneration in the mouse utricle and its potentiation by Atoh1

H. -I Jen, M. C. Hill, L. Tao, K. Sheng, W. Cao, H. Zhang, H. V. Yu, J. Llamas, C. Zong, J. F. Martin, …

eLife, Vol.8

2019

DOI: https://doi.org/10.7554/eLife.44328

Abstract

caspase

epithelial cell adhesion molecule

myosin VIIa

tamoxifen

transcription factor Sox2

Atoh1 protein, mouse

basic helix loop helix transcription factor

transcription factor

transcriptome

adult

animal cell

animal experiment

Article

Atoh1 gene

cell death

cell differentiation

cell fate

cell isolation

cell maturation

cell regeneration

cell reprogramming technique

controlled study

DNA repair

down regulation

enzyme activity

epigenetics

female

flow cytometry

fluorescence microscopy

gene

gene identification

gene locus

genetic transduction

hair cell

immunohistochemistry

male

mouse

nonhuman

perinatal period

real time polymerase chain reaction

RNA extraction

RNA sequence

sequence analysis

transcriptomics

upregulation

utricle

Western blotting

animal

cell cycle

cochlea

cochlear hair cell

gene expression regulation

genetic epigenesis

genetics

metabolism

physiology

regeneration

vestibule

Animals

Basic Helix-Loop-Helix Transcription Factors

Epigenesis, Genetic

Hair Cells, Auditory

Mice

Saccule and Utricle

Transcription Factors

Transduction, Genetic

The mammalian cochlea loses its ability to regenerate new hair cells prior to the onset of hearing. In contrast, the adult vestibular system can produce new hair cells in response to damage, or by reprogramming of supporting cells with the hair cell transcription factor Atoh1. We used RNA-seq and ATAC-seq to probe the transcriptional and epigenetic responses of utricle supporting cells to damage and Atoh1 transduction. We show that the regenerative response of the utricle correlates with a more accessible chromatin structure in utricle supporting cells compared to their cochlear counterparts. We also provide evidence that Atoh1 transduction of supporting cells is able to promote increased transcriptional accessibility of some hair cell genes. Our study offers a possible explanation for regenerative differences between sensory organs of the inner ear, but shows that additional factors to Atoh1 may be required for optimal reprogramming of hair cell fate. © Jen et al.

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Details

Title: Transcriptomic and epigenetic regulation of hair cell regeneration in the mouse utricle and its potentiation by Atoh1
Creators: H. -I Jen - Baylor College of Medicine
M. C. Hill
L. Tao - University of Southern California
K. Sheng - Baylor College of Medicine
W. Cao - Baylor College of Medicine
H. Zhang - Baylor College of Medicine
H. V. Yu - University of Southern California
J. Llamas - University of Southern California
C. Zong - Baylor College of Medicine
J. F. Martin - Baylor College of Medicine
N. Segil - University of Southern California
A. K. Groves - Baylor College of Medicine
Publication Details: eLife, Vol.8
Publisher: eLife Sciences Publications Ltd
Identifiers: 991006028350602656
Academic Unit: Biomedical Sciences
Language: English
Resource Type: Journal article