Long-range Atoh1 enhancers maintain competency for hair cell regeneration in the inner ear.

IF 9.4 1区 综合性期刊 Q1 MULTIDISCIPLINARY SCIENCES Proceedings of the National Academy of Sciences of the United States of America Pub Date : 2024-12-17 Epub Date: 2024-12-13 DOI:10.1073/pnas.2418098121
Tuo Shi, Yeeun Kim, Juan Llamas, Xizi Wang, Peter Fabian, Thomas P Lozito, Neil Segil, Ksenia Gnedeva, J Gage Crump
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Abstract

During tissue regeneration, lineage-related cells can switch their fate to replace missing cells. This cell plasticity is particularly prominent in more regenerative vertebrates such as zebrafish, yet the molecular basis by which cells transdifferentiate into another cell type upon injury remains unclear. Here, we investigate the epigenetic basis of regenerative transdifferentiation in the inner ear, where supporting cells (SCs) generate mechanosensory hair cells (HCs) upon damage. By comparing the chromatin landscapes in regenerative zebrafish and green anole lizards versus nonregenerative mice, we identified a class of enhancers that function in progenitors to generate HCs and then are selectively maintained in SCs of regenerative vertebrates to regenerate HCs. In particular, we uncovered a syntenic class of long-range enhancers for Atoh1, a master transcription factor for HC differentiation. In the absence of injury, these enhancers maintain accessibility in SCs through adulthood but are prevented from driving zebrafish atoh1a expression through Notch repression. Deletion of these enhancers not only impaired atoh1a expression and HC formation during development but also blocked the ability of SCs to transdifferentiate into HCs during regeneration. Moreover, defects were specific to the inner ear versus the lateral line, revealing distinct mechanisms of regeneration in these mechanosensory organs. These findings reveal a class of regenerative enhancer that maintains competency of inner ear SCs to upregulate atoh1a and transdifferentiate into HCs upon damage. We propose that the continued accessibility of developmental enhancers for one cell fate in lineage-related cells may be a common theme underlying adult cell plasticity in regenerative vertebrates.

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在组织再生过程中,与细胞系相关的细胞可以改变其命运,以替代缺失的细胞。这种细胞可塑性在斑马鱼等再生能力较强的脊椎动物中尤为突出,但细胞在损伤后转分化为另一种细胞类型的分子基础仍不清楚。在这里,我们研究了内耳再生性转分化的表观遗传学基础,内耳的支持细胞(SC)在损伤后会产生机械感觉毛细胞(HC)。通过比较再生斑马鱼和绿肛蜥与非再生小鼠的染色质景观,我们发现了一类增强子,它们在祖细胞中起作用,产生HCs,然后在再生脊椎动物的SCs中选择性地维持,再生HCs。特别是,我们发现了一类与Atoh1同源的长程增强子,Atoh1是HC分化的主转录因子。在没有损伤的情况下,这些增强子在整个成年期都能保持在SCs中的可及性,但通过Notch抑制却无法驱动斑马鱼atoh1a的表达。缺失这些增强子不仅会影响发育过程中 atoh1a 的表达和 HC 的形成,还会阻碍 SCs 在再生过程中向 HCs 转分化的能力。此外,内耳与侧线的缺陷是特异性的,揭示了这些机械感觉器官的不同再生机制。这些发现揭示了一类再生增强子,它能维持内耳SC上调atoh1a并在受损时转分化为HC的能力。我们认为,发育增强子在细胞系相关细胞中对一种细胞命运的持续可及性可能是再生脊椎动物成体细胞可塑性的一个共同主题。
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来源期刊
CiteScore
19.00
自引率
0.90%
发文量
3575
审稿时长
2.5 months
期刊介绍: The Proceedings of the National Academy of Sciences (PNAS), a peer-reviewed journal of the National Academy of Sciences (NAS), serves as an authoritative source for high-impact, original research across the biological, physical, and social sciences. With a global scope, the journal welcomes submissions from researchers worldwide, making it an inclusive platform for advancing scientific knowledge.
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