ΔNp63 is a pioneer factor that binds inaccessible chromatin and elicits chromatin remodeling

Yu, Xinyang; Singh, Prashant; Tabrejee, Shamira; Sinha, Satrajit; Buck, Michael

doi:10.1186/s13072-021-00394-8

Cited by 25 publications

(26 citation statements)

References 65 publications

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“…SFN was identified as a direct p53 and Np63 target that is FIGURE 2 | (A) p53 and Np63 can act as pioneer factors to evict/remodel nucleosomes and facilitate DNA accessibility, although other pioneer factors are likely responsible for nucleosome eviction at the majority of p53/ Np63 binding sites. (B) Certain nucleosome contexts, such as when the p53/p63 RE motif is near the nucleosome dyad, are recalcitrant to p53 and/or Np63 pioneer factor activity and remain unbound (Yu and Buck, 2019;Yu et al, 2021). (C) In epithelial cell types, p53 DNA binding can be facilitated by Np63 s pioneer factor activity, although specific biochemical mechanisms are still being fully elucidated.…”

Section: P53 and P63 -Dueling Rivals?mentioning

confidence: 99%

“…This rule is broken by pioneer transcription factors, which can bind to nucleosomal DNA either sequence-dependent or independent ( Zaret and Mango, 2016 ). Numerous recent studies suggest that the p53 family of transcription factors are pioneer transcription factors ( Sammons et al, 2015 ; Yu and Buck, 2019 ; Yu et al, 2021 ; Figure 2A ). Indeed, differential pioneer activity of p53 and p63 has the potential to explain some of the observed gene regulatory differences between these two siblings.…”

Section: Engaging Chromatin – the Pioneer Role Of The P53 Familymentioning

confidence: 99%

“…Given the high sequence and functional homology to p53, perhaps it is unsurprising that p63 has also emerged as a pioneer transcription factor with similar nucleosomal constraints ( Yu et al, 2021 ). Control of cell type-specific chromatin accessibility and gene expression is a feature shared by many other pioneer transcription factors ( Iwafuchi-Doi and Zaret, 2014 , 2016 ; Zaret and Mango, 2016 ).…”

Section: Engaging Chromatin – the Pioneer Role Of The P53 Familymentioning

confidence: 99%

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p63 and p53: Collaborative Partners or Dueling Rivals?

Woodstock

Sammons

Fischer

2021

Front. Cell Dev. Biol.

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The tumor suppressor p53 and its oncogenic sibling p63 (ΔNp63) direct opposing fates in tumor development. These paralog proteins are transcription factors that elicit their tumor suppressive and oncogenic capacity through the regulation of both shared and unique target genes. Both proteins predominantly function as activators of transcription, leading to a paradigm shift away from ΔNp63 as a dominant negative to p53 activity. The discovery of p53 and p63 as pioneer transcription factors regulating chromatin structure revealed new insights into how these paralogs can both positively and negatively influence each other to direct cell fate. The previous view of a strict rivalry between the siblings needs to be revisited, as p53 and p63 can also work together toward a common goal.

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Section: P53 and P63 -Dueling Rivals?mentioning

confidence: 99%

Section: Engaging Chromatin – the Pioneer Role Of The P53 Familymentioning

confidence: 99%

Section: Engaging Chromatin – the Pioneer Role Of The P53 Familymentioning

confidence: 99%

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p63 and p53: Collaborative Partners or Dueling Rivals?

Woodstock

Sammons

Fischer

2021

Front. Cell Dev. Biol.

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“…ΔNp63 is necessary to maintain basal cell identity and function; without ΔNp63, these cells downregulate basal markers, exit the cell cycle, and undergo a program of precocious differentiation into more committed epithelial cells of their resident tissue (Haas et al, 2019; Romano et al, 2012; Truong et al, 2006; Yang et al, 2018). While ΔNp63 exterts its control over basal cell identity directly by transcriptionally regulating expression of basal cell markers and functional components such as basement membrane-anchoring adhesion molecules (Carroll et al, 2006; Ferone et al, 2013; Ihrie et al, 2005; Kurata et al, 2004; Laurikkala et al, 2006; Romano et al, 2009), recent studies propose an epigenetic role for ΔNp63 as well, in which ΔNp63 cooperates with higher order chromatin remodelers and histone modifiers to rearrange the 3D topology and chromatin accessibility of the genome (Fan et al, 2018; Fessing et al, 2011; Mardaryev et al, 2014; Qu et al, 2019; Sethi et al, 2014), bookmark tissue-specific enhancer regions during differentiation (Kouwenhoven et al, 2015; Lin-Shiao et al, 2019), and acts as a pionner-like factor by binding and opening inaccessible chromatin (Fan et al, 2018; Santos-Pereira et al, 2019; Yu et al, 2021). With its multi-tiered influence over the fundamental basal cell program and critical role in virtually all epithelial tissue contexts in which its been studied, ΔNp63 serves as a promising target to modulate basal cell fate choice in regions of dysplastic remodeling within injured lungs.…”

Section: Introductionmentioning

confidence: 99%

ΔNp63 drives dysplastic alveolar remodeling and restricts epithelial plasticity upon severe lung injury

Weiner

Zhao

Zayas

et al. 2022

Preprint

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Unlike many mammalian vital organs, the lung exhibits a robust, multifaceted regenerative response to severe injuries such as influenza infection, which primarily targets epithelial cells in the airways and alveoli. Quiescent lung-resident epithelial progenitors proliferate, migrate, and differentiate following lung injury, participating in two distinct reparative pathways: functionally beneficial regeneration and dysplastic tissue remodeling. Intrapulmonary airway-resident basal-like p63+ progenitors are one such progenitor cell type that migrates from the airways to form ectopic bronchiolar tissue in the alveoli, generating honeycomb-like cysts that fail to resolve after injury. Though this phenomenon is now well described, the cell-autonomous signals that drive dysplastic alveolar remodeling remain uncertain, a question made especially salient by observations that p63+ progenitors also expand dramatically upon diffuse alveolar damage in humans resulting from a variety of insults including SARS-CoV-2-induced ARDS. Here we show that the master basal cell transcription factor ΔNp63 is required for the immense migratory capacity of intrapulmonary p63+ progenitors and consequently for the dysplastic repair pathway manifest by these cells. We further demonstrate that ΔNp63 restricts the fate plasticity of intrapulmonary p63+ progenitors by regulating their epigenetic landscape, and that loss of ΔNp63 alters the deposition of active and repressive histone modifications at key differentiation gene loci, allowing ΔNp63KO progenitors to proceed towards airway or alveolar differentiation depending on their surrounding environment. These insights into the regulatory mechanisms of dysplastic repair and intrapulmonary p63+ progenitor fate choice highlight potential therapeutic targets to promote more effective alveolar regeneration following severe lung injuries.

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“…Furthermore, incubation of Lola-I protein with nucleosome-bound sequences in vitro suggested that Lola-I preferentially binds to its motifs near the nucleosome edge when the DNA is partially unwrapped. Although there is no consensus on whether pioneer factors are defined by a certain binding mode in vitro (Klemm et al, 2019), such binding preference has previously been observed for some pioneer factors (Yu and Buck, 2019; Yu et al, 2021; Zhu et al 2018). Like for other pioneer factors, binding of Lola-I may lead to the recruitment of chromatin remodelers that remove the nucleosome (Judd et al, 2021; Zaret, 2020).…”

Section: Discussionmentioning

confidence: 99%

Lola-I is a developmentally regulated promoter pioneer factor

Ramalingam

Slaughter

et al. 2022

Preprint

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While enhancers are often regulated at the level of accessibility by pioneer factors, promoters tend to be constitutively accessible and poised for activation by paused Pol II — thus are often not considered as sites of developmental regulation. Here we show that the accessibility of promoters and the acquisition of paused Pol II can be subject to developmental regulation by pioneer factors. We show that Lola-I, a Drosophila zinc finger transcription factor, is ubiquitously expressed at the end of embryogenesis and causes its target promoters to become accessible and acquire paused Pol II throughout the embryo. This promoter transition is required but not sufficient for tissue-specific target gene expression. Lola-I mediates this function by binding to the edges of the promoter nucleosomes, which leads to their depletion, similar to the action of pioneer factors at enhancers. These results uncover a level of regulation for promoters that is normally found at enhancers, providing further evidence that promoters and enhancers display unexpectedly similar characteristics.

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ΔNp63 is a pioneer factor that binds inaccessible chromatin and elicits chromatin remodeling

Cited by 25 publications

References 65 publications

p63 and p53: Collaborative Partners or Dueling Rivals?

p63 and p53: Collaborative Partners or Dueling Rivals?

ΔNp63 drives dysplastic alveolar remodeling and restricts epithelial plasticity upon severe lung injury

Lola-I is a developmentally regulated promoter pioneer factor

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