Proneural factors Ascl1 and Neurog2 contribute to neuronal subtype identities by establishing distinct chromatin landscapes

Aydın, Begüm; Kakumanu, Akshay; Rossillo, Mary; Moreno-Estellés, Mireia; Garipler, Görkem; Ringstad, Niels; Flames, Nuria; Mahony, Shaun; Mazzoni, Esteban O.

doi:10.1038/s41593-019-0399-y

Cited by 111 publications

(143 citation statements)

References 71 publications

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“…To understand the molecular mechanisms of general neuronal fate committed to CR neurons identities, we focus on the genetic network of some key transcription factors that may predominate the differentiation progression. Ebf2 is enriched in Cluster 2 and its target genes has been identified in Neurog2-induced neurogenesis from mESC assays recently (38). We found that 457 of the early phase C157 genes and 611 of the intermediate C0346 genes were the target genes of EBF2 during neural differentiation, implying that it might affect the molecular pathways of CR neuron differentiation (Table S1).…”

Section: Transcriptional Factors Involved In Transitions In Gene Exprmentioning

confidence: 61%

Integrative genomic analysis of early neurogenesis reveals a temporal genetic program for differentiation and specification of preplate and Cajal-Retzius neurons

Sun

Peng

et al. 2018

Preprint

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Section: Transcriptional Factors Involved In Transitions In Gene Exprmentioning

confidence: 61%

Integrative genomic analysis of early neurogenesis reveals a temporal genetic program for differentiation and specification of preplate and Cajal-Retzius neurons

Sun

Peng

et al. 2018

Preprint

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“…Some data indicate that Ngn2, when using an appropriate conversion medium, not only binds most of the Ascl1 binding sites in fibroblasts, but also possesses many additional binding sites [30,33]. However, other data suggest that Ascl1 and Ngn2 possess divergent binding patterns that result in distinct chromatin states and different neuronal fates [34]. While further (meta-)analysis will likely shed more light on these different views, it is not surprising that the most efficient and reliable conversion strategies involve the combined expression of Ascl1 and Ngn2 [9,10,31,35].…”

Section: Enabling In Conversionmentioning

confidence: 99%

“…1A). The epigenetic identity of the starting cell population and remnant signaling cues present during the fibroblast-to-iN transition state finally determine subtype identity [23,34]. In highly heterogeneous cell populations, such as astrocytes in the rodent brain or primary human fibroblasts, the subtype of the starting cell type was shown to determine subtype outcomes of the iNs [73].…”

Section: Subtype-specific In Conversionmentioning

confidence: 99%

“…Further, unlike for most other human cell types, primary human neuronal cultures of defined brain regions are not available for direct comparison, which further complicates the definition of gold standard criteria. By any means, the value of cell models should be measured by how well they perform their respective tasks, and these tasks might range from teaching us more about a complex disease, or how well they integrate into a neuronal circuit following transplantation [6,[33][34][35][36][37][38]114,115].…”

Section: Updating Our Criteria To Define Neuronsmentioning

confidence: 99%

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Next‐generation disease modeling with direct conversion: a new path to old neurons

2019

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Within just over a decade, human reprogramming-based disease modeling has developed from a rather outlandish idea into an essential part of disease research. While iPSCs are a valuable tool for modeling developmental and monogenetic disorders, their rejuvenated identity poses limitations for modeling age-associated diseases. Direct cell-type conversion of fibroblasts into induced neurons (iNs) circumvents rejuvenation and preserves hallmarks of cellular aging. iNs are thus advantageous for modeling diseases that possess strong age-related and epigenetic contributions and can complement iPSCbased strategies for disease modeling. In this review, we provide an overview of the state of the art of direct iN conversion and describe the key epigenetic, transcriptomic, and metabolic changes that occur in converting fibroblasts. Furthermore, we summarize new insights into this fascinating process, particularly focusing on the rapidly changing criteria used to define and characterize in vitro-born human neurons. Finally, we discuss the unique features that distinguish iNs from other reprogramming-based neuronal cell models and how iNs are relevant to disease modeling.

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“…The advent of in vitro cell fate reprogramming has demonstrated that overexpression of specific TF combinations can be sufficient to drive specification of the same starting cells towards diverse cell types in the absence of other context-specific variables (Nakamori et al 2017;Pfisterer et al 2011;Zhao et al 2015;Masserdotti et al 2016). Therefore, cellular reprogramming provides a controlled system in which to investigate how TFs cooperate and modulate each other's functions for cell fate specificity in the absence of other differences in cellular context (Aydin et al 2019).…”

Section: Introductionmentioning

confidence: 99%

Atoh1 is repurposed from neuronal to hair cell determinant by Gfi1 acting as a coactivator without redistribution of its genomic binding sites

Costa

Powell

Soufi

et al. 2019

Preprint

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Although the lineage-determining ability of transcription factors is often modulated according to cellular context, the mechanisms by which such switching occurs are not well known. Using a transcriptional programming model, we found that Atoh1 is repurposed from a neuronal to an inner ear hair cell (HC) determinant by the combined activities of Gfi1 and Pou4f3. In this process, Atoh1 maintains its regulation of neuronal genes but gains ability to regulate HC genes. Pou4f3 enables Atoh1 access to genomic locations controlling the expression of sensory (including HC) genes, but Atoh1+Pou4f3 are not sufficient for HC differentiation. Gfi1 is key to the Atoh1-induced lineage switch, but surprisingly does not alter Atoh1's binding profile. Gfi1 acts in two divergent ways. It represses the induction by Atoh1 of genes that antagonise HC differentiation, a function in keeping with its well-known repressor role in haematopoiesis. Remarkably, we find that Gfi1 also acts as a co-activator: it binds directly to Atoh1 at existing target genes to enhance its activity. These findings highlight the diversity of mechanisms by which one TF can redirect the activity of another to enable combinatorial control of cell identity.

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Proneural factors Ascl1 and Neurog2 contribute to neuronal subtype identities by establishing distinct chromatin landscapes

Cited by 111 publications

References 71 publications

Integrative genomic analysis of early neurogenesis reveals a temporal genetic program for differentiation and specification of preplate and Cajal-Retzius neurons

Integrative genomic analysis of early neurogenesis reveals a temporal genetic program for differentiation and specification of preplate and Cajal-Retzius neurons

Next‐generation disease modeling with direct conversion: a new path to old neurons

Atoh1 is repurposed from neuronal to hair cell determinant by Gfi1 acting as a coactivator without redistribution of its genomic binding sites

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