Esrrb extinction triggers dismantling of naïve pluripotency and marks commitment to differentiation

Festuccia, Nicola; Halbritter, Florian; Corsinotti, Andrea; Gagliardi, Alessia; Colby, Douglas; Tomlinson, Simon R.; Chambers, Ian

doi:10.15252/embj.201695476

Cited by 28 publications

(44 citation statements)

References 92 publications

(185 reference statements)

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“…The net consequence would then be that single‐cell expression analysis shows that in all stages a subset of cells is more resilient to differentiation cues. Similar observations of associations between transcriptional heterogeneity and differences in differentiation or reprogramming have previously been documented for several single factors, including Esrrb and Nanog , with particular focus on the pluripotent state …”

Section: Resultssupporting

confidence: 79%

“…Similar observations of associations between transcriptional heterogeneity and differences in differentiation or reprogramming have previously been documented for several single factors, including Esrrb and Nanog, with particular focus on the pluripotent state. [78][79][80][81] A more complex narrative applies to N4 with its three subpopulations ( Figure 6A, right, and Figure S7D). Besides the aforementioned delayed subpopulation (ie, 14 cells here in blue), there were two more subpopulations (which can be described by six groups of gene expression dynamics): (a) a more neural-orientated group of 22 cells marked by higher average levels of NP-cell associated genes such as Zfp521, Pax6, Cxcr4, Zeb2, Zic3, and Sox9, and (b) the largest group of 39 cells that showed slightly lower levels of neural mRNAs and higher levels of specific combinations of genes, such as Stat3, Srf, Snai1, Tagln, Skil, Pou3f1, and Cdh1.…”

Section: Transcriptional Heterogeneity Between Single Cells Denotesmentioning

confidence: 99%

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Integrative and perturbation-based analysis of the transcriptional dynamics of TGFβ/BMP system components in transition from embryonic stem cells to neural progenitors

et al. 2019

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Cooperative actions of extrinsic signals and cell-intrinsic transcription factors alter gene regulatory networks enabling cells to respond appropriately to environmental cues. Signaling by transforming growth factor type β (TGFβ) family ligands (eg, bone morphogenetic proteins [BMPs] and Activin/Nodal) exerts cell-type specific and context-dependent transcriptional changes, thereby steering cellular transitions throughout embryogenesis. Little is known about coordinated regulation and transcriptional interplay of the TGFβ system. To understand intrafamily transcriptional regulation as part of this system's actions during development, we selected 95 of its components and investigated their mRNA-expression dynamics, gene-gene interactions, and single-cell expression heterogeneity in mouse embryonic stem cells transiting to neural progenitors. Interrogation at 24 hour intervals identified four types of temporal gene transcription profiles that capture all stages, that is, pluripotency, epiblast formation, and neural commitment. Then, between each stage we performed esiRNA-based perturbation of each individual component and documented the effect on steady-state mRNA levels of the remaining 94 components. This exposed an intricate system of multilevel regulation whereby the majority of gene-gene interactions display a marked cell-stage specific behavior. Furthermore, single-cell RNA-profiling at individual stages demonstrated the presence of detailed co-expression modules and subpopulations showing stable co-expression modules such as that of the core pluripotency genes at all stages. Our combinatorial experimental approach demonstrates how intrinsically complex transcriptional regulation within a given pathway is during cell fate/state transitions. cell state transitions, embryonic stem cells, esiRNA, genetic interaction, neural differentiation, signaling pathway, TGFβ/BMP 204 DRIES ET AL.

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Section: Resultssupporting

confidence: 79%

Section: Transcriptional Heterogeneity Between Single Cells Denotesmentioning

confidence: 99%

Integrative and perturbation-based analysis of the transcriptional dynamics of TGFβ/BMP system components in transition from embryonic stem cells to neural progenitors

et al. 2019

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“…Esrrb has been shown to be critical for the sustained activity of the naïve pluripotency regulatory network and in enhanced reprogramming to the naïve state [41]. Moreover, drop in Esrrb concentration below certain levels has been shown to trigger exit from naïve pluripotency [42]. Our finding that G2M cells exist either as Esrrb-H or Esrrb-L populations therefore strongly suggest G2M to be the phase when the decision to maintain or exit the naïve state is made.…”

Section: Developmental Heterogeneity In G2mmentioning

confidence: 64%

G2M splits mouse embryonic stem cells into naïve and formative pluripotency states

Jääger

Simpson

Kalantzaki

et al. 2019

Preprint

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Embryonic stem cells (ESCs) express heterogeneous levels of pluripotency and developmental transcription factors (TFs) and their cell cycle is unsynchronised when grown in the presence of serum. Here, we asked whether the cell cycle and developmental heterogeneities of ESCs are coordinated by determining the state identities of G1-and G2M-enriched mouse ESCs (mESCs) at single cell resolution. We found that G2M cells were not all the same and demonstrate their split into the naïve and formative (intermediate) pluripotency states marked by high or low Esrrb expression, respectively. The naïve G2M sub-state resembles 'ground' state pluripotency of the LIF/2i cultured mESCs. The naïve and formative G2M sub-states exist in the pre-and post-implantation stages of the mouse embryo, respectively, verifying developmental distinction. Moreover, the G2M sub-states partially match between the mouse and human ESCs, suggesting higher similarity of transcriptional control between these species in G2M. Our findings propose a model whereby G2M separates mESCs into naïve and formative pluripotency states. This concept of G2M-diverted pluripotency states provides new framework for understanding the mechanisms of pluripotency maintenance and lineage specification in vitro and in vivo, and the development of more efficient and clinically relevant reprogramming strategies.

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“…The reduction in expression of some pluripotency TFs including Esrrb marks mESC commitment to differentiation (Festuccia et al, 2018). Moreover, variable Esrrb levels separate distinct pluripotency states in G2M (Jääger et al, 2019).…”

Section: Discussionmentioning

confidence: 99%

Cell cycle-balanced expression of pluripotency regulators via cyclin-dependent kinase 1

Kasvandik

Schilf

Saarma

et al. 2019

Preprint

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Embryonic stem cells (ESCs) have a unique ability to remain pluripotent while undergoing rapid rounds of cell division required for self-renewal. However, it is not known how cell cycle and pluripotency regulatory networks co-operate in ESCs. Here, we used stable isotope labeling with amino acids in cell culture (SILAC) combined with mass spectrometry to determine pluripotency proteome dynamics during cell cycle in mouse ESCs (mESCs). We found the S/G2M-fluctuating pluripotency transcription factors (Esrrb, Rest), chromatin regulators (Jarid2, Trim24) and proteins with E3 ligase activity (Nedd4l, Pias2) to peak in S phase. This expression balance was disrupted upon inhibition of cyclin-dependent kinase 1 activity resulting in the shift of the expression peak from S to G2M. Our results show that mESCs require Cdk1 activity to maintain high S to G2M ratio of pluripotency regulators revealing critical role of cell cycle dynamics in balancing mESC identity.

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Esrrb extinction triggers dismantling of naïve pluripotency and marks commitment to differentiation

Cited by 28 publications

References 92 publications

Integrative and perturbation-based analysis of the transcriptional dynamics of TGFβ/BMP system components in transition from embryonic stem cells to neural progenitors

Integrative and perturbation-based analysis of the transcriptional dynamics of TGFβ/BMP system components in transition from embryonic stem cells to neural progenitors

G2M splits mouse embryonic stem cells into naïve and formative pluripotency states

Cell cycle-balanced expression of pluripotency regulators via cyclin-dependent kinase 1

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