Your search keyword '"H, Gretarsson"' showing total 4 results

1. Dppa2 and Dppa4 counteract de novo methylation to establish a permissive epigenome for development

Author

Kristjan H. Gretarsson and Jamie A. Hackett

Subjects

Regulation of gene expression, 0303 health sciences, Epigenome, Biology, Chromatin, Cell biology, 03 medical and health sciences, 0302 clinical medicine, Structural Biology, DNA methylation, CRISPR, Epigenetics, Molecular Biology, 030217 neurology & neurosurgery, 030304 developmental biology, DNA hypomethylation, Epigenomics

Abstract

Early mammalian development entails genome-wide epigenome remodeling, including DNA methylation erasure and reacquisition, which facilitates developmental competence. To uncover the mechanisms that orchestrate DNA methylation dynamics, we coupled a single-cell ratiometric DNA methylation reporter with unbiased CRISPR screening in murine embryonic stem cells (ESCs). We identify key genes and regulatory pathways that drive global DNA hypomethylation, and characterize roles for Cop1 and Dusp6. We also identify Dppa2 and Dppa4 as essential safeguards of focal epigenetic states. In their absence, developmental genes and evolutionarily young LINE1 elements, which are specifically bound by DPPA2, lose H3K4me3 and gain ectopic de novo DNA methylation in pluripotent cells. Consequently, lineage-associated genes and LINE1 acquire a repressive epigenetic memory, which renders them incompetent for activation during future lineage specification. Dppa2/4 thereby sculpt the pluripotent epigenome by facilitating H3K4me3 and bivalency to counteract de novo methylation, a function co-opted by evolutionarily young LINE1 to evade epigenetic decommissioning. Coupling of a single-cell ratiometric DNA methylation reporter with an unbiased CRISPR screen in ESCs identifies key genes and regulatory pathways that drive global DNA hypomethylation and establishes Dppa2 and Dppa4 as essential safeguards of focal epigenetic states.

Published

2020

2. Genome-Scale CRISPR Screening for Regulators of Cell Fate Transitions

Author

Valentina Carlini, Jamie A. Hackett, and Kristjan H. Gretarsson

Subjects

Candidate gene, Cas9, Gene regulatory network, CRISPR, Guide RNA, Computational biology, Cell fate determination, Biology, Phenotype, Gene

Abstract

Knockout CRISPR screening enables the unbiased discovery of genes with a functional role in almost any cellular or molecular process of interest. The approach couples a genome-scale library of guide RNA (gRNA), the Cas9 endonuclease, and a faithful phenotypic read-out to systematically identify candidate genes via their loss-of-function effect. Here we provide a detailed description of the CRISPR screen protocol and outline how to apply it to decipher the gene networks that underlie developmental cell fate decisions. As a paradigm we use the in vitro model of cell state transition(s) from naive pluripotency to primordial germ cell (PGC) fate, exploiting the Stella-GFP:Esg1-tdTomato (SGET) mouse ESC line. The principles in this protocol can be readily adapted to characterize lineage regulators for other cell fate models and/or for other species.

Published

2020

3. Dppa2/4 Counteract De Novo Methylation to Establish a Permissive Epigenome for Development

Author

Jamie A. Hackett and Kristjan H. Gretarsson

Subjects

DNA methylation, H3K4me3, CRISPR, Epigenome, Epigenetics, Methylation, Biology, Gene, DNA hypomethylation, Cell biology

Abstract

Early mammalian development entails genome-wide epigenome remodeling, including DNA methylation erasure and reacquisition, which facilitates developmental competence. To uncover the mechanisms that orchestrate DNA methylation (DNAme) dynamics, we coupled a single-cell ratiometric DNAme reporter with unbiased CRISPR screening in ESC. We identify key genes and regulatory pathways that drive global DNA hypomethylation, and characterise roles for Cop1 and Dusp6. We also identify Dppa2 and Dppa4 as essential safeguards of focal epigenetic states. In their absence, developmental genes and evolutionary-young LINE1 elements, which DPPA2 specifically binds, lose H3K4me3 and gain ectopic de novo DNA methylation in pluripotent cells. Consequently, lineage-associated genes (and LINE1) acquire a repressive epigenetic memory, which renders them incompetent for activation during future lineage-specification. Dppa2/4 thereby sculpt the pluripotent epigenome by facilitating H3K4me3 and bivalency to counteract de novo methylation; a function co-opted by evolutionary young LINE1 to evade epigenetic decommissioning.

Published

2020

4. Cell Surface Mechanics Gate Embryonic Stem Cell Differentiation

Author

Alba Diz-Muñoz, Evangelia Petsalaki, Jamie A. Hackett, Martin Bergert, Sumana Sharma, Kristjan H. Gretarsson, Mandy Börmel, Danica Milovanović, Luigi Russo, Sergio Lembo, and Pierre Neveu

Subjects

naive-to-primed transition, exit from pluripotency, Cellular differentiation, Cell, membrane-to-cortex attachment (MCA), atomic force spectroscopy, Biology, membrane tension, 03 medical and health sciences, Mice, 0302 clinical medicine, Ezrin, mESC, Genetics, medicine, Animals, Actin, Embryonic Stem Cells, 030304 developmental biology, 0303 health sciences, Brief Report, Cell Membrane, Cell Differentiation, Mouse Embryonic Stem Cells, Cell Biology, Mechanics, Embryonic stem cell, Cortex (botany), Membrane, medicine.anatomical_structure, Molecular Medicine, Stem cell, 030217 neurology & neurosurgery, Signal Transduction

Abstract

Summary Cell differentiation typically occurs with concomitant shape transitions to enable specialized functions. To adopt a different shape, cells need to change the mechanical properties of their surface. However, whether cell surface mechanics control the process of differentiation has been relatively unexplored. Here we show that membrane mechanics gate exit from naive pluripotency of mouse embryonic stem cells. By measuring membrane tension during early differentiation, we find that naive stem cells release their plasma membrane from the underlying actin cortex when transitioning to a primed state. By mechanically tethering the plasma membrane to the cortex by enhancing Ezrin activity or expressing a synthetic signaling-inert linker, we demonstrate that preventing this detachment forces stem cells to retain their naive pluripotent identity. We thus identify a decrease in membrane-to-cortex attachment as a new cell-intrinsic mechanism that is essential for stem cells to exit pluripotency., Graphical Abstract, Highlights • Early mESC differentiation is accompanied by a decrease in apparent membrane tension • Differentiating mESCs decrease their membrane-to-cortex attachment (MCA) • Development of a signaling-inert MCA (iMC) linker • MCA reduction is necessary but not sufficient for naive-to-primed transition, Bergert et al. use biophysical methods to investigate the role of cell surface mechanics during stem cell differentiation. They show that naive cells release their plasma membrane from the underlying actin cortex when transitioning to a primed state. Preventing this detachment forces cells to retain a naive pluripotent identity.

Published

2021