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1. Differential elasticity in lineage segregation of embryonic stem cells

Author

Ritter, Christine M., Leijnse, Natascha, Barooji, Younes Farhangi, Brickman, Joshua M., Doostmohammadi, Amin, and Oddershede, Lene B.

Subjects
Physics - Biological Physics, Condensed Matter - Soft Condensed Matter, Quantitative Biology - Cell Behavior
Abstract

The question of what guides lineage segregation is central to development, where cellular differentiation leads to segregated cell populations destined for specialized functions. Here, using optical tweezers measurements of mouse embryonic stem cells (mESCs), we reveal a mechanical mechanism based on differential elasticity in the second lineage segregation of the embryonic inner cell mass into epiblast (EPI) cells - that will develop into the fetus - and primitive endoderm (PrE) - which will form extraembryonic structures such as the yolk sac. Remarkably, we find that these mechanical differences already occur during priming and not just after a cell has committed to differentiation. Specifically, we show that the mESCs are highly elastic compared to any other reported cell type and that the PrE cells are significantly more elastic than EPI-primed cells. Using a model of two cell types differing only in elasticity we show that differential elasticity alone can lead to segregation between cell types, suggesting that the mechanical attributes of the cells contribute to the segregation process. Our findings present differential elasticity as a previously unknown mechanical contributor to the lineage segregation during the embryo morphogenesis.

Published
2022

2. Marmoset and human trophoblast stem cells differ in signaling requirements and recapitulate divergent modes of trophoblast invasion

Author

Siriwardena, Dylan, Munger, Clara, Penfold, Christopher, Kohler, Timo N., Weberling, Antonia, Linneberg-Agerholm, Madeleine, Slatery, Erin, Ellermann, Anna L., Bergmann, Sophie, Clark, Stephen J., Rawlings, Thomas M., Brickman, Joshua M., Reik, Wolf, Brosens, Jan J., Zernicka-Goetz, Magdalena, Sasaki, Erika, Behr, Rüdiger, Hollfelder, Florian, and Boroviak, Thorsten E.

Published
2024
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10. Transcription factor co-expression mediates lineage priming for embryonic and extra-embryonic differentiation

Author

Redó-Riveiro, Alba, Al-Mousawi, Jasmina, Linneberg-Agerholm, Madeleine, Proks, Martin, Perera, Marta, Salehin, Nazmus, Brickman, Joshua M., Redó-Riveiro, Alba, Al-Mousawi, Jasmina, Linneberg-Agerholm, Madeleine, Proks, Martin, Perera, Marta, Salehin, Nazmus, and Brickman, Joshua M.

Abstract

In early mammalian development, cleavage stage blastomeres and inner cell mass (ICM) cells co-express embryonic and extra-embryonic transcriptional determinants. Using a protein-based double reporter we identify an embryonic stem cell (ESC) population that co-expresses the extra-embryonic factor GATA6 alongside the embryonic factor SOX2. Based on single cell transcriptomics, we find this population resembles the unsegregated ICM, exhibiting enhanced differentiation potential for endoderm while maintaining epiblast competence. To relate transcription factor binding in these cells to future fate, we describe a complete enhancer set in both ESCs and naive extra-embryonic endoderm stem cells and assess SOX2 and GATA6 binding at these elements in the ICM-like ESC sub-population. Both factors support cooperative recognition in these lineages, with GATA6 bound alongside SOX2 on a fraction of pluripotency enhancers and SOX2 alongside GATA6 more extensively on endoderm enhancers, suggesting that cooperative binding between these antagonistic factors both supports self-renewal and prepares progenitor cells for later differentiation., In early mammalian development, cleavage stage blastomeres and inner cell mass (ICM) cells co-express embryonic and extra-embryonic transcriptional determinants. Using a protein-based double reporter we identify an embryonic stem cell (ESC) population that co-expresses the extra-embryonic factor GATA6 alongside the embryonic factor SOX2. Based on single cell transcriptomics, we find this population resembles the unsegregated ICM, exhibiting enhanced differentiation potential for endoderm while maintaining epiblast competence. To relate transcription factor binding in these cells to future fate, we describe a complete enhancer set in both ESCs and naive extra-embryonic endoderm stem cells and assess SOX2 and GATA6 binding at these elements in the ICM-like ESC sub-population. Both factors support cooperative recognition in these lineages, with GATA6 bound alongside SOX2 on a fraction of pluripotency enhancers and SOX2 alongside GATA6 more extensively on endoderm enhancers, suggesting that cooperative binding between these antagonistic factors both supports self-renewal and prepares progenitor cells for later differentiation.

Published
2024

12. Suppression of ERK signalling promotes pluripotent epiblast in the human blastocyst

Author

Simon, Claire S., primary, McCarthy, Afshan, additional, Woods, Laura, additional, Staneva, Desislava, additional, Huang, Qiulin, additional, Linneberg-Agerholm, Madeleine, additional, Faulkner, Alex, additional, Papathanasiou, Athanasios, additional, Elder, Kay, additional, Snell, Phil, additional, Christie, Leila, additional, Garcia, Patricia, additional, Shaikly, Valerie, additional, Taranissi, Mohamed, additional, Choudhary, Meenakshi, additional, Herbert, Mary, additional, Brickman, Joshua M, additional, and Niakan, Kathy K., additional

Published
2024
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17. Neighbor-specific gene expression revealed from physically interacting cells during mouse embryonic development

Author

Kim, Junil, Rothová, Michaela Mrugala, Madan, Esha, Rhee, Siyeon, Weng, Guangzheng, Palma, António M., Liao, Linbu, David, Eyal, Amit, Ido, Hajkarim, Morteza Chalabi, Vudatha, Vignesh, Gutiérrez-García, Andrés, Moreno, Eduardo, Winn, Robert, Trevino, Jose, Fisher, Paul B., Brickman, Joshua M., Gogna, Rajan, Won, Kyoung Jae, Kim, Junil, Rothová, Michaela Mrugala, Madan, Esha, Rhee, Siyeon, Weng, Guangzheng, Palma, António M., Liao, Linbu, David, Eyal, Amit, Ido, Hajkarim, Morteza Chalabi, Vudatha, Vignesh, Gutiérrez-García, Andrés, Moreno, Eduardo, Winn, Robert, Trevino, Jose, Fisher, Paul B., Brickman, Joshua M., Gogna, Rajan, and Won, Kyoung Jae

Abstract

Development of multicellular organisms is orchestrated by persistent cell–cell communication between neighboring partners. Direct interaction between different cell types can induce molecular signals that dictate lineage specification and cell fate decisions. Current single-cell RNA-seq technology cannot adequately analyze cell–cell contact-dependent gene expression, mainly due to the loss of spatial information. To overcome this obstacle and resolve cell–cell contact-specific gene expression during embryogenesis, we performed RNA sequencing of physically interacting cells (PIC-seq) and assessed them alongside similar single-cell transcriptomes derived from developing mouse embryos between embryonic day (E) 7.5 and E9.5. Analysis of the PIC-seq data identified gene expression signatures that were dependent on the presence of specific neighboring cell types. Our computational predictions, validated experimentally, demonstrated that neural progenitor (NP) cells upregulate Lhx5 and Nkx2-1 genes, when exclusively interacting with definitive endoderm (DE) cells. Moreover, there was a reciprocal impact on the transcriptome of DE cells, as they tend to upregulate Rax and Gsc when in contact with NP cells. Using individual cell transcriptome data, we formulated a means of computationally predicting the impact of one cell type on the transcriptome of its neighboring cell types. We have further developed a distinctive spatial-t-distributed stochastic neighboring embedding to display the pseudospatial distribution of cells in a 2-dimensional space. In summary, we describe an innovative approach to study contact-specific gene regulation during embryogenesis., Development of multicellular organisms is orchestrated by persistent cell–cell communication between neighboring partners. Direct interaction between different cell types can induce molecular signals that dictate lineage specification and cell fate decisions. Current single-cell RNA-seq technology cannot adequately analyze cell–cell contact-dependent gene expression, mainly due to the loss of spatial information. To overcome this obstacle and resolve cell–cell contact-specific gene expression during embryogenesis, we performed RNA sequencing of physically interacting cells (PIC-seq) and assessed them alongside similar single-cell transcriptomes derived from developing mouse embryos between embryonic day (E) 7.5 and E9.5. Analysis of the PIC-seq data identified gene expression signatures that were dependent on the presence of specific neighboring cell types. Our computational predictions, validated experimentally, demonstrated that neural progenitor (NP) cells upregulate Lhx5 and Nkx2-1 genes, when exclusively interacting with definitive endoderm (DE) cells. Moreover, there was a reciprocal impact on the transcriptome of DE cells, as they tend to upregulate Rax and Gsc when in contact with NP cells. Using individual cell transcriptome data, we formulated a means of computationally predicting the impact of one cell type on the transcriptome of its neighboring cell types. We have further developed a distinctive spatial-t-distributed stochastic neighboring embedding to display the pseudospatial distribution of cells in a 2-dimensional space. In summary, we describe an innovative approach to study contact-specific gene regulation during embryogenesis.

Published
2023

18. Neighbor-specific gene expression revealed from physically interacting cells during mouse embryonic development

Author

Kim, Junil, primary, Rothová, Michaela Mrugala, additional, Madan, Esha, additional, Rhee, Siyeon, additional, Weng, Guangzheng, additional, Palma, António M., additional, Liao, Linbu, additional, David, Eyal, additional, Amit, Ido, additional, Hajkarim, Morteza Chalabi, additional, Vudatha, Vignesh, additional, Gutiérrez-García, Andrés, additional, Moreno, Eduardo, additional, Winn, Robert, additional, Trevino, Jose, additional, Fisher, Paul B., additional, Brickman, Joshua M., additional, Gogna, Rajan, additional, and Won, Kyoung Jae, additional

Published
2023
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23. Transcriptional heterogeneity and cell cycle regulation as central determinants of Primitive Endoderm priming

Author

Perera, Marta, Nissen, Silas Boye, Proks, Martin, Pozzi, Sara, Monteiro, Rita S., Trusina, Ala, and Brickman, Joshua M.

Subjects
EXPRESSION, Mouse, selection, PLURIPOTENCY, General Biochemistry, Genetics and Molecular Biology, EPIBLAST, CULTURE, Mice, Pregnancy, G1 PHASE, Animals, Cell Lineage, SEGREGATION, endoderm, Mammals, General Immunology and Microbiology, General Neuroscience, Endoderm, Gene Expression Regulation, Developmental, Cell Differentiation, Cell Cycle Checkpoints, differentiation, General Medicine, embryonic stem cells, Fibroblast Growth Factors, SELF-RENEWAL, Blastocyst, GROUND-STATE, embryonic structures, Female, cell cycle, heterogeneity, EMBRYONIC STEM-CELLS, Germ Layers
Abstract

During embryonic development cells acquire identity at the same time as they are proliferating, implying that an intrinsic facet of cell fate choice requires coupling lineage decisions to rates of cell division. How is the cell cycle regulated to promote or suppress heterogeneity and differentiation? We explore this question combining time lapse imaging with single cell RNA-seq in the contexts of self-renewal, priming and differentiation of embryonic stem cells (ESCs) towards the Primitive Endoderm lineage (PrE). Since ESCs are derived from the Inner Cell Mass of the mammalian blastocyst, ESCs in standard culture conditions are transcriptionally heterogeneous containing subfractions that are primed for either of the two ICM lineages, Epiblast and PrE. These subfractions represent dynamic states that can readily interconvert in culture, and the PrE subfraction is functionally primed for endoderm differentiation. Here we find that differential regulation of cell cycle can tip the balance between these primed populations, such that naïve ESC culture conditions promote Epiblast-like expansion and PrE differentiation stimulates the selective proliferation of PrE-primed cells. In endoderm differentiation, we find that this change is accompanied by a counter-intuitive increase in G1 length that also appears replicatedin vivo. While FGF/ERK signalling is a known key regulator of ESCs and PrE differentiation, we find it is not just responsible for ESCs heterogeneity, but also cell cycle synchronisation, required for the inheritance of similar cell cycles between sisters and cousins. Taken together, our results point to a tight relationship between transcriptional heterogeneity and cell cycle regulation in the context of lineage priming, with primed cell populations providing a pool of flexible cell types that can be expanded in a lineage-specific fashion while allowing plasticity during early determination.

Published
2022

26. Cell-state transitions and collective cell movement generate an endoderm-like region in gastruloids

Author

Hashmi, Ali, Tlili, Sham, Perrin, Pierre, Lowndes, Molly, Peradziryi, Hanna, Brickman, Joshua M., Martínez Arias, Alfonso, Lenne, Pierre François, Hashmi, Ali, Tlili, Sham, Perrin, Pierre, Lowndes, Molly, Peradziryi, Hanna, Brickman, Joshua M., Martínez Arias, Alfonso, and Lenne, Pierre François

Abstract

Shaping the animal body plan is a complex process that involves the spatial organization and patterning of the different germ layers. Recent advances in live imaging have started to unravel the cellular choreography underlying this process in mammals, however, the sequence of events transforming an unpatterned cell ensemble into structured territories is largely unknown. Here, using gastruloids -3D aggregates of mouse embryonic stem cells- we study the formation of one of the three germ layers, the endoderm. We show that the endoderm is generated from an epiblast-like homogeneous state by a three-step mechanism: (i) a loss of E-cadherin mediated contacts in parts of the aggregate leading to the appearance of islands of E-cadherin expressing cells surrounded by cells devoid of E-cadherin, (ii) a separation of these two populations with islands of E-cadherin expressing cells flowing toward the aggregate tip, and (iii) their differentiation into an endoderm population. During the flow, the islands of E-cadherin expressing cells are surrounded by cells expressing T-Brachyury, reminiscent of the process occurring at the primitive streak. Consistent with recent in vivo observations, the endoderm formation in the gastruloids does not require an epithelial-to-mesenchymal transition, but rather a maintenance of an epithelial state for a subset of cells coupled with fragmentation of E-cadherin contacts in the vicinity, and a sorting process. Our data emphasize the role of signaling and tissue flows in the establishment of the body plan.

Published
2022

27. Evolutionary Origin of Vertebrate OCT4/POU5 Functions in Supporting Pluripotency

Author

Sukparangsi, Woranop, primary, Morganti, Elena, additional, Lowndes, Molly, additional, Mayeur, Hélène, additional, Weisser, Melanie, additional, Hammachi, Fella, additional, Peradziryi, Hanna, additional, Roske, Fabian, additional, Hölzenspies, Jurriaan, additional, Livigni, Alessandra, additional, Godard, Benoit Gilbert, additional, Sugahara, Fumiaki, additional, Kuratani, Shigeru, additional, Montoya, Guillermo, additional, Frankenberg, Stephen R., additional, Mazan, Sylvie, additional, and Brickman, Joshua M, additional

Published
2022
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32. Neighbor-specific gene expression revealed from physically interacting cells during mouse embryonic development

Author

Kim, Junil, primary, Rothová, Michaela Mrugala, additional, Madan, Esha, additional, Rhee, Siyeon, additional, Weng, Guangzheng, additional, Palma, António M., additional, Liao, Linbu, additional, David, Eyal, additional, Amit, Ido, additional, Hajkarim, Morteza Chalabi, additional, Gutiérrez-García, Andrés, additional, Fisher, Paul B., additional, Brickman, Joshua M., additional, Gogna, Rajan, additional, and Won, Kyoung Jae, additional

Published
2021
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33. Neighbor-specific gene expression revealed from physically interacting cells during mouse embryonic development.

Author

Junil Kim, Rothová, Michaela Mrugala, Madan, Esha, Rhee, Siyeon, Guangzheng Weng, Palma, António M., Liao, Linbu, David, Eyal, Amit, Ido, Hajkarim, Morteza Chalabi, Vudatha, Vignesh, Gutiérrez-García, Andrés, Moreno, Eduardo, Winn, Robert, Trevino, Jose, Fisher, Paul B., Brickman, Joshua M., Gogna, Rajan, and Kyoung Jae Won

Subjects
GENE expression, EMBRYOLOGY, CELL differentiation, GENETIC regulation, RNA sequencing
Abstract

Development of multicellular organisms is orchestrated by persistent cell–cell communication between neighboring partners. Direct interaction between different cell types can induce molecular signals that dictate lineage specification and cell fate decisions. Current single-cell RNA-seq technology cannot adequately analyze cell–cell contact-dependent gene expression, mainly due to the loss of spatial information. To overcome this obstacle and resolve cell–cell contact-specific gene expression during embryogenesis, we performed RNA sequencing of physically interacting cells (PIC-seq) and assessed them alongside similar single-cell transcriptomes derived from developing mouse embryos between embryonic day (E) 7.5 and E9.5. Analysis of the PIC-seq data identified gene expression signatures that were dependent on the presence of specific neighboring cell types. Our computational predictions, validated experimentally, demonstrated that neural progenitor (NP) cells upregulate Lhx5 and Nkx2-1 genes, when exclusively interacting with definitive endoderm (DE) cells. Moreover, there was a reciprocal impact on the transcriptome of DE cells, as they tend to upregulate Rax and Gsc when in contact with NP cells. Using individual cell transcriptome data, we formulated a means of computationally predicting the impact of one cell type on the transcriptome of its neighboring cell types. We have further developed a distinctive spatial-t-distributed stochastic neighboring embedding to display the pseudospatial distribution of cells in a 2-dimensional space. In summary, we describe an innovative approach to study contact-specific gene regulation during embryogenesis. [ABSTRACT FROM AUTHOR]

Published
2023
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41. Changes in Cell Morphology and Actin Organization in Embryonic Stem Cells Cultured under Different Conditions

Author

Barooji, Younes F., Hvid, Kasper G., Petitjean, Irene Isturiz, Brickman, Joshua M., Oddershede, Lene B., Bendix, Poul M., Barooji, Younes F., Hvid, Kasper G., Petitjean, Irene Isturiz, Brickman, Joshua M., Oddershede, Lene B., and Bendix, Poul M.

Abstract

The cellular cytoskeleton provides the cell with a mechanical rigidity that allows mechanical interaction between cells and the extracellular environment. The actin structure plays a key role in mechanical events such as motility or the establishment of cell polarity. From the earliest stages of development, as represented by the ex vivo expansion of naive embryonic stem cells (ESCs), the critical mechanical role of the actin structure is becoming recognized as a vital cue for correct segregation and lineage control of cells and as a regulatory structure that controls several transcription factors. Naive ESCs have a characteristic morphology, and the ultrastructure that underlies this condition remains to be further investigated. Here, we investigate the 3D actin cytoskeleton of naive mouse ESCs using super-resolution optical reconstruction microscopy (STORM). We investigate the morphological, cytoskeletal, and mechanical changes in cells cultured in 2i or Serum/LIF media reflecting, respectively, a homogeneous preimplantation cell state and a state that is closer to embarking on differentiation. STORM imaging showed that the peripheral actin structure undergoes a dramatic change between the two culturing conditions. We also detected micro-rheological differences in the cell periphery between the cells cultured in these two media correlating well with the observed nano-architecture of the ESCs in the two different culture conditions. These results pave the way for linking physical properties and cytoskeletal architecture to cell morphology during early development.

Published
2021

42. Enhancers are activated by p300/CBP activity-dependent PIC assembly, RNAPII recruitment, and pause release

Author

Narita, Takeo, Ito, Shinsuke, Higashijima, Yoshiki, Chu, Wai Kit, Neumann, Katrin, Walter, Jonas, Satpathy, Shankha, Liebner, Tim, Hamilton, William B, Maskey, Elina, Prus, Gabriela, Shibata, Marika, Iesmantavicius, Vytautas, Brickman, Joshua M, Anastassiadis, Konstantinos, Koseki, Haruhiko, Choudhary, Chunaram, Narita, Takeo, Ito, Shinsuke, Higashijima, Yoshiki, Chu, Wai Kit, Neumann, Katrin, Walter, Jonas, Satpathy, Shankha, Liebner, Tim, Hamilton, William B, Maskey, Elina, Prus, Gabriela, Shibata, Marika, Iesmantavicius, Vytautas, Brickman, Joshua M, Anastassiadis, Konstantinos, Koseki, Haruhiko, and Choudhary, Chunaram

Abstract

The metazoan-specific acetyltransferase p300/CBP is involved in activating signal-induced, enhancer-mediated transcription of cell-type-specific genes. However, the global kinetics and mechanisms of p300/CBP activity-dependent transcription activation remain poorly understood. We performed genome-wide, time-resolved analyses to show that enhancers and super-enhancers are dynamically activated through p300/CBP-catalyzed acetylation, deactivated by the opposing deacetylase activity, and kinetic acetylation directly contributes to maintaining cell identity at very rapid (minutes) timescales. The acetyltransferase activity is dispensable for the recruitment of p300/CBP and transcription factors but essential for promoting the recruitment of TFIID and RNAPII at virtually all enhancers and enhancer-regulated genes. This identifies pre-initiation complex assembly as a dynamically controlled step in the transcription cycle and reveals p300/CBP-catalyzed acetylation as the signal that specifically promotes transcription initiation at enhancer-regulated genes. We propose that p300/CBP activity uses a "recruit-and-release" mechanism to simultaneously promote RNAPII recruitment and pause release and thereby enables kinetic activation of enhancer-mediated transcription.

Published
2021

44. Enhancers are activated by p300/CBP activity-dependent PIC assembly, RNAPII recruitment, and pause release

Author

Narita, Takeo, primary, Ito, Shinsuke, additional, Higashijima, Yoshiki, additional, Chu, Wai Kit, additional, Neumann, Katrin, additional, Walter, Jonas, additional, Satpathy, Shankha, additional, Liebner, Tim, additional, Hamilton, William B., additional, Maskey, Elina, additional, Prus, Gabriela, additional, Shibata, Marika, additional, Iesmantavicius, Vytautas, additional, Brickman, Joshua M., additional, Anastassiadis, Konstantinos, additional, Koseki, Haruhiko, additional, and Choudhary, Chunaram, additional

Published
2021
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46. 2020_BSDB_2.pdf

Author

Hamilton, William, Brickman, Joshua M., Knudsen, Teresa E., Nielsen, Alexander Valentin, and Trusina, Ala

Subjects
embryonic structures
Abstract

Mouse embryonic stem cells (mESCs) represent are the primary in vitro model for many aspects of early embryonic development. They are the descendants of the cells of the cells inner cell mass (ICM) of early blastocyst and whilst they maintain the potency of their forerunner cells, they acquire the ability to self-renew during ex vivo culture.Over the past decades considerable work has focused in understanding the molecular basis of this ex vivo self-renewal and how it relates to cellular potency. The dominant model is that the combined activities of a discrete network of transcription factors (TFs), referred to as the pluripotency network, act cooperatively to maintain their own expression and promote proliferation whilst simultaneously blocking differentiation. However useful, this model has yet to adequately explain why such a complex, self-sustaining and robust self-renewal network would have evolved in a population that exhibits negligible self-renewal in vivo. In the context of Waddingtonian lineage transitions, as a cell traverses developmental landscapes, the gene regulatory network (GRN) that establishes each discernible cell state must also define the range of lineage trajectories available to it, incorporating various inputs like signalling and positional information to choose one trajectory over the other. Here we present data that argues that the canonical pluripotency network can be divided into at least two distinct subgroups; those that promote lineage and those that balance lineage decisions, with both classes of TFs functioning in creating a state of lineage competency, similar to what is seen in the ICM. Specifically, we see that the combined activities of ESRRB and NANOG promote a gene expression signature similar to the ICM when expressed at a near 1:1 ratio. However if ESRRB expression persists in the absence of NANOG it is no longer tethered to epiblast associated loci and acts to drive the expression of primitive endoderm (PrE) associated genes. We formalise the kinetics of this interaction and show that oscillation of ERK signalling result in asynchronous fluctuations in NANOG and ESRRB ratios and a concomitant stepwise increase in PrE determinants, similar to what is seen in the ICM. From this we propose that the ex vivo culture environment selects for ratios of TFs that, whilst maintaining the expression of ICM-like genes, and as such potency, prevent cells from progressing further in development.

Published
2020
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47. Can a Cell Put Its Arms around a Memory?

Author

Knudsen, Teresa E., Brickman, Joshua M., Knudsen, Teresa E., and Brickman, Joshua M.

Abstract

Johnny Thunders once wrote, "You can't put your arms around a memory.'' and the song continues, "don't try.'' Yet, when complex morphogenetic movements accompany differentiation, the cellular memory of signaling becomes essential. In this issue of Cell Stem Cell, Gunne-Braden et al. (2020) report a network wrapping its arms around the memory of BMP signaling, a phenomenon known as hysteresis.

Published
2020

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