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Stochasticity and the molecular mechanisms of induced pluripotency

Stochasticity and the molecular mechanisms of induced pluripotency
Stochasticity and the molecular mechanisms of induced pluripotency
The generation of induced pluripotent stem cells from adult somatic cells by ectopic expression of key transcription factors holds significant medical promise. However, current techniques for inducing pluripotency rely on viral infection and are therefore not, at present, viable within a clinical setting. Thus, there is now a need to better understand the molecular basis of stem cell pluripotency and lineage specification in order to investigate alternative methods to induce pluripotency for clinical application. However, the complexity of the underlying molecular circuitry makes this a conceptually difficult task. In order to address these issues, we considered a computational model of transcriptional control of cell fate specification. The model comprises two mutually interacting sub-circuits: a central pluripotency circuit consisting of interactions between stem-cell specific transcription factors OCT4, SOX2 and NANOG coupled to a differentiation circuit consisting of interactions between lineage-specifying master genes.The molecular switches which arise from feedback loops within these circuits give rise to a well-defined sequence of successive gene restrictions corresponding to a controlled differentiation cascade in response to environmental stimuli. Furthermore, we found that this differentiation cascade is strongly unidirectional: once silenced, core transcription factors cannot easily be reactivated. In the context of induced pluripotency, this indicates that differentiated cells are robustly resistant to reprogramming to a more primitive state. However, our model suggests that under certain circumstances, amplification of low-level fluctuations in transcriptional status (transcriptional "noise") may be sufficient to trigger reactivation of the core pluripotency switch and reprogramming to a pluripotent state. This interpretation offers an explanation of a number of experimental observations concerning the molecular mechanisms of cellular reprogramming by defined factors and suggests a role for stochasticity in reprogramming of somatic cells to pluripotency
disease, development, adult, health, protein, bone morphogenetic protein 2, expression, transcription factors, stochastic processes, transcription, united-kingdom, cytology, biological, human, environmental, bone, gene expression regulation, genetic, pluripotent stem cells, osteoblasts, cell differentiation, models, humans, developmental origins, physiology, ppar gamma, methods, stromal cells
1932-6203
e3086
MacArthur, Ben D.
2c0476e7-5d3e-4064-81bb-104e8e88bb6b
Please, Colin P.
118dffe7-4b38-4787-a972-9feec535839e
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778
MacArthur, Ben D.
2c0476e7-5d3e-4064-81bb-104e8e88bb6b
Please, Colin P.
118dffe7-4b38-4787-a972-9feec535839e
Oreffo, Richard O.C.
ff9fff72-6855-4d0f-bfb2-311d0e8f3778

MacArthur, Ben D., Please, Colin P. and Oreffo, Richard O.C. (2008) Stochasticity and the molecular mechanisms of induced pluripotency. PLoS ONE, 3 (8), e3086. (doi:10.1371/journal.pone.0003086).

Record type: Article

Abstract

The generation of induced pluripotent stem cells from adult somatic cells by ectopic expression of key transcription factors holds significant medical promise. However, current techniques for inducing pluripotency rely on viral infection and are therefore not, at present, viable within a clinical setting. Thus, there is now a need to better understand the molecular basis of stem cell pluripotency and lineage specification in order to investigate alternative methods to induce pluripotency for clinical application. However, the complexity of the underlying molecular circuitry makes this a conceptually difficult task. In order to address these issues, we considered a computational model of transcriptional control of cell fate specification. The model comprises two mutually interacting sub-circuits: a central pluripotency circuit consisting of interactions between stem-cell specific transcription factors OCT4, SOX2 and NANOG coupled to a differentiation circuit consisting of interactions between lineage-specifying master genes.The molecular switches which arise from feedback loops within these circuits give rise to a well-defined sequence of successive gene restrictions corresponding to a controlled differentiation cascade in response to environmental stimuli. Furthermore, we found that this differentiation cascade is strongly unidirectional: once silenced, core transcription factors cannot easily be reactivated. In the context of induced pluripotency, this indicates that differentiated cells are robustly resistant to reprogramming to a more primitive state. However, our model suggests that under certain circumstances, amplification of low-level fluctuations in transcriptional status (transcriptional "noise") may be sufficient to trigger reactivation of the core pluripotency switch and reprogramming to a pluripotent state. This interpretation offers an explanation of a number of experimental observations concerning the molecular mechanisms of cellular reprogramming by defined factors and suggests a role for stochasticity in reprogramming of somatic cells to pluripotency

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Published date: 2008
Keywords: disease, development, adult, health, protein, bone morphogenetic protein 2, expression, transcription factors, stochastic processes, transcription, united-kingdom, cytology, biological, human, environmental, bone, gene expression regulation, genetic, pluripotent stem cells, osteoblasts, cell differentiation, models, humans, developmental origins, physiology, ppar gamma, methods, stromal cells

Identifiers

Local EPrints ID: 70466
URI: http://eprints.soton.ac.uk/id/eprint/70466
DOI: doi:10.1371/journal.pone.0003086
ISSN: 1932-6203
PURE UUID: 58a1ad34-a20c-4e38-93c9-41935ba82506
ORCID for Ben D. MacArthur: ORCID iD orcid.org/0000-0002-5396-9750
ORCID for Richard O.C. Oreffo: ORCID iD orcid.org/0000-0001-5995-6726

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Date deposited: 03 Feb 2010
Last modified: 14 Mar 2024 02:44

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Contributors

Author: Ben D. MacArthur ORCID iD
Author: Colin P. Please
Author: Richard O.C. Oreffo ORCID iD

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