DNA and chromatin modification networks distinguish stem cell pluripotent ground states
DNA and chromatin modification networks distinguish stem cell pluripotent ground states
Pluripotent stem cells are capable of differentiating into all cell types of the body and therefore hold tremendous promise for regenerative medicine. Despite their widespread use in laboratories across the world, a detailed understanding of the molecular mechanisms that regulate the pluripotent state is currently lacking. Mouse embryonic (mESC) and epiblast (mEpiSC) stem cells are two closely related classes of pluripotent stem cells, derived from distinct embryonic tissues. Although both mESC and mEpiSC are pluripotent, these cell types show important differences in their properties suggesting distinct pluripotent ground states. To understand the molecular basis of pluripotency, we analyzed the nuclear proteomes of mESCs and mEpiSCs to identify protein networks that regulate their respective pluripotent states. Our study used label-free LC-MS/MS to identify and quantify 1597 proteins in embryonic and epiblast stem cell nuclei. Immunoblotting of a selected protein subset was used to confirm that key components of chromatin regulatory networks are differentially expressed in mESCs and mEpiSCs. Specifically, we identify differential expression of DNA methylation, ATP-dependent chromatin remodeling and nucleosome remodeling networks in mESC and mEpiSC nuclei. This study is the first comparative study of protein networks in cells representing the two distinct, pluripotent states, and points to the importance of DNA and chromatin modification processes in regulating pluripotency. In addition, by integrating our data with existing pluripotency networks, we provide detailed maps of protein networks that regulate pluripotency that will further both the fundamental understanding of pluripotency as well as efforts to reliably control the differentiation of these cells into functional cell fates.
1036-1047
Song, Jing
c3f6ccf2-4c63-487c-9c39-e25382b9ee91
Saha, Sudipto
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Gokulrangan, Giridharan
dfe5f205-72aa-4e41-b11b-5155ef82c9ad
Tesar, Paul J.
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Ewing, Rob M.
022c5b04-da20-4e55-8088-44d0dc9935ae
October 2012
Song, Jing
c3f6ccf2-4c63-487c-9c39-e25382b9ee91
Saha, Sudipto
77b0a09f-c013-4418-b3b5-659cca46fe9d
Gokulrangan, Giridharan
dfe5f205-72aa-4e41-b11b-5155ef82c9ad
Tesar, Paul J.
2a5b96a5-2328-47e9-83e5-c65a84f64cae
Ewing, Rob M.
022c5b04-da20-4e55-8088-44d0dc9935ae
Song, Jing, Saha, Sudipto, Gokulrangan, Giridharan, Tesar, Paul J. and Ewing, Rob M.
(2012)
DNA and chromatin modification networks distinguish stem cell pluripotent ground states.
Molecular & Cellular Proteomics, 11 (10), .
(doi:10.1074/mcp.M111.011114).
(PMID:22822199)
Abstract
Pluripotent stem cells are capable of differentiating into all cell types of the body and therefore hold tremendous promise for regenerative medicine. Despite their widespread use in laboratories across the world, a detailed understanding of the molecular mechanisms that regulate the pluripotent state is currently lacking. Mouse embryonic (mESC) and epiblast (mEpiSC) stem cells are two closely related classes of pluripotent stem cells, derived from distinct embryonic tissues. Although both mESC and mEpiSC are pluripotent, these cell types show important differences in their properties suggesting distinct pluripotent ground states. To understand the molecular basis of pluripotency, we analyzed the nuclear proteomes of mESCs and mEpiSCs to identify protein networks that regulate their respective pluripotent states. Our study used label-free LC-MS/MS to identify and quantify 1597 proteins in embryonic and epiblast stem cell nuclei. Immunoblotting of a selected protein subset was used to confirm that key components of chromatin regulatory networks are differentially expressed in mESCs and mEpiSCs. Specifically, we identify differential expression of DNA methylation, ATP-dependent chromatin remodeling and nucleosome remodeling networks in mESC and mEpiSC nuclei. This study is the first comparative study of protein networks in cells representing the two distinct, pluripotent states, and points to the importance of DNA and chromatin modification processes in regulating pluripotency. In addition, by integrating our data with existing pluripotency networks, we provide detailed maps of protein networks that regulate pluripotency that will further both the fundamental understanding of pluripotency as well as efforts to reliably control the differentiation of these cells into functional cell fates.
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Published date: October 2012
Organisations:
Faculty of Natural and Environmental Sciences, Centre for Biological Sciences
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Local EPrints ID: 345204
URI: http://eprints.soton.ac.uk/id/eprint/345204
ISSN: 1535-9476
PURE UUID: 993de60b-a889-47fe-b12c-7ffd5e7aa490
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Date deposited: 13 Nov 2012 11:45
Last modified: 15 Mar 2024 03:44
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Contributors
Author:
Jing Song
Author:
Sudipto Saha
Author:
Giridharan Gokulrangan
Author:
Paul J. Tesar
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