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Transcriptional memory in skeletal muscle. Don't forget (to) exercise
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Zeitschriftentitel: | Journal of Cellular Physiology |
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Personen und Körperschaften: | , , |
In: | Journal of Cellular Physiology, 235, 2020, 7-8, S. 5476-5489 |
Format: | E-Article |
Sprache: | Englisch |
veröffentlicht: |
Wiley
|
Schlagwörter: |
author_facet |
Beiter, Thomas Nieß, Andreas M. Moser, Dirk Beiter, Thomas Nieß, Andreas M. Moser, Dirk |
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author |
Beiter, Thomas Nieß, Andreas M. Moser, Dirk |
spellingShingle |
Beiter, Thomas Nieß, Andreas M. Moser, Dirk Journal of Cellular Physiology Transcriptional memory in skeletal muscle. Don't forget (to) exercise Cell Biology Clinical Biochemistry Physiology |
author_sort |
beiter, thomas |
spelling |
Beiter, Thomas Nieß, Andreas M. Moser, Dirk 0021-9541 1097-4652 Wiley Cell Biology Clinical Biochemistry Physiology http://dx.doi.org/10.1002/jcp.29535 <jats:title>Abstract</jats:title><jats:p>Transcriptional memory describes an ancient and highly conserved form of cellular learning that enables cells to benefit from recent experience by retaining a mitotically inheritable but reversible memory of the initial transcriptional response when encountering an environmental or physiological stimulus. Herein, we will review recent progress made in the understanding of how cells can make use of diverse constituents of the epigenetic toolbox to retain a transcriptional memory of past states and perturbations. Specifically, we will outline how these mechanisms will help to improve our understanding of skeletal muscle plasticity in health and disease. We describe the epigenetic road map that allows skeletal muscle fibers to navigate through training‐induced adaptation processes, and how epigenetic memory marks can preserve an autobiographical history of lifestyle behavior changes, pathological challenges, and aging. We will further consider some key findings in the field of exercise epigenomics to emphasize major challenges when interpreting dynamic changes in the chromatin landscape in response to acute exercise and training.</jats:p> Transcriptional memory in skeletal muscle. Don't forget (to) exercise Journal of Cellular Physiology |
doi_str_mv |
10.1002/jcp.29535 |
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Wiley |
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Journal of Cellular Physiology |
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title |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_unstemmed |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_full |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_fullStr |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_full_unstemmed |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_short |
Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_sort |
transcriptional memory in skeletal muscle. don't forget (to) exercise |
topic |
Cell Biology Clinical Biochemistry Physiology |
url |
http://dx.doi.org/10.1002/jcp.29535 |
publishDate |
2020 |
physical |
5476-5489 |
description |
<jats:title>Abstract</jats:title><jats:p>Transcriptional memory describes an ancient and highly conserved form of cellular learning that enables cells to benefit from recent experience by retaining a mitotically inheritable but reversible memory of the initial transcriptional response when encountering an environmental or physiological stimulus. Herein, we will review recent progress made in the understanding of how cells can make use of diverse constituents of the epigenetic toolbox to retain a transcriptional memory of past states and perturbations. Specifically, we will outline how these mechanisms will help to improve our understanding of skeletal muscle plasticity in health and disease. We describe the epigenetic road map that allows skeletal muscle fibers to navigate through training‐induced adaptation processes, and how epigenetic memory marks can preserve an autobiographical history of lifestyle behavior changes, pathological challenges, and aging. We will further consider some key findings in the field of exercise epigenomics to emphasize major challenges when interpreting dynamic changes in the chromatin landscape in response to acute exercise and training.</jats:p> |
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author | Beiter, Thomas, Nieß, Andreas M., Moser, Dirk |
author_facet | Beiter, Thomas, Nieß, Andreas M., Moser, Dirk, Beiter, Thomas, Nieß, Andreas M., Moser, Dirk |
author_sort | beiter, thomas |
container_issue | 7-8 |
container_start_page | 5476 |
container_title | Journal of Cellular Physiology |
container_volume | 235 |
description | <jats:title>Abstract</jats:title><jats:p>Transcriptional memory describes an ancient and highly conserved form of cellular learning that enables cells to benefit from recent experience by retaining a mitotically inheritable but reversible memory of the initial transcriptional response when encountering an environmental or physiological stimulus. Herein, we will review recent progress made in the understanding of how cells can make use of diverse constituents of the epigenetic toolbox to retain a transcriptional memory of past states and perturbations. Specifically, we will outline how these mechanisms will help to improve our understanding of skeletal muscle plasticity in health and disease. We describe the epigenetic road map that allows skeletal muscle fibers to navigate through training‐induced adaptation processes, and how epigenetic memory marks can preserve an autobiographical history of lifestyle behavior changes, pathological challenges, and aging. We will further consider some key findings in the field of exercise epigenomics to emphasize major challenges when interpreting dynamic changes in the chromatin landscape in response to acute exercise and training.</jats:p> |
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spelling | Beiter, Thomas Nieß, Andreas M. Moser, Dirk 0021-9541 1097-4652 Wiley Cell Biology Clinical Biochemistry Physiology http://dx.doi.org/10.1002/jcp.29535 <jats:title>Abstract</jats:title><jats:p>Transcriptional memory describes an ancient and highly conserved form of cellular learning that enables cells to benefit from recent experience by retaining a mitotically inheritable but reversible memory of the initial transcriptional response when encountering an environmental or physiological stimulus. Herein, we will review recent progress made in the understanding of how cells can make use of diverse constituents of the epigenetic toolbox to retain a transcriptional memory of past states and perturbations. Specifically, we will outline how these mechanisms will help to improve our understanding of skeletal muscle plasticity in health and disease. We describe the epigenetic road map that allows skeletal muscle fibers to navigate through training‐induced adaptation processes, and how epigenetic memory marks can preserve an autobiographical history of lifestyle behavior changes, pathological challenges, and aging. We will further consider some key findings in the field of exercise epigenomics to emphasize major challenges when interpreting dynamic changes in the chromatin landscape in response to acute exercise and training.</jats:p> Transcriptional memory in skeletal muscle. Don't forget (to) exercise Journal of Cellular Physiology |
spellingShingle | Beiter, Thomas, Nieß, Andreas M., Moser, Dirk, Journal of Cellular Physiology, Transcriptional memory in skeletal muscle. Don't forget (to) exercise, Cell Biology, Clinical Biochemistry, Physiology |
title | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_full | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_fullStr | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_full_unstemmed | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_short | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
title_sort | transcriptional memory in skeletal muscle. don't forget (to) exercise |
title_unstemmed | Transcriptional memory in skeletal muscle. Don't forget (to) exercise |
topic | Cell Biology, Clinical Biochemistry, Physiology |
url | http://dx.doi.org/10.1002/jcp.29535 |