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1. GLI3 regulates muscle stem cell entry into GAlert and self-renewal

Author

Caroline E. Brun, Marie-Claude Sincennes, Alexander Y. T. Lin, Derek Hall, William Jarassier, Peter Feige, Fabien Le Grand, and Michael A. Rudnicki

Subjects
Science
Abstract

Primary cilia regulate the processing of the GLI transcription factors and Hedgehog signaling. Here, the authors show that cilia-related GLI3 controls both the quiescence-to-activation transition and self-renewal in muscle stem cells.

Published
2022
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2. Acetylation of PAX7 controls muscle stem cell self-renewal and differentiation potential in mice

Author

Marie-Claude Sincennes, Caroline E. Brun, Alexander Y. T. Lin, Tabitha Rosembert, David Datzkiw, John Saber, Hong Ming, Yoh-ichi Kawabe, and Michael A. Rudnicki

Subjects
Science
Abstract

The acetyltransferase MYST1 stimulated by acetyl-CoA, and the deacetylase SIRT2 stimulated by NAD+, regulate PAX7 acetylation in muscle stem cells, which in turn, regulates stem cell self-renewal and regeneration following injury in mouse skeletal muscle.

Published
2021
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3. MLL1 is required for PAX7 expression and satellite cell self-renewal in mice

Author

Gregory C. Addicks, Caroline E. Brun, Marie-Claude Sincennes, John Saber, Christopher J. Porter, A. Francis Stewart, Patricia Ernst, and Michael A. Rudnicki

Subjects
Science
Abstract

PAX7 transcription factor specifies the myogenic identity of muscle stem cells and acts as a nodal factor by stimulating proliferation while inhibiting differentiation. Here authors find that Mll1 deletion in myoblasts in mice results in reduced H3K4me3 at both Pax7 and Myf5 promoters, reduced Pax7 and Myf5 expression, and proliferation defects.

Published
2019
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5. Mouse WIF1 Is Only Modified with O-Fucose in Its EGF-like Domain III Despite Two Evolutionarily Conserved Consensus Sites

Author

Florian Pennarubia, Emilie Pinault, Bilal Al Jaam, Caroline E. Brun, Abderrahman Maftah, Agnès Germot, and Sébastien Legardinier

Subjects
click chemistry, EGF-LD, O-fucosylation, phylogeny, Pofut1, Wif1, Microbiology, QR1-502
Abstract

The Wnt Inhibitory Factor 1 (Wif1), known to inhibit Wnt signaling pathways, is composed of a WIF domain and five EGF-like domains (EGF-LDs) involved in protein interactions. Despite the presence of a potential O-fucosylation site in its EGF-LDs III and V, the O-fucose sites occupancy has never been demonstrated for WIF1. In this study, a phylogenetic analysis on the distribution, conservation and evolution of Wif1 proteins was performed, as well as biochemical approaches focusing on O-fucosylation sites occupancy of recombinant mouse WIF1. In the monophyletic group of gnathostomes, we showed that the consensus sequence for O-fucose modification by Pofut1 is highly conserved in Wif1 EGF-LD III while it was more divergent in EGF-LD V. Using click chemistry and mass spectrometry, we demonstrated that mouse WIF1 was only modified with a non-extended O-fucose on its EGF-LD III. In addition, a decreased amount of mouse WIF1 in the secretome of CHO cells was observed when the O-fucosylation site in EGF-LD III was mutated. Based on sequence comparison and automated protein modeling, we suggest that the absence of O-fucose on EGF-LD V of WIF1 in mouse and probably in most gnathostomes, could be related to EGF-LD V inability to interact with POFUT1.

Published
2020
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6. [PAX7 acetylation controls muscle stem cell self-renewal]

Author

Caroline E, Brun and Marie-Claude, Sincennes

Subjects
Satellite Cells, Skeletal Muscle, Muscles, Humans, PAX7 Transcription Factor, Acetylation, Cell Differentiation, Cell Self Renewal, Muscle Development, Muscle, Skeletal, Cells, Cultured, Cell Proliferation
Published
2022

8. MLL1 is required for PAX7 expression and satellite cell self-renewal in mice

Author

Michael A. Rudnicki, Caroline E. Brun, Christopher J. Porter, Marie-Claude Sincennes, A. Francis Stewart, John Saber, Patricia Ernst, and Gregory C. Addicks

Subjects
Male, 0301 basic medicine, Molecular biology, General Physics and Astronomy, Stem cells, Myoblasts, Mice, 0302 clinical medicine, Myocyte, Promoter Regions, Genetic, lcsh:Science, Cells, Cultured, Mice, Knockout, Multidisciplinary, PAX7 Transcription Factor, Cell Differentiation, musculoskeletal system, Cell biology, medicine.anatomical_structure, Epigenetics, Female, MYF5, Myogenic Regulatory Factor 5, Stem cell, Cell activation, Transcription, tissues, Myeloid-Lymphoid Leukemia Protein, animal structures, Satellite Cells, Skeletal Muscle, Science, Biology, Methylation, Article, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, medicine, Animals, Transcription factor, Cell Proliferation, Cell growth, Skeletal muscle, Promoter, Histone-Lysine N-Methyltransferase, General Chemistry, Mice, Inbred C57BL, 030104 developmental biology, lcsh:Q, 030217 neurology & neurosurgery
Abstract

PAX7 is a paired-homeobox transcription factor that specifies the myogenic identity of muscle stem cells and acts as a nodal factor by stimulating proliferation while inhibiting differentiation. We previously found that PAX7 recruits the H3K4 methyltransferases MLL1/2 to epigenetically activate target genes. Here we report that in the absence of Mll1, myoblasts exhibit reduced H3K4me3 at both Pax7 and Myf5 promoters and reduced Pax7 and Myf5 expression. Mll1-deficient myoblasts fail to proliferate but retain their differentiation potential, while deletion of Mll2 had no discernable effect. Re-expression of PAX7 in committed Mll1 cKO myoblasts restored H3K4me3 enrichment at the Myf5 promoter and Myf5 expression. Deletion of Mll1 in satellite cells reduced satellite cell proliferation and self-renewal, and significantly impaired skeletal muscle regeneration. Pax7 expression was unaffected in quiescent satellite cells but was markedly downregulated following satellite cell activation. Therefore, MLL1 is required for PAX7 expression and satellite cell function in vivo. Furthermore, PAX7, but not MLL1, is required for Myf5 transcriptional activation in committed myoblasts., PAX7 transcription factor specifies the myogenic identity of muscle stem cells and acts as a nodal factor by stimulating proliferation while inhibiting differentiation. Here authors find that Mll1 deletion in myoblasts in mice results in reduced H3K4me3 at both Pax7 and Myf5 promoters, reduced Pax7 and Myf5 expression, and proliferation defects.

Published
2019

9. Acetylation of PAX7 controls muscle stem cell self-renewal and differentiation potential in mice

Author

David Datzkiw, Yoh-ichi Kawabe, Alexander Y.T. Lin, Michael A. Rudnicki, John Saber, Tabitha Rosembert, Marie-Claude Sincennes, Hong Ming, and Caroline E. Brun

Subjects
0301 basic medicine, Transcriptional regulatory elements, General Physics and Astronomy, Mice, 0302 clinical medicine, Sirtuin 2, Gene expression, Chlorocebus aethiops, Sf9 Cells, Cell Self Renewal, Promoter Regions, Genetic, Histone Acetyltransferases, Multidisciplinary, PAX7 Transcription Factor, Acetylation, Cell Differentiation, musculoskeletal system, Cell biology, Acetyltransferase, Gene Knockdown Techniques, COS Cells, Stem cell, tissues, Transcriptional Activation, Satellite Cells, Skeletal Muscle, Science, Transgene, Primary Cell Culture, Mice, Transgenic, Biology, Spodoptera, SIRT2, Cardiotoxins, General Biochemistry, Genetics and Molecular Biology, Article, 03 medical and health sciences, Muscle stem cells, Animals, Humans, Regeneration, Muscle, Skeletal, General Chemistry, Disease Models, Animal, 030104 developmental biology, Cell culture, Mutagenesis, Homeobox, CRISPR-Cas Systems, 030217 neurology & neurosurgery
Abstract

Muscle stem cell function has been suggested to be regulated by Acetyl-CoA and NAD+ availability, but the mechanisms remain unclear. Here we report the identification of two acetylation sites on PAX7 that positively regulate its transcriptional activity. Lack of PAX7 acetylation reduces DNA binding, specifically to the homeobox motif. The acetyltransferase MYST1 stimulated by Acetyl-CoA, and the deacetylase SIRT2 stimulated by NAD +, are identified as direct regulators of PAX7 acetylation and asymmetric division in muscle stem cells. Abolishing PAX7 acetylation in mice using CRISPR/Cas9 mutagenesis leads to an expansion of the satellite stem cell pool, reduced numbers of asymmetric stem cell divisions, and increased numbers of oxidative IIA myofibers. Gene expression analysis confirms that lack of PAX7 acetylation preferentially affects the expression of target genes regulated by homeodomain binding motifs. Therefore, PAX7 acetylation status regulates muscle stem cell function and differentiation potential to facilitate metabolic adaptation of muscle tissue., The acetyltransferase MYST1 stimulated by acetyl-CoA, and the deacetylase SIRT2 stimulated by NAD+, regulate PAX7 acetylation in muscle stem cells, which in turn, regulates stem cell self-renewal and regeneration following injury in mouse skeletal muscle.

Published
2021

10. GLI3 Processing by the Primary Cilium Regulates Muscle Stem Cell Entry into GAlert

Author

William Jarassier, Fabien Le Grand, Marie-Claude Sincennes, Caroline E. Brun, Peter Feige, Alexander Y.T. Lin, Morten Ritso, Derek Hall, and Michael A. Rudnicki

Subjects
animal structures, Regeneration (biology), Cilium, Skeletal muscle, Biology, biology.organism_classification, Cell biology, medicine.anatomical_structure, embryonic structures, GLI3, medicine, Satellite (biology), Stem cell, Cell activation, Transcription factor
Abstract

Satellite cells are required for the growth, maintenance, and regeneration of skeletal muscle. Quiescent satellite cells possess a primary cilium, a structure that regulates the processing of the GLI family of transcription factors. Here we find that GLI3, specifically, plays a critical role in satellite cell activation. Primary cilia-mediated processing of GLI3 is required to maintain satellite cells in a G0 dormant state. Strikingly, satellite cells lacking GLI3 enter GAlert in the absence of injury. Furthermore, GLI3 depletion or inhibition of its processing stimulates symmetrical division in satellite cells and expansion of the stem cell pool. As a result, satellite cells lacking GLI3 display rapid cell-cycle entry, increased proliferation and augmented self-renewal, and markedly enhanced long-term regenerative capacity. Therefore, our results reveal an essential role for primary cilia processing of GLI3 in regulating muscle stem cell activation and fate.

Published
2020

11. GLI3 regulates muscle stem cell entry into G

Author

Caroline E, Brun, Marie-Claude, Sincennes, Alexander Y T, Lin, Derek, Hall, William, Jarassier, Peter, Feige, Fabien, Le Grand, and Michael A, Rudnicki

Subjects
Satellite Cells, Skeletal Muscle, Stem Cells, Cell Differentiation, Mechanistic Target of Rapamycin Complex 1, Virus Internalization, Muscle, Skeletal, Cell Proliferation
Abstract

Satellite cells are required for the growth, maintenance, and regeneration of skeletal muscle. Quiescent satellite cells possess a primary cilium, a structure that regulates the processing of the GLI family of transcription factors. Here we find that GLI3 processing by the primary cilium plays a critical role for satellite cell function. GLI3 is required to maintain satellite cells in a G

Published
2020

12. GREM1 is epigenetically reprogrammed in muscle cells after exercise training and controls myogenesis and metabolism

Author

Cedric Moro, Emil Andersen, Leonidas S. Lundell, Alice Parisi, Pascal Maire, Michael A. Rudnicki, Virginie Bourlier, Danial Ahwazi, Odile Fabre, Alexandre Blais, Anissa Taleb, Iman Chakroun, Fabien Le Grand, Claire Laurens, Lorenzo Giordani, Lars R. Ingerslev, Atul S Desmukh, Caroline E. Brun, Christian Garde, Rémi Mounier, Kiymet Citirikkaya, Pattarawan Pattamaprapanont, and Romain Barrès

Subjects
medicine.medical_specialty, Myogenesis, Skeletal muscle, AMPK, Biology, medicine.anatomical_structure, Endocrinology, Lipid oxidation, Endurance training, Internal medicine, DNA methylation, medicine, Myocyte, Stem cell
Abstract

Exercise training improves skeletal muscle function, notably through tissue regeneration by muscle stem cells. Here, we hypothesized that exercise training reprograms the epigenome of muscle cell, which could account for better muscle function. Genome-wide DNA methylation of myotube cultures established from middle-aged obese men before and after endurance exercise training identified a differentially methylated region (DMR) located downstream ofGremlin 1(GREM1), which was associated with increasedGREM1expression. GREM1 expression was lower in muscle satellite cells from obese, compared to lean mice, and exercise training restored GREM1 levels to those of control animals. We show that GREM1 regulates muscle differentiation through the negative control of satellite cell self-renewal, and that GREM1 controls muscle lineage commitment and lipid oxidation through the AMPK pathway. Our study identifies novel functions of GREM1 and reveals an epigenetic mechanism by which exercise training reprograms muscle stem cells to improve skeletal muscle function.

Published
2020

13. The myogenic regulatory factors, determinants of muscle development, cell identity and regeneration

Author

Estela G. García-González, Caroline E. Brun, J. Manuel Hernández-Hernández, and Michael A. Rudnicki

Subjects
0301 basic medicine, Cellular differentiation, Biology, Muscle Development, MyoD, Article, Mice, 03 medical and health sciences, medicine, Animals, Regeneration, Cell Lineage, Muscle, Skeletal, Phylogeny, Myogenin, Genetics, Myogenesis, Regeneration (biology), Gene Expression Regulation, Developmental, Skeletal muscle, Cell Differentiation, Cell Biology, Cell biology, 030104 developmental biology, medicine.anatomical_structure, Myogenic Regulatory Factors, Myogenic regulatory factors, MYF5, Developmental Biology
Abstract

The Myogenic Regulatory Factors (MRFs) Myf5, MyoD, myogenin and MRF4 are members of the basic helix-loop-helix family of transcription factors that control the determination and differentiation of skeletal muscle cells during embryogenesis and postnatal myogenesis. The dynamics of their temporal and spatial expression as well as their biochemical properties have allowed the identification of a precise and hierarchical relationship between the four MRFs. This relationship establishes the myogenic lineage as well as the maintenance of the terminal myogenic phenotype. The application of genome-wide technologies has provided important new information as to how the MRFs function to activate muscle gene expression. Application of combined functional genomics technologies along with single cell lineage tracing strategies will allow a deeper understanding of the mechanisms mediating myogenic determination, cell differentiation and muscle regeneration.

Published
2017

14. Muscle Stem Cell Self Renewal is Regulated by Acetylation of PAX7

Author

Michael A. Rudnicki, Caroline E. Brun, Yoh-ichi Kawabe, Marie-Claude Sincennes, Tabitha Rosembert, and John Saber

Subjects
Chemistry, Chromatin binding, Skeletal muscle, musculoskeletal system, SIRT2, Cell biology, medicine.anatomical_structure, Acetylation, Asymmetric cell division, medicine, Myocyte, Stem cell, tissues, Transcription factor
Abstract

The transcription factor PAX7 is a critical regulator of satellite cell survival, self-renewal and proliferation. PAX7 protein is regulated by different post-translational modifications that affect its transcriptional activity, and consequently, influence muscle regeneration. Here, we report two novel acetylation sites on the PAX7 protein, which regulate its transcriptional activity and chromatin binding. Abolishing PAX7 acetylation using CRISPR/Cas9 mutant mice impairs muscle regeneration and leads to progressive satellite cell exhaustion. We identified molecular regulators of PAX7 acetylation, the acetyltransferase MYST1 as well as with the deacetylase SIRT2, both of which control PAX7 acetylation levels and PAX7 target gene expression in myoblasts. MYST1 and SIRT2 are also important players in regulating the balance between satellite stem cell symmetric versus asymmetric division, therefore controlling satellite cell expansion, self-renewal and commitment. Our data demonstrate that acetylation levels regulate PAX7 transcriptional activity and function in satellite cells.

Published
2019

16. Single EDL Myofiber Isolation for Analyses of Quiescent and Activated Muscle Stem Cells

Author

Caroline E, Brun, Yu Xin, Wang, and Michael A, Rudnicki

Subjects
Mice, Inbred C57BL, Mice, Satellite Cells, Skeletal Muscle, Muscle Fibers, Skeletal, Animals, Regeneration, Cell Differentiation, Cell Separation, Muscle Development, Cells, Cultured
Abstract

Adult satellite cells are quiescent, but are poised for activation in response to exercise, injury, or disease allowing adult muscle growth or repair. Once activated, satellite cells proliferate extensively to produce enough myogenic progenitors in order to regenerate the muscles. In order to self-renew, a subset of activated satellite cells can resist the myogenic differentiation and return to quiescence to replenish the satellite cell pool. These cellular processes that normally occur during skeletal muscle regeneration can be recapitulated ex vivo using isolated and cultured myofibers. Here, we describe a protocol to isolate single myofibers from the extensor digitorum longus muscle. Moreover, we detail experimental conditions for analyzing satellite cells in quiescence and progression through the myogenic lineage.

Published
2017

17. Single EDL Myofiber Isolation for Analyses of Quiescent and Activated Muscle Stem Cells

Author

Yu Xin Wang, Caroline E. Brun, and Michael A. Rudnicki

Subjects
0301 basic medicine, Regeneration (biology), Skeletal muscle, Anatomy, Biology, MyoD, Cell biology, Extensor digitorum longus muscle, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, medicine, Myocyte, Progenitor cell, PAX7, Stem cell, 030217 neurology & neurosurgery
Abstract

Adult satellite cells are quiescent, but are poised for activation in response to exercise, injury, or disease allowing adult muscle growth or repair. Once activated, satellite cells proliferate extensively to produce enough myogenic progenitors in order to regenerate the muscles. In order to self-renew, a subset of activated satellite cells can resist the myogenic differentiation and return to quiescence to replenish the satellite cell pool. These cellular processes that normally occur during skeletal muscle regeneration can be recapitulated ex vivo using isolated and cultured myofibers. Here, we describe a protocol to isolate single myofibers from the extensor digitorum longus muscle. Moreover, we detail experimental conditions for analyzing satellite cells in quiescence and progression through the myogenic lineage.

Published
2017

18. List of Contributors

Author

Abu S.I. Ahmed, Piero Anversa, Fnu Apoorva, Christopher K. Arakawa, David J. Baylink, Laila Benameur, Jonathan Bernhard, Mickie Bhatia, Michael Blatchley, Jeffrey T. Borenstein, Nathalie Brandenberg, David T. Breault, Caroline E. Brun, Rebecca L. Carrier, Naniye Malli Cetinbas, Wanqiu Chen, Yu-Hao Cheng, Fabien P. Chevalier, Hans Clevers, Michael J. Conboy, Irina M. Conboy, Joanne C. Conover, Cole A. DeForest, Henry J. Donahue, Nicolas A. Dumont, Kimberly M. Ferlin, Michael W. Findlay, John P. Fisher, Uwe Freudenberg, Makoto Funaki, Sharon Gerecht, Polina Goichberg, Linda G. Griffith, Géraldine Guasch, Joshua Guild, Ting Guo, Geoffrey C. Gurtner, Pamela Habibovic, Amranul Haque, Xi C. He, Victor Hernandez-Gordillo, Toru Hosoda, Jie Huang, Yoshihiro Ito, Paul A. Janmey, Lei Jiang, Peter Anthony Jones, David S. Kaplan, Jeffrey M. Karp, Christina Klecker, Abigail N. Koppes, Arthur Krause, Maria Leena, Annarosa Leri, Shulamit Levenberg, Xiaowei Li, Yingying Li, Yan Li, Linheng Li, Jung Yul Lim, Yijun Liu, Matthias P. Lutolf, Teng Ma, Kay Maeda, Angad Malhotra, Geetha Manivasagam, Hongli Mao, Hai-Quan Mao, Todd C. McDevitt, Mina Mekhail, Tiziano Moccetti, Eike Müller, Lakshmi S. Nair, Mio Nakanishi, Johnathan Ng, Renu Pasricha, John Perry, Tilo Pompe, Murugan Ramalingam, Keerthana Ramasamy, Deepti Rana, Alexander Revzin, Brandon D. Riehl, Jose Roman, Jatin Roper, Dekel Rosenfeld, Marcello Rota, Jeroen Rouwkema, Michael A. Rudnicki, Marc Ruel, Borja Saez, Nobuo Sasaki, Toshiro Sato, David T. Scadden, Sanaya N. Shroff, Ankur Singh, Quinton Smith, Kara Spiller, Erik J. Suuronen, Maryam Tabrizian, Xiaolei Tang, Krysti L. Todd, Ang-Chen Tsai, Clemens van Blitterswijk, Aparna Venkatraman, Ajaykumar Vishwakarma, Gordana Vunjak-Novakovic, Jane Wang, Shutao Wang, Samiksha Wasnik, Carsten Werner, Jenna L. Wilson, Ömer H. Yılmaz, Xuegang Yuan, Rushdia Z. Yusuf, Xiao-Bing Zhang, and Meng Zhao

Published
2017

19. The Satellite Cell Niche in Skeletal Muscle

Author

Michael A. Rudnicki, Fabien P. Chevalier, Nicolas A. Dumont, and Caroline E. Brun

Subjects
education.field_of_study, Regeneration (biology), Population, Skeletal muscle, Biology, biology.organism_classification, Cell biology, Endothelial stem cell, medicine.anatomical_structure, medicine, Satellite (biology), Progenitor cell, Stem cell, Cell activation, education
Abstract

The regenerative capacity of skeletal muscle is due to a population of satellite cells known as satellite stem cells. Owing to their ability to generate both stem cells and committed myogenic progenitors, satellite stem cells allow self-renewal of the satellite cell reservoir and provide myogenic progenitor cells to repair the muscle tissue. Increasing numbers of studies have highlighted the indispensable role of the niche in the regulation of the stem cell functions. The niche maintains the muscle stem cell in a quiescent state but in response to muscle injury, the niche actively generates signals for satellite cell activation, proliferation, and differentiation. The cross talk between the muscle stem cell and its niche is critical and alterations of the niche components result in defective regeneration and muscle pathologies. Here, we describe how the satellite cell niche regulates satellite cell functions, namely commitment and self-renewal, in resting, injured, and pathologic muscle.

Published
2017

20. EGFR-Aurka Signaling Rescues Polarity and Regeneration Defects in Dystrophin-Deficient Muscle Stem Cells by Increasing Asymmetric Divisions

Author

Peter Feige, Yu Xin Wang, Jean-Marc Renaud, Sharlene Faulkes, Nicolas A. Dumont, Bahareh Hekmatnejad, Michael A. Rudnicki, Caroline E. Brun, and Daniel E. Guindon

Subjects
Male, Duchenne muscular dystrophy, Mice, Transgenic, Biology, Article, Dystrophin, Mice, 03 medical and health sciences, 0302 clinical medicine, Mice, Inbred NOD, Genetics, Asymmetric cell division, medicine, Animals, Humans, Regeneration, Mitosis, Cells, Cultured, Aurora Kinase A, 030304 developmental biology, 0303 health sciences, Stem Cells, Regeneration (biology), Cell Polarity, Skeletal muscle, Cell Biology, Muscular Dystrophy, Animal, medicine.disease, Cell biology, ErbB Receptors, HEK293 Cells, medicine.anatomical_structure, Mice, Inbred mdx, biology.protein, Molecular Medicine, Female, Stem cell, Cell Division, 030217 neurology & neurosurgery, Signal Transduction
Abstract

Summary Loss of dystrophin expression in Duchenne muscular dystrophy (DMD) causes progressive degeneration of skeletal muscle, which is exacerbated by reduced self-renewing asymmetric divisions of muscle satellite cells. This, in turn, affects the production of myogenic precursors and impairs regeneration and suggests that increasing such divisions may be beneficial. Here, through a small-molecule screen, we identified epidermal growth factor receptor (EGFR) and Aurora kinase A (Aurka) as regulators of asymmetric satellite cell divisions. Inhibiting EGFR causes a substantial shift from asymmetric to symmetric division modes, whereas EGF treatment increases asymmetric divisions. EGFR activation acts through Aurka to orient mitotic centrosomes, and inhibiting Aurka blocks EGF stimulation-induced asymmetric division. In vivo EGF treatment markedly activates asymmetric divisions of dystrophin-deficient satellite cells in mdx mice, increasing progenitor numbers, enhancing regeneration, and restoring muscle strength. Therefore, activating an EGFR-dependent polarity pathway promotes functional rescue of dystrophin-deficient satellite cells and enhances muscle force generation.

Published
2019

21. GDF11 and the Mythical Fountain of Youth

Author

Michael A. Rudnicki and Caroline E. Brun

Subjects
medicine.medical_specialty, Myogenesis, Physiology, Regeneration (biology), Skeletal muscle, Cell Biology, Biology, Article, Growth Differentiation Factors, medicine.anatomical_structure, Endocrinology, Internal medicine, GDF11, Bone Morphogenetic Proteins, medicine, Animals, Humans, Regeneration, Stem cell, Muscle, Skeletal, Neuroscience, Inhibitory effect, Molecular Biology
Abstract

Age-related frailty may be due to decreased skeletal muscle regeneration. The role of TGF-β molecules myostatin and GDF11 in regeneration is unclear. Recent studies showed an age-related decrease in GDF11 and that GDF11 treatment improves muscle regeneration, which were contrary to prior studies. We now show that these recent claims are not reproducible and the reagents previously used to detect GDF11 are not GDF11 specific. We develop a GDF11-specific immunoassay and show a trend toward increased GDF11 levels in sera of aged rats and humans. GDF11 mRNA increases in rat muscle with age. Mechanistically, GDF11 and myostatin both induce SMAD2/3 phosphorylation, inhibit myoblast differentiation, and regulate identical downstream signaling. GDF11 significantly inhibited muscle regeneration and decreased satellite cell expansion in mice. Given early data in humans showing a trend for an age-related increase, GDF11 could be a target for pharmacologic blockade to treat age-related sarcopenia.

Published
2015
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23. Concise Review: Epigenetic Regulation of Myogenesis in Health and Disease

Author

Marie-Claude Sincennes, Michael A. Rudnicki, and Caroline E. Brun

Subjects
0301 basic medicine, Epigenetic regulation of neurogenesis, Satellite Cells, Skeletal Muscle, Cellular differentiation, Skeletal muscle, Biology, Muscle Development, Chromatin remodeling, Histone Deacetylases, Epigenesis, Genetic, 03 medical and health sciences, Regeneration, Cell Lineage, Cancer epigenetics, Muscle, Skeletal, Cell Proliferation, Genetics, Histone deacetylase 5, Histone deacetylase inhibitor, Myogenesis, Histone marks, Gene Expression Regulation, Developmental, PAX7 Transcription Factor, Epigenetic, Cell Differentiation, Cell Biology, General Medicine, Tissue-Specific Progenitor and Stem Cells, Muscular dystrophy, Pax7, Chromatin, Cell biology, 030104 developmental biology, Organ Specificity, Differentiation, Histone deacetylase, Gene expression, MyoD, Satellite cell, Transcription, Developmental Biology
Abstract

This review describes the recent findings on epigenetic regulation in satellite stem cells and committed myoblasts. It also addresses the potential of epigenetic drugs, such as histone deacetylase inhibitors, and their molecular mechanism of action in muscle cells., Skeletal muscle regeneration is initiated by satellite cells, a population of adult stem cells that reside in the muscle tissue. The ability of satellite cells to self-renew and to differentiate into the muscle lineage is under transcriptional and epigenetic control. Satellite cells are characterized by an open and permissive chromatin state. The transcription factor Pax7 is necessary for satellite cell function. Pax7 is a nodal factor regulating the expression of genes associated with satellite cell growth and proliferation, while preventing differentiation. Pax7 recruits chromatin modifiers to DNA to induce expression of specific target genes involved in myogenic commitment following asymmetric division of muscle stem cells. Emerging evidence suggests that replacement of canonical histones with histone variants is an important regulatory mechanism controlling the ability of satellite cells and myoblasts to differentiate. Differentiation into the muscle lineage is associated with a global gene repression characterized by a decrease in histone acetylation with an increase in repressive histone marks. However, genes important for differentiation are upregulated by the specific action of histone acetyltransferases and other chromatin modifiers, in combination with several transcription factors, including MyoD and Mef2. Treatment with histone deacetylase (HDAC) inhibitors enhances muscle regeneration and is considered as a therapeutic approach in the treatment of muscular dystrophy. This review describes the recent findings on epigenetic regulation in satellite stem cells and committed myoblasts. The potential of epigenetic drugs, such as HDAC inhibitors, as well as their molecular mechanism of action in muscle cells, will be addressed. Significance This review summarizes recent findings concerning the epigenetic regulation of satellite cells in skeletal muscle.

Published
2015

24. Dystrophin expression in muscle stem cells regulates their polarity and asymmetric division

Author

Caroline E. Brun, Michael A. Rudnicki, Alessandra Pasut, C. Florian Bentzinger, Yu Xin Wang, Nicolas A. Dumont, and Julia von Maltzahn

Subjects
musculoskeletal diseases, Satellite Cells, Skeletal Muscle, Duchenne muscular dystrophy, Cell Cycle Proteins, Cell Separation, Spindle Apparatus, Protein Serine-Threonine Kinases, General Biochemistry, Genetics and Molecular Biology, Dystrophin, Utrophin, Cell polarity, medicine, Asymmetric cell division, Myocyte, Animals, Regeneration, Muscle, Skeletal, Cell Proliferation, Oligonucleotide Array Sequence Analysis, biology, Cell growth, Stem Cells, Asymmetric Cell Division, Skeletal muscle, Cell Polarity, General Medicine, medicine.disease, Flow Cytometry, Molecular biology, medicine.anatomical_structure, biology.protein, Mice, Inbred mdx, Protein Binding
Abstract

Dystrophin is expressed in differentiated myofibers, in which it is required for sarcolemmal integrity, and loss-of-function mutations in the gene that encodes it result in Duchenne muscular dystrophy (DMD), a disease characterized by progressive and severe skeletal muscle degeneration. Here we found that dystrophin is also highly expressed in activated muscle stem cells (also known as satellite cells), in which it associates with the serine-threonine kinase Mark2 (also known as Par1b), an important regulator of cell polarity. In the absence of dystrophin, expression of Mark2 protein is downregulated, resulting in the inability to localize the cell polarity regulator Pard3 to the opposite side of the cell. Consequently, the number of asymmetric divisions is strikingly reduced in dystrophin-deficient satellite cells, which also display a loss of polarity, abnormal division patterns (including centrosome amplification), impaired mitotic spindle orientation and prolonged cell divisions. Altogether, these intrinsic defects strongly reduce the generation of myogenic progenitors that are needed for proper muscle regeneration. Therefore, we conclude that dystrophin has an essential role in the regulation of satellite cell polarity and asymmetric division. Our findings indicate that muscle wasting in DMD not only is caused by myofiber fragility, but also is exacerbated by impaired regeneration owing to intrinsic satellite cell dysfunction.

Published
2015

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