scholarly journals Protein arginine methyltransferase expression and activity during myogenesis

2018 ◽  
Vol 38 (1) ◽  
Author(s):  
Nicole Y. Shen ◽  
Sean Y. Ng ◽  
Stephen L. Toepp ◽  
Vladimir Ljubicic
Keyword(s):  
Skeletal Muscle ◽  
Muscle Development ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
Type I ◽  
Protein Arginine Methyltransferases ◽  
Methyl Donors ◽  
Muscle Plasticity ◽  
Expression And Activity

Despite the emerging importance of protein arginine methyltransferases (PRMTs) in regulating skeletal muscle plasticity, PRMT biology during muscle development is complex and not completely understood. Therefore, our purpose was to investigate PRMT1, -4, and -5 expression and function in skeletal muscle cells during the phenotypic remodeling elicited by myogenesis. C2C12 muscle cell maturation, assessed during the myoblast (MB) stage, and during days 1, 3, 5, and 7 of differentiation, was employed as an in vitro model of myogenesis. We observed PRMT-specific patterns of expression and activity during myogenesis. PRMT4 and -5 gene expression was unchanged, while PRMT1 mRNA and protein content were significantly induced. Cellular monomethylarginines (MMAs) and symmetric dimethylarginines (SDMAs), indicative of global and type II PRMT activities, respectively, remained steady during development, while type I PRMT activity indicator asymmetric dimethylarginines (ADMAs) increased through myogenesis. Histone 4 arginine 3 (H4R3) and H3R17 contents were elevated coincident with the myonuclear accumulation of PRMT1 and -4. Collectively, this suggests that PRMTs are methyl donors throughout myogenesis and demonstrate specificity for their protein targets. Cells were then treated with TC-E 5003 (TC-E), a selective inhibitor of PRMT1 in order to specifically examine the enzymes role during myogenic differentiation. TC-E treated cells exhibited decrements in muscle differentiation, which were consistent with attenuated mitochondrial biogenesis and respiratory function. In summary, the present study increases our understanding of PRMT1, -4, and -5 biology during the plasticity of skeletal muscle development. Our results provide evidence for a role of PRMT1, via a mitochondrially mediated mechanism, in driving the muscle differentiation program.

scholarly journals The SMYD3 methyltransferase promotes myogenesis by activating the myogenin regulatory network

2019 ◽  
Vol 9 (1) ◽  
Author(s):  
Roberta Codato ◽  
Martine Perichon ◽  
Arnaud Divol ◽  
Ella Fung ◽  
Athanassia Sotiropoulos ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Development ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
Skeletal Muscle Differentiation ◽  
Skeletal Muscle Development ◽  
Genome Wide ◽  
Coordinated Expression

AbstractThe coordinated expression of myogenic regulatory factors, including MyoD and myogenin, orchestrates the steps of skeletal muscle development, from myoblast proliferation and cell-cycle exit, to myoblast fusion and myotubes maturation. Yet, it remains unclear how key transcription factors and epigenetic enzymes cooperate to guide myogenic differentiation. Proteins of the SMYD (SET and MYND domain-containing) methyltransferase family participate in cardiac and skeletal myogenesis during development in zebrafish, Drosophila and mice. Here, we show that the mammalian SMYD3 methyltransferase coordinates skeletal muscle differentiation in vitro. Overexpression of SMYD3 in myoblasts promoted muscle differentiation and myoblasts fusion. Conversely, silencing of endogenous SMYD3 or its pharmacological inhibition impaired muscle differentiation. Genome-wide transcriptomic analysis of murine myoblasts, with silenced or overexpressed SMYD3, revealed that SMYD3 impacts skeletal muscle differentiation by targeting the key muscle regulatory factor myogenin. The role of SMYD3 in the regulation of skeletal muscle differentiation and myotube formation, partially via the myogenin transcriptional network, highlights the importance of methyltransferases in mammalian myogenesis.

scholarly journals The SMYD3 methyltransferase promotes myogenesis by activating the myogenin regulatory network

2019 ◽  
Author(s):  
Roberta Codato ◽  
Martine Perichon ◽  
Arnaud Divol ◽  
Ella Fung ◽  
Athanassia Sotiropoulos ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Development ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
Skeletal Muscle Differentiation ◽  
Skeletal Muscle Development ◽  
Genome Wide ◽  
Coordinated Expression

ABSTRACTThe coordinated expression of myogenic regulatory factors, including MyoD and myogenin, orchestrates the steps of skeletal muscle development, from myoblast proliferation and cell-cycle exit, to myoblast fusion and myotubes maturation. Yet, it remains unclear how key transcription factors and epigenetic enzymes cooperate to guide myogenic differentiation. Proteins of the SMYD (SET and MYND domain-containing) methyltransferase family participate in cardiac and skeletal myogenesis during development in zebrafish, Drosophila and mice. Here, we show that the mammalian SMYD3 methyltransferase coordinates skeletal muscle differentiation in vitro. Overexpression of SMYD3 in myoblasts promoted muscle differentiation and myoblasts fusion. Conversely, silencing of endogenous SMYD3 or its pharmacological inhibition impaired muscle differentiation. Genome-wide transcriptomic analysis of murine myoblasts, with silenced or overexpressed SMYD3, revealed that SMYD3 impacts skeletal muscle differentiation by targeting the key muscle regulatory factor myogenin. The role of SMYD3 in the regulation of skeletal muscle differentiation and myotube formation, partially via the myogenin transcriptional network, highlights the importance of methyltransferases in mammalian myogenesis.

Eph/Ephrin signalling in skeletal muscle development and regeneration

2014 ◽  
Author(s):  
◽  
Danny A. Stark
Keyword(s):  
Skeletal Muscle ◽  
Satellite Cells ◽  
Tyrosine Kinases ◽  
Muscle Development ◽  
Receptor Tyrosine Kinases ◽  
Repulsive Interaction ◽  
Type I ◽  
Ephrin Ligands

[ACCESS RESTRICTED TO THE UNIVERSITY OF MISSOURI AT AUTHOR'S REQUEST.] Skeletal muscle can be isolated into 642 individual muscles and makes up to one third to one half of the mass of the human body. Each of these muscles is specified and patterned prenatally and after birth they will increase in size and take on characteristics suited to each muscle's unique function. To make the muscles functional, each muscle cell must be innervated by a motor neuron, which will also affect the characteristics of the mature muscle. In a healthy adult, muscles will maintain their specialized pattern and function during physiological homeostasis, and will also recapitulate them if the integrity or health of the muscle is disrupted. This repair and regeneration is dependent satellite cells, the skeletal muscle stem cells. In this dissertation, we study a family of receptor tyrosine kinases, Ephs, and their juxtacrine ephrin ligands in the context of skeletal muscle specification and regeneration. First, using a classical ephrin 'stripe' assay to test for contact-mediated repulsion, we found that satellite cells respond to a subset of ephrins with repulsive motility in vitro and that these forward signals through Ephs also promote patterning of differentiating myotubes parallel to ephrin stripes. This pattering can be replicated in a heterologous in vivo system (the hindbrain of the developing quail, where neural crest cells migrate in streams to the branchial arches, and in the forelimb of the developing quail, where presumptive limb myoblasts emigrate from the somite). Second, we present evidence that specific pairwise interactions between Eph receptor tyrosine kinases and ephrin ligands are required to ensure appropriate muscle innervation when it is originally set during postnatal development and when it is recapitulated after muscle or nerve trauma during adulthood. We show expression of a single ephrin, ephrin-A3, exclusively on type I (slow) myofibers shortly after birth, while its receptor EphA8 is only localized to fast motor endplates, suggesting a functional repulsive interaction for motor axon guidance and/or synaptogenesis. Adult EFNA3-/- mutant mice show a significant loss of slow myofibers, while misexpression of ephrin-A3 on fast myofibers results in a switch from a fast fiber type to slow in the context of sciatic nerve injury and regrowth. Third, we show that EphA7 is expressed on satellite cell derived myocytes in vitro, and marks both myocytes and regenerating myofibers in vivo. In the EPHA7 knockout mouse, we find a regeneration defect in a barium chloride injury model starting 3 days post injection in vivo, and that cultured mutant satellite cells are slow to differentiate and divide. Finally, we present other potential Ephs and ephrins that may affect skeletal muscle, such as EphB1 that is expressed on all MyHC-IIb fibers and a subset of MyHC-IIx fibers, and we show a multitude of Ephs and ephrins at the neuromuscular junction that appear to localize on specific myofibers and at different areas of the synapse. We propose that Eph/ephrin signaling, though well studied in development, continues to be important in regulating post natal development, regeneration, and homeostasis of skeletal muscle.

scholarly journals 6-Bromoindirubin-3′-oxime intercepts GSK3 signaling to promote and enhance skeletal muscle differentiation affecting miR-206 expression in mice

2019 ◽  
Vol 9 (1) ◽  
Author(s):  
Elvira Ragozzino ◽  
Mariarita Brancaccio ◽  
Antonella Di Costanzo ◽  
Francesco Scalabrì ◽  
Gennaro Andolfi ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
C2c12 Cells ◽  
Skeletal Muscle Differentiation ◽  
Myoblast Proliferation ◽  
Enhanced Expression ◽  
Pharmacologically Active

AbstractDystrophies are characterized by progressive skeletal muscle degeneration and weakness as consequence of their molecular abnormalities. Thus, new drugs for restoring skeletal muscle deterioration are critically needed. To identify new and alternative compounds with a functional role in skeletal muscle myogenesis, we screened a library of pharmacologically active compounds and selected the small molecule 6-bromoindirubin-3′-oxime (BIO) as an inhibitor of myoblast proliferation. Using C2C12 cells, we examined BIO’s effect during myoblast proliferation and differentiation showing that BIO treatment promotes transition from cell proliferation to myogenic differentiation through the arrest of cell cycle. Here, we show that BIO is able to promote myogenic differentiation in damaged myotubes in-vitro by enriching the population of newly formed skeletal muscle myotubes. Moreover, in-vivo experiments in CTX-damaged TA muscle confirmed the pro-differentiation capability of BIO as shown by the increasing of the percentage of myofibers with centralized nuclei as well as by the increasing of myofibers number. Additionally, we have identified a strong correlation of miR-206 with BIO treatment both in-vitro and in-vivo: the enhanced expression of miR-206 was observed in-vitro in BIO-treated proliferating myoblasts, miR-206 restored expression was observed in a forced miR-206 silencing conditions antagomiR-mediated upon BIO treatment, and in-vivo in CTX-injured muscles miR-206 enhanced expression was observed upon BIO treatment. Taken together, our results highlight the capacity of BIO to act as a positive modulator of skeletal muscle differentiation in-vitro and in-vivo opening up a new perspective for novel therapeutic targets to correct skeletal muscle defects.

scholarly journals Muscle LIM Proteins Are Associated with Muscle Sarcomeres and Require dMEF2 for Their Expression during DrosophilaMyogenesis

1999 ◽  
Vol 10 (7) ◽  
pp. 2329-2342 ◽  
Author(s):  
Beth E. Stronach ◽  
Patricia J. Renfranz ◽  
Brenda Lilly ◽  
Mary C. Beckerle
Keyword(s):  
Muscle Development ◽  
Target Genes ◽  
Striated Muscle ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
Epistasis Analysis ◽  
Lim Proteins ◽  
Muscle Lim Proteins ◽  
Genetic Hierarchy

A genetic hierarchy of interactions, involving myogenic regulatory factors of the MyoD and myocyte enhancer-binding 2 (MEF2) families, serves to elaborate and maintain the differentiated muscle phenotype through transcriptional regulation of muscle-specific target genes. Much work suggests that members of the cysteine-rich protein (CRP) family of LIM domain proteins also play a role in muscle differentiation; however, the specific functions of CRPs in this process remain undefined. Previously, we characterized two members of the Drosophila CRP family, the muscle LIM proteins Mlp60A and Mlp84B, which show restricted expression in differentiating muscle lineages. To extend our analysis ofDrosophila Mlps, we characterized the expression of Mlps in mutant backgrounds that disrupt specific aspects of muscle development. We show a genetic requirement for the transcription factor dMEF2 in regulating Mlp expression and an ability of dMEF2 to bind, in vitro, to consensus MEF2 sites derived from those present inMlp genomic sequences. These data suggest that theMlp genes may be direct targets of dMEF2 within the genetic hierarchy controlling muscle differentiation. Mutations that disrupt myoblast fusion fail to affect Mlp expression. In later stages of myogenic differentiation, which are dedicated primarily to assembly of the contractile apparatus, we analyzed the subcellular distribution of Mlp84B in detail. Immunofluorescent studies revealed the localization of Mlp84B to muscle attachment sites and the periphery of Z-bands of striated muscle. Analysis of mutations that affect expression of integrins and α-actinin, key components of these structures, also failed to perturb Mlp84B distribution. In conclusion, we have used molecular epistasis analysis to position Mlp function downstream of events involving mesoderm specification and patterning and concomitant with terminal muscle differentiation. Furthermore, our results are consistent with a structural role for Mlps as components of muscle cytoarchitecture.

scholarly journals KDM4A regulates myogenesis by demethylating H3K9me3 of myogenic regulatory factors

2021 ◽  
Vol 12 (6) ◽  
Author(s):  
Qi Zhu ◽  
Feng Liang ◽  
Shufang Cai ◽  
Xiaorong Luo ◽  
Tianqi Duo ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Cell Proliferation ◽  
Satellite Cells ◽  
Muscle Development ◽  
Kinase Inhibitor ◽  
Myogenic Differentiation ◽  
Myoblast Differentiation ◽  
Proliferation And Differentiation ◽  
H3k9me3 Level

AbstractHistone lysine demethylase 4A (KDM4A) plays a crucial role in regulating cell proliferation, cell differentiation, development and tumorigenesis. However, little is known about the function of KDM4A in muscle development and regeneration. Here, we found that the conditional ablation of KDM4A in skeletal muscle caused impairment of embryonic and postnatal muscle formation. The loss of KDM4A in satellite cells led to defective muscle regeneration and blocked the proliferation and differentiation of satellite cells. Myogenic differentiation and myotube formation in KDM4A-deficient myoblasts were inhibited. Chromatin immunoprecipitation assay revealed that KDM4A promoted myogenesis by removing the histone methylation mark H3K9me3 at MyoD, MyoG and Myf5 locus. Furthermore, inactivation of KDM4A in myoblasts suppressed myoblast differentiation and accelerated H3K9me3 level. Knockdown of KDM4A in vitro reduced myoblast proliferation through enhancing the expression of the cyclin-dependent kinase inhibitor P21 and decreasing the expression of cell cycle regulator Cyclin D1. Together, our findings identify KDM4A as an important regulator for skeletal muscle development and regeneration, orchestrating myogenic cell proliferation and differentiation.

scholarly journals Inositide-Dependent Phospholipase C Signaling Mimics Insulin in Skeletal Muscle Differentiation by Affecting Specific Regions of the Cyclin D3 Promoter

Endocrinology ◽  
2007 ◽  
Vol 148 (3) ◽  
pp. 1108-1117 ◽  
Author(s):  
Irene Faenza ◽  
Giulia Ramazzotti ◽  
Alberto Bavelloni ◽  
Roberta Fiume ◽  
Gian Carlo Gaboardi ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Phospholipase C ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
C2c12 Cells ◽  
Cyclin D3 ◽  
Expression Vectors ◽  
Skeletal Muscle Differentiation ◽  
Small Interfering Rnas

Our main goal in this study was to investigate the role of phospholipase C (PLC) β1 and PLCγ1 in skeletal muscle differentiation and the existence of potential downstream targets of their signaling activity. To examine whether PLC signaling can modulate the expression of cyclin D3, a target of PLCβ1 in erythroleukemia cells, we transfected C2C12 cells with expression vectors containing PLCβ1 or PLCγ1 cDNA and with small interfering RNAs from regions of the PLCβ1 or PLCγ1 gene and followed myogenic differentiation in this well-established cell system. Intriguingly, overexpressed PLCβ1 and PLCγ1 were able to mimic insulin induction of both cyclin D3 and muscle differentiation. By knocking down PLCβ1 or PLCγ1 expression, C2C12 cells almost completely lost the increase in cyclin D3, and the differentiation program was down-regulated. To explore the induction of the cyclin D3 gene promoter during this process, we used a series of 5′-deletions of the 1.68-kb promoter linked to a reporter gene and noted a 5-fold augmentation of promoter activity upon insulin stimulation. These constructs were also cotransfected with PLCβ1 or PLCγ1 cDNAs and small interfering RNAs, respectively. Our data indicate that PLCβ1 or PLCγ1 signaling is capable of acting like insulin in regard to both the myogenic differentiation program and cyclin D3 up-regulation. Taken together, this is the first study that hints at cyclin D3 as a target of PLCβ1 and PLCγ1 during myogenic differentiation in vitro and implies that up-regulation of these enzymes is sufficient to mimic the actions of insulin in this process.

scholarly journals The histone methyltransferase Set7/9 promotes myoblast differentiation and myofibril assembly

2011 ◽  
Vol 194 (4) ◽  
pp. 551-565 ◽  
Author(s):  
Yazhong Tao ◽  
Ronald L. Neppl ◽  
Zhan-Peng Huang ◽  
Jianfu Chen ◽  
Ru-Hang Tang ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Development ◽  
Myogenic Differentiation ◽  
Muscle Differentiation ◽  
Histone Methyltransferase ◽  
Contractile Proteins ◽  
Dominant Negative ◽  
Myoblast Differentiation ◽  
Skeletal Muscle Differentiation ◽  
Muscle Gene Expression

The molecular events that modulate chromatin structure during skeletal muscle differentiation are still poorly understood. We report in this paper that expression of the H3-K4 histone methyltransferase Set7 is increased when myoblasts differentiate into myotubes and is required for skeletal muscle development, expression of muscle contractile proteins, and myofibril assembly. Knockdown of Set7 or expression of a dominant-negative Set7 mutant impairs skeletal muscle differentiation, accompanied by a decrease in levels of histone monomethylation (H3-K4me1). Set7 directly interacts with MyoD to enhance expression of muscle differentiation genes. Expression of myocyte enhancer factor 2 and genes encoding contractile proteins is decreased in Set7 knockdown myocytes. Furthermore, we demonstrate that Set7 also activates muscle gene expression by precluding Suv39h1-mediated H3-K9 methylation on the promoters of myogenic differentiation genes. Together, our experiments define a biological function for Set7 in muscle differentiation and provide a molecular mechanism by which Set7 modulates myogenic transcription factors during muscle differentiation.

scholarly journals EphA7 promotes myogenic differentiation via cell-cell contact

eLife ◽  
2020 ◽  
Vol 9 ◽  
Author(s):  
Laura L Arnold ◽  
Alessandra Cecchini ◽  
Danny A Stark ◽  
Jacqueline Ihnat ◽  
Rebecca N Craigg ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Regeneration ◽  
Muscle Development ◽  
Myogenic Differentiation ◽  
Cell Contact ◽  
Postnatal Life ◽  
Differentiation Markers ◽  
Hindlimb Muscles

The conversion of proliferating skeletal muscle precursors (myoblasts) to terminally-differentiated myocytes is a critical step in skeletal muscle development and repair. We show that EphA7, a juxtacrine signaling receptor, is expressed on myocytes during embryonic and fetal myogenesis and on nascent myofibers during muscle regeneration in vivo. In EphA7-/- mice, hindlimb muscles possess fewer myofibers at birth, and those myofibers are reduced in size and have fewer myonuclei and reduced overall numbers of precursor cells throughout postnatal life. Adult EphA7-/- mice have reduced numbers of satellite cells and exhibit delayed and protracted muscle regeneration, and satellite cell-derived myogenic cells from EphA7-/- mice are delayed in their expression of differentiation markers in vitro. Exogenous EphA7 extracellular domain will rescue the null phenotype in vitro, and will also enhance commitment to differentiation in WT cells. We propose a model in which EphA7 expression on differentiated myocytes promotes commitment of adjacent myoblasts to terminal differentiation.

scholarly journals LMNA Mutations G232E and R482L Cause Dysregulation of Skeletal Muscle Differentiation, Bioenergetics, and Metabolic Gene Expression Profile

Genes ◽  
2020 ◽  
Vol 11 (9) ◽  
pp. 1057
Author(s):  
Elena V. Ignatieva ◽  
Oksana A. Ivanova ◽  
Margarita Y. Komarova ◽  
Natalia V. Khromova ◽  
Dmitrii E. Polev ◽  
...  
Keyword(s):  
Skeletal Muscle ◽  
Muscle Development ◽  
Neuromuscular Disorders ◽  
Control Cell ◽  
Muscle Differentiation ◽  
Mitochondrial Uncoupling ◽  
Partial Lipodystrophy ◽  
Differentiated Cells ◽  
Wide Range

Laminopathies are a family of monogenic multi-system diseases resulting from mutations in the LMNA gene which include a wide range of neuromuscular disorders. Although lamins are expressed in most types of differentiated cells, LMNA mutations selectively affect only specific tissues by mechanisms that remain largely unknown. We have employed the combination of functional in vitro experiments and transcriptome analysis in order to determine how two LMNA mutations associated with different phenotypes affect skeletal muscle development and metabolism. We used a muscle differentiation model based on C2C12 mouse myoblasts genetically modified with lentivirus constructs bearing wild-type human LMNA (WT-LMNA) or R482L-LMNA/G232E-LMNA mutations, linked to familial partial lipodystrophy of the Dunnigan type and muscular dystrophy phenotype accordingly. We have shown that both G232E/R482L-LMNA mutations cause dysregulation in coordination of pathways that control cell cycle dynamics and muscle differentiation. We have also found that R482/G232E-LMNA mutations induce mitochondrial uncoupling and a decrease in glycolytic activity in differentiated myotubes. Both types of alterations may contribute to mutation-induced muscle tissue pathology.

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