cAMP signaling in skeletal muscle adaptation: hypertrophy, metabolism, and regeneration

Berdeaux, Rebecca; Stewart, Randi

doi:10.1152/ajpendo.00555.2011

Cited by 148 publications

(130 citation statements)

References 254 publications

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“…This would allow cells to rapidly return to a resting state after the cAMP signal decays. In vivo, exercise or activation of the "fight-or-flight response" causes catecholamine release from the adrenal medulla, resulting in cAMP accumulation in skeletal muscle and other tissues (5). We hypothesize that in this setting if muscle precursor cells responded with induction of Sik1, the protein would be rapidly degraded.…”

Section: Discussionmentioning

confidence: 99%

“…M yoblast differentiation is driven by a transcriptional cascade that is subject to precise temporal control during development as well as after acute muscle injury (1). The second messenger cAMP and its primary effector PKA are known to contribute to myoblast proliferation in the developing dermomyotome (2), to promote migration and fusion of muscle precursor cells (3,4), and to exert potent anabolic effects on adult skeletal muscle (5). During differentiation of myoblasts ex vivo, intracellular cAMP peaks transiently before cell-cell fusion (6,7), and PKA signaling is required for expression of differentiation markers in cultured myoblasts (8) and in mouse embryos (2).…”

mentioning

confidence: 99%

“…The mechanisms by which a transient peak of cAMP promotes myoblast differentiation are still poorly understood. Because ligands that induce cAMP production promote muscle regeneration (5), it is important to identify promyogenic cAMP signaling effectors.…”

mentioning

confidence: 99%

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Regulation of SIK1 abundance and stability is critical for myogenesis

Stewart¹,

Akhmedov²,

Robb³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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cAMP signaling can both promote and inhibit myogenic differentiation, but little is known about the mechanisms mediating promyogenic effects of cAMP. We previously demonstrated that the cAMP response element-binding protein (CREB) transcriptional target salt-inducible kinase 1 (SIK1) promotes MEF2 activity in myocytes via phosphorylation of class II histone deacetylase proteins (HDACs). However, it was unknown whether SIK1 couples cAMP signaling to the HDAC-MEF2 pathway during myogenesis and how this response could specifically occur in differentiating muscle cells. To address these questions, we explored SIK1 regulation and function in muscle precursor cells before and during myogenic differentiation. We found that in primary myogenic progenitor cells exposed to cAMP-inducing agents, Sik1 transcription is induced, but the protein is rapidly degraded by the proteasome. By contrast, sustained cAMP signaling extends the half-life of SIK1 in part by phosphorylation of Thr475, a previously uncharacterized site that we show can be phosphorylated by PKA in cell-free assays. We also identified a functional PEST domain near Thr475 that contributes to SIK1 degradation. During differentiation of primary myogenic progenitor cells, when PKA activity has been shown to increase, we observe elevated Sik1 transcripts as well as marked accumulation and stabilization of SIK1 protein. Depletion of Sik1 in primary muscle precursor cells profoundly impairs MEF2 protein accumulation and myogenic differentiation. Our findings support an emerging model in which SIK1 integrates cAMP signaling with the myogenic program to support appropriate timing of differentiation. M yoblast differentiation is driven by a transcriptional cascade that is subject to precise temporal control during development as well as after acute muscle injury (1). The second messenger cAMP and its primary effector PKA are known to contribute to myoblast proliferation in the developing dermomyotome (2), to promote migration and fusion of muscle precursor cells (3, 4), and to exert potent anabolic effects on adult skeletal muscle (5). During differentiation of myoblasts ex vivo, intracellular cAMP peaks transiently before cell-cell fusion (6, 7), and PKA signaling is required for expression of differentiation markers in cultured myoblasts (8) and in mouse embryos (2). However, sustained cAMP-PKA signaling prevents myogenic differentiation, in part through inhibition of basic helix-loop-helix and MADS transcription factors (9-11). The mechanisms by which a transient peak of cAMP promotes myoblast differentiation are still poorly understood. Because ligands that induce cAMP production promote muscle regeneration (5), it is important to identify promyogenic cAMP signaling effectors.The transcription factor CREB (cAMP response elementbinding protein) is a key effector of cAMP-PKA in many cell types (12). CREB phosphorylation is induced during early stages of vertebrate myogenesis (2, 13), and CREB activity is required in mice for dermomyotome development (2). We previously...

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Section: Discussionmentioning

confidence: 99%

mentioning

confidence: 99%

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Regulation of SIK1 abundance and stability is critical for myogenesis

Stewart¹,

Akhmedov²,

Robb³

et al. 2012

Proc. Natl. Acad. Sci. U.S.A.

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“…Signals via cAMP/PKA pathway control the development (Chen et al 2005a, Knight & Kothary 2011) and metabolism (Berdeaux & Stewart 2012) of skeletal muscle, which plays an essential role in the regulation of glucose homeostasis (Stump et al 2006). As mentioned above, liver and skeletal muscle are the major sites for glycogen storage.…”

Section: Camp/pka In Skeletal Musclementioning

confidence: 99%

Targeting cAMP/PKA pathway for glycemic control and type 2 diabetes therapy

Yang

2016

Journal of Molecular Endocrinology

141

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In mammals, cyclic adenosine monophosphate (cAMP) is an intracellular second messenger that is usually elicited by binding of hormones and neurotransmitters to G protein-coupled receptors (GPCRs). cAMP exerts many of its physiological effects by activating cAMPdependent protein kinase (PKA), which in turn phosphorylates and regulates the functions of downstream protein targets including ion channels, enzymes, and transcription factors. cAMP/PKA signaling pathway regulates glucose homeostasis at multiple levels including insulin and glucagon secretion, glucose uptake, glycogen synthesis and breakdown, gluconeogenesis, and neural control of glucose homeostasis. This review summarizes recent genetic and pharmacological studies concerning the regulation of glucose homeostasis by cAMP/PKA in pancreas, liver, skeletal muscle, adipose tissues, and brain. We also discuss the strategies for targeting cAMP/PKA pathway for research and potential therapeutic treatment of type 2 diabetes mellitus (T2D).

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“…As a consequence of its muscle anabolic properties, CB might have therapeutic potential for the treatment of muscle wasting associated with sarcopenia, cancer cachexia, sepsis, denervation, disuse, inactivity, unloading, microgravity, or heart failure, although it is necessary to obviate cardiovascular side-effects (4). The b 2 -adrenergic signaling pathways responsible for CB-induced hypertrophy have been well studied, often with the aim of identifying novel therapeutic targets for the treatment of muscle-wasting disorders, and it appears that b 2 -AR stimulation with CB can increase protein synthesis and inhibit protein degradation through activation of the Akt and/or protein kinase A signaling pathways (4,7). Adult skeletal muscle is composed of muscle fibers that differ in their speed of contraction and predominant type of energy metabolism.…”

Section: Introductionmentioning

confidence: 99%

Role of Masseter Muscle β2-Adrenergic Signaling in Regulation of Muscle Activity, Myosin Heavy Chain Transition, and Hypertrophy

et al. 2013

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Abstract. Chronic administration of clenbuterol (CB), a lipophilic b 2 -adrenoceptor (b 2 -AR) agonist, induces skeletal muscle hypertrophy and slow-to-fast fiber-type transitions in mammalian species, but the mechanism and pathophysiological roles of these changes have not been explored. Here, we examined the effects of CB not only on masseter muscle mass, fiber diameter, and myosin heavy chain (MHC) composition, but also on daily muscle activity, a factor influencing muscle phenotype, by means of electromyogram analysis in rats. MHC transition towards faster isoforms was induced by 2-week CB treatment. In addition, daily duty time was increased at 1 day, 1 week, and 2 weeks after the start of CB treatment and its increase was greater at high activity level (6-fold) than at low activity level (2-fold). In order to examine whether these effects of CB were mediated through muscle or CNS b 2 -AR stimulation, we compared these effects of CB with those of salbutamol (SB), a hydrophilic b 2 -AR agonist. SB treatment induced masseter hypertrophy and MHC transition, like CB, but did not increase daily activity. These results suggest that CB-mediated slow-to-fast MHC transition with hypertrophy was induced through direct muscle b 2 -AR stimulation, but the increase of daily duty time was mediated through the CNS.

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cAMP signaling in skeletal muscle adaptation: hypertrophy, metabolism, and regeneration

Cited by 148 publications

References 254 publications

Regulation of SIK1 abundance and stability is critical for myogenesis

Regulation of SIK1 abundance and stability is critical for myogenesis

Targeting cAMP/PKA pathway for glycemic control and type 2 diabetes therapy

Role of Masseter Muscle β2-Adrenergic Signaling in Regulation of Muscle Activity, Myosin Heavy Chain Transition, and Hypertrophy

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