Multiple types of skeletal muscle atrophy involve a common program of changes in gene expression

Lecker, Stewart H.; Jagoe, R. Thomas; Gilbert, Alexander D.; Gomes, Marcelo D.; Baracos, Vickie E.; Bailey, James L.; Price, S. Russ; Mitch, William E.; Goldberg, Alfred L.

doi:10.1096/fj.03-0610com

Cited by 1,351 publications

(1,489 citation statements)

References 88 publications

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“…Furthermore, we found that all three TGFbs are fibrogenic and placed P311 as a stimulator of fibrosis acting immediately upstream of TGF-b1 to -b3. Because P311 expression is up-regulated or down-regulated by hormones, 52 retinoic acid, 53 growth factors, 54 and mechanical tension, 4 and because P311 has proven to be decreased in muscular atrophy 55,56 and pulmonary emphysema, 6 it is likely that in pathologic conditions with decreased P311 expression scar formation will be affected in ways similar to those presented in this study, leading thereby to a higher risk of dehiscence.…”

Section: Resultssupporting

confidence: 51%

Neuronal Protein 3.1 Deficiency Leads to Reduced Cutaneous Scar Collagen Deposition and Tensile Strength due to Impaired Transforming Growth Factor-β1 to -β3 Translation

Cheng

Yue

Aslam

et al. 2017

The American Journal of Pathology

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Neuronal protein 3.1 (P311), a conserved RNA-binding protein, represents the first documented protein known to stimulate transforming growth factor (TGF)-b1 to -b3 translation in vitro and in vivo. Because TGF-bs play critical roles in fibrogenesis, we initiated efforts to define the role of P311 in skin scar formation. Here, we show that P311 is up-regulated in skin wounds and in normal and hypertrophic scars. Genetic ablation of p311 resulted in a significant decrease in skin scar collagen deposition. Lentiviral transfer of P311 corrected the deficits, whereas down-regulation of P311 levels by lentiviral RNA interference reproduced the deficits seen in P311 À/À mice. The decrease in collagen deposition resulted in scars with reduced stiffness but also reduced scar tensile strength. In vitro studies using murine and human dermal fibroblasts showed that P311 stimulated TGF-b1 to -b3 translation, a process that involved eukaryotic translation initiation factor 3 subunit b as a P311 binding partner. This resulted in increased TGF-b levels/activity and increased collagen production. In addition, P311 induced dermal fibroblast activation and proliferation. Finally, exogenous TGF-b1 to -b3, each restituted the normal scar phenotype. These studies demonstrate that P311 is required for the production of normal cutaneous scars and place P311 immediately up-stream of TGF-bs in the process of fibrogenesis. Conditions that decrease P311 levels could result in less tensile scars, which could potentially lead to higher incidence of dehiscence after surgery. (Am J Pathol 2017, 187: 292e303; http://dx

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Section: Resultssupporting

confidence: 51%

Neuronal Protein 3.1 Deficiency Leads to Reduced Cutaneous Scar Collagen Deposition and Tensile Strength due to Impaired Transforming Growth Factor-β1 to -β3 Translation

Cheng

Yue

Aslam

et al. 2017

The American Journal of Pathology

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“…Skeletal muscle atrophy could be due to reduced protein synthesis and/or increased protein catabolism due to targeted ubiquitination of muscle-specific proteins. Two muscle-specific E3 ligases, Atrogin1 and MuRF1, are up-regulated in skeletal muscle tissue in response to numerous atrophic signals [31][32][33]. Western blot analysis confirmed that there is increased ubiquitination of intracellular proteins in skeletal muscle tis-…”

Section: Muscle Atrophy Seen In Smad3-null Muscles Could Be Due To Inmentioning

confidence: 81%

Smad3 signaling is required for satellite cell function and myogenic differentiation of myoblasts

McFarlane

Vajjala

et al. 2011

Cell Res

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TGF-β and myostatin are the two most important regulators of muscle growth. Both growth factors have been shown to signal through a Smad3-dependent pathway. However to date, the role of Smad3 in muscle growth and differentiation is not investigated. Here, we demonstrate that Smad3-null mice have decreased muscle mass and pronounced skeletal muscle atrophy. Consistent with this, we also find increased protein ubiquitination and elevated levels of the ubiquitin E3 ligase MuRF1 in muscle tissue isolated from Smad3-null mice. Loss of Smad3 also led to defective satellite cell (SC) functionality. Smad3-null SCs showed reduced propensity for self-renewal, which may lead to a progressive loss of SC number. Indeed, decreased SC number was observed in skeletal muscle from Smad3-null mice showing signs of severe muscle wasting. Further in vitro analysis of primary myoblast cultures identified that Smad3-null myoblasts exhibit impaired proliferation, differentiation and fusion, resulting in the formation of atrophied myotubes. A search for the molecular mechanism revealed that loss of Smad3 results in increased myostatin expression in Smad3-null muscle and myoblasts. Given that myostatin is a negative regulator, we hypothesize that increased myostatin levels are responsible for the atrophic phenotype in Smad3-null mice. Consistent with this theory, inactivation of myostatin in Smad3-null mice rescues the muscle atrophy phenotype.

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“…E3 ligases, of which hundreds have been identified, confer substrate specificity (Glass, 2003a). During muscle atrophy, many of the genes encoding the Ub-proteasome pathway are upregulated , including E2 (such as E2 14K and UbcH2) and E3 (such as E3a / UBr1) genes (Li et al, 2003;Lecker et al, 2004). In particular, two E3 ubiquitin ligases, MuRF1 (muscle ring finger 1) and MAFbx (muscle atrophy F-box or atrogin-1) have been identified as mediators of muscle atrophy (Bodine et al, 2001a;Dehoux et al, 2003).…”

Section: Fibre Types: Coordinated Isoform-specific Expressionmentioning

confidence: 99%

Key signalling factors and pathways in the molecular determination of skeletal muscle phenotype

Chang

2007

Animal

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The molecular basis and control of the biochemical and biophysical properties of skeletal muscle, regarded as muscle phenotype, are examined in terms of fibre number, fibre size and fibre types. A host of external factors or stimuli, such as ligand binding and contractile activity, are transduced in muscle into signalling pathways that lead to protein modifications and changes in gene expression which ultimately result in the establishment of the specified phenotype. In skeletal muscle, the key signalling cascades include the Ras-extracellular signal regulated kinase-mitogen activated protein kinase (Erk-MAPK), the phosphatidylinositol 3 0 -kinase (PI3K)-Akt1, p38 MAPK, and calcineurin pathways. The molecular effects of external factors on these pathways revealed complex interactions and functional overlap. A major challenge in the manipulation of muscle of farm animals lies in the identification of regulatory and target genes that could effect defined and desirable changes in muscle quality and quantity. To this end, recent advances in functional genomics that involve the use of micro-array technology and proteomics are increasingly breaking new ground in furthering our understanding of the molecular determinants of muscle phenotype.

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Multiple types of skeletal muscle atrophy involve a common program of changes in gene expression

Cited by 1,351 publications

References 88 publications

Neuronal Protein 3.1 Deficiency Leads to Reduced Cutaneous Scar Collagen Deposition and Tensile Strength due to Impaired Transforming Growth Factor-β1 to -β3 Translation

Neuronal Protein 3.1 Deficiency Leads to Reduced Cutaneous Scar Collagen Deposition and Tensile Strength due to Impaired Transforming Growth Factor-β1 to -β3 Translation

Smad3 signaling is required for satellite cell function and myogenic differentiation of myoblasts

Key signalling factors and pathways in the molecular determination of skeletal muscle phenotype

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