Smad2/3 Proteins Are Required for Immobilization-induced Skeletal Muscle Atrophy

Tando, Toshimi; Hirayama, Akiyoshi; Furukawa, Mitsuru; Sato, Yuiko; Kobayashi, Tami; Funayama, Atsushi; Kanaji, Arihiko; Hao, Wu; Watanabe, Ryuichi; Morita, Mayu; Oike, Takatsugu; Miyamoto, Kana; Soga, Tomoyoshi; Nomura, Masatoshi; Yoshimura, Akihiko; Tomita, Masaru; Matsumoto, Morio; Nakamura, Masaya; Toyama, Yoshiaki; Miyamoto, Takeshi

doi:10.1074/jbc.m115.680579

Cited by 51 publications

(47 citation statements)

References 57 publications

(63 reference statements)

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“…Denervation was observed to increase phosphorylation of AMPK␣2 and decrease phosphorylation of FoxO3, whereas ablation of AMPK␣2 protects against wasting and reversed the effect on FoxO3 (32). Another study found that Smad2/3 protein levels but not mRNA levels are increased in denervation independent of myostatin levels and that muscle-specific ablation of Smad2/3 is protective against atrophy (107). During disuse, mitochondrial reactive oxygen species (ROS) production leads to mitochondrial dysfunction and muscle atrophy (71).…”

Section: Tgf-␤mentioning

confidence: 99%

The ubiquitin proteasome system in atrophying skeletal muscle: roles and regulation

Bilodeau

Coyne

Wing

2016

American Journal of Physiology-Cell Physiology

127

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Bilodeau PA, Coyne ES, Wing SS. The ubiquitin proteasome system in atrophying skeletal muscle: roles and regulation. Am J Physiol Cell Physiol 311: C392-C403, 2016. First published August 10, 2016; doi:10.1152/ajpcell.00125.2016.-Muscle atrophy complicates many diseases as well as aging, and its presence predicts both decreased quality of life and survival. Much work has been conducted to define the molecular mechanisms involved in maintaining protein homeostasis in muscle. To date, the ubiquitin proteasome system (UPS) has been shown to play an important role in mediating muscle wasting. In this review, we have collated the enzymes in the UPS whose roles in muscle wasting have been confirmed through loss-of-function studies. We have integrated information on their mechanisms of action to create a model of how they work together to produce muscle atrophy. These enzymes are involved in promoting myofibrillar disassembly and degradation, activation of autophagy, inhibition of myogenesis as well as in modulating the signaling pathways that control these processes. Many anabolic and catabolic signaling pathways are involved in regulating these UPS genes, but none appear to coordinately regulate a large number of these genes. A number of catabolic signaling pathways appear to instead function by inhibition of the insulin/IGF-I/protein kinase B anabolic pathway. This pathway is a critical determinant of muscle mass, since it can suppress key ubiquitin ligases and autophagy, activate protein synthesis, and promote myogenesis through its downstream mediators such as forkhead box O, mammalian target of rapamycin, and GSK3␤, respectively. Although much progress has been made, a more complete inventory of the UPS genes involved in mediating muscle atrophy, their mechanisms of action, and their regulation will be useful for identifying novel therapeutic approaches to this important clinical problem.hormones; muscle atrophy SKELETAL MUSCLE SERVES TWO essential functions, a contractile function for locomotion/maintenance of posture and a metabolic function as the protein reservoir of the body. The myofibers that make up the muscle consist primarily of myofibrillar proteins. The ability of the body to maintain posture or to move arises from the precise organization of myofibrillar proteins into a contractile unit called the sarcomere. The sarcomere consists of thick filaments containing primarily myosin that can slide over thin filaments containing primarily actin. Both types of filaments contain additional regulatory proteins and are linked to the ␣-actinin-containing Z disk, the thin filaments directly so and the thick filaments via titin. Vimentin and desmin are intermediate filaments that serve to anchor sarcomeres properly at the Z disks. These myofibrillar proteins, as well as the sarcoplasmic proteins, also serve as the protein reservoir of the body. Upon fasting, once hepatic glycogen stores are depleted, muscle protein degradation must be activated to provide amino acids to the liver for gluconeogenesis. These amino a...

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Section: Tgf-␤mentioning

confidence: 99%

The ubiquitin proteasome system in atrophying skeletal muscle: roles and regulation

Bilodeau

Coyne

Wing

2016

American Journal of Physiology-Cell Physiology

127

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“…The atrophy is executed mainly by regulated proteolysis of contractile proteins through the proteasome but also autophagy‐lysosomal breakdown of other redundant myofibre constituents occur in parallel . The signalling pathways governing contractile protein breakdown is normally active and balanced by stimuli to increase myosins to enlarge myofibre size and muscle mass . Originating from theory that the DNA of a nucleus can support but a limited cellular volume and that this relationship sets a ceiling for growth (; myonuclear domain, MND), major alteration in fibre size should be accompanied by either a reduction of total number of myonuclei or the recruitment and incorporation of de novo formed myonuclei deriving from the regional stem cell niche, ie, Satellite cell (SC) niche .…”

Section: Introductionmentioning

confidence: 99%

“…We have used the nerve crush model to study the responses to denervation and the following re‐innervation in target hind limb muscles of the Sprague‐Dawley (SD) rat. This model may be useful in exploring details of muscle atrophy in response to denervation but also muscle regeneration because of re‐innervation . Further advantages of this model are that the insult recovery process may be assessed by behavioural testing, and that there is a reliable and high degree of un‐intrusive muscle function recovery across a few weeks owing to that the nerve conduit remains in continuity despite the crush insult ( idem ).…”

Section: Introductionmentioning

confidence: 99%

Muscle atrophy and regeneration associated with behavioural loss and recovery of function after sciatic nerve crush

et al. 2019

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Aim To resolve timing and coordination of denervation atrophy and the re‐innervation recovery process to discern correlations indicative of common programs governing these processes. Methods Female Sprague‐Dawley (SD) rats had a unilateral sciatic nerve crush. Based on longitudinal behavioural observations, the triceps surae muscle was analysed at different time points post‐lesion. Results Crush results in a loss of muscle function and mass (−30%) followed by a recovery to almost pre‐lesion status at 30 days post‐crush (dpc). There was no loss of fibres nor any significant change in the number of nuclei per fibre but a shift in fibres expressing myosins I and II that reverted back to control levels at 30 dpc. A residual was the persistence of hybrid fibres. Early on a CHNR ‐ε to ‐γ switch and a re‐expression of embryonic MyHC showed as signs of denervation. Foxo1, Smad3, Fbxo32 and Trim63 transcripts were upregulated but not Myostatin, InhibinA and ActivinR2B. Combined this suggests that the mechanism instigating atrophy provides a selectivity of pathway(s) activated. The myogenic differentiation factors (MDFs: Myog, Myod1 and Myf6) were upregulated early on suggesting a role also in the initial atrophy. The regulation of these transcripts returned towards baseline at 30 dpc. The examined genes showed a strong baseline covariance in transcript levels which dissolved in the response to crush driven mainly by the MDFs. At 30 dpc the naïve expression pattern was re‐established. Conclusion Peripheral nerve crush offers an excellent model to assess and interfere with muscle adaptions to denervation and re‐innervation.

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“…It is phosphorylated by the TGF‐β receptors to regulate other processes . Previous studies showed that Smad2 has a significant role in skeletal muscle development . Smad transcription factors regulate the expression of myostatin and control the growth and differentiation of myoblasts .…”

Section: Introductionmentioning

confidence: 99%

“…[22][23][24] Previous studies showed that Smad2 has a significant role in skeletal muscle development. 25,26 Smad transcription factors regulate the expression of myostatin and control the growth and differentiation of myoblasts. [27][28][29] Furthermore, some genes regulate myogenesis through the Smad2 signaling pathway.…”

Section: Introductionmentioning

confidence: 99%

MicroRNA‐323‐3p promotes myogenesis by targeting Smad2

Qin

Sun

Liu

et al. 2019

J of Cellular Biochemistry

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Skeletal muscle is an important and complex organ with multiple biological functions in humans and animals. Proliferation and differentiation of myoblasts are the key steps during the development of skeletal muscle. MicroRNA (miRNA) is a class of 21‐nucleotide noncoding RNAs regulating gene expression by combining with the 3′‐untranslated region of target messenger RNA. Many studies in recent years have suggested that miRNAs play a critical role in myogenesis. Through high‐throughput sequencing, we found that miR‐323‐3p showed significant changes in the longissimus dorsi muscle of Rongchang pigs in different age groups. In this study, we discovered that overexpression of miR‐323‐3p repressed myoblast proliferation and promoted differentiation, whereas the inhibitor of miR‐323‐3p displayed the opposite results. Furthermore, we predicted Smad2 as the target gene of miR‐323‐3p and found that miR‐323‐3p directly modulated the expression level of Smad2. Then luciferase reporter assays verified that Smad2 was a target gene of miR‐323‐3p during the differentiation of myoblasts. These findings reveal that miR‐323‐3p is a positive regulator of myogenesis by targeting Smad2. This provides a novel mechanism of miRNAs in myogenesis.

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Smad2/3 Proteins Are Required for Immobilization-induced Skeletal Muscle Atrophy

Cited by 51 publications

References 57 publications

The ubiquitin proteasome system in atrophying skeletal muscle: roles and regulation

The ubiquitin proteasome system in atrophying skeletal muscle: roles and regulation

Muscle atrophy and regeneration associated with behavioural loss and recovery of function after sciatic nerve crush

MicroRNA‐323‐3p promotes myogenesis by targeting Smad2

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