Signal Transduction Pathway through Activin Receptors as a Therapeutic Target of Musculoskeletal Diseases and Cancer

Tsuchida, Kunihiro; Nakatani, Masashi; Uezumi, Akiyoshi; Murakami, Tatsuya; Cui, Xueling

doi:10.1507/endocrj.kr-110

Cited by 146 publications

(112 citation statements)

References 90 publications

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“…The major type I activin receptor is ActRIB, also known as Alk4, but ActRIC (Alk7) can also mediate activin signalling. ActRIA (Alk2) had been shown to bind activin, but it is predominantly a receptor for bonemorphogenetic proteins (reviewed by Tsuchida et al, 2008). Once phosphorylated by the type II receptor, and thereby activated, the type I receptor kinase phosphorylates the receptor-Smad proteins (R-Smads), SMAD2 and SMAD3.…”

Section: Introductionmentioning

confidence: 99%

The bright and the dark sides of activin in wound healing and cancer

Antsiferova

Werner

2012

Journal of Cell Science

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SummaryActivin was initially described as a protein that stimulates release of follicle stimulating hormone from the pituitary, and it is well known for its important roles in different reproductive functions. In recent years, this multifunctional factor has attracted the attention of researchers in other fields, as new functions of activin in angiogenesis, inflammation, immunity, fibrosis and cancer have been discovered. Studies from our laboratory have identified activin as a crucial regulator of wound healing and skin carcinogenesis. On the one hand, it strongly accelerates the healing process of skin wounds but, on the other hand, it enhances scar formation and the susceptibility to skin tumorigenesis. Finally, results from several laboratories have revealed that activin enhances tumour formation and/ or progression in some other organs, in particular through its effect on the tumour microenvironment, and that it also promotes cancerinduced bone disruption and muscle wasting. These findings provide the basis for the use of activin or its downstream targets for the improvement of impaired wound healing, and of activin antagonists for the prevention and treatment of fibrosis and of malignant tumours that overexpress activin. Here, we summarize the previously described roles of activin in wound healing and scar formation and discuss functional studies that revealed different functions of activin in the pathogenesis of cancer. The relevance of these findings for clinical applications will be highlighted.

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Section: Introductionmentioning

confidence: 99%

The bright and the dark sides of activin in wound healing and cancer

Antsiferova

Werner

2012

Journal of Cell Science

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“…1,2 Recently, a growing number of transcription factors, membrane and cytoskeletal proteins, and cytokines have been found to participate in the molecular mechanisms leading to muscle atrophy, including caveolin 3 and myostatin. [3][4][5][6][7][8] Caveolin 3, a muscle-specific integral membrane protein, forms flask-shaped invaginations of the plasma membrane known as caveolae, and regulates signal transduction pathways by binding specific lipid-modified signal molecules, including Ha-Ras, G protein-coupled receptors, Srk-family kinases, and nitric oxide synthases.…”

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confidence: 99%

“…Each member of the TGF-b family binds to a membrane serine/ threonine kinase receptor, termed as a type II receptor, which then recruits a type I kinase receptor. 1,14 Seven different type I receptors, the activin receptor-like kinases 1-7 (ALK1-7), thus determine the intracellular signal specificity of the 33 members of the TGF-b family. 1,14 Small-molecule inhibitors of TGF-b type I receptor (TbRI) kinase were originally developed to compete with the binding of adenosine triphosphate to the kinase domain of ALK5, the type I receptor for TGF-b1-3.…”

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confidence: 99%

“…1,14 Seven different type I receptors, the activin receptor-like kinases 1-7 (ALK1-7), thus determine the intracellular signal specificity of the 33 members of the TGF-b family. 1,14 Small-molecule inhibitors of TGF-b type I receptor (TbRI) kinase were originally developed to compete with the binding of adenosine triphosphate to the kinase domain of ALK5, the type I receptor for TGF-b1-3. 12 TbRI kinase inhibitors have been found to suppress tumor enlargement and metastasis in the advanced stages of cancer in animals.…”

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confidence: 99%

“…[15][16][17][18] Notably, these inhibitors also suppress a similar kinase domain of ALK4, the type I receptor for activin, and potentially block ALK4/5, the type I receptor for myostatin. 1,12,19,20 However, the impact and clinical significance of TbRI kinase inhibitors on the skeletal muscle signaling of activin, myostatin, and TGF-b1-3 is unknown.…”

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confidence: 99%

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An inhibitor of transforming growth factor beta type I receptor ameliorates muscle atrophy in a mouse model of caveolin 3-deficient muscular dystrophy

Ohsawa

Okada

Nishimatsu

et al. 2012

Laboratory Investigation

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Skeletal muscle expressing Pro104Leu mutant caveolin 3 (CAV3 P104L ) in mouse becomes atrophied and serves as a model of autosomal dominant limb-girdle muscular dystrophy 1C. We previously found that caveolin 3-deficient muscles showed activated intramuscular transforming growth factor beta (TGF-b) signals. However, the cellular mechanism by which loss of caveolin 3 leads to muscle atrophy is unknown. Recently, several small-molecule inhibitors of TGF-b type I receptor (TbRI) kinase have been developed as molecular-targeting drugs for cancer therapy by suppressing intracellular TGF-b1, -b2, and -b3 signaling. Here, we show that a TbRI kinase inhibitor, Ki26894, restores impaired myoblast differentiation in vitro caused by activin, myostatin, and TGF-b1, as well as CAV3 P104L . Oral administration of Ki26894 increased muscle mass and strength in vivo in wild-type mice, and improved muscle atrophy and weakness in the CAV3 P104L mice. The inhibitor restored the number of satellite cells, the resident stem cells of adult skeletal muscle, with suppression of the increased phosphorylation of Smad2, an effector, and the upregulation of p21 (also known as Cdkn1a), a target gene of the TGF-b family members in muscle. These data indicate that both TGF-b-dependent reduction in satellite cells and impairment of myoblast differentiation contribute to the cellular mechanism underlying caveolin 3-deficient muscle atrophy. TbRI kinase inhibitors could antagonize the activation of intramuscular anti-myogenic TGF-b signals, thereby providing a novel therapeutic rationale for the alternative use of this type of anticancer drug in reversing muscle atrophy in various clinical settings.

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The Potential of Enhancing Muscle Growth in Cultured Fish through the Inhibition of Members of the Transforming Growth Factor‐β Superfamily

Phelps

Bradley

2011

Aquaculture Biotechnology

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Signal Transduction Pathway through Activin Receptors as a Therapeutic Target of Musculoskeletal Diseases and Cancer

Cited by 146 publications

References 90 publications

The bright and the dark sides of activin in wound healing and cancer

The bright and the dark sides of activin in wound healing and cancer

An inhibitor of transforming growth factor beta type I receptor ameliorates muscle atrophy in a mouse model of caveolin 3-deficient muscular dystrophy

The Potential of Enhancing Muscle Growth in Cultured Fish through the Inhibition of Members of the Transforming Growth Factor‐β Superfamily

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