Analysis of the Role of Piezo1 Channels in Mechano-Anabolic Coupling in Rat Soleus Muscle

K. V. Sergeeva; Сергеева К. В.; S. A. Tyganov; Тыганов С. А.; V. E. Kalashnikov; Калашников В. Е.; B. S. Shenkman; Шенкман Б. С.; T. M. Mirzoev; Мирзоев Т. М.

doi:10.31857/S0233475523050080

Analysis of the Role of Piezo1 Channels in Mechano-Anabolic Coupling in Rat Soleus Muscle

Авторлар: Sergeeva K.V.¹, Tyganov S.A.¹, Kalashnikov V.E.¹, Shenkman B.S.¹, Mirzoev T.M.¹
Мекемелер:
1. Institute of Biomedical Problems, Russian Academy of Sciences
Шығарылым: Том 40, № 5 (2023)
Беттер: 362-369
Бөлім: Articles
URL: https://journal-vniispk.ru/0233-4755/article/view/135042
DOI: https://doi.org/10.31857/S0233475523050080
EDN: https://elibrary.ru/NXXYPK
ID: 135042

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Аннотация
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Әдебиет тізімі
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Статистика

Аннотация

It is known that mTORC1-dependent pathway is involved in the activation of muscle protein synthesis and hypertrophy in response to mechanical stress. However, mechanosensors that mediate sensing and transmission of mechanical signals to the mTORC1 signaling pathway (mechanotransduction) are not yet identified. Mechanically activated (MA) ion channels are viewed as potential candidates for the role of such sarcolemmal mechanosensors. The aim of our work was to investigate the potential role of MA channels (Piezo1) in the activation of the mTORC1 pathway in the isolated rat soleus muscle in response to mechanical stress. Wistar rats were divided into 3 groups: 1) “Control” (isolated muscles were not exposed to MA channel inhibitor or Piezo1 channel activator); 2) “Gadolinium” (muscles were incubated with MA channel inhibitor, gadolinium chloride); 3) “Yoda” (muscles were incubated with Yoda1, Piezo1 activator). In rats from each group, the soleus from the left limb was incubated in the appropriate solution without mechanical stress in the form of a passive stretching, and the soleus from the right limb was subjected to passive stretching and then incubated in the appropriate solution. Phosphorylation of mTORC1 targets (p70S6K, rpS6, 4E-BP1) in rat soleus was determined by PAGE and immunoblotting. After passive stretching of the isolated soleus muscle there was an increase in phosphorylation of p70S6K, its substrate, rpS6, as well as 4E-BP1, by 38.5%, 168%, and 112%, respectively, compared to the soleus muscle that was not subjected to stretching. Incubation of the muscles with gadolinium completely prevented the activation of mTORC1 markers caused by stretching. Incubation of the soleus muscle in the solution with Yoda1 resulted in a decrease in the mechano-dependent phosphorylation of p70S6K, rpS6, and 4E-BP1 compared to a muscle that was not exposed to Yoda1. Thus, Piezo1 channels do not appear to play a role in the activation of mTORC1 signaling in rat soleus muscle in response to passive stretching.

Негізгі сөздер

skeletal muscle, mechanotransduction, passive stretch, Piezo1 channels, gadolinium, Yoda1, mTORC1, p70S6K, rpS6, 4E-BP1

Әдебиет тізімі

Srikanthan P., Karlamangla A.S. 2014. Muscle mass index as a predictor of longevity in older adults. Am. J. Med. 127 (6), 547–553.
Phillips B.E., Hill D.S., Atherton P.J. 2012. Regulation of muscle protein synthesis in humans. Curr. Opin. Clin. Nutr. Metab. Care. 15 (1), 58–63.
Atherton P.J., Greenhaff P.L., Phillips S.M., Bodine S.C., Adams C.M., Lang C.H. 2016. Control of skeletal muscle atrophy in response to disuse: Clinical/preclinical contentions and fallacies of evidence. Am. J. Physiol. Endocrinol. Metab. 311 (3), E594–E604.
Damas F., Phillips S., Vechin F.C., Ugrinowitsch C. 2015. A review of resistance training-induced changes in skeletal muscle protein synthesis and their contribution to hypertrophy. Sports Med. 45 (6), 801–807.
Goldberg A.L., Etlinger J.D., Goldspink D.F., Jablecki C. 1975. Mechanism of work-induced hypertrophy of skeletal muscle. Med. Sci. Sports. 7 (3), 185–198.
Bodine S.C., Stitt T.N., Gonzalez M., Kline W.O., Stover G.L., Bauerlein R., Zlotchenko E., Scrimgeour A., Lawrence J.C., Glass D.J., Yancopoulos G.D. 2001. Akt/mTOR pathway is a crucial regulator of skeletal muscle hypertrophy and can prevent muscle atrophy in vivo. Nat. Cell Biol. 3 (11), 1014–1019.
Drummond M.J., Fry C.S., Glynn E.L., Dreyer H.C., Dhanani S., Timmerman K.L., Volpi E., Rasmussen B.B. 2009. Rapamycin administration in humans blocks the contraction-induced increase in skeletal muscle protein synthesis. J. Physiol. 587 (Pt 7), 1535–1546.
Goodman C.A., Frey J.W., Mabrey D.M., Jacobs B.L., Lincoln H.C., You J.S., Hornberger T.A. 2011. The role of skeletal muscle mTOR in the regulation of mechanical load-induced growth. J. Physiol. 589 (Pt 22), 5485–5501.
Goodman C.A. 2019. Role of mTORC1 in mechanically induced increases in translation and skeletal muscle mass. J. Appl. Physiol (1985). 127 (2), 581–590.
Hornberger T.A., Stuppard R., Conley K.E., Fedele M.J., Fiorotto M.L., Chin E.R., Esser K.A. 2004. Mechanical stimuli regulate rapamycin-sensitive signalling by a phosphoinositide 3-kinase-, protein kinase B- and growth factor-independent mechanism. Biochem. J. 380 (Pt 3), 795–804.
Hornberger T.A., Chu W.K., Mak Y.W., Hsiung J.W., Huang S.A., Chien S. 2006. The role of phospholipase D and phosphatidic acid in the mechanical activation of mTOR signaling in skeletal muscle. Proc. Natl. Acad. Sci. USA. 103 (12), 4741–4746.
You J.S., Lincoln H.C., Kim C.R., Frey J.W., Goodman C.A., Zhong X.P., Hornberger T.A. 2014. The role of diacylglycerol kinase zeta and phosphatidic acid in the mechanical activation of mammalian target of rapamycin (mTOR) signaling and skeletal muscle hypertrophy. J. Biol. Chem. 289 (3), 1551–1563.
Graham Z.A., Gallagher P.M., Cardozo C.P. 2015. Focal adhesion kinase and its role in skeletal muscle. J. Muscle Res. Cell Motil. 36 (4–5), 305–315.
Spangenburg E.E., McBride T.A. 2006. Inhibition of stretch-activated channels during eccentric muscle contraction attenuates p70S6K activation. J. Appl. Physiol. (1985). 100 (1), 129–135.
Bosutti A., Giniatullin A., Odnoshivkina Y., Giudice L., Malm T., Sciancalepore M., Giniatullin R., D’Andrea P., Lorenzon P., Bernareggi A. 2021. “Time window” effect of Yoda1-evoked Piezo1 channel activity during mouse skeletal muscle differentiation. Acta. Physiol. (Oxf). 233 (4), e13702.
Rindom E., Kristensen A.M., Overgaard K., Vissing K., de Paoli F.V. 2019. Activation of mTORC1 signalling in rat skeletal muscle is independent of the EC-coupling sequence but dependent on tension per se in a dose-response relationship. Acta. Physiol. (Oxf). 227 (3), e13336.
O’Neil T.K., Duffy L.R., Frey J.W., Hornberger T.A. 2009. The role of phosphoinositide 3-kinase and phosphatidic acid in the regulation of mammalian target of rapamycin following eccentric contractions. J. Physiol. 587 (Pt 14), 3691–3701.
Tyganov S., Mirzoev T., Shenkman B. 2019. An anabolic signaling response of rat soleus muscle to eccentric contractions following hindlimb unloading: A potential role of stretch-activated ion channels. Int. J. Mol. Sci. 20 (5), 1165.
Gehlert S., Suhr F., Gutsche K., Willkomm L., Kern J., Jacko D., Knicker A., Schiffer T., Wackerhage H., Bloch W. 2015. High force development augments skeletal muscle signalling in resistance exercise modes equalized for time under tension. Pflügers Arch. 467 (6), 1343–1356.
Rahbek S.K., Farup J., Moller A.B., Vendelbo M.H., Holm L., Jessen N., Vissing K. 2014. Effects of divergent resistance exercise contraction mode and dietary supplementation type on anabolic signalling, muscle protein synthesis and muscle hypertrophy. Amino Acids. 46 (10), 2377–2392.
Mirzoev T.M., Tyganov S.A., Petrova I.O., Shenkman B.S. 2019. Acute recovery from disuse atrophy: The role of stretch-activated ion channels in the activation of anabolic signaling in skeletal muscle. Am. J. Physiol. Endocrinol. Metab. 316 (1), E86–E95.
Yeung E.W., Allen D.G. 2004. Stretch-activated channels in stretch-induced muscle damage: Role in muscular dystrophy. Clin. Exp. Pharmacol. Physiol. 31 (8), 551–556.
Coste B., Mathur J., Schmidt M., Earley T.J., Ranade S., Petrus M.J., Dubin A.E., Patapoutian A. 2010. Piezo1 and Piezo2 are essential components of distinct mechanically activated cation channels. Science. 330 (6000), 55–60.
Tsuchiya M., Hara Y., Okuda M., Itoh K., Nishioka R., Shiomi A., Nagao K., Mori M., Mori Y., Ikenouchi J., Suzuki R., Tanaka M., Ohwada T., Aoki J., Kanagawa M., Toda T., Nagata Y., Matsuda R., Takayama Y., Tominaga M., Umeda M. 2018. Cell surface flip-flop of phosphatidylserine is critical for PIEZO1-mediated myotube formation. Nat. Commun. 9 (1), 2049.
Syeda R., Xu J., Dubin A.E., Coste B., Mathur J., Huynh T., Matzen J., Lao J., Tully D.C., Engels I.H., Petrassi H.M., Schumacher A.M., Montal M., Bandell M., Patapoutian A. 2015. Chemical activation of the mechanotransduction channel Piezo1. Elife. 4, e07369.
Tyganov S.A., Mirzoev T.M., Rozhkov S.V., Shenkman B.S. 2019. Role of the focal adhesion kinase in the anabolic response to the mechanical stimulus in rat’s atrophied postural muscle. Aviakosm. Ekolog. Med. 53 (4), 74–79.
Sbrana F., Sassoli C., Meacci E., Nosi D., Squecco R., Paternostro F., Tiribilli B., Zecchi-Orlandini S., Francini F., Formigli L. 2008. Role for stress fiber contraction in surface tension development and stretch-activated channel regulation in C2C12 myoblasts. Am. J. Physiol. Cell Physiol. 295 (1), C160–C172.
Martino F., Perestrelo A.R., Vinarsky V., Pagliari S., Forte G. 2018. Cellular mechanotransduction: From tension to function. Front. Physiol. 9, 824.