problendoПроблемы ЭндокринологииProblems of Endocrinology0375-96602308-1430Endocrinology Research Centre10.14341/probl12779problendo-12779Research ArticleБолезни костной и жировой тканиBones & Adipose tissues diseasesМиокины и адипомиокины: медиаторы воспаления или уникальные молекулы таргетной терапии ожирения?Myokines and adipomyokines: inflammatory mediators or unique molecules of targeted therapy for obesity?https://orcid.org/0000-0002-9299-1053ВасюковаО. В.VasyukovaO. V.

Васюкова Ольга Владимировна, к.м.н.

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Olga V. Vasyukova, MD, PhD

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Moscow

o.vasyukova@mail.ruhttps://orcid.org/0000-0002-2974-667XКасьяноваЮ. В.KasyanovaYu. V.

Касьянова Юлия Вадимовна

117036, Москва, ул. Дм. Ульянова, д. 11

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Yulia V. Kasyanova, MD

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yulia839@yandex.ruhttps://orcid.org/0000-0001-9834-727XОкороковП. Л.OkorokovP. L.

Окороков Павел Леонидович, к.м.н.

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Pavel L. Okorokov, MD, PhD

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pokorokov@gmail.comhttps://orcid.org/0000-0001-9621-5732БезлепкинаО. Б.BezlepkinaO. B.

Безлепкина Ольга Борисовна, д.м.н., профессор

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Olga B. Bezlepkina, MD, PhD, Professor

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olgabezlepkina@mail.ruНациональный медицинский исследовательский центр эндокринологииРоссияEndocrinology Research CenterRussian Federation2021100820216743645Copyright © Васюкова О.В., Касьянова Ю.В., Окороков П.Л., Безлепкина О.Б., 20212021Васюкова О.В., Касьянова Ю.В., Окороков П.Л., Безлепкина О.Б.Vasyukova O.V., Kasyanova Y.V., Okorokov P.L., Bezlepkina O.B.This work is licensed under a Creative Commons Attribution 4.0 License.https://www.probl-endojournals.ru/jour/article/view/12779

Скелетная мускулатура составляет около 25% общей массы у детей и более 40% — у взрослых. Исследования последних 20 лет показали, что наряду с основными функциями мышечная ткань обладает гормональной активностью. Установлено, что миоциты способны высвобождать сигнальные молекулы — миокины. Они действуют ауто- и паракринно в пределах мышцы, а при высоком уровне — через системную циркуляцию, осуществляя взаимодействия между скелетными мышцами и различными органами и тканями, такими как печень, костная и жировая ткань, головной мозг. Доказано, что ключевым фактором экспрессии миокинов является физическая нагрузка, а их уровень во многом зависит от физической тренированности, количества скелетной мышечной массы и ее состава (соотношение быстрых и медленных волокон), от интенсивности и продолжительности физических нагрузок. Миокины имеют широкий спектр физиологических эффектов: миостатин подавляет рост и дифференцировку мышечной ткани, а декорин, действуя как его антагонист, способствует гипертрофии мышц. Интерлейкин-6 обеспечивает энергетическим субстратом сокращающиеся мышечные волокна, фактор роста фибробластов 21 активирует механизмы получения энергии при голодании и улучшает чувствительность тканей к инсулину; ирисин стимулирует термогенез, поглощение глюкозы миоцитами, а также способствует повышению минеральной плотности костной ткани. Изучение миокинов является одним из ключевых звеньев в понимании механизмов, лежащих в основе ожирения и метаболических осложнений, последствий малоподвижного образа жизни, а также реализации действия физической активности. Учитывая физиологические эффекты миокинов в организме, в перспективе они могут стать мишенями для терапии данных состояний.

Skeletal muscles make up about 25% of the total mass in children and more than 40% in adults. Studies of the last twenty years have shown that along with the main functions, muscle tissue has hormonal activity. It was found that myocytes are able to release signaling molecules-myokines. They act auto-and paracrine within the muscle, and at a high level-through the systemic circulation, carrying out interactions between skeletal muscles and various organs and tissues, such as the liver, bone and adipose tissue, the brain. It is proved that the key factor in the expression of myokines is physical activity, and their level largely depends on physical fitness, the amount of skeletal muscle mass and its composition (the ratio of fast and slow fibers), on the intensity and duration of physical activity. Myokines have a wide range of physiological effects: myostatin suppresses the growth and differentiation of muscle tissue, and decorin, acting as its antagonist, promotes muscle hypertrophy. Interleukin 6 provides an energy substrate for contracting muscle fibers, fibroblast growth factor 21 activates the mechanisms of energy production during fasting and improves tissue sensitivity to insulin; irisin stimulates thermogenesis, glucose uptake by myocytes, and also contributes to an increase in bone mineral density. The study of myokines is one of the key links in understanding the mechanisms underlying obesity and metabolic complications, the consequences of a sedentary lifestyle, as well as the implementation of the action of physical activity. Taking into account the physiological effects of myokines in the body, in the future they can become therapeutic targets for the treatment of these conditions.

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The authors declare that there are no conflicts of interest present.