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Adipose-derived exosomes ameliorate skeletal muscle atrophy via miR-146a-5p/IGF-1R signaling

Mengran Qin, Jiahao Zhu, Lipeng Xing, Yaotian Fan, Junyi Luo, Jiajie Sun, Ting Chen, Yongliang Zhang, Qianyun Xi

2024Journal of Nanobiotechnology10 citationsDOIOpen Access PDF

Abstract

The study of muscle disorders has gained popularity, with a particular emphasis on the relationship between adipose tissue and skeletal muscle. In our investigation, we discovered that the deletion of miR-146a-5p specifically in adipose tissue (aKO) led to a notable rise in mice's mass and adiposity. In contrast, it led to a decline in lean mass, ability to exercise, diameter of muscle fibers, and the levels of genes associated with differentiation. The co-culture experiment showed that the transfection of miR-146a-5p mimics to 3T3-L1 significantly suppressive cell growth and promotes myotube differentiation in C2C12 cells. Exosomes from white adipose tissue (WAT) of aKO mice (aKO-WAT-Exos) significantly promoted muscle atrophy and inhibited differentiation of C2C12 cells but were reversed by co-incubation with miR-146a-5p-mimics. The miR-146a-5p can specifically target IGF-1R to improve skeletal muscle wasting. In this process, the PI3K/AKT/mTOR pathway is activated or the FoxO3 pathway is inhibited to enhance the synthesis of skeletal muscle proteins. Significantly, miR-146a-5p serves a crucial function as a microRNA in the communication of the fat-muscle connection. It can be transported through the pathway of exosomes derived from adipose tissue, ultimately ameliorating skeletal muscle atrophy and modulating body mass index (BMI).

Topics & Concepts

MicrovesiclesAtrophyAdipose tissueSkeletal muscleMuscle atrophyCell biologymicroRNAMedicineEndocrinologyChemistryInternal medicineBiologyBiochemistryGeneExtracellular vesicles in diseaseMuscle Physiology and DisordersAdipose Tissue and Metabolism