Myostatin regulates energy homeostasis through autocrine- and paracrine-mediated microenvironment communication
Hui Wang, … , Tiemin Liu, Xingxing Kong
Hui Wang, … , Tiemin Liu, Xingxing Kong
Published June 18, 2024
Citation Information: J Clin Invest. 2024;134(16):e178303. https://doi.org/10.1172/JCI178303.
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Research Article Endocrinology

Myostatin regulates energy homeostasis through autocrine- and paracrine-mediated microenvironment communication

Abstract

Myostatin (MSTN) has long been recognized as a critical regulator of muscle mass. Recently, there has been increasing interest in its role in metabolism. In our study, we specifically knocked out MSTN in brown adipose tissue (BAT) from mice (MSTNΔUCP1) and found that the mice gained more weight than did controls when fed a high-fat diet, with progressive hepatosteatosis and impaired skeletal muscle activity. RNA-Seq analysis indicated signatures of mitochondrial dysfunction and inflammation in the MSTN-ablated BAT. Further studies demonstrated that Kruppel-like factor 4 (KLF4) was responsible for the metabolic phenotypes observed, whereas fibroblast growth factor 21 (FGF21) contributed to the microenvironment communication between adipocytes and macrophages induced by the loss of MSTN. Moreover, the MSTN/SMAD2/3-p38 signaling pathway mediated the expression of KLF4 and FGF21 in adipocytes. In summary, our findings suggest that brown adipocyte–derived MSTN regulated BAT thermogenesis via autocrine and paracrine effects on adipocytes or macrophages, ultimately regulating systemic energy homeostasis.

Authors

Hui Wang, Shanshan Guo, Huanqing Gao, Jiyang Ding, Hongyun Li, Xingyu Kong, Shuang Zhang, Muyang He, Yonghao Feng, Wei Wu, Kexin Xu, Yuxuan Chen, Hanyin Zhang, Tiemin Liu, Xingxing Kong

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Figure 4

Loss of MSTN attenuates mitochondrial biogenesis and mitophagy in BAT.

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Loss of MSTN attenuates mitochondrial biogenesis and mitophagy in BAT. (...
(A) Relative mRNA expression of thermogenesis-related genes in BAT of BKO and Flox mice on a 12-week HFD (n = 7). (B) Western blot analysis of PGC1-α and UCP1 in BAT (n = 3). (C) UCP1 staining of BAT from BKO and Flox mice fed a HFD for 12 weeks. Scale bars: 20 μm. (D) Electron microscopy images and analysis of mitochondria numbers in BAT. Scale bars: 2 μm. (E) Relative mtDNA expression in BAT (n = 6). (F and G) Western blot analysis of mitochondrial complex and mitophagy proteins (n = 3). (H) Electron microscopy images of mitophagy. Scale bars: 2 μm. (I) OCR of BAT and basal and maximal OCRs of mitochondrial complex II (n = 4). (J) The body temperature of BKO and Flox mice after 7 days of cold exposure (n = 7). (K) Thermography assessment of the surface temperature of the indicated mice after 7 days of cold exposure (n = 7). (L) H&E staining of BAT and iWAT from BKO and Flox mice after 7 days of cold exposure. Scale bars: 20 μm. (M) Western blot analysis of PGC1-α and UCP1 in iWAT from BKO and Flox mice after 7 days of cold exposure (n = 3). (N) Relative mRNA expression of thermogenesis-related genes in iWAT from mice after 7 days of cold exposure (n = 7). (O) Western blot analysis of mitophagy proteins in iWAT from BKO and Flox mice after 7 days of cold exposure (n = 3). All results are shown as the mean ± SEM. *P < 0.05, **P < 0.01, and ***P < 0.001, by 2-tailed Student t test.