Extracellular vesicle transfer of miR-1 to adipose tissue modifies lipolytic pathways following resistance exercise
Benjamin I. Burke, Ahmed Ismaeel, Douglas E. Long, Lauren A. Depa, Peyton T. Coburn, Jensen Goh, Tolulope P. Saliu, Bonnie J. Walton, Ivan J. Vechetti, Bailey D. Peck, Taylor R. Valentino, C. Brooks Mobley, Hasiyet Memetimin, Dandan Wang, Brian S. Finlin, Philip A. Kern, Charlotte A. Peterson, John J. McCarthy, Yuan Wen
Benjamin I. Burke, Ahmed Ismaeel, Douglas E. Long, Lauren A. Depa, Peyton T. Coburn, Jensen Goh, Tolulope P. Saliu, Bonnie J. Walton, Ivan J. Vechetti, Bailey D. Peck, Taylor R. Valentino, C. Brooks Mobley, Hasiyet Memetimin, Dandan Wang, Brian S. Finlin, Philip A. Kern, Charlotte A. Peterson, John J. McCarthy, Yuan Wen
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Research Article Metabolism Muscle biology

Extracellular vesicle transfer of miR-1 to adipose tissue modifies lipolytic pathways following resistance exercise

Abstract

Extracellular vesicles (EVs) have emerged as important mediators of intertissue signaling and exercise adaptations. In this human study, we provide evidence that muscle-specific microRNA-1 (miR-1) was transferred to adipose tissue via EVs following an acute bout of resistance exercise. Using a multimodel machine learning automation tool, we discovered muscle primary miR-1 transcript and CD63+ EV count in circulation as top explanatory features for changes in adipose miR-1 levels in response to resistance exercise. RNA-Seq and in-silico prediction of miR-1 target genes identified caveolin 2 (CAV2) and tripartite motif containing 6 (TRIM6) as miR-1 target genes downregulated in the adipose tissue of a subset of participants with the highest increases in miR-1 levels following resistance exercise. Overexpression of miR-1 in differentiated human adipocyte-derived stem cells downregulated these miR-1 targets and enhanced catecholamine-induced lipolysis. These data identify a potential EV-mediated mechanism by which skeletal muscle communicates with adipose tissue and modulates lipolysis via miR-1.

Authors

Benjamin I. Burke, Ahmed Ismaeel, Douglas E. Long, Lauren A. Depa, Peyton T. Coburn, Jensen Goh, Tolulope P. Saliu, Bonnie J. Walton, Ivan J. Vechetti, Bailey D. Peck, Taylor R. Valentino, C. Brooks Mobley, Hasiyet Memetimin, Dandan Wang, Brian S. Finlin, Philip A. Kern, Charlotte A. Peterson, John J. McCarthy, Yuan Wen

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Figure 4

miR-1 targets CAV2 and TRIM6 mRNAs to enhance catecholamine-induced lipolysis.

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miR-1 targets CAV2 and TRIM6 mRNAs to enhance catecholamine-induced lipo...
Differences in (A) caveolin 2 (CAV2) and (B) tripartite motif-containing protein 6 (TRIM6) expression between participants with high (n = 10) versus low (n = 7) changes in adipose miR-1 in response to exercise, as well as seed sequence schematic depicting the miR-1 binding affinity for these mRNAs. (C) Efficiency of miR-1 transfection as depicted by fold change in miR-1 relative to scrambled control (Scr). (D) Changes in CAV2 and TRIM6 expression with miR-1 transfection. The abundance of (E) Nonesterified fatty acids (NEFAs) and (F) glycerol in the media of scrambled control (Scr) and miR-1–transfected human adipose-derived stem cells (ADSCs) treated with vehicle (VEH) or epinephrine (EPI). (G) Protein abundance of (H) comparative gene identification-58 (CGI-58), (I) adipose triglyceride lipase (ATGL), (J) phosphorylated hormone-sensitive lipase (p-HSL), and (K) tuberous sclerosis protein 1 (TSC1) in Scr and miR-1–transfected ADSCs treated with VEH or EPI normalized to β-actin. Data are expressed as mean ± SD. Unpaired, 1-tailed Mann-Whitney tests were used to compare differences in CAV2 and TRIM6 expression in panel A and B. 1-tailed Welch’s unpaired t tests with Holm-Šidák’s corrections for multiple comparisons as needed were used to compare gene expression in panels C and D. 2-way ANOVAs with Tukey’s corrections for multiple comparisons were used to compare glycerol, NEFA, and protein levels in panels E, F, and HK. *P < 0.05; **P < 0.01; ***P < 0.001.