β3-Adrenergic receptors regulate human brown/beige adipocyte lipolysis and thermogenesis
Cheryl Cero, … , Yu-Hua Tseng, Aaron M. Cypess
Cheryl Cero, … , Yu-Hua Tseng, Aaron M. Cypess
Published June 8, 2021
Citation Information: JCI Insight. 2021;6(11):e139160. https://doi.org/10.1172/jci.insight.139160.
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Research Article Cell biology Metabolism

β3-Adrenergic receptors regulate human brown/beige adipocyte lipolysis and thermogenesis

Abstract

β3-Adrenergic receptors (β3-ARs) are the predominant regulators of rodent brown adipose tissue (BAT) thermogenesis. However, in humans, the physiological relevance of BAT and β3-AR remains controversial. Herein, using primary human adipocytes from supraclavicular neck fat and immortalized brown/beige adipocytes from deep neck fat from 2 subjects, we demonstrate that the β3-AR plays a critical role in regulating lipolysis, glycolysis, and thermogenesis. Silencing of the β3-AR compromised genes essential for thermogenesis, fatty acid metabolism, and mitochondrial mass. Functionally, reduction of β3-AR lowered agonist-mediated increases in intracellular cAMP, lipolysis, and lipolysis-activated, uncoupling protein 1–mediated thermogenic capacity. Furthermore, mirabegron, a selective human β3-AR agonist, stimulated BAT lipolysis and thermogenesis, and both processes were lost after silencing β3-AR expression. This study highlights that β3-ARs in human brown/beige adipocytes are required to maintain multiple components of the lipolytic and thermogenic cellular machinery and that β3-AR agonists could be used to achieve metabolic benefit in humans.

Authors

Cheryl Cero, Hannah J. Lea, Kenneth Y. Zhu, Farnaz Shamsi, Yu-Hua Tseng, Aaron M. Cypess

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Figure 1

Establishment of primary human brown/beige adipocytes and the effects of silencing ADRB3 on the cellular machinery.

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Establishment of primary human brown/beige adipocytes and the effects of...
(A) Representative microscopic pictures of the morphology of undifferentiated and differentiated adipocytes. (B) Oil Red O staining of differentiated human primary adipocytes at passage number 10 (P10) and 15 (P15). (C) Protein expression of FABP4, adiponectin, and UCP1 at P10 and P15 in pre- and mature adipocytes. (D) Immunofluorescence of differentiated adipocytes staining for mitochondria (MitoTracker, red), lipid droplets (LipidTOX, green), anti-UCP1 (white), and nuclei (DAPI, blue). Scale bars: 100 μm for all images except the higher magnification, which is 50 μm. (E and F) The mRNA expression profiles of β-ARs (E) and thermogenic related genes (F) in transfected siRNA-control (siRNA-Ctrl) and siRNA-ADRB3 adipocytes after 48 hours of transfection. (G) UCP1 protein levels in transfected adipocytes after 48 hours and 72 hours of transfection. (H) Immunofluorescence of siRNA-Ctrl and siRNA-ADRB3 adipocytes stained with MitoTracker (red), LipidTOX (green), anti-UCP1 (white), and DAPI (blue). Scale bars: 100 μm. (I) Quantification of UCP1-positive adipocytes in siRNA-Ctrl and siRNA-ADRB3 adipocytes from 5 sections. Arrows indicate cells expressing UCP1. (JM) Expression levels of mtDNA-encoded gene (J), fatty acid oxidation genes (K), fatty acid synthesis genes (L), and creatinine kinase genes (M) in transfected siRNA-Ctrl and siRNA-ADRB3 adipocytes. Gene expression data are normalized to siRNA-Ctrl adipocytes and expressed as mean ± SEM expression on a log10 scale. Data were analyzed by 2-tailed unpaired Student’s t test. ****P < 0.0001; ***P < 0.001; **P < 0.01; *P < 0.05.