[HTML][HTML] Functional characterization of the Ucp1-associated oxidative phenotype of human epicardial adipose tissue

K Chechi, P Voisine, P Mathieu, M Laplante… - Scientific Reports, 2017 - nature.com
K Chechi, P Voisine, P Mathieu, M Laplante, S Bonnet, F Picard, P Joubert, D Richard
Scientific Reports, 2017nature.com
Brown fat presence and metabolic activity has been associated with lower body mass index,
higher insulin sensitivity and better cardiometabolic profile in humans. We, and others, have
previously reported the presence of Ucp1, a marker of brown adipocytes, in human
epicardial adipose tissue (eAT). Characterization of the metabolic activity and associated
physiological relevance of Ucp1 within eAT, however, is still awaited. Here, we validate the
presence of Ucp1 within human eAT and its 'beige'nature. Using in-vitro analytical …
Abstract
Brown fat presence and metabolic activity has been associated with lower body mass index, higher insulin sensitivity and better cardiometabolic profile in humans. We, and others, have previously reported the presence of Ucp1, a marker of brown adipocytes, in human epicardial adipose tissue (eAT). Characterization of the metabolic activity and associated physiological relevance of Ucp1 within eAT, however, is still awaited. Here, we validate the presence of Ucp1 within human eAT and its ‘beige’ nature. Using in-vitro analytical approaches, we further characterize its thermogenic potential and demonstrate that human eAT is capable of undergoing enhanced uncoupling respiration upon stimulation. Direct biopsy gene expression analysis reveals a negative association between thermogenic markers and oxidative stress-related genes in this depot. Consistently, isoproterenol (Iso) stimulation of eAT leads to a downregulation of secreted proteins included in the GO terms ‘cell redox homeostasis’ and ‘protein folding’. In addition, cardiac endothelial cells exhibit a downregulation in the expression of adhesion markers upon treatment with Iso-stimulated eAT derived conditioned media. Overall, these observations suggest that Ucp1- associated metabolic activity plays a significant role in local tissue homeostasis within eAT and can plausibly alter its communication with neighboring cells of the cardiovascular system.
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