Abstract
Adropin is a liver‐ and brain‐secreted peptide hormone with striking effects on fuel metabolism regulation in a number of tissues. Previous studies demonstrated that adropin secretion is decreased in obese mice subjected to a long‐term high‐fat diet (HFD), and that whole‐body loss of adropin expression resulted in systemic insulin resistance. Treatment of obese mice with adropin improves glucose tolerance, which has been linked to increased glucose oxidation and inhibition of fatty acid utilization in isolated skeletal muscle homogenates. In this study, we used in vivo physiological measurements to determine how treatment of obese mice with adropin affects whole‐body glucose metabolism. Treatment with adropin reduced fasting blood glucose and, as shown previously, increased glucose tolerance in HFD mice during standard glucose tolerance tests. Under hyperinsulinemic‐euglycemic clamp conditions, adropin treatment led to a nonsignificant increase in whole‐body insulin sensitivity, and a significant reduction in whole‐body glucose uptake. Finally, we show that adropin treatment suppressed hepatic glucose production and improved hepatic insulin sensitivity. This correlated with reduced expression of fatty acid import proteins and gluconeogenic regulatory enzymes in the liver, suggesting that adropin treatment may impact the pathways that drive vital aspects of hepatic glucose metabolism.
Highlights
Adropin is a liver- and brain-derived peptide that elicits powerful metabolic effects on a number of diverse tissue types
Whole-body glucose clearance was significantly decreased in vehicle-treated high-fat diet (HFD) mice relative to low-fat diet (LFD)-fed controls, while adropin-treated HFD mice showed no change relative to LFD-fed controls (Fig. 1F,G)
We demonstrate that treatment of obese mice with adropin leads to improved glucose homeostasis
Summary
Adropin is a liver- and brain-derived peptide that elicits powerful metabolic effects on a number of diverse tissue types. Using a combination of in vivo and in vitro analysis, Butler and colleagues have shown that adropin regulates fuel substrate preference in skeletal muscle (Gao et al 2014, 2015). Of note, these studies showed that adropin treatment could improve glucose homeostasis, and restore glucose utilization in the skeletal muscle of obese, insulin-resistant mice by partially downregulating fatty acid oxidation (Gao et al 2015). Exogenous adropin treatment impacted the expression of several mitochondrial fuel metabolism enzymes in vivo (Gao et al 2014, 2015), and these effects have been further supported by similar findings using cardiac cells in vitro (Thapa et al 2018)
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