👤 Marita Rivir

Unimolecular triagonists drive substantial weight loss in patients with obesity by engaging the glucagon-like peptide 1 receptor (GLP-1R) and glucose dependent insulinotropic polypeptide receptor (GIPR) to reduce food intake (FI) and the hepatic glucagon receptor (GcgR) to enhance energy expenditure (EE). However, their development has been challenged by deleterious cardiovascular (CV) effects, including increased heart rate (HR), elongated QTc, and arrhythmia mediated by GcgR agonism. GLP-1R mono-agonists on the other hand improve both obesity and CV outcomes with negligible effects on EE. We sought to imbue peptide GLP-1R agonists with an EE enhancing effect by combining them with ectopic GLP-1R expression and agonism in hepatocytes. We used an adeno-associated virus (AAV) to induce the expression of a functional, liver-specific GLP-1R combined with traditional peptide agonist treatment to drive greater body weight loss via reduced energy intake and increased energy expenditure. Agonism of the ectopic GLP-1R with either semaglutide, a cAMP biased GLP-1R analogue (NNC5840), or a dual GLP-1R/GIPR agonist in wild-type (WT) diet induced obese (DIO) mice led to enhanced EE and improved weight loss compared to peptide agonist treatment alone. This represents a novel mechanism for achieving poly-pharmacology to treat obesity. Show less

Recent decades have seen a marked increase in the prevalence of obesity and its associated comorbidities. This increase correlates with greater access to calorie-dense food that is often consumed later in the active phase of the day. Studies in high-fat diet-induced obese (DIO) mice indicate that restricting food access to their active (dark) phase is sufficient to reduce obesity. However, the specific mechanisms mediating these beneficial metabolic effects of dark restricted feeding (DRF) remain unknown. We examined the impact of DRF on the response to peripheral signals regulating the central melanocortin system of DIO mice and on Mc4r The body weight loss following DRF has an acute onset that is sustained over time. This effect is contributed by a reduction on food intake that requires a functional central melanocortin system. Specifically, DRF impacts the circadian expression of melanocortin system genes in the arcuate nucleus of the hypothalamus (ARC). Consistent with this, DRF significantly increases the effectiveness of the fasting-feeding signals ghrelin and leptin that interact with the melanocortin system to regulate energy balance. Importantly, DRF did not reduce or prevent obesity in Mc4r Taken together, our data reveal a critical role of brain melanocortin signaling in mediating the beneficial effects of timed feeding on metabolic control, supporting potential meaningful benefits in combining timed feeding with pharmacological targeting of the melanocortin signaling for the treatment of obesity. Show less

The melanocortin system is a brain circuit that influences energy balance by regulating energy intake and expenditure. In addition, the brain-melanocortin system controls adipose tissue metabolism to optimize fuel mobilization and storage. Specifically, increased brain-melanocortin signaling or negative energy balance promotes lipid mobilization by increasing sympathetic nervous system input to adipose tissue. In contrast, calorie-independent mechanisms favoring energy storage are less understood. Here, we demonstrate that reduction of brain-melanocortin signaling actively promotes fat mass gain by activating the lipogenic program and adipocyte and endothelial cell proliferation in white fat depots independently of caloric intake via efferent nerve fibers conveyed by the common hepatic branch of the vagus nerve. Those vagally regulated obesogenic signals also contribute to the fat mass gain following chronic high-fat diet feeding. These data reveal a physiological mechanism whereby the brain controls energy stores that may contribute to increased susceptibility to obesity. Show less