Adrβ2 in skeletal muscle cells is required for exercise-induced Pgc1α but not for metabolic benefits of exercise on diet-induced obesity

{beta}2-Adrenergic receptor (Adr{beta}2) is the most abundant form of adrenergic receptors in skeletal muscle. Our previous studies have shown that the ventromedial hypothalamic nucleus (VMH) regulates metabolic benefits of exercise, potentially by skeletal muscle Adr{beta}2. Although a large body of literature has shown the importance of Adr{beta}2 on skeletal muscle physiology, it remains unexplored whether skeletal muscle Adr{beta}2 contributes to metabolic benefits of exercise, such as prevention of diet-induced obesity (DIO). Here, we generated mice lacking Adr{beta}2 in skeletal muscle cells (SKMAdr{beta}2) and tested whether SKMAdr{beta}2 is required for metabolic benefits of exercise on DIO. Deletion of SKMAdr{beta}2 completely abolished the induction of peroxisome proliferator-activated receptor gamma coactivator 1-alpha (Pgc-1) in skeletal muscle by {beta}2-agonist, which is a potent activator of Pgc-1. Exercise upregulates Pgc-1, which regulates a broad range of skeletal muscle physiology, including hypertrophy and mitochondrial function. Deletion of SKMAdr{beta}2 hampers augmented Pgc-1 in skeletal muscle by a single bout of exercise. Intriguingly, we found that deletion of SKMAdr{beta}2 increased endurance capacity. Further, our data showed that body weight in DIO mice lacking SKMAdr{beta}2 is comparable to that of control DIO mice during exercise training, suggesting that deletion of SKMAdr{beta}2 did not affect the metabolic benefits of exercise in DIO. Collectively, our data indicate that SKMAdr{beta}2 contributes to exercise-induced transcriptional changes and endurance capacity, however, it is not required for exercise benefits on bodyweight in DIO mice.