Abstract
The AMP-activated protein kinase (AMPK), a central regulator of cellular energy balance and metabolism, binds glycogen via its β subunit. However, the physiological effects of disrupting AMPK-glycogen interactions remain incompletely understood. To chronically disrupt AMPK-glycogen binding, AMPK β double knock-in (DKI) mice were generated with mutations in residues critical for glycogen binding in both the β1 (W100A) and β2 (W98A) subunit isoforms. We examined the effects of this DKI mutation on whole-body substrate utilization, glucose homeostasis, and tissue glycogen dynamics. Body composition, metabolic caging, glucose and insulin tolerance, serum hormone and lipid profiles, and tissue glycogen and protein content were analyzed in chow-fed male DKI and age-matched wild-type (WT) mice. DKI mice displayed increased whole-body fat mass and glucose intolerance associated with reduced fat oxidation relative to WT. DKI mice had reduced liver glycogen content in the fed state concomitant with increased utilization and no repletion of skeletal muscle glycogen in response to fasting and refeeding, respectively, despite similar glycogen-associated protein content relative to WT. DKI liver and skeletal muscle displayed reductions in AMPK protein content versus WT. These findings identify phenotypic effects of the AMPK DKI mutation on whole-body metabolism and tissue AMPK content and glycogen dynamics.
Highlights
We demonstrated that mice with a KI mutation to chronically disrupt glycogen-binding capacity in a single AMP-activated protein kinase (AMPK) β subunit isoform predominately expressed in liver or skeletal muscle displayed reduced total AMPK content and kinase activity, which was associated with increased fat content in liver and skeletal muscle of β1 W100A and β2 W98A KI mice, respectively [14]
This study aimed to investigate the phenotypic effects of the double knock-in (DKI) mutation used to chronically disrupt whole-body AMPK-glycogen binding in vivo on whole-body composition, glucose homeostasis, and tissue glycogen dynamics
We report that DKI mutation of residues critical for AMPK-glycogen binding in both AMPK β subunit isoforms—AMPK
Summary
The AMP-activated protein kinase (AMPK) is a central regulator of cellular energy balance and metabolism. AMPK becomes activated in response to reductions in cellular energy availability such as those induced by fasting and exercise, which are characterized by increases in ADP and AMP concentrations relative to ATP. AMPK stimulates several catabolic pathways to promote energy production and inhibits anabolic processes to preserve cellular energy homeostasis [1]. These downstream AMPK-regulated pathways facilitate increases in lipid oxidation, reductions in lipid synthesis, and stimulation of insulin-independent glucose uptake in skeletal muscle to help maintain cellular energy stores [2]
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