Glucagon promotes net hepatic glycogen repletion following meal ingestion
Nidhi Kejriwal, David Bouslov, Cheyenne R. Castle, Riya S. Karve, Galina A. Arkharova, Ashot Sargsyan, Daniel J. Drucker, Guo-Fang Zhang, David A. D’Alessio, Jonathan E. Campbell, Megan E. Capozzi
Nidhi Kejriwal, David Bouslov, Cheyenne R. Castle, Riya S. Karve, Galina A. Arkharova, Ashot Sargsyan, Daniel J. Drucker, Guo-Fang Zhang, David A. D’Alessio, Jonathan E. Campbell, Megan E. Capozzi
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Research Article Endocrinology Metabolism

Glucagon promotes net hepatic glycogen repletion following meal ingestion

Abstract

Insulin and glucagon are described as having opposing actions on hepatic glycogen metabolism. However, here we showed that their coordinated action promoted glycogen turnover and meal glucose storage. In mice, pharmacological doses of insulin or glucagon failed to alter hepatic glycogen, but the combination produced a robust decrease in glycogen content. Additivity between insulin and glucagon was also seen with the activation of hepatic insulin signaling intermediates. This signaling pathway drove glycogen synthesis, suggesting concurrent actions on glycogen breakdown and repletion. A mixed nutrient meal, which stimulates an increase in both insulin and glucagon, enhanced the incorporation of dietary glucose into hepatic glycogen. This was much more pronounced than the effects of glucose alone, which only stimulated insulin secretion. These findings revealed that glucagon is required for efficient hepatic glucose storage when acting in concert with insulin. Coordinated insulin-glucagon signaling, thus, emerged as a critical mechanism for hepatic glycogen cycling, challenging the classical paradigm that these hormones work in opposition.

Authors

Nidhi Kejriwal, David Bouslov, Cheyenne R. Castle, Riya S. Karve, Galina A. Arkharova, Ashot Sargsyan, Daniel J. Drucker, Guo-Fang Zhang, David A. D’Alessio, Jonathan E. Campbell, Megan E. Capozzi

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Figure 4

Mixed nutrient meal promotes greater meal glucose storage as glycogen than oral glucose matched for carbohydrate content.

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Mixed nutrient meal promotes greater meal glucose storage as glycogen th...
(A) Schematic of experimental strategy depicting source of glucose isotopologue (gluconeogenesis [GNG]). (BD) Figure created with BioRender.com. Blood glucose (B), insulin (C), and relative glucagon levels (D) following oral gavage with oral glucose (OGTT; 1.5 g/kg; n = 7–12) or mixed-nutrient meal matched for carbohydrate load (MTT; 10 μL/g Ensure; n = 8–12). (E) Hepatic glycogen content after a 5-hour fast followed by sham gavage (n = 6), oral glucose (OGTT; 1.5g/kg; n = 14), or Ensure mixed meal (MTT; 10 uL/g; n = 14) in WT mice containing 10% 13C6-glucose. (F) Percentage of hepatic glycogen containing 13C6-glucose tracer (M+6 glucose) 60 minutes after gavage in OGTT and MTT (n = 14). (G) The estimated amount of meal glucose stored as hepatic glycogen after OGTT or MTT (n = 14). (H) Percentage of plasma M+3 glucose 60 minutes after gavage (n = 14). (I) Percentage of plasma M+6 glucose 60 minutes after gavage (n = 14). Two-way ANOVA (B and C), one-way ANOVA with Tukey’s post hoc (E) or 2-tailed t-test (F–I) were used to determine significance, defined as P < 0.05.