Hepatic glycogen directly regulates gluconeogenesis through an AMPK/CRTC2 axis in mice
Bichen Zhang, … , Jeffrey E. Pessin, Alan R. Saltiel
Bichen Zhang, … , Jeffrey E. Pessin, Alan R. Saltiel
Published June 2, 2025
Citation Information: J Clin Invest. 2025;135(11):e188363. https://doi.org/10.1172/JCI188363.
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Research Article Cell biology Metabolism

Hepatic glycogen directly regulates gluconeogenesis through an AMPK/CRTC2 axis in mice

Abstract

Glycogenolysis and gluconeogenesis ensure sufficient hepatic glucose production during energy shortages. Here, we report that hepatic glycogen levels control the phosphorylation of a transcriptional coactivator to determine the amplitude of gluconeogenesis. Decreased liver glycogen during fasting promotes gluconeogenic gene expression, while feeding-induced glycogen accumulation suppresses it. Liver-specific deletion of the glycogen scaffolding protein, protein targeting to glycogen (PTG), reduces glycogen levels, increases the expression of gluconeogenic genes, and promotes glucose production in primary hepatocytes. In contrast, liver glycogen phosphorylase (PYGL) knockdown or inhibition increases glycogen levels and represses gluconeogenic gene expression. These changes in hepatic glycogen levels are sensed by AMP-activated protein kinase (AMPK). AMPK activity is increased when glycogen levels decline, resulting in the phosphorylation and stabilization of CREB-regulated transcriptional coactivator 2 (CRTC2), which is crucial for the full activation of the cAMP-responsive transcriptional factor CREB. High glycogen allosterically inhibits AMPK, leading to CRTC2 degradation and reduced CREB transcriptional activity. Hepatocytes with low glycogen levels or high AMPK activity show higher CRTC2 protein levels, priming the cell for gluconeogenesis through transcriptional regulation. Thus, glycogen plays a regulatory role in controlling hepatic glucose metabolism through the glycogen/AMPK/CRTC2 signaling axis, safeguarding efficient glucose output during fasting and suppressing it during feeding.

Authors

Bichen Zhang, Morgan M. Johnson, Timothy Yuan, Tammy-Nhu Nguyen, Junichi Okada, Fajun Yang, Alus M. Xiaoli, Liana H. Melikian, Songran Xu, Benyamin Dadpey, Jeffrey E. Pessin, Alan R. Saltiel

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Figure 5

Phosphorylation of CRTC2 by AMPK promotes gluconeogenic gene expression.

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Phosphorylation of CRTC2 by AMPK promotes gluconeogenic gene expression....
(A) Total and glycogen-bound (AMPD fraction) proteins in WT and PTGLKO primary hepatocytes. Blot quantifications are shown in Supplemental Figure 4A. (B) Nuclear and cytosolic proteins from WT and PTGLKO hepatocytes treated with or without glucagon. Histone H3 and tubulin were used as markers for nuclear and cytosolic fractions. (C) Conserved sequence of CRTC2 across species. Serine 340 and 349 are highlighted. (D) Gluconeogenic gene expression in AML12 cells treated with cAMP. AML12 cells were transfected with vector control, WT, or S349D CRTC2. Data were normalized to vehicle-treated vector group shown in Supplemental Figure 4G. (E) Crtc2 gene expression in transfected AML12 cells. (F and G) Western blots of immunoprecipitated (IP) FLAG-CRTC2 and inputs. AML12 cells were transfected with FLAG-tagged indicated plasmids and treated with vehicle (F) or cAMP (G) for 1 hour. Cells were lysed to harvest input and IP proteins. n = 3–6 per group. Experiments were performed at least 3 times. #*P < 0.05; ##**P < 0.01; ###***P < 0.001 by 1-way ANOVA. Hatch marks indicate comparison with vector group; asterisks indicate comparison with WT CRTC2.