A nutrient-responsive AMPK/TBK1 circuit restricts adipocyte catabolism
Churaibhon Wisessaowapak, Yuliya Skorobogatko, Hyeonhui Kim, Xue Feng, Seunghwan Son, Haipeng Fu, Sitao Zhang, Pichaya Lertvilai, Lina Chang, Annie Hoang, Hetty Chen, Sarah Bedsted, Joseph Valentine, Jin Young Huh, Peng Zhao, Shannon M. Reilly, Piyajit Watcharasit, Maryam Ahmadian, Alan R. Saltiel
Churaibhon Wisessaowapak, Yuliya Skorobogatko, Hyeonhui Kim, Xue Feng, Seunghwan Son, Haipeng Fu, Sitao Zhang, Pichaya Lertvilai, Lina Chang, Annie Hoang, Hetty Chen, Sarah Bedsted, Joseph Valentine, Jin Young Huh, Peng Zhao, Shannon M. Reilly, Piyajit Watcharasit, Maryam Ahmadian, Alan R. Saltiel
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Research Article Endocrinology Metabolism

A nutrient-responsive AMPK/TBK1 circuit restricts adipocyte catabolism

Abstract

Metabolic adaptation to both caloric excess and restriction promotes energy conservation by suppressing catabolic pathways via feedback mechanisms that remain incompletely defined. We identified TANK binding kinase 1 (TBK1) as a nutrient- and inflammation-responsive brake on AMPK signaling in adipocytes. Fasting or pharmacological AMPK activation induced Tbk1 transcription via a PGC1α/nuclear respiratory factor 1 axis, which, in turn, limited AMPK activity through a phosphorylation cascade to conserve energy. In obesity, this AMPK/TBK1 axis was disrupted due to chronically elevated basal TBK1, thereby restricting energy expenditure during fasting. Adipocyte-specific TBK1 deletion enhanced fasting-induced AMPK activation, mitochondrial function, and lipolytic gene expression in both lean and obese mice. Pharmacological TBK1 inhibition with amlexanox recapitulated these effects. Combined treatment of mice with amlexanox and the AMPK activator AICAR enhanced weight loss, improved glucose tolerance and insulin sensitivity, and suppressed inflammatory and lipogenic programs in adipose tissue, as well as fibrotic gene expression in the liver. Building on prior clinical observations linking TBK1 inhibition to metabolic health, these findings defined a nutrient-sensitive AMPK/TBK1 feedback loop that limited adipocyte catabolism and suggested that dual targeting of TBK1 and AMPK may help counteract metabolic adaptation and enhance the durability of obesity therapies.

Authors

Churaibhon Wisessaowapak, Yuliya Skorobogatko, Hyeonhui Kim, Xue Feng, Seunghwan Son, Haipeng Fu, Sitao Zhang, Pichaya Lertvilai, Lina Chang, Annie Hoang, Hetty Chen, Sarah Bedsted, Joseph Valentine, Jin Young Huh, Peng Zhao, Shannon M. Reilly, Piyajit Watcharasit, Maryam Ahmadian, Alan R. Saltiel

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Figure 4

NRF1 acts as the downstream transcriptional effector of AMPK and PGC1α to activate Tbk1 in adipocytes.

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NRF1 acts as the downstream transcriptional effector of AMPK and PGC1α t...
(A) qPCR analysis of Tbk1 mRNA (n = 4–5) and (B) quantitative Western blot analysis of NRF1 and TBK1 (n = 3) from 3T3-L1 adipocytes transfected with scramble or Nrf1 siRNA and treated with 10 μM PF-739 for 6 hours. One-way ANOVA with Tukey’s multiple-comparison test. (C) qPCR analysis of Nrf1 and Tbk1 mRNA (n = 3) (D) and quantitative immunoblot analysis of NRF1, pT172 AMPK, and TBK1 protein (L) in PPDIVs from WT and PKO mice transfected with Nrf1 siRNA and treated with 10 μM PF-739. n = 3, 1-way ANOVA with Tukey’s multiple-comparison test. (E) ChIP-qPCR analysis of NRF1 binding to the Tbk1 promoter region containing the predicted NRF1 motif in 3T3-L1 adipocytes. n = 3, 1-way ANOVA with Tukey’s multiple-comparison test. (F) Dual-luciferase reporter assay in HEK293T cells transfected with a reporter plasmid containing the WT Tbk1 promoter (incorporating the NRF1-binding site) and cotransfected with plasmids encoding AMPK, kinase-dead AMPK (KD), and/or PGC1α. n = 4, 1-way ANOVA with Tukey’s multiple-comparison test. Data are presented as mean ± SEM; each dot represents a biological replicate. *P < 0.05, **P < 0.01, ***P < 0.001, ****P < 0.0001.