Dendritic cell–intrinsic LKB1-AMPK/SIK signaling controls metabolic homeostasis by limiting the hepatic Th17 response during obesity
Hendrik J.P. vanderZande, Eline C. Brombacher, Joost M. Lambooij, Leonard R. Pelgrom, Anna Zawistowska-Deniziak, Thiago A. Patente, Graham A. Heieis, Frank Otto, Arifa Ozir-Fazalalikhan, Maria Yazdanbakhsh, Bart Everts, Bruno Guigas
Hendrik J.P. vanderZande, Eline C. Brombacher, Joost M. Lambooij, Leonard R. Pelgrom, Anna Zawistowska-Deniziak, Thiago A. Patente, Graham A. Heieis, Frank Otto, Arifa Ozir-Fazalalikhan, Maria Yazdanbakhsh, Bart Everts, Bruno Guigas
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Research Article Immunology Metabolism

Dendritic cell–intrinsic LKB1-AMPK/SIK signaling controls metabolic homeostasis by limiting the hepatic Th17 response during obesity

Abstract

Obesity-associated metabolic inflammation drives the development of insulin resistance and type 2 diabetes, notably through modulating innate and adaptive immune cells in metabolic organs. The nutrient sensor liver kinase B1 (LKB1) has recently been shown to control cellular metabolism and T cell priming functions of DCs. Here, we report that hepatic DCs from high-fat diet–fed (HFD-fed) obese mice display increased LKB1 phosphorylation and that LKB1 deficiency in DCs (CD11cΔLKB1) worsened HFD-driven hepatic steatosis and impaired glucose homeostasis. Loss of LKB1 in DCs was associated with increased expression of Th17-polarizing cytokines and accumulation of hepatic IL-17A+ Th cells in HFD-fed mice. Importantly, IL-17A neutralization rescued metabolic perturbations in HFD-fed CD11cΔLKB1 mice. Mechanistically, deficiency of the canonical LKB1 target AMPK in HFD-fed CD11cΔAMPKα1 mice recapitulated neither the hepatic Th17 phenotype nor the disrupted metabolic homeostasis, suggesting the involvement of other and/or additional LKB1 downstream effectors. We indeed provide evidence that the control of Th17 responses by DCs via LKB1 is actually dependent on both AMPKα1 and salt-inducible kinase signaling. Altogether, our data reveal a key role for LKB1 signaling in DCs in protection against obesity-induced metabolic dysfunctions by limiting hepatic Th17 responses.

Authors

Hendrik J.P. vanderZande, Eline C. Brombacher, Joost M. Lambooij, Leonard R. Pelgrom, Anna Zawistowska-Deniziak, Thiago A. Patente, Graham A. Heieis, Frank Otto, Arifa Ozir-Fazalalikhan, Maria Yazdanbakhsh, Bart Everts, Bruno Guigas

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Figure 3

Obese CD11cΔLKB1 mice are more susceptible to HFD-induced hepatic steatosis and have increased hepatic Treg and Th17 cells.

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Obese CD11cΔLKB1 mice are more susceptible to HFD-induced hepatic steato...
CD11cWT (black symbols) and CD11cΔLKB1 (open symbols) mice were fed a HFD for 18 weeks. (AD) At sacrifice, liver was collected and immune cells were isolated. Total leukocytes per gram liver were quantified (A). Percentages of DCs (B), cDC subsets (C), and CD4+ T cells (D) were determined by flow cytometry. (EG) Liver leukocytes were restimulated with PMA and ionomycin in the presence of Brefeldin A for intracellular cytokine detection. Representative plots (E) and percentages of FOXP3+ Tregs, IL-5+ Th2, and IL-17A+ Th17 cells were determined as frequencies of CD4+ T cells (F) or cells per gram liver (G). (H) A part of liver was sectioned and H&E stained. (I) Lipid droplet size distribution and mean lipid droplet diameter were quantified from H&E-stained slides. (J) Hepatic triglyceride (TG) and total cholesterol (TC) contents were determined. (K and L) Hepatic gene expression of genes involved in lipid metabolism (K) and fibrosis (L) was measured by qPCR. Data shown are a pool of 2 independent experiments, except for B, C, and J. Data are expressed as mean ± SEM. Statistical analyses were performed using unpaired t tests (AL) or 2-way ANOVA followed by Fisher’s post hoc tests (I). *P < 0.05 versus CD11cWT (n = 6–17 mice per group for A and DI; n = 4–9 mice per group for B, C, and J). Scale bar: 50 μm.