HGFAC is a ChREBP-regulated hepatokine that enhances glucose and lipid homeostasis
Ashot Sargsyan, Ludivine Doridot, Sarah A. Hannou, Wenxin Tong, Harini Srinivasan, Rachael Ivison, Ruby Monn, Henry H. Kou, Jonathan M. Haldeman, Michelle Arlotto, Phillip J. White, Paul A. Grimsrud, Inna Astapova, Linus T. Tsai, Mark A. Herman
Ashot Sargsyan, Ludivine Doridot, Sarah A. Hannou, Wenxin Tong, Harini Srinivasan, Rachael Ivison, Ruby Monn, Henry H. Kou, Jonathan M. Haldeman, Michelle Arlotto, Phillip J. White, Paul A. Grimsrud, Inna Astapova, Linus T. Tsai, Mark A. Herman
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Research Article Metabolism

HGFAC is a ChREBP-regulated hepatokine that enhances glucose and lipid homeostasis

Abstract

Carbohydrate response element–binding protein (ChREBP) is a carbohydrate-sensing transcription factor that regulates both adaptive and maladaptive genomic responses in coordination of systemic fuel homeostasis. Genetic variants in the ChREBP locus associate with diverse metabolic traits in humans, including circulating lipids. To identify novel ChREBP-regulated hepatokines that contribute to its systemic metabolic effects, we integrated ChREBP ChIP-Seq analysis in mouse liver with human genetic and genomic data for lipid traits and identified hepatocyte growth factor activator (HGFAC) as a promising ChREBP-regulated candidate in mice and humans. HGFAC is a protease that activates the pleiotropic hormone hepatocyte growth factor. We demonstrate that HGFAC-KO mice had phenotypes concordant with putative loss-of-function variants in human HGFAC. Moreover, in gain- and loss-of-function genetic mouse models, we demonstrate that HGFAC enhanced lipid and glucose homeostasis, which may be mediated in part through actions to activate hepatic PPARγ activity. Together, our studies show that ChREBP mediated an adaptive response to overnutrition via activation of HGFAC in the liver to preserve glucose and lipid homeostasis.

Authors

Ashot Sargsyan, Ludivine Doridot, Sarah A. Hannou, Wenxin Tong, Harini Srinivasan, Rachael Ivison, Ruby Monn, Henry H. Kou, Jonathan M. Haldeman, Michelle Arlotto, Phillip J. White, Paul A. Grimsrud, Inna Astapova, Linus T. Tsai, Mark A. Herman

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Figure 6

HGFAC overexpression enhances glucose homeostasis.

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HGFAC overexpression enhances glucose homeostasis. (A) Immunoblot and qu...
(A) Immunoblot and quantification by densitometry of plasma HGFAC collected 3 days after 8-week-old male mice were transduced with adenovirus expressing GFP (ADV-GFP) or HGFAC (ADV-HGFAC). (B) Weights and lean and fat mass of ADV-GFP and ADV-HGFAC mice after 9 days of transduction (n = 10/group). (C) IP glucose tolerance test and corresponding iAUC performed 5 days after viral transduction (n = 8–9/group). (D) Overnight-fasted and 3-hour refed glycemia and peripheral insulin levels of GFP- and HGFAC-transduced mice (n = 10). (E) Hepatic mRNA levels of Hgfac, Pparg and -a, and PPARγ targets measured by qPCR 14 days after viral transduction. (F) Hepatic PPARγ, phospho-S293 PDHA, total PDHA, and PCNA immunoblots of liver from ADV-HGFAC– and ADV-GFP–transduced mice and quantification of PPARγ normalized to P85, phosphorylated PDHA normalized to total PDHA, and PCNA normalized to the total protein content (n = 4–5/group). (G) Hepatic and circulating triglyceride levels 14 days after viral transduction in ad libitum–fed mice. (H) Pparg mRNA levels in AML12 cells after overnight treatment with 50 ng/mL HGF or BSA. (I) c-MET phosphorylation by HGF in AML12 cells is inhibited by the c-MET inhibitor PHA-665752 (2.5 μM) preventing induction of Pparg mRNA. Data represent means ± SEM. Statistics assessed by 2-tailed unpaired t test, *P < 0.05; or by 2-way ANOVA with Holm-Šídák multiple comparisons between individual groups, ^P < 0.05 for comparison of effects of inhibitor within HGF treatment condition, $P < 0.05 for effect of HGF within inhibitor or control treatment.