Hepatocyte ALOXE3 is induced during adaptive fasting and enhances insulin sensitivity by activating hepatic PPARγ
Cassandra B. Higgins, … , Benjamin M. Swarts, Brian J. DeBosch
Cassandra B. Higgins, … , Benjamin M. Swarts, Brian J. DeBosch
Published August 23, 2018
Citation Information: JCI Insight. 2018;3(16):e120794. https://doi.org/10.1172/jci.insight.120794.
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Research Article Hepatology Metabolism

Hepatocyte ALOXE3 is induced during adaptive fasting and enhances insulin sensitivity by activating hepatic PPARγ

Abstract

The hepatic glucose fasting response is gaining traction as a therapeutic pathway to enhance hepatic and whole-host metabolism. However, the mechanisms underlying these metabolic effects remain unclear. Here, we demonstrate the epidermal-type lipoxygenase, eLOX3 (encoded by its gene, Aloxe3), is a potentially novel effector of the therapeutic fasting response. We show that Aloxe3 is activated during fasting, glucose withdrawal, or trehalose/trehalose analogue treatment. Hepatocyte-specific Aloxe3 expression reduced weight gain and hepatic steatosis in diet-induced and genetically obese (db/db) mouse models. Aloxe3 expression, moreover, enhanced basal thermogenesis and abrogated insulin resistance in db/db diabetic mice. Targeted metabolomics demonstrated accumulation of the PPARγ ligand 12-KETE in hepatocytes overexpressing Aloxe3. Strikingly, PPARγ inhibition reversed hepatic Aloxe3–mediated insulin sensitization, suppression of hepatocellular ATP production and oxygen consumption, and gene induction of PPARγ coactivator-1α (PGC1α) expression. Moreover, hepatocyte-specific PPARγ deletion reversed the therapeutic effect of hepatic Aloxe3 expression on diet-induced insulin intolerance. Aloxe3 is, therefore, a potentially novel effector of the hepatocellular fasting response that leverages both PPARγ-mediated and pleiotropic effects to augment hepatic and whole-host metabolism, and it is, thus, a promising target to ameliorate metabolic disease.

Authors

Cassandra B. Higgins, Yiming Zhang, Allyson L. Mayer, Hideji Fujiwara, Alicyn I. Stothard, Mark J. Graham, Benjamin M. Swarts, Brian J. DeBosch

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Figure 1

Aloxe3 is induced in response to fasting and pseudofasting.

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Aloxe3 is induced in response to fasting and pseudofasting. (A) Aloxe3 ...
(A) Aloxe3 expression in liver and white adipose tissue (WAT) from fasting WT mice (0–48 hours [h]). n = 6 each of fed, 12 h fasting, and 24 h fasting mice. For 48 h fasting mice, n = 7. (B) Aloxe3 expression in WT mice fed oral trehalose (3% in sterile water fed ad libitum, 0–48 h). For control and trehalose (24 h) mice, n = 5 and 6. For 48 h trehalose-treated mice, n = 6. (C) Aloxe3 expression in isolated primary murine hepatocytes treated with 0.5% FCS/1 g/l glucose media, 100 mM trehalose, or 100 mM lactotrehalose (24 h). n = 4 per group. (D) Aloxe3 expression in trehalose-treated isolated primary hepatocytes pretreated with or without 5 mM pyruvate. n = 4 per group. (E) Aloxe3 expression in trehalose-treated WT and Atg16l1-mutant mice in vivo (24 h). n = 6 per group. (F) Aloxe3 expression in response to trehalose in the presence or absence of kinase-dead AMPK overexpression or siRNA-mediated AMPK knockdown. n = 4 per group. (G) Aloxe3 expression in response to trehalose in the presence or absence of antisense oligonucleotide (ASO) directed against PGC1, or FGF21. FGF receptor 1–4 inhibitor (LY2874455) was included as a control to demonstrate Aloxe3 blockade in context. n = 4 per group. (H) Fasting-responsive marker gene expression in the presence or absence of trehalose following treatment with or without Aloxe3-directed siRNA. *P < 0.05, **P < 0.01, ***P < 0.001, and ****P < 0.0001 by 2-tailed t test with Bonferroni-Dunn post hoc correction versus untreated controls group or versus the bracketed comparison group where indicated.