LRH-1 regulates hepatic lipid homeostasis and maintains arachidonoyl phospholipid pools critical for phospholipid diversity
Diego A. Miranda, … , David L. Silver, Holly A. Ingraham
Diego A. Miranda, … , David L. Silver, Holly A. Ingraham
Published March 8, 2018
Citation Information: JCI Insight. 2018;3(5):e96151. https://doi.org/10.1172/jci.insight.96151.
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Research Article Hepatology Metabolism

LRH-1 regulates hepatic lipid homeostasis and maintains arachidonoyl phospholipid pools critical for phospholipid diversity

Abstract

Excess lipid accumulation is an early signature of nonalcoholic fatty liver disease (NAFLD). Although liver receptor homolog 1 (LRH-1) (encoded by NR5A2) is suppressed in human NAFLD, evidence linking this phospholipid-bound nuclear receptor to hepatic lipid metabolism is lacking. Here, we report an essential role for LRH-1 in hepatic lipid storage and phospholipid composition based on an acute hepatic KO of LRH-1 in adult mice (LRH-1AAV8-Cre mice). Indeed, LRH-1–deficient hepatocytes exhibited large cytosolic lipid droplets and increased triglycerides (TGs). LRH-1–deficient mice fed high-fat diet displayed macrovesicular steatosis, liver injury, and glucose intolerance, all of which were reversed or improved by expressing wild-type human LRH-1. While hepatic lipid synthesis decreased and lipid export remained unchanged in mutants, elevated circulating free fatty acid helped explain the lipid imbalance in LRH-1AAV8-Cre mice. Lipidomic and genomic analyses revealed that loss of LRH-1 disrupts hepatic phospholipid composition, leading to lowered arachidonoyl (AA) phospholipids due to repression of Elovl5 and Fads2, two critical genes in AA biosynthesis. Our findings reveal a role for the phospholipid sensor LRH-1 in maintaining adequate pools of hepatic AA phospholipids, further supporting the idea that phospholipid diversity is an important contributor to healthy hepatic lipid storage.

Authors

Diego A. Miranda, William C. Krause, Amaury Cazenave-Gassiot, Miyuki Suzawa, Hazel Escusa, Juat Chin Foo, Diyala S. Shihadih, Andreas Stahl, Mark Fitch, Edna Nyangau, Marc Hellerstein, Markus R. Wenk, David L. Silver, Holly A. Ingraham

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Figure 3

Lrh-1AAV8-Cre hepatocytes preferentially store fatty acids in large lipid droplets.

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Lrh-1AAV8-Cre hepatocytes preferentially store fatty acids in large lip...
(A) Representative bright-field images and images of BODIPY-stained primary hepatocytes from Lrh-1AAV8-GFP and Lrh-1AAV8-Cre male mice 2 weeks after infection; black or yellow arrows highlight lipid droplets in Lrh-1AAV8-Cre hepatocytes. Quantification of lipid droplet size and frequency is shown, as measured by ImageJ. (B) TG content obtained from Lrh-1AAV8-GFP and Lrh-1AAV8-Cre mouse hepatocytes with or without FA loading with oleic acid for 16 hours. (C) Measurement of FA uptake and expression of hepatic fatty acid transporters (Fatp2 and Fatp5) in Lrh-1AAV8-GFP and Lrh-1AAV8-Cre hepatocytes. (D) De novo lipogenesis (DNL) in hepatic tissue 2 weeks after infection, as quantified by the percentage of new hepatic palmitate (n = 4 per group), and expression of key lipogenic genes in hepatocytes isolated from Lrh-1AAV8-GFP and Lrh-1AAV8-Cre mice. (E) Fatty acid oxidation in hepatocytes from Lrh-1AAV8-GFP and Lrh-1AAV8-Cre mice. Primary hepatocytes were analyzed from at least 2–4 males per group, with each assay done in triplicate for B–E. Error bars represent ± SEM. For box-and-whisker plots, maximum and minimum values are shown with median. *P < 0.05, **P < 0.01, ***P < 0.001, unpaired Student’s t test for B, D, and E.