LRH-1–dependent glucose sensing determines intermediary metabolism in liver
Maaike H. Oosterveer, Chikage Mataki, Hiroyasu Yamamoto, Taoufiq Harach, Norman Moullan, Theo H. van Dijk, Eduard Ayuso, Fatima Bosch, Catherine Postic, Albert K. Groen, Johan Auwerx, Kristina Schoonjans
Maaike H. Oosterveer, Chikage Mataki, Hiroyasu Yamamoto, Taoufiq Harach, Norman Moullan, Theo H. van Dijk, Eduard Ayuso, Fatima Bosch, Catherine Postic, Albert K. Groen, Johan Auwerx, Kristina Schoonjans
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Research Article Metabolism

LRH-1–dependent glucose sensing determines intermediary metabolism in liver

Abstract

Liver receptor homolog 1 (LRH-1), an established regulator of cholesterol and bile acid homeostasis, has recently emerged as a potential drug target for liver disease. Although LRH-1 activation may protect the liver against diet-induced steatosis and insulin resistance, little is known about how LRH-1 controls hepatic glucose and fatty acid metabolism under physiological conditions. We therefore assessed the role of LRH-1 in hepatic intermediary metabolism. In mice with conditional deletion of Lrh1 in liver, analysis of hepatic glucose fluxes revealed reduced glucokinase (GCK) and glycogen synthase fluxes as compared with those of wild-type littermates. These changes were attributed to direct transcriptional regulation of Gck by LRH-1. Impaired glucokinase-mediated glucose phosphorylation in LRH-1–deficient livers was also associated with reduced glycogen synthesis, glycolysis, and de novo lipogenesis in response to acute and prolonged glucose exposure. Accordingly, hepatic carbohydrate response element-binding protein activity was reduced in these animals. Cumulatively, these data identify LRH-1 as a key regulatory component of the hepatic glucose-sensing system required for proper integration of postprandial glucose and lipid metabolism.

Authors

Maaike H. Oosterveer, Chikage Mataki, Hiroyasu Yamamoto, Taoufiq Harach, Norman Moullan, Theo H. van Dijk, Eduard Ayuso, Fatima Bosch, Catherine Postic, Albert K. Groen, Johan Auwerx, Kristina Schoonjans

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Figure 6

Impaired GCK activity in Alb-Cre;Lrh1fl/fl mice reduces ChREBP expression and activity.

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Impaired GCK activity in Alb-Cre;Lrh1fl/fl mice reduces ChREBP expressio...
(A) Hepatic Chrebp, Pklr, Srebp-1c, and G6pd1 expression in fed, 24-hour–fasted, or 6-hour–refed Lrh1fl/fl mice (white bars) and Alb-Cre;Lrh1fl/fl mice (black bars) (n = 7–9 per genotype). (B) Nuclear ChREBP protein expression in 24-hour–fasted and 6-hour–refed Lrh1fl/fl and Alb-Cre;Lrh1fl/fl mice. (C) Hepatic G6P content in fasted and refed Lrh1fl/fl mice (white bars) and Alb-Cre;Lrh1fl/fl mice (black bars) (n = 6–7 per genotype). (D) Hepatic Chrebp and Pklr expression in Alb-Cre;Lrh1fl/fl mice 5 weeks after in vivo transduction of the liver using AAV8-SHP virus (gray bars) in comparison with that in Lrh1fl/fl mice (white bars) and Alb-Cre;Lrh1fl/fl mice (black bars) (n = 4–5 per group). (E) Luciferase activities in HeLa cells transfected with Chrebp (ChREBP-Luc) or SHP (SHP-Luc) promoter (black bars) constructs in the absence (empty; white bars) or presence (LRH-1; black bars) of LRH-1. Data are expressed as relative light units and normalized to empty reporter (pGL3). (F) Hepatic mRNA levels in Alb-Cre;Lrh1fl/fl mice 5 weeks after in vivo transduction of the liver using 2 different titers of AAV8-GCK virus (low, 1011 particles per mouse [light gray bars], and high, 1012 particles per mouse [dark gray bars]) in comparison with those in Lrh1fl/fl mice (white bars) and Alb-Cre;Lrh1fl/fl mice (black bars) (n = 4–5 per group). Data represent mean ± SEM. *P < 0.05 versus Lrh1fl/fl or versus empty vector (pCMX); #P < 0.05 versus Alb-Cre;Lrh1fl/fl.