Project description:The liver is essential for fatty acid utilization during fasting. Fatty acids released by lipolysis from adipose tissue during fasting are taken up from the blood by hepatocytes and esterified as triacylglycerols for oxidative metabolization and ketogenesis. Whereas the regulation of fatty acid oxidation in hepatocytes is well understood, transport of non-esterified fatty acids (NEFAs) from the liver sinusoidal lumen to the hepatocyte is not. Here, we show that murine hepatic stellate cells (HSCs), enveloping the liver sinusoids as pericytes, and their abundantly expressed plasmalemma vesicle-associated protein (PLVAP) control hepatic NEFA uptake during fasting. HSC-specific ablation of PLVAP suppresses hepatocyte fatty acid esterification to di- and triacylglycerols along with fasting fatty acid utilization and ketogenesis. Consistently, single cell-resolved transcriptomics further revealed severe perturbation of hepatocyte gene programs governing normal fatty acid handling, oxidation, and ketogenesis. By super-resolution microscopy we localized HSC PLVAP to caveolae residing along the sinusoidal lumen strongly supporting a role for PLVAP in caveolar transcytosis of NEFAs across HSCs and hence the sinusoid wall as rate-limiting for hepatic fatty acid utilization during fasting. This was supported by a similar decline in neutral lipid droplet formation in livers of fasting Caveolin-1 knockout mice. Altogether, our study shows vital roles for PLVAP and for HSCs in normal fasting metabolism of liver.

Project description:Contacts between organelles create microdomains that play major roles in regulating key intracellular activities and signaling pathways, but whether they also regulate systemic functions remains unknown. Here, we report the ultrastructural organization and dynamics of the inter-organellar contact established by rough-Endoplasmic Reticulum closely wrapped around the mitochondria (wrappER). To elucidate the in vivo function of this contact, mouse liver fractions enriched in wrappER-associated-mitochondria are analyzed by transcriptomics, proteomics and lipidomics. The biochemical signature of the wrappER points to a role in the biogenesis of very-low-density lipoproteins (VLDL). Altering wrappER-mitochondria contacts curtails VLDL secretion and increases hepatic fatty acids, lipid droplets and neutral lipid content. Conversely, acute liver-specific ablation of Mttp, the most upstream regulator of VLDL biogenesis, recapitulates this hepatic dyslipidemia phenotype and promotes remodelling of the wrappER-mitochondria contact. The discovery that liver wrappER-mitochondria contacts participate in VLDL biology suggests an involvement of inter-organelle contacts in systemic lipid homeostasis.

Project description:*Objectives:* In addition to their well-known role in the control of cellular proliferation and cancer, cell cycle regulators are increasingly identified as important metabolic modulators. Genome wide association studies identified SNPs near the cell cycle regulator CDKN2A/p16INK4a (p16) as strongly associated with risk of developing type 2 diabetes (T2D). T2D is associated with numerous perturbations of hepatic lipid and glucose metabolism. We have recently shown that p16 controls fasting-induced hepatic gluconeogenesis in mice. However, whether p16 may also affect hepatic lipid homeostasis is unknown. *Results:* In primary hepatocytes, p16-deficiency was associated with elevated expression of genes involved in fatty acid catabolism and enhanced activation of PPAR. This led to increased mitochondrial fatty acid oxidation (FAO) through a mechanism requiring the catalytic AMPK 2 subunit and SIRT1. By contrast, *p16* overexpression was associated with triglyceride accumulation and increased lipid droplet numbers *in vitro*, and decreased ketogenesis and hepatic mitochondrial activity *in vivo*. Gene expression analysis of human liver samples revealed a negative correlation between *CDKN2A* expression and *PPARA* and its target genes, suggesting a potential association between hepatic p16 expression and FAO in obese humans. *Conclusions:* Our findings demonstrate that p16 plays a key role in hepatic lipid metabolism and may thus contribute to the development of metabolic diseases.

Project description:Contacts between organelles create microdomains that play major roles in regulating key intracellular activities and signaling pathways, but whether they also directly regulate systemic cellular activities, remains unknown. Here, we report the ultrastructural organization and dynamics of a new type of inter-organelle contact which is formed by rough-Endoplasmic Reticulum that is closely wrapped around the mitochondrion (wrappER). To elucidate the in vivo function of this inter-organelle association, mouse liver fractions enriched in wrappER-associated-mitochondria were analyzed in parallel by transcriptomics, proteomics, and lipidomics. The biochemical signature of the wrappER points to an unexpected role in the biogenesis of very-low-density lipoproteins (VLDLs). Altering wrappER-mitochondria contacts curtails liver VLDL secretion and increases hepatic fatty acids, lipid droplets and neutral lipid content. Conversely, acute liver-specific ablation of Mttp, the most upstream regulator of VLDL biogenesis, mirrors this hepatic dyslipidemia phenotype and promotes remodelling of the wrappER-mitochondria contact. The participation of liver wrappER-mitochondria contacts in VLDL biology reveals a role of inter-organelle contacts in systemic lipid homeostasis.

Project description:Hepatic ketogenesis is crucial for energy homeostasis in a fast state, whereas defective ketogenesis is associated with various diseases. We explored the role of PAK4, an oncoprotein, in ketogenesis. To investigate the molecular basis, we carried out RNA-sequencing analysis using littermate WT and hepatocyte-specific Pak4 KO mice in fasted conditions.

Project description:A reduction in hepatocyte growth hormone (GH)-signaling promotes non-alcoholic fatty liver disease (NAFLD). However, debate remains as to the relative contribution of the direct effects of GH on hepatocyte function vs indirect effects, via alterations in insulin-like growth factor 1 (IGF1). To isolate the role of hepatocyte GH receptor (GHR) signaling, independent of changes in IGF1, mice with adult-onset, hepatocyte-specific GHR knockdown (aHepGHRkd) were treated with a vector expressing rat IGF1 targeted specifically to hepatocytes. Compared to GHR-intact mice, aHepGHRkd reduced circulating IGF1 and elevated GH. In male aHepGHRkd, the shift in IGF1/GH did not alter plasma glucose or non-esterified fatty acids (NEFA), but was associated with increased insulin, enhanced systemic lipid oxidation and reduced white adipose tissue (WAT) mass. Livers of male aHepGHRkd exhibited steatosis associated with increased de novo lipogenesis, hepatocyte ballooning and inflammation. In female aHepGHRkd, hepatic GHR protein levels were not detectable, but moderate levels of IGF1 were maintained, with minimal alterations in systemic metabolism and no evidence of steatosis. Reconstitution of hepatocyte IGF1 in male aHepGHRkd lowered GH and normalized insulin, whole body lipid utilization and WAT mass. However, IGF1 reconstitution did not reduce steatosis or eliminate liver injury. RNAseq analysis showed IGF1 reconstitution did not impact aHepGHRkd-induced changes in liver gene expression, despite changes in systemic metabolism. These results demonstrate the impact of aHepGHRkd is sexually dimorphic and the steatosis and liver injury observed in male aHepGHRkd mice is autonomous of IGF1, suggesting GH acts directly on the adult hepatocyte to control NAFLD progression.

Project description:This SuperSeries is composed of the SubSeries listed below. Summary: The liver is essential for normal fatty acid utilization during fasting. Circulating fatty acids are taken up by hepatocytes and esterified as triacylglycerols for either oxidative metabolization and ketogenesis or export. Whereas the regulation of fatty acid oxidation in hepatocytes is well understood, the uptake and retention of non-esterified fatty acids by hepatocytes is not. Here, we show that murine hepatic stellate cells (HSCs) and their abundantly expressed plasmalemma vesicle-associated protein (PLVAP) control hepatic substrate preference for fasting energy metabolism. HSC-specific ablation of PLVAP in mice elevated hepatic insulin signaling and improved glucose tolerance. Fasted HSC PLVAP knockout mice showed suppressed hepatic fatty acid esterification to di- and triacylglycerols shifting fasting metabolism from fatty acid oxidation to reliance on carbohydrates. By super-resolution microscopy we localized HSC PLVAP to caveolae residing along the sinusoidal lumen supporting a role for HSCs and PLVAP-diaphragmed caveolae in normal fasting metabolism of the liver.

Project description:The liver is essential for normal fatty acid utilization during fasting. Circulating fatty acids are taken up by hepatocytes and esterified as triacylglycerols for either oxidative metabolization and ketogenesis or export. Whereas the regulation of fatty acid oxidation in hepatocytes is well understood, the uptake and retention of non-esterified fatty acids by hepatocytes is not. Here, we show that murine hepatic stellate cells (HSCs) and their abundantly expressed plasmalemma vesicle-associated protein (PLVAP) control hepatic substrate preference for fasting energy metabolism. HSC-specific ablation of PLVAP in mice elevated hepatic insulin signaling and improved glucose tolerance. Fasted HSC PLVAP knockout mice showed suppressed hepatic fatty acid esterification to di- and triacylglycerols shifting fasting metabolism from fatty acid oxidation to reliance on carbohydrates. By super-resolution microscopy we localized HSC PLVAP to caveolae residing along the sinusoidal lumen supporting a role for HSCs and PLVAP-diaphragmed caveolae in normal fasting metabolism of the liver.

Project description:The liver is essential for normal fatty acid utilization during fasting. Circulating fatty acids are taken up by hepatocytes and esterified as triacylglycerols for either oxidative metabolization and ketogenesis or export. Whereas the regulation of fatty acid oxidation in hepatocytes is well understood, the uptake and retention of non-esterified fatty acids by hepatocytes is not. Here, we show that murine hepatic stellate cells (HSCs) and their abundantly expressed plasmalemma vesicle-associated protein (PLVAP) control hepatic substrate preference for fasting energy metabolism. HSC-specific ablation of PLVAP in mice elevated hepatic insulin signaling and improved glucose tolerance. Fasted HSC PLVAP knockout mice showed suppressed hepatic fatty acid esterification to di- and triacylglycerols shifting fasting metabolism from fatty acid oxidation to reliance on carbohydrates. By super-resolution microscopy we localized HSC PLVAP to caveolae residing along the sinusoidal lumen supporting a role for HSCs and PLVAP-diaphragmed caveolae in normal fasting metabolism of the liver.

Project description:Gene expression in livers of wild type adult male mice and in lncRNA 3930402G23Rik ("G23Rik") knockdown adult male mouse liver was assayed by RNA-seq, as part of a study of liver transcriptomic changes in response to activation of PPARA by WY-14,643, published in Molecular and Cellular Endocrinology (2022). These studies found that G23Rik-null mice were more susceptible to hepatic lipid accumulation in response to acute fasting. Histological analysis further revealed a pronounced buildup of lipid droplets and a significant increase in neutral triglycerides and lipids as indicated by enhanced oil red O staining of liver sections. Hepatic cholesterol, non-esterified fatty acid, and triglyceride levels were significantly elevated in G23Rik-null mice and associated with induction of the lipid-metabolism related gene Cd36. These findings provide evidence for a lncRNA dependent mechanism by which PPARA attenuates hepatic lipid accumulation in response to metabolic stress through lncRNA G23Rik induction.