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:Accumulating studies have shown that mitochondria-lipid droplet (LD) interaction is crucial for maintaining the homeostasis of lipid metabolism in the liver. However, the proteins involved in mitochondria-LD interaction and the functioning mechanism remain largely elusive. Here, we applied a systematic approach to characterize the proteome of mitochondria-LD contacts under normal or starvation condition by combining the bimolecular fluorescence complementary assay and a proximity labeling strategy. We first established a reporter of mitochondria-LD contacts in HepG2 cells and demonstrated that mitochondria-LD contacts are pretty sensitive to nutritional stresses. Furthermore, we uncovered 60 proteins are up-or down-regulated at contact sites upon starvation. Finally, we validated that SQLE translocates from endoplasmic reticulum to LDs and accumulates at mitochondria-LD contact sites upon starvation so as to utilize local ATP for cholesterol synthesis. This work also provides a versatile tool to profile the proteomes of any other inter-organelle membrane contacts in living cells.

Project description:Inter-organelle membrane contacts especially mitochondria-endoplasmic reticulum contacts (MERC) conduct important biological functions including exchange of lipids and ions, and modulation of membrane dynamics. Alterations of inter-organelle membrane contacts have been implicated with the pathogenesis of diseases, such as neurodegenerative diseases, cancers and type 2 diabetes. However, the protein compositions of inter-organelle contacts remain largely unknown as no biomarker has been discovered and it’s difficult to purify intact inter-organelle contact proteins. Here, we applied a systematic approach to probe the spatial proteome of MERC in living cells by combining the bimolecular fluorescence complementation assay and a proximity labeling strategy based on APEX2. As a result, we discovered 403 highly confident MERC proteins including many well-known MERC proteins and a variety of novel protein species as well. We further validated that WFS1, BAG2, SPTLC1 and GLUD1 are enriched at MERC with high resolution fluorescent imaging. Our study provides a powerful tool to characterize the spatial proteomes of inter-organelle membrane contacts in living cells.

Project description:Hepatic lipid homeostasis depends on intracellular pathways that respire fatty acid in peroxisomes and mitochondria, and on systemic pathways that secrete fatty acid into the bloodstream, either free or condensed in very-low-density lipoprotein (VLDL) triglycerides. These systemic and intracellular pathways are interdependent, but it is unclear whether and how they integrate into a single cellular circuit. Here, we report that mouse liver wrappER, a distinct endoplasmic reticulum (ER) compartment with apparent fatty acid- and VLDL secretion functions, connects peroxisomes and mitochondria. Correlative light electron microscopy, quantitative serial section electron tomography and three-dimensional organelle reconstruction analysis show that the number of peroxisome-wrappER-mitochondria complexes changes throughout fasting-to-feeding transitions and doubles when VLDL synthesis stops following acute genetic ablation of Mttp in the liver. Quantitative proteomic analysis of peroxisome-wrappER-mitochondria complex-enriched fractions indicates that the loss of Mttp upregulates global fatty acid ?-oxidation, thereby integrating the dynamics of this three-organelle association into hepatic fatty acid flux responses. Therefore, liver lipid homeostasis occurs through the convergence of systemic and intracellular fatty acid-elimination pathways in the peroxisome-wrappER-mitochondria complex.

Project description:Major causes of lipid accumulation in liver are increased import, synthesis or decreased catabolism of fatty acids. The latter is caused by dysfunction of cellular organelle controlling energy homeostasis, i.e. mitochondria. However, peroxisomes appear to be an important organelle in lipid metabolism of hepatocytes, but little is known about their role in the development of non-alcoholic fatty liver disease (NAFLD). To investigate the role of peroxisomes next to mitochondria in excessive hepatic lipid accumulation we used the leptin resistant db/db mice on C57BLKS background, a mouse model that develops hyperphagia induced diabetes with obesity and NAFLD. We used microarrays to determine differences in hepatic gene expression in a mouse model for NAFDL (BKS.Cg-Leprdb (db/db)) and their wildtype littermates C57BL/KSlepr+/+ (BKS) to determine the effect of persistent hepatic lipid accumulation.

Project description:Mitochondria-Rough-ER Contacts in The Liver Regulate Systemic Lipid Homeostasis

Project description:Purpose: MetS consist of five risk factors: elevated blood pressure and fasting glucose, visceral obesity, dyslipidemia and hypercholesterinemia. The physiological impact of lipid metabolism indicated as visceral obesity and hepatic lipid accumulation is still under debate. One major cause of disturbed lipid metabolism might be dysfunction of cellular organelles controlling energy homeostasis, i.e. mitochondria and peroxisomes. Experimental design: The New Zealand Obese (NZO) mouse model exhibits a polygenic syndrome of obesity, insulin resistance, triglyceridemia and hypercholesterolemia that resembles human metabolic syndrome. We applied a combinatorial approach of lipidomics with liver transcriptomics, 2D-DIGETM and mass spectroscopy based organelle proteomics of highly purified mitochondria and peroxisomes in male mice, to investigate molecular mechanisms related to the impact of lipid metabolism in the pathophysiology of the metabolic syndrome. Conclusions and clinical relevance: Proteome analyses of liver organelles indicated differences in fatty acid metabolism, oxidative stress and response, mainly influenced by PG-C1α/PPARα mediated pathways. These results were in accordance with serum lipid profiles and elevated organelle functionality. These data emphasize that metabolic syndrome is accompanied with increased mitochondria and peroxisomal activity controlling directly cellular energy homeostasis to cope with dyslipidemia and hypercholesterinemia driven hepatic lipid overflow in developing a fatty liver.

Project description:Obesity induced non-alcoholic fatty liver disease (NAFLD) is associated with the development of type 2 diabetes and constitutes a major health problem. A hallmark of the diseases is extensive lipid droplet (LD) formation and accumulation of toxic lipid species interfering with cellular signaling and functions. However, the cellular mechanisms during disease progression and cellular lipid overflow are poorly understood. Here, we develop a novel workflow for label free mass spectrometry based protein and phosphopeptide correlation profiling to systematically monitor the level and cellular distribution of ~6000 liver proteins and ~16,000 phosphosites during the development of dietary induced steatosis in mice. We see a redistribution of the secretory apparatus including a mislocalization of the COPI complex, and targeting of all analyzed Golgi apparatus proteins to LDs what leads to a general reduction of hepatic protein secretion. Further, we identify targeting of several organelle contact site proteins to LDs, accompanied by increased contacts between LDs and other organelles. Our resource provides the first systematic in vivo analysis of subcellular re-arrangements and organelle specific phosphorylation during disease development.

Project description:Organelle communication is largely mediated by proteins at membrane contact sites (MCS), such as the endoplasmic reticulum (ER)-mitochondria, ER-plasma membrane (PM), and mitochondria-lipid droplets (LD). In this project, we developed a new tool for identifying membrane proteins at MCS by utilizing two mutually orthogonal binding pair systems, streptavidin-biotin (SA-Bt) and cucurbit[7]uril-adamantane (CB[7]-Ad), in conjunction with two distinct engineered enzymes, TurboID and APEX2. This enabled us to successfully identify proteins at the contact sites of the ER and mitochondria, and further allowed us to detect protein sets that undergo structural and locational changes at the ER-mitochondria contact site during the process of mitophagy.

Project description:The intimate association between the endoplasmic reticulum (ER) and mitochondrial membranes at ER-mitochondria contact sites (ERMCS) serves as a platform for several critical cellular processes, in particular lipid synthesis. Enzymes involved in lipid biosynthesis are enriched at contacts and membrane lipid composition at contacts is distinct relative to surrounding membranes. How contacts are remodeled and the subsequent biological consequences of altered contacts such as perturbed lipid metabolism remains poorly understood. Here we investigate if the ER-tethered ubiquitin-X domain adaptor 8 (UBXD8) regulates the lipids found in mitochondria-associated membranes (MAM). LC-MS/MS lipidomics found significant changes in distinct lipid species in the MAM fraction of UBXD8 knockout cells. Our results suggest that lipids in MAM are regulated by UBXD8.