Project description:Mitochondrial integrated stress response emerged as a major adaptive pathway to respiratory chain deficiency, but tissue-specifics of its regulation or how it adapts to different levels of mitochondrial dysfunction are largely unknown. Here we report that diverse levels of mitochondrial cardiomyopathy activate mitoISR, including high production of FGF21, a cytokine with both paracrine and endocrine function, shown to be induced by respiratory chain dysfunction. Remarkably, although being fully dispensable for the cell-autonomous and systemic responses to severe mitochondrial cardiomyopathy, in the conditions of mild-to-moderate cardiac OXPHOS dysfunction, FGF21 regulates a portion of the mitoISR. In the absence of FGF21, a large part of the metabolic adaptation to mitochondrial dysfunction (one-carbon metabolism, transsulfuration and serine and proline biosynthesis) is strongly blunted, independent of the primary mitoISR activator ATF4. Collectively, our work highlights the complexity of mitochondrial stress responses by revealing the importance of the tissue-specificity and dose-dependency of the mitoISR.

Project description:Fibroblast growth factor 21 (FGF21) is a key metabolic regulator which was recently discovered as stress-induced myokine and common denominator of muscle mitochondrial disease. However, its precise function and pathophysiological relevance remains unknown. Here we demonstrate that white adipose tissue (WAT) is the major target of muscle mitochondrial stress-induced FGF21. Strikingly, substantial browning and metabolic remodeling of subcutaneous WAT, together with the reduction of circulating triglycerides and cholesterol are fully FGF21 dependent. Unexpectedly and in contrast to prior expectations, we found a negligible role of FGF21 in muscle stress-related improved glycemic control, obesity resistance and hepatic lipid homeostasis. Furthermore, we show that the protective muscle mitohormesis and metabolic stress adaptation does not require FGF21 action. Taken together, our data imply that although FGF21 drives WAT remodeling, this effect and FGF21 as stress hormone per se may not be essential for the adaptive response under muscle mitochondrial stress conditions. Wildtype male mice and FGF21-knockout male mice, together with muscle specific UCP1-transgenic male animals, and double cross of FGF21-KO with UCP1-Tg male mice, were kept on a standardized low fat diet for 40 weeks. After sacrifice, subcutaneous white adipose tisseu (scWAT) was rapidly removed, weighed, and snap frozen in liquid nitrogen and used for RNA isolation and whole genome gene expression microarray hybridisation using Agilent arrays.

Project description:FGF21 modulates mitochondrial stress response in cardiomyocytes only under mild mitochondrial dysfunction

Project description:Dilated cardiomyopathy (DCM) is characterized by left ventricular dilation and continuous systolic dysfunction. Mitochondrial impairment is critical in DCM, but the mechanism remains to be elucidated. Here we explored the cardio-protective role of a heart-enriched long non-coding RNA (lncRNA), named dilated cardiomyopathy repressive transcript (DCRT), via maintaining mitochondrial function. We found the lncRNA DCRT was highly enriched in normal heart tissue and its expression was significantly down-regulated in myocardium of DCM patients. DCRT knockout in mice spontaneously developed cardiac dysfunction with cardiac enlargement and mitochondrial impairment. DCRT transgenic or overexpressed mice attenuated cardiac dysfunction induced by transverse aortic constriction (TAC) treatment.

Project description:Background & Aims: Transporters of the SLC25 mitochondrial carrier superfamily bridge cytoplasmic and mitochondrial metabolism by channeling metabolites across mitochondrial membranes and are pivotal for metabolic homeostasis. Despite their physiological relevance as gatekeepers of cellular metabolism, most of the SLC25 family members remain uncharacterized. We undertook a comprehensive tissue distribution analysis of all Slc25 family members across metabolic organs and identified SLC25A47 as a liver-specific mitochondrial carrier. Method: We used a murine loss-of-function (LOF) model to unravel the role of this transporter in mitochondrial and hepatic homeostasis. We performed extensive metabolic phenotyping and molecular characterization of Slc25a47hep-/- mice. Results: Slc25a47hep-/- mice displayed a wide variety of metabolic abnormalities, as a result of sustained energy deficiency in the liver originating from impaired mitochondrial respiration in this organ. This mitochondrial phenotype was associated with a robust activation of the mitochondrial stress response in the liver, which in turn, induced the secretion of several mitokines, amongst which FGF21 played a preponderant role in the translation of the effects of the MSR on systemic physiology. To dissect the FGF21-dependent and -independent physiological changes induced by the loss of Slc25a47, we generated a double Slc25a47-Fgf21 LOF mouse model, and demonstrated that several aspects of the hypermetabolic state was entirely driven by hepatic secretion of FGF21. On the other hand, the metabolic fuel inflexibility induced by loss of Slc25a47 could not be rescued by genetical removal of Fgf21. Conclusion: Collectively, our data place SLC25A47 at the center of mitochondrial homeostasis, which upon dysfunction triggers robust liver-specific and systemic adaptive stress responses.

Project description:CR6-interacting factor-1 (CRIF1) interacting with large mitoribosome subunits is essential for the maturation and insertion of oxidative phosphorylation (OxPhos) polypeptides into the mitochondrial inner membrane. Recently, it has reported that the genetic ablation of Crif1 in a tissue-specific manner results in mitochondrial stress response (MSR) including mitochondrial unfolded protein response (UPRmt). In this study, we aim to obtain a comprehensive understanding of systemic energy metabolism in response to hepatic mitochondrial dysfunction. Through the liver-specific Crif1 deficient mice (LKO), we explore the adaptive response not only in the liver but also in inguinal white adipose tissue (iWAT). Moreover, RNA sequencing in liver, iWAT, skeletal muscle, and hypothalamus suggest that hepatic mitochondrial dysfunction enhance metabolic pathways, including glycolysis, fatty acid elongation and degradation, and 1C metabolism in liver and insulin signaling in iWAT. RNA sequencing also suggests that hepato-mitokines, GDF15 and FGF21 are highly increased in liver of LKO mice. To identify the role of hepato-mitokines, we generate double knockout mice (LKO/Gdf15-/- and LKO/Fgf21-/-), suggesting that GDF15 is responsible for the regulation of the body and fat mass and FGF21 has a critical role for the insulin sensitivity and energy expenditure in this mice.

Project description:Altered Cardiac Energetics and Mitochondrial Dysfunction in Hypertrophic Cardiomyopathy

Project description:A comparison of epigenetic nuclear DNA methylation and gene expression changes between human dialated cardiomypathy left ventricle samples and non-failing cardiac left ventricule samples This study addresses how depletion of huaman cardiac left ventricle mitochondrial DNA and epigentic nuclear DNA methylation promote cardiac dysfunction in human dilated cardiomyopathy. Each sample was fluorescently labeled and hybridized to Roche Nimblegen 2.1M Deluxe Promoter Arrays and Expression arrays.

Project description:Fibroblast growth factor 21 (FGF21) is a key metabolic regulator which was recently discovered as stress-induced myokine and common denominator of muscle mitochondrial disease. However, its precise function and pathophysiological relevance remains unknown. Here we demonstrate that white adipose tissue (WAT) is the major target of muscle mitochondrial stress-induced FGF21. Strikingly, substantial browning and metabolic remodeling of subcutaneous WAT, together with the reduction of circulating triglycerides and cholesterol are fully FGF21 dependent. Unexpectedly and in contrast to prior expectations, we found a negligible role of FGF21 in muscle stress-related improved glycemic control, obesity resistance and hepatic lipid homeostasis. Furthermore, we show that the protective muscle mitohormesis and metabolic stress adaptation does not require FGF21 action. Taken together, our data imply that although FGF21 drives WAT remodeling, this effect and FGF21 as stress hormone per se may not be essential for the adaptive response under muscle mitochondrial stress conditions.

Project description:Progressive mitochondrial respiratory chain (RC) deficiency is associated with a wide spectrum of adult-onset degenerative diseases, as well as with normal aging. We have previously generated the Deletor mice to model late-onset progressive RC defects. Here we report novel tissue-specific pathways contributing to mitochondrial disease pathogenesis, identified by gene expression analysis. We found that RC-deficient muscle fibers secrete the fasting-induced hormone, fibroblast growth factor 21 (FGF21). This response leads to fatty acid recruitment from adipocytes and resistance to high-fat-diet induced obesity in mice, but does not affect glucose or insulin metabolism. FGF21 is also induced in the muscle of mitochondrial myopathy patients and in other RC-deficient mice. These data show that skeletal muscle is an endocrine organ, which signals its energy deficiency through FGF21. Furthermore, RC deficiency in single muscle fibers initiates a global starvation response. These data have important implications for conditions with primary or secondary RC deficiency. Mice overexpressing mutant Twinkle (C10ORF2) protein are the first animal model for Progressive External Ophtalmoplegia (PEO). Using PEO-model and wt-mice, skeletal muscle (quadriceps femoris) was analyzed for gene expression profile.