Project description:3 ventricles from E18.5 male mice were pooled for each array. Three arrays per genotype. Title: ERRγ Directs and Maintains the Transition to Oxidative Metabolism in the Post-Natal Heart; Abstract: At birth the heart undergoes a critical metabolic switch to transition from a predominant dependence on carbohydrates during fetal life to a greater dependence on postnatal oxidative metabolism. This remains the principle metabolic state throughout life; although pathologic conditions such as heart failure and cardiac hypertrophy reactivate components of the fetal genetic program to increase carbohydrate utilization. Disruption of the ERRγ gene, which is expressed at high levels in the fetal and postnatal mouse heart, blocks this switch resulting in lactatemia, electrocardiographic (ECG) abnormalities and death during the first week of life. Genomic ChIP-on-chip and expression analysis at E18.5 clearly identifies ERRγ as both a direct and indirect regulator of a nuclear-encoded mitochondrial genetic network that coordinates the postnatal metabolic transition. These findings reveal an unexpected and essential molecular genetic component of the oxidative metabolic gene program in the heart and highlight ERRγ in the study of cardiac hypertrophy and failure. Experiment Overall Design: Fetal mice were collected by caesarean secation. Hearts were stored in RNALater (Qiagen)

Project description:During late gestation, the fetal heart relies primarily on glucose and lactate to support rapid growth and development. While numerous studies describe changes in heart metabolism a few weeks after birth to preferentially utilize fatty acids, little is known about metabolic changes of the heart within the first day of life. Therefore, we used the ovine model of pregnancy to investigate metabolic differences between the near-term fetal and the newborn heart. We observed greater abundance of metabolites involved in butanoate and propanoate metabolism, and glycolysis/gluconeogenesis in the term fetal heart (FDR-corrected p<0.10) and differential expression in these pathways were confirmed with single-sample gene set enrichment analysis (ssGSEA) (FDR-corrected p<0.05). Immediately following birth, newborn hearts displayed enrichment in purine, fatty acid, and glycerophospholipid metabolic pathways, as well as oxidative phosphorylation with significant alterations in lipids and metabolites to support transcriptomic findings. While other studies suggest a switch from carbohydrate metabolism to fatty acid metabolism in the neonatal heart in as early as 2 weeks following birth, our data show that this metabolic switch in the heart begins by the first day of postnatal life. A better understanding of metabolic alterations that occur in the heart following birth may improve treatment of neonates at risk for heart failure.

Project description:Neurons utilize glucose to generate adenosine triphosphate (ATP) essential for their survival, excitability and synaptic signaling, as well as initiating changes in neuronal structure and function. Defects in oxidative metabolism and mitochondria functions are also associated with aging and diverse human neurological diseases1-4. While neurons are known to adapt their metabolism to meet the increased energy demands of complex behaviors such as learning and memory, the molecular underpinnings regulating this process remain poorly understood4-6. Here we show that the orphan nuclear receptor estrogen related receptor gamma (ERRγ) becomes highly expressed during retinoic-acid induced neurogenesis and is widely expressed in neuronal nuclei throughout the brain. Mechanistically, we show that ERRγ directly orchestrates the expression of networks of genes involved in mitochondrial oxidative phosphorylation and energy generation in neurons. The importance of this regulation is evidenced by decreased adaptive metabolic capacity in cultured neurons lacking ERRγ, and reduced long-term potentiation (LTP) in ERRγ-/- hippocampal slices. Notably, the defect in LTP was rescued by the metabolic intermediate pyruvate, functionally linking the ERRγ knockout metabolic phenotype and memory formation. Consistent with this notion, mice lacking neuronal ERRγ exhibit defects in spatial learning and memory. These findings implicate ERRγ in the metabolic adaptations required for long-term memory formation. We used ChIP-Seq analysis to determine the genome-wide binding of ERRγ in neurons derived from ES cells.

Project description:Neurons utilize glucose to generate adenosine triphosphate (ATP) essential for their survival, excitability and synaptic signaling, as well as initiating changes in neuronal structure and function. Defects in oxidative metabolism and mitochondria functions are also associated with aging and diverse human neurological diseases1-4. While neurons are known to adapt their metabolism to meet the increased energy demands of complex behaviors such as learning and memory, the molecular underpinnings regulating this process remain poorly understood4-6. Here we show that the orphan nuclear receptor estrogen related receptor gamma (ERRγ) becomes highly expressed during retinoic-acid induced neurogenesis and is widely expressed in neuronal nuclei throughout the brain. Mechanistically, we show that ERRγ directly orchestrates the expression of networks of genes involved in mitochondrial oxidative phosphorylation and energy generation in neurons. The importance of this regulation is evidenced by decreased adaptive metabolic capacity in cultured neurons lacking ERRγ, and reduced long-term potentiation (LTP) in ERRγ-/- hippocampal slices. Notably, the defect in LTP was rescued by the metabolic intermediate pyruvate, functionally linking the ERRγ knockout metabolic phenotype and memory formation. Consistent with this notion, mice lacking neuronal ERRγ exhibit defects in spatial learning and memory. These findings implicate ERRγ in the metabolic adaptations required for long-term memory formation. We used microarray analysis to compare the genome-wide gene expression changes between wild type (WT) and ERRγ-/- P0 cerebral cortex as it contains mainly neuronal lineage at this stage compared to adult cortex.

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the motherM-bM-^@M-^Ys milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions. Liver gene expression was measured in mice with a maternally-inherited deletion of the miR-379/miR-410 cluster and in wild-type littermates at embryonic day E19.5, 4h following the caesarean delivery (n=4 biological replicates per genotype)

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the motherM-bM-^@M-^Ys milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions. Liver gene expression at P1 was measured in neonates with a maternally-inherited deletion of the miR-379/miR-410 cluster (KO) and compared to that of wild-type littermates (n=5). KO_normoglycemic and KO_hypoglycemic individuals correspond to mutant pups wild mild hypoglycemia (n=3) and with severe hypoglycemia (n =7), respectively.

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the motherM-bM-^@M-^Ys milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions. Liver gene expression was measured in mice with a maternally-inherited deletion of the miR-379/miR-410 cluster (KO) and in wild-type littermates (WT) at embryonic day E19.5 (n=3 per genotype) and on the day of birth (P0, n=4 WT and 5 KO).

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the mother’s milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions.

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the mother’s milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions.

Project description:In placental mammals, adaptation to extra-uterine life requires complex metabolic adjustments linked to the abrupt transition from the transplacental transfer of glucose toward the use of fat originating from the mother’s milk as a major energy source. The study of a novel knock-out mouse model led us to identify the biological roles of the miR-379/miR-410 cluster at the imprinted Dlk1-Dio3 region during this metabolic transition. The miR-379/miR-410 cluster is the largest mammalian-specific miRNA cluster composed of 39 pre-miRNA and expressed from the maternally-inherited allele. We unexpectedly found that ~ 35% of heterozygous neonates with a maternal - but not paternal - deletion of the entire 40kb-long miRNA cluster die shortly after birth due to defects in the maintenance of energy homeostasis, as evidenced by impaired hepatic glycogenolysis, gluconeogenesis and ketogenesis. This maladaptive metabolic response is accompanied by profound changes in the neonatal hepatic gene expression program, notably a decrease in the activation of a large set of metabolic genes linked to lipid metabolism. Our study unveils essential roles for the miR-379/miR-410 cluster at the transition from fetal to postnatal life, revealing new layers of RNA-mediated gene regulation at the Dlk1-Dio3 domain that impose parent-of-origin effects on postnatal metabolic functions.