about
Dietary inorganic nitrate: From villain to hero in metabolic disease?β-Aminoisobutyric acid induces browning of white fat and hepatic β-oxidation and is inversely correlated with cardiometabolic risk factors.Increased hepatic oxidative metabolism distinguishes the action of Peroxisome proliferator-activated receptor delta from Peroxisome proliferator-activated receptor gamma in the ob/ob mouse.An in vivo zebrafish screen identifies organophosphate antidotes with diverse mechanisms of actionThe contrasting roles of PPARδ and PPARγ in regulating the metabolic switch between oxidation and storage of fats in white adipose tissue.Nitrate enhances skeletal muscle fatty acid oxidation via a nitric oxide-cGMP-PPAR-mediated mechanism.Targeted metabolomics.Mechanistic insights revealed by lipid profiling in monogenic insulin resistance syndromes.Metabolite profiling identifies pathways associated with metabolic risk in humansAdipose tissue fatty acid chain length and mono-unsaturation increases with obesity and insulin resistanceChemical and metabolomic screens identify novel biomarkers and antidotes for cyanide exposure.PPAR-pan activation induces hepatic oxidative stress and lipidomic remodelling.Metabolomics dataset of PPAR-pan treated rat liverA matter of fat: an introduction to lipidomic profiling methods.Metabolic phenotyping of a model of adipocyte differentiation.Relationship between postprandial metabolomics and colon motility in children with constipationToward new biomarkers of cardiometabolic diseases.Towards metabolic biomarkers of insulin resistance and type 2 diabetes: progress from the metabolome.A role for vaccinia virus protein C16 in reprogramming cellular energy metabolism.Erratum: Adipose tissue fatty acid chain length and mono-unsaturation increases with obesity and insulin resistance.Does inorganic nitrate say NO to obesity by browning white adipose tissue?Inorganic nitrate promotes the browning of white adipose tissue through the nitrate-nitrite-nitric oxide pathway.PTPMT1 Inhibition Lowers Glucose through Succinate Dehydrogenase Phosphorylation.Methods for performing lipidomics in white adipose tissue.Inorganic Nitrate Mimics Exercise-Stimulated Muscular Fiber-Type Switching and Myokine and γ-Aminobutyric Acid Release.Metabolomics and Lipidomics Study of Mouse Models of Type 1 Diabetes Highlights Divergent Metabolism in Purine and Tryptophan Metabolism Prior to Disease Onset.A type III complement factor D deficiency: Structural insights for inhibition of the alternative pathway.Response to Comment on Lee et al. Diabetes 2015;64:2836–2846. Comment on Roberts et al. Diabetes 2015;64:471–484Hepatic steatosis risk is partly driven by increased de novo lipogenesis following carbohydrate consumption.KHS101 disrupts energy metabolism in human glioblastoma cells and reduces tumor growth in miceIce-Age Climate Adaptations Trap the Alpine Marmot in a State of Low Genetic Diversity.Detergent-Free Simultaneous Sample Preparation Method for Proteomics and MetabolomicsChronic heart failure with diabetes mellitus is characterized by a severe skeletal muscle pathologyDivergent skeletal muscle mitochondrial phenotype between male and female patients with chronic heart failure
P50
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