Search results for "MITOCHONDRIAL BIOGENESIS"

showing 5 items of 45 documents

Antioxidant supplements in exercise: worse than useless?

2012

TO THE EDITOR: In a recent paper by Higashida et al. (5), the authors report that very large doses of antioxidant vitamins do not prevent the exercise-induced adaptive responses of muscle mitochondria, GLUT4, and insulin action to exercise. As clearly stated in the paper, their data disagree with those reported by three independent research groups from Germany (14), Australia (17), and Spain (4). Using a significantly different experimental protocol regarding exercise training intensity and duration, antioxidant supplementation (doses and types of antioxidants), and molecular parameters analyzed (mRNA vs. protein levels), Higashida et al. compared their data with ours and came to exactly th…

medicine.medical_specialtyAntioxidantVitamin CbiologyPhysiologybusiness.industryEndocrinology Diabetes and Metabolismmedicine.medical_treatmentInsulinSkeletal muscleClinical nutritionmedicine.anatomical_structureEndocrinologyMitochondrial biogenesisPhysiology (medical)Internal medicinemedicinebiology.proteinbusinessInhibitory effectGLUT4American Journal of Physiology-Endocrinology and Metabolism
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Could thiazolidinediones increase the risk of heart failure in Friedreich's ataxia patients?

2011

Clinical evidence and the recent decisions of the European Medicines Agency and the Food and Drug Administration challenge the safety of thiazolidinediones treatment. Recently, this treatment has been suggested for Friedreich's ataxia because thiazolidinediones improve neurological symptoms. Hypertrophic cardiomyopathy is the most prevalent cardiac feature and the cause of premature death in Friedreich's ataxia patients. We recommend that therapy with peroxisome proliferator-activated receptor-gamma agonists like thiazolidinediones be taken with caution, as they cause a decrease in the number of fast fibers and an increase in mitochondrial biogenesis in cardiac muscle because of the inducti…

medicine.medical_specialtyAtaxiaHeart diseasebusiness.industryInsulinmedicine.medical_treatmentHypertrophic cardiomyopathymedicine.diseaseBioinformaticsEndocrinologyNeurologyMitochondrial biogenesisHeart failureInternal medicinemedicineNeurology (clinical)medicine.symptomRosiglitazonebusinessPioglitazonemedicine.drugMovement Disorders
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Mitochondrial dysfunction in cholestatic liver diseases

2011

et al.

medicine.medical_specialtyMitochondrial DNABiliary cirrhosisMitochondrial HepatopathyApoptosisReviewBiologyMitochondrionmedicine.disease_causeGeneral Biochemistry Genetics and Molecular BiologyLiver diseaseCholestasisInternal medicinemedicineHumansBiología y BiomedicinaCholestasisGeneral Immunology and MicrobiologyLiver Diseasesmedicine.diseaseBile acidsCell biologyMitochondriaEndocrinologyMitochondrial biogenesisOxidative stressMitochondrial functionMitochondrial dysfunctionOxidative stressFrontiers in Bioscience (Elite edition) 4: 2233-2252 (2012)
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PGC-1 isoforms and their target genes are expressed differently in human skeletal muscle following resistance and endurance exercise

2015

The primary aim of the present study was to investigate the acute gene expression responses of PGC-1 isoforms and PGC-1a target genes related to mitochondrial biogenesis (cytochrome C), angiogenesis (VEGF-A), and muscle hypertrophy (myostatin), after a resistance or endurance exercise bout. In addition, the study aimed to elucidate whether the expression changes of studied transcripts were linked to phosphorylation of AMPK and MAPK p38. Nineteen physically active men were divided into resistance exercise (RE, n = 11) and endurance exercise (EE, n = 8) groups. RE group performed leg press exercise (10 9 10 RM, 50 min) and EE walked on a treadmill (~80% HRmax, 50 min). Muscle biopsies were ob…

medicine.medical_specialtybiologysplice variantPhysiologyVastus lateralis musclePGC-1αphysical activitySkeletal muscleta3141MyostatinMuscle hypertrophyExonmedicine.anatomical_structureEndocrinologyPGC1-1βMitochondrial biogenesisEndurance trainingPhysiology (medical)Internal medicineGene expressionmedicinebiology.proteinta315Original ResearchPhysiological Reports
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The oxidative capacity of skeletal muscle : effects of genotype, high-fat diet and physical activity

2016

sopeutuminenmitochondrial biogenesisrasvatexerciselihaksetliikuntafysiologiaadaptationhiiretruokavaliotgenotyyppiangiogenesishigh-fat dietgene expressionmetabolinen oireyhtymäfyysinen aktiivisuushapenotto
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