Genetically increasing flux through b-oxidation in skeletal muscle increases mitochondrial reductive stress and glucose intolerance

Biochemistry, Genetics and Molecular Biology

• Skeletal Muscle 100%
• Glucose 100%
• Stress 100%
• Alpha Oxidation 100%
• Mouse 50%
• Fat 37%
• Beta Oxidation 37%
• Insulin Resistance 25%
• Lipid 25%
• Wild Type Mouse 25%
• Glucose Transport 25%
• Energy 12%
• Insulin 12%
• Mitochondrial Respiration 12%
• Metabolic Pathway 12%
• Mitochondrion 12%
• Genetic Model 12%
• Homeostasis 12%
• Bioenergy 12%
• Metabolic Regulation 12%
• Hydrogen Peroxide 12%
• Body Fat 12%
• Catalase 12%
• Membrane Potential 12%
• Peroxisome Proliferator-Activated Receptor 12%
• Energy Expenditure 12%

Medicine and Dentistry

• Glucose Intolerance 100%
• Muscle 100%
• Skeletal Muscle 100%
• Stress 100%
• Lipid Diet 37%
• Fatty Acid Oxidation 37%
• Hydrogen Peroxide 37%
• Insulin Resistance 25%
• Lipid 25%
• Absence 25%
• Glucose Uptake 25%
• Glucose Tolerance 25%
• Metabolism 12%
• Insulin 12%
• Metabolic Regulation 12%
• Homeostasis 12%
• Energy Expenditure 12%
• Mitochondrion 12%
• Metabolic Stress 12%
• Body Fat 12%
• Fatty Liver 12%
• Catalase 12%
• Membrane Potential 12%
• Peroxisome Proliferator Activated Receptor 12%
• Mitochondrial Respiration 12%

Neuroscience

• Skeletal Muscle 100%
• Glucose 100%
• Fat 50%
• Insulin 37%
• Fatty Acids 37%
• Lipid 25%
• Glucose Transport 25%
• Mitochondrial Respiration 12%
• Mitochondrion 12%
• Mitochondrial Function 12%
• Membrane Potential 12%
• Hydrogen Peroxide 12%
• Peroxisome Proliferator-Activated Receptor 12%
• Catalase 12%
• Energy Expenditure 12%