about
OPA1-dependent cristae modulation is essential for cellular adaptation to metabolic demandGenipin-induced inhibition of uncoupling protein-2 sensitizes drug-resistant cancer cells to cytotoxic agentsA novel strategy involved in [corrected] anti-oxidative defense: the conversion of NADH into NADPH by a metabolic network.The tricarboxylic acid cycle, an ancient metabolic network with a novel twist.Mitochondrial lactate dehydrogenase is involved in oxidative-energy metabolism in human astrocytoma cells (CCF-STTG1).An ATP and oxalate generating variant tricarboxylic acid cycle counters aluminum toxicity in Pseudomonas fluorescens.Glutaredoxin-2 is required to control oxidative phosphorylation in cardiac muscle by mediating deglutathionylation reactions.Galactose enhances oxidative metabolism and reveals mitochondrial dysfunction in human primary muscle cellsExposure to a northern contaminant mixture (NCM) alters hepatic energy and lipid metabolism exacerbating hepatic steatosis in obese JCR rats.SPG7 variant escapes phosphorylation-regulated processing by AFG3L2, elevates mitochondrial ROS, and is associated with multiple clinical phenotypes.Teaching the fundamentals of electron transfer reactions in mitochondria and the production and detection of reactive oxygen species.Oxidative stress evokes a metabolic adaptation that favors increased NADPH synthesis and decreased NADH production in Pseudomonas fluorescensGlutathionylation state of uncoupling protein-2 and the control of glucose-stimulated insulin secretion.Mitochondrial uncoupling in skeletal muscle by UCP1 augments energy expenditure and glutathione content while mitigating ROS production.Redox regulation of mitochondrial function with emphasis on cysteine oxidation reactions.Metabolic networks to combat oxidative stress in Pseudomonas fluorescens.Hepatic response to aluminum toxicity: dyslipidemia and liver diseases.Mitochondrial proticity and ROS signaling: lessons from the uncoupling proteins.Unearthing the secrets of mitochondrial ROS and glutathione in bioenergetics.S-glutathionylation reactions in mitochondrial function and diseaseSuperoxide anion radical (O2(-)) degrades methylmercury to inorganic mercury in human astrocytoma cell line (CCF-STTG1).A Northern contaminant mixture impairs pancreas function in obese and lean JCR rats and inhibits insulin secretion in MIN6 cells.Impact of methylmercury exposure on mitochondrial energetics in AC16 and H9C2 cardiomyocytes.Mitochondrial lactate metabolism is involved in antioxidative defense in human astrocytoma cells.Involvement of fumarase C and NADH oxidase in metabolic adaptation of Pseudomonas fluorescens cells evoked by aluminum and gallium toxicity.Aluminum-induced defective mitochondrial metabolism perturbs cytoskeletal dynamics in human astrocytoma cells.Alpha-ketoglutarate abrogates the nuclear localization of HIF-1alpha in aluminum-exposed hepatocytes.Aluminum-induced mitochondrial dysfunction leads to lipid accumulation in human hepatocytes: a link to obesity.Aluminum toxicity elicits a dysfunctional TCA cycle and succinate accumulation in hepatocytes.Blue native polyacrylamide gel electrophoresis and the monitoring of malate- and oxaloacetate-producing enzymes.Alpha-ketoglutarate dehydrogenase and glutamate dehydrogenase work in tandem to modulate the antioxidant alpha-ketoglutarate during oxidative stress in Pseudomonas fluorescens.Crucial yet divergent roles of mitochondrial redox state in skeletal muscle vs. brown adipose tissue energetics.The overexpression of NADPH-producing enzymes counters the oxidative stress evoked by gallium, an iron mimetic.In-gel activity staining of oxidized nicotinamide adenine dinucleotide kinase by blue native polyacrylamide gel electrophoresis.The monitoring of nucleotide diphosphate kinase activity by blue native polyacrylamide gel electrophoresis.Metabolic adaptation and oxaloacetate homeostasis in P. fluorescens exposed to aluminum toxicity.Correction: A Novel Strategy Involved in Anti-Oxidative Defense: The Conversion of NADH into NADPH by a Metabolic Network.Correction: Galactose Enhances Oxidative Metabolism and Reveals Mitochondrial Dysfunction in Human Primary Muscle Cells.Protein S-glutathionylation lowers superoxide/hydrogen peroxide release from skeletal muscle mitochondria through modification of complex I and inhibition of pyruvate uptake.Correction: Galactose Enhances Oxidative Metabolism and Reveals Mitochondrial Dysfunction in Human Primary Muscle Cells.
P50
Q28249429-369504FE-BCCC-48DA-8DDC-87FA6E203517Q28475738-514F907D-2905-4AAE-90BB-F036D9C9FA92Q30845183-4462C684-3221-41C2-B660-6D69463FE5BFQ33292692-20BDCA3D-8036-42EE-A574-62EEE1BF7168Q33318462-18A3682F-0ED6-4B15-9C6B-EA7C88DBA971Q33509012-BEC0144F-E374-47AD-9A45-8494EE32DEEBQ33652142-2A639A03-7F09-4423-A1EF-3C5E841E3EE6Q34110088-EEC7BB2B-A49E-471E-8A85-37ED877B2FF3Q34182714-3B5CAD27-8C2A-45DE-B7F3-D1D395F38857Q34417189-96D88CAC-3477-48E5-873C-CD38EF8656D4Q35143664-BB13BFF4-CD01-4920-AE87-3CEB833D479DQ36098321-E47FE335-7D95-4EA2-9A5E-DFBBE1F8FB5FQ36407981-2E163E21-CFE8-42D1-978B-61154B4D9C08Q37093602-1A1F1A84-7475-44F7-A956-4B1BEB26E08AQ37493001-F51F39C8-83DF-4DB1-BF38-0422AA5FFDE8Q37820419-B9B7038F-E56F-47AC-8BFA-4EC7A9B85FF2Q37905235-664EF44F-5BBC-4905-AA1A-586D97EC3099Q38010576-2AB9F110-9D5F-4CC8-94AF-8BAB83DC6021Q38152075-849E2F8C-1FA6-4C47-91F8-E87321781B0DQ38276703-D0A6F531-BA6E-4D6A-B736-24F73C872911Q38860082-23A9ACDC-44FB-48E2-95BC-7ACAD5AE72F5Q38864971-2DD8DC4F-9B91-4113-BDF7-A3BCFEF60040Q38891647-1F4AC8A2-CA21-41DA-8F3F-48C79D6E8871Q39031661-C125A0E5-D768-4D17-A2F9-A5988D37C585Q39752431-4ED331EF-4BC6-4DA6-8B3A-3845FDAD7D12Q39904806-6CBE7894-90F7-46FE-9838-E7A32FF83C2BQ39912989-E449C959-13A4-45F6-AFC1-84F7F623EB2BQ40086768-E074C058-3066-411C-96C5-D99338D80223Q40244023-B39D887F-6C01-461C-81B7-A5242F75B3DFQ40375067-DF84E62D-E1ED-495B-BCA9-B06C6C70C37BQ41369671-3B5B15CB-EF8C-4F4A-8F0E-450923CE9568Q42494884-3413BC29-E37A-486B-8A1D-2C75FCA44FDDQ44867795-BEBB9493-AD2C-4AAE-AD3D-57173F073F2FQ44868440-5D897D84-BC0F-4266-BA98-A31C463C40DFQ44873227-B287D5F4-04E6-4BD4-93DE-D2E6591BFEB5Q44874867-5E9B539A-F0B1-42C1-85B6-D004F83B9CA1Q46372179-D9519D31-CF71-442F-8B72-40861688D94CQ46431224-3D89D01B-8EF5-4121-A0A2-74AEFBD34D70Q50000308-C8FF0F8F-C2DF-48A6-AE82-E07A18C7E783Q50322281-259BB5D1-3930-43E6-9C05-FB07A47F64F1
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Ryan J Mailloux
@ast
Ryan J Mailloux
@en
Ryan J Mailloux
@es
Ryan J Mailloux
@nl
Ryan J Mailloux
@sl
type
label
Ryan J Mailloux
@ast
Ryan J Mailloux
@en
Ryan J Mailloux
@es
Ryan J Mailloux
@nl
Ryan J Mailloux
@sl
prefLabel
Ryan J Mailloux
@ast
Ryan J Mailloux
@en
Ryan J Mailloux
@es
Ryan J Mailloux
@nl
Ryan J Mailloux
@sl
P106
P31
P496
0000-0003-3986-9830