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Difference between revisions of "Droese 2009 Biochim Biophys Acta"

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{{Publication
{{Publication
|title=Dröse S, Hanley PJ, Brandt U (2009) Ambivalent effects of diazoxide on mitochondrial ROS production at respiratory chain complexes I and III. Biochim Biophys Acta 1790: 558-565.
|title=Dröse S, Hanley PJ, Brandt U (2009) Ambivalent effects of diazoxide on mitochondrial ROS production at respiratory chain Complexes I and III. Biochim Biophys Acta 1790:558-65.
|info=[http://www.ncbi.nlm.nih.gov/pubmed/19364480 PMID: 19364480]
|info=[http://www.ncbi.nlm.nih.gov/pubmed/19364480 PMID: 19364480]
|authors=Droese S, Hanley PJ, Brandt U
|authors=Droese S, Hanley PJ, Brandt U
|year=2009
|year=2009
|journal=Biochim Biophys Acta
|journal=Biochim Biophys Acta
|abstract='''Background'''
|abstract='''Background''': Reactive oxygen species (ROS) are among the main determinants of cellular damage during ischemia and reperfusion. There is also ample evidence that mitochondrial ROS production is involved in signaling during ischemic and pharmacological preconditioning. In a previous study we analyzed the mitochondrial effects of the efficient preconditioning drug diazoxide and found that it increased the mitochondrial oxidation of the ROS-sensitive fluorescent dye 2′,7′-dichlorodihydrofluorescein (H<sub>2</sub>DCF) but had no direct impact on the H<sub>2</sub>O<sub>2</sub> production of submitochondrial particles (SMP) or intact rat heart mitochondria (RHM).


Reactive oxygen species (ROS) are among the main determinants of cellular damage during ischemia and reperfusion. There is also ample evidence that mitochondrial ROS production is involved in signaling during ischemic and pharmacological preconditioning. In a previous study we analyzed the mitochondrial effects of the efficient preconditioning drug diazoxide and found that it increased the mitochondrial oxidation of the ROS-sensitive fluorescent dye 2′,7′-dichlorodihydrofluorescein (H<sub>2</sub>DCF) but had no direct impact on the H<sub>2</sub>O<sub>2</sub> production of submitochondrial particles (SMP) or intact rat heart mitochondria (RHM).
'''Methods''': H<sub>2</sub>O<sub>2</sub> generation of bovine SMP and tightly coupled RHM was monitored under different conditions using the amplex red/horseradish peroxidase assay in response to diazoxide and a number of inhibitors.


'''Methods'''
'''Results''': We show that diazoxide reduces ROS production by mitochondrial Complex I under conditions of reverse electron transfer in tightly coupled RHM, but stimulates mitochondrial ROS production at the Qo site of Complex III under conditions of oxidant-induced reduction; this stimulation is greatly enhanced by uncoupling. These opposing effects can both be explained by inhibition of Complex II by diazoxide. 5-Hydroxydecanoate had no effect, and the results were essentially identical in the presence of Na<sup>+</sup> or K<sup>+</sup> excluding a role for putative mitochondrial KATP-channels.


H<sub>2</sub>O<sub>2</sub> generation of bovine SMP and tightly coupled RHM was monitored under different conditions using the amplex red/horseradish peroxidase assay in response to diazoxide and a number of inhibitors.
'''General significance''': A straightforward rationale is presented to mechanistically explain the ambivalent effects of diazoxide reported in the literature. Depending on the metabolic state and the membrane potential of mitochondria, diazoxide-mediated inhibition of Complex II promotes transient generation of signaling ROS at Complex III (during preconditioning) or attenuates the production of deleterious ROS at Complex I (during ischemia and reperfusion).
 
'''Results'''
 
We show that diazoxide reduces ROS production by mitochondrial complex I under conditions of reverse electron transfer in tightly coupled RHM, but stimulates mitochondrial ROS production at the Qo site of complex III under conditions of oxidant-induced reduction; this stimulation is greatly enhanced by uncoupling. These opposing effects can both be explained by inhibition of complex II by diazoxide. 5-Hydroxydecanoate had no effect, and the results were essentially identical in the presence of Na<sup>+</sup> or K<sup>+</sup> excluding a role for putative mitochondrial KATP-channels.
 
'''General significance'''
 
A straightforward rationale is presented to mechanistically explain the ambivalent effects of diazoxide reported in the literature. Depending on the metabolic state and the membrane potential of mitochondria, diazoxide-mediated inhibition of complex II promotes transient generation of signaling ROS at complex III (during preconditioning) or attenuates the production of deleterious ROS at complex I (during ischemia and reperfusion).
|keywords=Mitochondria, Reactive oxygen species, Diazoxide, Pharmacological preconditioning, Respiratory chain,Redox signaling
|keywords=Mitochondria, Reactive oxygen species, Diazoxide, Pharmacological preconditioning, Respiratory chain,Redox signaling
|mipnetlab=DE_Frankfurt_Brandt U
|mipnetlab=NL Nijmegen Brandt U, DE Frankfurt Droese S
}}
}}
{{Labeling
{{Labeling
|instruments=Oxygraph-2k
|area=Respiration, Pharmacology;toxicology
|injuries=RONS; Oxidative Stress
|organism=Rat
|organism=Rat
|taxonomic group=Mammals
|tissues=Heart
|tissues=Heart
|preparations=Isolated Mitochondria, SMP
|preparations=Isolated mitochondria, SMP
|enzymes=Complex I, Complex III
|injuries=Oxidative stress;RONS
|topics=Inhibitor
|couplingstates=OXPHOS
|couplingstates=OXPHOS
|enzymes=Complex I, Complex III
|instruments=Oxygraph-2k
|kinetics=Inhibitor; Uncoupler
}}
}}

Latest revision as of 15:49, 19 February 2018

Publications in the MiPMap
Dröse S, Hanley PJ, Brandt U (2009) Ambivalent effects of diazoxide on mitochondrial ROS production at respiratory chain Complexes I and III. Biochim Biophys Acta 1790:558-65.

» PMID: 19364480

Droese S, Hanley PJ, Brandt U (2009) Biochim Biophys Acta

Abstract: Background: Reactive oxygen species (ROS) are among the main determinants of cellular damage during ischemia and reperfusion. There is also ample evidence that mitochondrial ROS production is involved in signaling during ischemic and pharmacological preconditioning. In a previous study we analyzed the mitochondrial effects of the efficient preconditioning drug diazoxide and found that it increased the mitochondrial oxidation of the ROS-sensitive fluorescent dye 2′,7′-dichlorodihydrofluorescein (H2DCF) but had no direct impact on the H2O2 production of submitochondrial particles (SMP) or intact rat heart mitochondria (RHM).

Methods: H2O2 generation of bovine SMP and tightly coupled RHM was monitored under different conditions using the amplex red/horseradish peroxidase assay in response to diazoxide and a number of inhibitors.

Results: We show that diazoxide reduces ROS production by mitochondrial Complex I under conditions of reverse electron transfer in tightly coupled RHM, but stimulates mitochondrial ROS production at the Qo site of Complex III under conditions of oxidant-induced reduction; this stimulation is greatly enhanced by uncoupling. These opposing effects can both be explained by inhibition of Complex II by diazoxide. 5-Hydroxydecanoate had no effect, and the results were essentially identical in the presence of Na+ or K+ excluding a role for putative mitochondrial KATP-channels.

General significance: A straightforward rationale is presented to mechanistically explain the ambivalent effects of diazoxide reported in the literature. Depending on the metabolic state and the membrane potential of mitochondria, diazoxide-mediated inhibition of Complex II promotes transient generation of signaling ROS at Complex III (during preconditioning) or attenuates the production of deleterious ROS at Complex I (during ischemia and reperfusion). Keywords: Mitochondria, Reactive oxygen species, Diazoxide, Pharmacological preconditioning, Respiratory chain, Redox signaling

O2k-Network Lab: NL Nijmegen Brandt U, DE Frankfurt Droese S


Labels: MiParea: Respiration, Pharmacology;toxicology 

Stress:Oxidative stress;RONS  Organism: Rat  Tissue;cell: Heart  Preparation: Isolated mitochondria, SMP  Enzyme: Complex I, Complex III  Regulation: Inhibitor  Coupling state: OXPHOS 

HRR: Oxygraph-2k