Difference between revisions of "Nigericin"
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{{MitoPedia | {{MitoPedia | ||
|description= Nigericin is a H<sup>+</sup>/K<sup>+</sup> antiporter, which allows the electroneutral transport of these two ions in opposite directions across the mitochondrial inner membrane following the K<sup>+</sup> concentration gradient. In the presence of K<sup>+</sup>, nigericin decreases pH in the mitchondrial matrix, thus, almost fully collapses the transmembrane ΔpH, which leads to the compensatory increase of the electric [[Mitochondrial membrane potential|mt-membrane potential]]. Therefore, it is ideal to use to dissect the two components of the [[Protonmotive force|protonmotive force]], ΔpH and [[Mitochondrial membrane potential|mt-membrane potential]]. It is recommended to use the lowest possible concentration of nigericin, which creates a maximal mitochondrial hyperpolarization. In the study of [[Komlodi 2018 J Bioenerg Biomembr]], 20 nM was applied on brain mitochondria isolated from guinea-pigs using 5 mM [[Succinate|succinate]] in the [[LEAK respiration|LEAK state]] which caused maximum hyperpolarisation, but did not fully dissipate the transmembrane ΔpH. Other groups (Selivanov et al ; Lambert et al | |description= Nigericin is a H<sup>+</sup>/K<sup>+</sup> antiporter, which allows the electroneutral transport of these two ions in opposite directions across the mitochondrial inner membrane following the K<sup>+</sup> concentration gradient. In the presence of K<sup>+</sup>, nigericin decreases pH in the mitchondrial matrix, thus, almost fully collapses the transmembrane ΔpH, which leads to the compensatory increase of the electric [[Mitochondrial membrane potential|mt-membrane potential]]. Therefore, it is ideal to use to dissect the two components of the [[Protonmotive force|protonmotive force]], ΔpH and [[Mitochondrial membrane potential|mt-membrane potential]]. It is recommended to use the lowest possible concentration of nigericin, which creates a maximal mitochondrial hyperpolarization. In the study of [[Komlodi 2018 J Bioenerg Biomembr]], 20 nM was applied on brain mitochondria isolated from guinea-pigs using 5 mM [[Succinate|succinate]] in the [[LEAK respiration|LEAK state]] which caused maximum hyperpolarisation, but did not fully dissipate the transmembrane ΔpH. Other groups (Selivanov et al 2008; Lambert et al 2004), however, used 100 nM nigericin, which in their hands fully collapsed transmembrane ΔpH using succinate as a respiratory substrate on isolated rat brain and skeletal muscle in the [[LEAK respiration|LEAK state]]. | ||
|info= | |info= | ||
[[Dalmonte_2009_J_Biol_Chem]] | [[Dalmonte_2009_J_Biol_Chem]] | ||
[[Komlodi 2018 J Bioenerg Biomembr]] | [[Komlodi 2018 J Bioenerg Biomembr]] | ||
[ | [[Selivanov 2008 J Biol Chem]] | ||
[ | [[Lambert 2004 Biochem J]] | ||
}} | }} | ||
Revision as of 11:53, 9 June 2023
Description
Nigericin is a H+/K+ antiporter, which allows the electroneutral transport of these two ions in opposite directions across the mitochondrial inner membrane following the K+ concentration gradient. In the presence of K+, nigericin decreases pH in the mitchondrial matrix, thus, almost fully collapses the transmembrane ΔpH, which leads to the compensatory increase of the electric mt-membrane potential. Therefore, it is ideal to use to dissect the two components of the protonmotive force, ΔpH and mt-membrane potential. It is recommended to use the lowest possible concentration of nigericin, which creates a maximal mitochondrial hyperpolarization. In the study of Komlodi 2018 J Bioenerg Biomembr, 20 nM was applied on brain mitochondria isolated from guinea-pigs using 5 mM succinate in the LEAK state which caused maximum hyperpolarisation, but did not fully dissipate the transmembrane ΔpH. Other groups (Selivanov et al 2008; Lambert et al 2004), however, used 100 nM nigericin, which in their hands fully collapsed transmembrane ΔpH using succinate as a respiratory substrate on isolated rat brain and skeletal muscle in the LEAK state.
Reference: Dalmonte_2009_J_Biol_Chem Komlodi 2018 J Bioenerg Biomembr Selivanov 2008 J Biol Chem Lambert 2004 Biochem J
MitoPedia concepts: Respiratory state
MitoPedia methods:
Respirometry,
Fluorometry