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• Hyphenation
  ...nt), but if the compound adjective follows the term (measurement at steady state), hyphenation does not add any information and should be avoided. Find more ...ate]] (''NOT'' 'Coupling control state' - it is not 'coupling of a control state')
  4 KB (469 words) - 02:31, 23 January 2023
• PalOctPGM
  '''MitoPathway control state:''' [[FN]] |mitopedia concept=SUIT state
  829 bytes (96 words) - 14:36, 26 August 2020
• NS e-input
  ...linked respiration. For more details, see: [[Additive effect of convergent electron flow]].
  1 KB (149 words) - 18:49, 1 January 2021
• Complex I-linked substrate state
  |description=''See'' '''[[N-pathway control state]]''' (previous: CI-linked) versus '''[[Complex I]]''' |mitopedia concept=Respiratory state, SUIT state, Find
  706 bytes (93 words) - 10:14, 2 November 2023
• PGM-pathway control state
  '''MitoPathway control state:''' [[NADH electron transfer-pathway state]] ...-oxoglutarate]]), representing the [[glutamate-anaplerotic pathway control state]]. 2-oxoglutarate (α-ketoglutarate) is formed from isocitrate (isocitrate
  3 KB (316 words) - 13:14, 2 August 2023
• Flavin adenine dinucleotide
  ...ion]] (compare [[N-junction]], [[Q-junction]]), in the [[F-pathway control state]]. In contrast, FADH₂ is not the substrate but the internal prod ::::* Gnaiger E (2023) Complex II ambiguities ― FADH2 in the electron transfer system. MitoFit Preprints 2023.3.v3. https://doi.org/10.26124/mitofit:2023-
  1 KB (199 words) - 18:57, 7 May 2023
• FN
  ...bation medium. FS in combination exerts an [[additive effect of convergent electron flow]] in most types of mitochondria. |info=[[Electron-transfer-pathway state]], [[Gnaiger 2020 BEC MitoPathways]]
  2 KB (311 words) - 19:57, 1 January 2021
• Electron transfer pathway
  |abbr=ET pathway ...-membrane, (2) [[TCA cycle]] and other mt-matrix dehydrogenases generating NADH and succinate, and (3) the carriers involved in metabolite transport across
  5 KB (646 words) - 01:06, 31 December 2020
• FNS
  ...ation medium. FNS in combination exerts an [[additive effect of convergent electron flow]] in most types of mitochondria. |info=[[Electron-transfer-pathway state]], [[Gnaiger 2020 BEC MitoPathways]]
  3 KB (403 words) - 19:58, 1 January 2021
• NS-S pathway control efficiency
  ..., S(Rot) or S. Then the NS-S pathway control efficiency in the ET-coupling state is ...s added to the NS-state. The reversed protocol, adding N-substrates to a S-pathway control background does not provide a valid estimation of S-respiration wit
  2 KB (288 words) - 18:30, 1 January 2021
• Complex I
  ...er mt-membrane, responsible for electron transfer to [[ubiquinone]] from [[NADH]] formed in the mt-matrix. CI forms a [[supercomplex]] with [[Complex III]] ...rnatively to a '''Complex I-linked substrate state''' ([[N-pathway control state]]).
  2 KB (214 words) - 13:43, 3 November 2023
• Cardoso 2022 Q10 Hamburg
  ...redox state and respiration in permeabilized HEK 293T cells: coupling and pathway control. Q10 Hamburg. ...rial inner membrane. ET capacity is measured in the noncoupled respiratory state after application of uncouplers, whereas LEAK respiration is assessed in th
  4 KB (580 words) - 18:34, 5 May 2022
• SUIT-020 O2 mt D032
  ...f the ATP synthase. Since higher concentrations of Omy can decrease the ET state induced upon addition of uncoupler, the required concentration of Omy has t :::* Comparison of GM- with PM-capacity yields important information on N-pathway respiratory control upstream of CI.
  4 KB (636 words) - 15:11, 17 September 2020
• Fatty acid oxidation pathway control state
  ...in a reaction catalyzed by malate dehydrogenase to oxaloacetate (yielding NADH), which then stimulates the entry of Acetyl-CoA into the TCA cycle catalyze |info=[[Electron-transfer-pathway state]], [[Gnaiger 2020 BEC MitoPathways]]
  3 KB (456 words) - 16:12, 13 January 2022
• NS-pathway control state
  |description=[[File:SUIT-catg NS.jpg|right|300px|NS-pathway control]] ...bation medium. NS in combination exerts an [[additive effect of convergent electron flow]] in most types of mitochondria.
  4 KB (604 words) - 08:32, 25 November 2023
• PM-pathway control state
  '''MitoPathway control state:''' [[NADH Electron transfer-pathway state]] ...is oxidatively decarboxylated to acetyl-CoA and CO₂, yielding [[NADH]] catalyzed by pyruvate dehydrogenase. [[Malate]] (M) is oxidized to oxaloa
  5 KB (603 words) - 15:33, 2 August 2023
• Categories of SUIT protocols
  ...inhibitors which define the [[Electron-transfer-pathway state]]s. The [[N-pathway control |N-type substrates]] are listed in parentheses, independent of the ...>2</sub>]]-linked substrates (FAO) with obligatory support by the N-linked pathway.
  5 KB (673 words) - 16:25, 3 June 2020
• Glutamate-anaplerotic pathway control state
  ...ised via mt-[[glutamate dehydrogenase]] in the mitochondrial matrix. The G-pathway plays an important role in [[glutaminolysis]]. LEAK state (''L'') with G alone as substrate can be evaluated in the following SUIT pr
  2 KB (276 words) - 20:11, 1 January 2021
• SUIT-007
  |abbr=[[Glutamate-anaplerotic pathway control state|Glutamate anaplerosis]] ...''' '''[[Glutamate-anaplerotic pathway control state|Glutamate anaplerotic pathway]]'''
  3 KB (401 words) - 11:30, 3 June 2020
• Moore 2017 MiPschool Obergurgl
  ...[[File:Moore Anthony L.jpg|left|90px|Anthony Moore]] The electron transfer-pathway – Q redox regulation and mitochondrial pathways to oxygen. ...favour of a homogenous Q-pool the redox state of which governs the rate of electron transport. I will also discuss deviations form Q-pool behaviour, its role w
  2 KB (223 words) - 12:48, 3 April 2021

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