Template:Keywords: Coupling control: Difference between revisions
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! Coupling-control efficiency !! !! Definition !! !! Icon | ! Coupling-control efficiency !! !! Definition !! !! Icon | ||
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| [[P-L | | [[P-L control efficiency |''P-L'' control efficiency]] || ''j<sub>P-L</sub>'' || = (''P-L'')/''P'' || = 1-''L/P'' || [[Image:j(P-L).jpg|50 px|link=P-L control efficiency |''P-L'' control efficiency]] | ||
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| [[R-L ROUTINE-coupling efficiency |''R-L'' ROUTINE-coupling efficiency]] || ''j<sub>R-L</sub>'' || = (''R-L'')/''R'' || = 1-''L/R'' || [[Image:j(R-L).jpg|50 px|link=R-L ROUTINE-coupling efficiency |''R-L'' ROUTINE-coupling efficiency]] | | [[R-L ROUTINE-coupling efficiency |''R-L'' ROUTINE-coupling efficiency]] || ''j<sub>R-L</sub>'' || = (''R-L'')/''R'' || = 1-''L/R'' || [[Image:j(R-L).jpg|50 px|link=R-L ROUTINE-coupling efficiency |''R-L'' ROUTINE-coupling efficiency]] |
Revision as of 09:30, 12 November 2020
4-compartmental OXPHOS model. (1) ET capacity E of the noncoupled electron transfer system ETS. OXPHOS capacity P is partitioned into (2) the dissipative LEAK component L, and (3) ADP-stimulated P-L net OXPHOS capacity. (4) If P-L is kinetically limited by a low capacity of the phosphorylation system to utilize the protonmotive force pmF, then the apparent E-P excess capacity is available to drive coupled processes other than phosphorylation P» (ADP to ATP) without competing with P».
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Mitochondrial and cellular respiratory rates in coupling-control states
Respiratory rate | Definition | Icon | |
---|---|---|---|
OXPHOS capacity | P = P´-Rox | ||
ROUTINE respiration | R = R´-Rox | ||
ET capacity | E = E´-Rox | » Level flow | |
» Noncoupled respiration - Uncoupler[1] | |||
LEAK respiration | L = L´-Rox | » Static head | |
» LEAK state with ATP | |||
» LEAK state with oligomycin | |||
» LEAK state without adenylates | |||
Residual oxygen consumption Rox | L = L´-Rox |
FCR | Definition | Icon | |
---|---|---|---|
L/P coupling-control ratio | L/P | » Respiratory acceptor control ratio, RCR = P/L | |
L/R coupling-control ratio | L/R | ||
L/E coupling-control ratio | L/E | » Uncoupling-control ratio, UCR = E/L | |
P/E control ratio | P/E | ||
R/E control ratio | R/E | ||
net P/E control ratio | (P-L)/E | ||
net R/E control ratio | (R-L)/E |
Net, excess, and reserve capacities of respiration
Respiratory net rate | Definition | Icon |
---|---|---|
P-L net OXPHOS capacity | P-L | |
R-L net ROUTINE capacity | R-L | |
E-L net ET capacity | E-L | |
E-P excess capacity | E-P | |
E-R reserve capacity | E-R |
Coupling-control efficiency | Definition | Icon | |||
---|---|---|---|---|---|
P-L control efficiency | jP-L | = (P-L)/P | = 1-L/P | ||
R-L ROUTINE-coupling efficiency | jR-L | = (R-L)/R | = 1-L/R | ||
E-L ET-coupling efficiency | jE-L | = (E-L)/E | = 1-L/E | » Biochemical coupling efficiency | |
E-P control efficiency | jE-P | = (E-P)/E | = 1-P/E | ||
E-R control efficiency | jE-R | = (E-R)/E | = 1-R/E |
General