Template:Keywords: Coupling control: Difference between revisions

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=== Flux control ratios related to coupling in mt-preparations and living cells ===
=== Flux-control ratios related to coupling in mt-preparations and living cells ===
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=== Flux control efficiencies related to coupling control ratios ===
=== Flux-control efficiencies related to coupling control ratios ===
::::» [[Flux control efficiency]] ''j<sub>Z-Y</sub>''
::::» [[Flux-control efficiency]] ''j<sub>Z-Y</sub>''
::::» [[Background state]]
::::» [[Background state]]
::::» [[Reference state]]
::::» [[Reference state]]

Revision as of 23:10, 10 November 2020

  • The Blue Book 2020
    The Blue Book 2020
  • OXPHOS-, ROUTINE-, ET-, and LEAK states; respiratory capacities (P, R, E, L) corrected for residual oxygen consumption Rox.

    OXPHOS-, ROUTINE-, ET-, and LEAK states; respiratory capacities (P, R, E, L) corrected for residual oxygen consumption Rox.

  • 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».

    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».

  • Flux control ratios related to coupling.png
  • Net, excess, and reserve capacities PREL.png
  • (P-L)/P is the OXPHOS P-L control efficiency. The biochemical coupling efficiency is independent of kinetic control by the phosphorylation system when expressed as the E-L coupling efficiency, (E-L)/E. (E-P)/E is the kinetic E-P control efficiency.

    (P-L)/P is the OXPHOS P-L control efficiency. The biochemical coupling efficiency is independent of kinetic control by the phosphorylation system when expressed as the E-L coupling efficiency, (E-L)/E. (E-P)/E is the kinetic E-P control efficiency.


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Mitochondrial and cellular respiratory rates in coupling control states

OXPHOS-coupled energy cycles. Source: The Blue book
» Baseline state
Respiratory rate Definition Icon
OXPHOS-capacity P = -Rox P.jpg
ROUTINE-respiration R = -Rox R.jpg
ET-capacity E = -Rox E.jpg » Level flow
» Noncoupled respiration - Uncoupler[1]
LEAK-respiration L = -Rox L.jpg » Static head
» LEAK-state with ATP
» LEAK-state with oligomycin
» LEAK-state without adenylates
Residual oxygen consumption Rox L = -Rox ROX.jpg
  • Chance and Williams nomenclature: respiratory states
» State 1 —» State 2 —» State 3 —» State 4 —» State 5

Flux-control ratios related to coupling in mt-preparations and living cells

» Flux-control ratio
» Coupling-control ratio
» Coupling-control protocol
FCR Definition Icon
L/P coupling control ratio L/P L/P coupling control ratio » Respiratory acceptor control ratio, RCR = P/L
L/R coupling control ratio L/R L/R coupling control ratio
L/E coupling control ratio L/E L/E coupling control ratio » Uncoupling-control ratio, UCR = E/L
P/E control ratio P/E P/E control ratio
R/E control ratio R/E R/E control ratio
net P/E control ratio (P-L)/E net P/E control ratio
net R/E control ratio (R-L)/E net R/E control ratio

Net, excess, and reserve capacities of respiration

Respiratory net rate Definition Icon
Net OXPHOS-capacity P-L P-L Net OXPHOS-capacity P-L
Net ROUTINE-activity R-L Net ROUTINE-activity R-L
Net ET-capacity E-L E-L Net ET-capacity E-L
ET-excess capacity E-P E-P ET-excess capacity E-P
ET-reserve capacity E-R E-R ET-reserve capacity E-R

Flux-control efficiencies related to coupling control ratios

» Flux-control efficiency jZ-Y
» Background state
» Reference state
» Metabolic control variable
Coupling-control efficiency Definition Icon
OXPHOS-coupling efficiency P-L jP-L = (P-L)/P = 1-L/P OXPHOS-coupling efficiency P-L » Biochemical coupling efficiency
ROUTINE-coupling efficiency R-L jR-L = (R-L)/R = 1-L/R ROUTINE-coupling efficiency R-L
ET-coupling efficiency E-L jE-L = (E-L)/E = 1-L/E ET-coupling efficiency E-L » Biochemical coupling efficiency
ET-excess control efficiency E-P jE-P = (E-P)/E = 1-P/E ET-excess control efficiency E-P
ET-reserve control efficiency E-R jE-R = (E-R)/E = 1-R/E ET-reserve control efficiency E-R

General

» Basal respiration
» Dyscoupled respiration
» Dyscoupling
» Electron leak
» Electron-transfer-pathway state
» Oxidative phosphorylation
» Oxygen flow
» Oxygen flux
» Permeabilized cells
» Phosphorylation system
» Proton leak
» Proton slip
» Respiratory state
» Uncoupling


  1. Gnaiger E. Is respiration uncoupled - noncoupled - dyscoupled? Mitochondr Physiol Network. »Uncoupler«
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