E-L net ET capacity: Difference between revisions

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{{MitoPedia
{{MitoPedia
|abbr=''โ‰ˆE''
|abbr=''E-L''
|description=[[Image:E-L.jpg|50 px|Free ETS capacity]] The '''free ETS capacity''', ''โ‰ˆE'', is the [[ETS capacity]] corrected for [[LEAK respiration]], ''โ‰ˆE'' = ''E-L''. ''โ‰ˆE'' is the respiratory capacity potentially available for ion transport and phosphorylation of ADP to ATP. Oxygen consumption in the ETS state, therefore, is partitioned into the free ETS capacity, ''โ‰ˆE'', and LEAK respiration, ''L<sub>P</sub>'', compensating for proton leaks, slip and cation cycling: ''E'' = ''โ‰ˆE''+''L<sub>P</sub>'' (see [[free OXPHOS capacity]]).
|description=[[Image:E-L.jpg|50 px|E-L net ET capacity]] The '''''E-L'' net ET capacity''' is the [[ET capacity]] corrected for [[LEAK respiration]]. ''E-L'' is the respiratory capacity potentially available for ion transport and phosphorylation of ADP to ATP. Oxygen consumption in the ET-pathway state, therefore, is partitioned into the ''E-L'' net ET capacity and LEAK respiration ''L<sub>P</sub>'', compensating for proton leaks, slip and cation cycling: ''E'' = ''E-L''+''L<sub>P</sub>'' (see [[P-L net OXPHOS capacity]]).
|info=[[Gnaiger 2014 MitoPathways]]
|info=[[Gnaiger 2020 BEC MitoPathways]]
}}
}}
{{MitoPedia methods
Communicated by [[Gnaiger E]] (2014-09-21) last upate 2020-11-11.
|mitopedia method=Respirometry
}}
{{MitoPedia topics
|mitopedia topic=Respiratory state
}}
[[File:EPL-free and excess.jpg|right|300px|thumb|[[Gnaiger 2014 MitoPathways |The Blue Book 2014]]: Fig. 2.4.]]
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== Coupling control states for ''โ‰ˆE'' ==
::ยป [[Respiratory state]]
* [[Reference state]], ''Z<sub>X</sub>'': [[Image:E.jpg|link=ETS capacity|ETS capacity]] [[ETS capacity]], ''E'' = ''Eยด''-ROX
* [[Background state]], ''Y<sub>X</sub>'': [[Image:L.jpg|link=LEAK respiration|LEAK]] [[LEAK respiration]], ''L'' = ''Lยด''-ROX
* [[Metabolic control variable]], ''X=Z<sub>X</sub>-Y<sub>X</sub>'': [[Image:E-L.jpg|50 px|link=Free ETS capacity |Free ETS capacity]] Scope of uncoupler stimulation, [[free ETS capacity]], ''โ‰ˆE'' = ''E-L''
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== Flux control factor ==
::ยป [[Flux control factor]], ''FCF''
* [[Coupling control factor]], 1-''Y<sub>X</sub>/Z<sub>X</sub>'': [[Image:j--E.jpg|50 px|link=ETS coupling efficiency |ETS coupling efficiency]] ''E-L'' coupling control factor, [[ETS coupling efficiency]]: ''j<sub>โ‰ˆE</sub>'' = ''โ‰ˆE/E'' =(''E-L'')/''E'' = 1-''L/E''
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== Compare ==
== Keywords ==
* mt-Preparations [[Image:P-L.jpg|50 px|link=Free OXPHOS capacity |Free OXPHOS capacity]] [[Free OXPHOS capacity]], ''โ‰ˆP'' = ''P-L''
::::* Expand Bioblast links to '''''E-L'' net ET capacity'''
* Intact cells [[Image:R-L.jpg|50 px|link=Free ROUTINE activity |Free ROUTINE activity]] [[Free ROUTINE activity]], ''โ‰ˆR'' = ''R-L''
{{Template:Keywords: Coupling control}}

Latest revision as of 01:32, 31 December 2020


high-resolution terminology - matching measurements at high-resolution


E-L net ET capacity

Description

E-L net ET capacity The E-L net ET capacity is the ET capacity corrected for LEAK respiration. E-L is the respiratory capacity potentially available for ion transport and phosphorylation of ADP to ATP. Oxygen consumption in the ET-pathway state, therefore, is partitioned into the E-L net ET capacity and LEAK respiration LP, compensating for proton leaks, slip and cation cycling: E = E-L+LP (see P-L net OXPHOS capacity).

Abbreviation: E-L

Reference: Gnaiger 2020 BEC MitoPathways 

Communicated by Gnaiger E (2014-09-21) last upate 2020-11-11.

Keywords

  • Expand Bioblast links to E-L net ET capacity
  • 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 Pยป (ADP to ATP) without competing with Pยป.

    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 Pยป (ADP to ATP) without competing with Pยป.

  • 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.


Questions.jpg


Click to expand or collaps
Bioblast links: Coupling control - >>>>>>> - Click on [Expand] or [Collapse] - >>>>>>>

1. Mitochondrial and cellular respiratory rates in coupling-control states

OXPHOS-coupled energy cycles. Source: The Blue Book
ยป Baseline state
Respiratory rate Defining relations Icon
OXPHOS capacity P = Pยด-Rox P.jpg mt-preparations
ROUTINE respiration R = Rยด-Rox R.jpg living cells
ET capacity E = Eยด-Rox E.jpg ยป Level flow
ยป Noncoupled respiration - Uncoupler
LEAK respiration L = Lยด-Rox L.jpg ยป Static head
ยป LEAK state with ATP
ยป LEAK state with oligomycin
ยป LEAK state without adenylates
Residual oxygen consumption Rox L = Lยด-Rox ROX.jpg
  • Chance and Williams nomenclature: respiratory states
ยป State 1 โ€”ยป State 2 โ€”ยป State 3 โ€”ยป State 4 โ€”ยป State 5

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

ยป Flux control ratio
ยป Coupling-control ratio
ยป Coupling-control protocol
FCR Definition Icon
L/P coupling-control ratio L/P L/P coupling-control ratio ยป 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 ยป Uncoupling-control ratio, UCR = E/L (ambiguous)
P/E control ratio P/E P/E control ratio
R/E control ratio R/E R/E control ratio ยป Uncoupling-control ratio, UCR = E/L
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

3. Net, excess, and reserve capacities of respiration

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

4. Flux control efficiencies related to coupling-control ratios

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

5. General

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


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