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...iency |''E-R'' control efficiency]] and [[E-L coupling efficiency |''E-L'' coupling efficiency]].

...ly compensated by an increase of ROUTINE respiration and [[R-L net ROUTINE capacity]], ''R-L'', is maintained constant. {{Template:Keywords: Coupling control}}

|abbr=''j_E-R'' ...ation. Similarly, the apparent [[E-P excess ET capacity |''E-P'' excess ET capacity]] is not a respiratory reserve in the sense of oxidative phosphorylation.

'''<big>1. Mitochondrial and cellular respiratory rates in coupling-control states</big>''' | [[OXPHOS capacity]] || ''P'' = ''P´''-''Rox'' || [[File:P.jpg |link=OXPHOS capacity]] || mt-preparations

=== Respiratory coupling states in living cells === :::: [[Image:E.jpg|link=ET capacity|ET capacity]] [[ET capacity]], ''E'' = ''E´''-''Rox''

...'' = ''E''). The biochemical coupling efficiency is independent of kinetic control by the phosphorylation system. ::::* Expand Bioblast links to '''Biochemical coupling efficiency'''

|abbr=''E-R'' ...ve capacity]] The '''''E-R'' reserve capacity''' is the difference of [[ET capacity]] and [[ROUTINE respiration]]. For further information, see [[Cell ergometr

...E''), physiological control of energy demand, and limitation by the OXPHOS capacity. {{Template:Keywords: Coupling control}}

...rol ratio is an expression of how close ROUTINE respiration operates to ET capacity. == Boundaries of the ''R/E'' control ratio ==

...]] closer with the general concept of [[efficiency]] and linking [[pathway control ratio]]s with the definition of [[additivity]] (Gnaiger 2020). == MitoPedia terms: Respiratory control ratios ==

| ''P'' || [[OXPHOS capacity]], in OXPHOS state of mt-preparations || [[State 3]] | ''E'' || [[ET capacity]], electron transfer capacity || maximum respiration; State 3u

...]] is fully compensated by an increase of OXPHOS capacity and [[net OXPHOS capacity P-L]], ''P-L'', is maintained constant. {{Template:Keywords: Coupling control}}

File:Coupling control - mitochondrial and cellular respiratory rates.png |OXPHOS-, ROUTINE-, ET-, ...o utilize the protonmotive force ''pmF'', then the apparent ''E-P'' excess capacity is available to drive coupled processes other than phosphorylation P» (ADP

::: '''[[SUIT protocol pattern]]:''' linear monodirectional cell [[coupling-control protocol]] (ceCCP) [[File:R;L;E format_(S).jpg|200px]] In the diagrams of coupling-control protocols for intact cells (ceCCP), the steps may be replaced by the respir

::: '''[[SUIT protocol pattern]]:''' linear monodirectional cell [[coupling-control protocol]] (ceCCP) [[File:R;L;E format_(S).jpg|200px]] In the diagrams of coupling-control protocols for intact cells (ceCCP), the steps may be replaced by the respir

::: '''[[SUIT protocol pattern]]:''' linear monodirectional cell [[coupling-control protocol]] (ceCCP) [[File:R;L;E format_(S).jpg|200px]] In the diagrams of coupling-control protocols for intact cells (ceCCP), the steps may be replaced by the respir

...erts a limiting effect on OXPHOS capacity. In addition, ''E-P'' depends on coupling efficiency, since ''P'' aproaches ''E'' at increasing uncoupling. ::::* Expand Bioblast links to '''''E-P'' excess capacity'''

...r]]s (e.g. [[CCCP]]). [[Coupling-control protocol]]s induce these coupling-control states sequentially at a constant [[electron-transfer-pathway state]]. ...OUTINE respiration|ROUTINE respiration]] [[Image:E.jpg|link=ET capacity|ET capacity]] [[Image:L.jpg|link=LEAK respiration|LEAK respiration]] - [[Image:ROX.jpg|

...oupler]] titration, which yields the [[E-P excess capacity |''E-P'' excess capacity]]. |info=[[Flux control efficiency]], [[Gnaiger 2020 BEC MitoPathways]]

...nd cation cycling: ''E'' = ''E-L''+''L_P'' (see [[P-L net OXPHOS capacity]]). ::::* Expand Bioblast links to '''''E-L'' net ET capacity'''