Difference between revisions of "E-R control efficiency"
| Line 6: | Line 6: | ||
== Compare == | == Compare == | ||
:::» [[ROUTINE-control ratio]] ''R/E'' | :::» [[ROUTINE-control ratio]] ''R/E'' | ||
:::» [[ET-excess coupling efficiency E-P]] ''j<sub>E-P</sub>'' = (''E-P'')/''E'' = 1-''P/E'' | :::» [[ET-excess coupling efficiency E-P]], ''j<sub>E-P</sub>'' = (''E-P'')/''E'' = 1-''P/E'' | ||
:::» [[ET-coupling efficiency E-L]] ''j<sub>E-L</sub>'' = 1-''L/E'' | :::» [[ET-coupling efficiency E-L]], ''j<sub>E-L</sub>'' = 1-''L/E'' | ||
Revision as of 22:43, 8 November 2020
- high-resolution terminology - matching measurements at high-resolution
E-R control efficiency
Description
.jpg){kind=small}
The apparent ET-reserve control efficiency (E-R control efficiency), jE-R = (E-R)/E = 1-R/E, is an expression of the relative scope of increasing ROUTINE respiration in living cells by uncoupling. jE-R = 0.0 for zero excess capacity when R=E; jE-R = 1.0 for the maximum limit when R=0. The ROUTINE state of living cells is stimulated to electron transfer pathway by uncoupler titration, which yields the ET-reserve capacity E-R. Since ET-capacity is significantly higher than OXPHOS capacity in various cell types (as shown by cell ergometry), jE-R is not a reserve capacity available for the cell to increase oxidative phosphorylation, but strictly a scope (reserve) for uncoupling respiration. Similarly, the apparent ET-excess capacity E-P is not a respiratory reserve in the sense of oxidative phosphorylation.
Abbreviation: jE-R
Reference: Flux control efficiency
Compare
- » ROUTINE-control ratio R/E
- » ET-excess coupling efficiency E-P, jE-P = (E-P)/E = 1-P/E
- » ET-coupling efficiency E-L, jE-L = 1-L/E
MitoPedia concepts: Respiratory control ratio
