Difference between revisions of "Coupling-control protocol"
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{{MitoPedia | {{MitoPedia | ||
|abbr= | |abbr=CCP | ||
|description=A ''' | |description=A '''coupling control protocol, CCP''' induces different [[coupling control state]]s at constant substrate supply. In [[intact cell]]s, the CCP can be applied by using membrane-permeable inhibitors of the [[phosphorylation system]] (e.g. [[oligomycin]]) and [[uncoupler]]s (e.g. [[CCCP]]). Coupling control states in intact cells include ''R'', ''L'', ''E''; [[LEAK]], [[ROUTINE]], and [[ETS]]. Coupling control states in isolated mitochondria, permeabilized cells or homogenates include ''L'', ''P'', ''E''; LEAK, [[OXPHOS]], and ETS. The term '''phosphorylation control protocol''', PCP, has been introduced synonymous for CCP. | ||
|info=[[Gnaiger 2008 POS]] | » [[#From PCP to CCP |'''MiPNet article''']] | ||
|info=[[Gnaiger 2008 POS]], [[Gnaiger 2014 MitoPathways]] | |||
}} | }} | ||
{{MitoPedia methods | {{MitoPedia methods | ||
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|type=Respiration | |type=Respiration | ||
}} | }} | ||
== From PCP to CCP == | __TOC__ | ||
= From PCP to CCP = | |||
{{Publication | |||
|title=Gnaiger E (2015) From PCP to CCP. Mitochondr Physiol Network 2015-01-11. | |||
|info= | |||
|authors=OROBOROS | |||
|year=2015 | |||
|journal=MiPNet | |||
|abstract=The control of oxidative phosphorylation by coupling is of primary importance in OXPHOS analysis. To avoid misunderstandings, tt is suggested to replace the term 'phosphorylation control protocol' by '''coupling control protocol, CCP'''. | |||
|mipnetlab=AT Innsbruck Gnaiger E | |||
}} | |||
{{Labeling | |||
|topics=Coupling efficiency;uncoupling | |||
|couplingstates=LEAK, ROUTINE, OXPHOS, ETS | |||
|instruments=Theory | |||
}} | |||
In functional OXPHOS analysis, the control of oxidative phosphorylation by coupling is of primary importance, as studied by application of protocols, in which the [[phosphorylation system]] is either inhibited (lack of ADP; inhibition by oligomycin), activated (saturating ADP; activation by phyiological control in intact cells) or eliminated (uncoupling). It seems thus appropriate to use the term phosphorylation control protocol, PCP <ref> Gnaiger E (2008) Polarographic oxygen sensors, the oxygraph and high-resolution respirometry to assess mitochondrial function. In: Mitochondrial Dysfunction in Drug-Induced Toxicity (Dykens JA, Will Y, eds) John Wiley:327-52. »[[Gnaiger_2008_POS |Bioblast Access]]« </ref>. In this context it is taken for granted that we do not refer to metabolic control by phosphorylation of enzymes, which is an important mechanism to change specific enzyme activity. To avoid any such confusion, it is suggested to replace the term 'phosphorylation control protocol' by '''coupling control protocol, CCP''' | In functional OXPHOS analysis, the control of oxidative phosphorylation by coupling is of primary importance, as studied by application of protocols, in which the [[phosphorylation system]] is either inhibited (lack of ADP; inhibition by oligomycin), activated (saturating ADP; activation by phyiological control in intact cells) or eliminated (uncoupling). It seems thus appropriate to use the term phosphorylation control protocol, PCP <ref> Gnaiger E (2008) Polarographic oxygen sensors, the oxygraph and high-resolution respirometry to assess mitochondrial function. In: Mitochondrial Dysfunction in Drug-Induced Toxicity (Dykens JA, Will Y, eds) John Wiley:327-52. »[[Gnaiger_2008_POS |Bioblast Access]]« </ref>. In this context it is taken for granted that we do not refer to metabolic control by phosphorylation of enzymes, which is an important mechanism to change specific enzyme activity. To avoid any such confusion, it is suggested to replace the term 'phosphorylation control protocol' by '''coupling control protocol, CCP''' | ||
<ref> Gnaiger E (2014) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 4th ed. Mitochondr Physiol Network 19.12. OROBOROS MiPNet Publications, Innsbruck:80 pp. »[[Gnaiger 2014 MitoPathways |Open Access]]« </ref> | <ref> Gnaiger E (2014) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 4th ed. Mitochondr Physiol Network 19.12. OROBOROS MiPNet Publications, Innsbruck:80 pp. »[[Gnaiger 2014 MitoPathways |Open Access]]« </ref> | ||
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[[Image:L.jpg|link=LEAK respiration|LEAK]] - [[Image:P.jpg|link=OXPHOS capacity|OXPHOS]] - [[Image:L.jpg|link=LEAK respiration|LEAK]] - [[Image:P.jpg|link=OXPHOS capacity|OXPHOS]] - [[Image:E.jpg|link=ETS capacity|ETS]] - [[Image:ROX.jpg|link=Residual oxygen consumption|ROX]]: In mitochondrial preparations, various variations are possible for the coupling control protocol, for example in isolated mitochondria | [[Image:L.jpg|link=LEAK respiration|LEAK]] - [[Image:P.jpg|link=OXPHOS capacity|OXPHOS]] - [[Image:L.jpg|link=LEAK respiration|LEAK]] - [[Image:P.jpg|link=OXPHOS capacity|OXPHOS]] - [[Image:E.jpg|link=ETS capacity|ETS]] - [[Image:ROX.jpg|link=Residual oxygen consumption|ROX]]: In mitochondrial preparations, various variations are possible for the coupling control protocol, for example in isolated mitochondria | ||
<ref> Hand SC, Gnaiger E (2014) Flux control ratios in isolatd mitochondria. OXPHOS capacity and respiratory control in isolated mitochondria. Mitochondr Physiol Network 12.11(06):1-5. »[MiPNet12.11 MitoRespiration |Open Access]]« </ref>: (LEAK<sub>N</sub> - OXPHOS - LEAK<sub>T</sub> - OXPHOS - ETS - ROX).<ref> </ref> | <ref> Hand SC, Gnaiger E (2014) Flux control ratios in isolatd mitochondria. OXPHOS capacity and respiratory control in isolated mitochondria. Mitochondr Physiol Network 12.11(06):1-5. »[[MiPNet12.11 MitoRespiration |Open Access]]« </ref>: (LEAK<sub>N</sub> - OXPHOS - LEAK<sub>T</sub> - OXPHOS - ETS - ROX).<ref> [[LEAK respiration]] </ref> | ||
'''References''' | |||
<references/> | <references/> | ||
= Biochemical coupling efficiency: from 0 to <1 = | |||
* ''More details:'' [[ETS coupling efficiency]] | * ''More details:'' [[ETS coupling efficiency]] | ||
Revision as of 11:46, 11 January 2015
- high-resolution terminology - matching measurements at high-resolution
Coupling-control protocol
Description
A coupling control protocol, CCP induces different coupling control states at constant substrate supply. In intact cells, the CCP can be applied by using membrane-permeable inhibitors of the phosphorylation system (e.g. oligomycin) and uncouplers (e.g. CCCP). Coupling control states in intact cells include R, L, E; LEAK, ROUTINE, and ETS. Coupling control states in isolated mitochondria, permeabilized cells or homogenates include L, P, E; LEAK, OXPHOS, and ETS. The term phosphorylation control protocol, PCP, has been introduced synonymous for CCP. » MiPNet article
Abbreviation: CCP
Reference: Gnaiger 2008 POS, Gnaiger 2014 MitoPathways
MitoPedia methods:
Respirometry
MitoPedia topics: "Respiratory state" is not in the list (Enzyme, Medium, Inhibitor, Substrate and metabolite, Uncoupler, Sample preparation, Permeabilization agent, EAGLE, MitoGlobal Organizations, MitoGlobal Centres, ...) of allowed values for the "MitoPedia topic" property.
Respiratory state"Respiratory state" is not in the list (Enzyme, Medium, Inhibitor, Substrate and metabolite, Uncoupler, Sample preparation, Permeabilization agent, EAGLE, MitoGlobal Organizations, MitoGlobal Centres, ...) of allowed values for the "MitoPedia topic" property.
From PCP to CCP
| Gnaiger E (2015) From PCP to CCP. Mitochondr Physiol Network 2015-01-11. |
Abstract: The control of oxidative phosphorylation by coupling is of primary importance in OXPHOS analysis. To avoid misunderstandings, tt is suggested to replace the term 'phosphorylation control protocol' by coupling control protocol, CCP.
• O2k-Network Lab: AT Innsbruck Gnaiger E
Labels:
Regulation: Coupling efficiency;uncoupling
Coupling state: LEAK, ROUTINE, OXPHOS, ETS"ETS" is not in the list (LEAK, ROUTINE, OXPHOS, ET) of allowed values for the "Coupling states" property.
HRR: Theory
In functional OXPHOS analysis, the control of oxidative phosphorylation by coupling is of primary importance, as studied by application of protocols, in which the phosphorylation system is either inhibited (lack of ADP; inhibition by oligomycin), activated (saturating ADP; activation by phyiological control in intact cells) or eliminated (uncoupling). It seems thus appropriate to use the term phosphorylation control protocol, PCP [1]. In this context it is taken for granted that we do not refer to metabolic control by phosphorylation of enzymes, which is an important mechanism to change specific enzyme activity. To avoid any such confusion, it is suggested to replace the term 'phosphorylation control protocol' by coupling control protocol, CCP [2]
- 
- 
- 
: this is the coupling control protocol with intact cells (ROUTINE - LEAKOmy - ETS - ROX).
- - - : this is the comparable coupling control protocol with mitochondrial preparations (OXPHOS - LEAKOmy - ETS - ROX).
- - - - - : In mitochondrial preparations, various variations are possible for the coupling control protocol, for example in isolated mitochondria
[3]: (LEAKN - OXPHOS - LEAKT - OXPHOS - ETS - ROX).[4]
References
- ↑ Gnaiger E (2008) Polarographic oxygen sensors, the oxygraph and high-resolution respirometry to assess mitochondrial function. In: Mitochondrial Dysfunction in Drug-Induced Toxicity (Dykens JA, Will Y, eds) John Wiley:327-52. »Bioblast Access«
- ↑ Gnaiger E (2014) Mitochondrial pathways and respiratory control. An introduction to OXPHOS analysis. 4th ed. Mitochondr Physiol Network 19.12. OROBOROS MiPNet Publications, Innsbruck:80 pp. »Open Access«
- ↑ Hand SC, Gnaiger E (2014) Flux control ratios in isolatd mitochondria. OXPHOS capacity and respiratory control in isolated mitochondria. Mitochondr Physiol Network 12.11(06):1-5. »Open Access«
- ↑ LEAK respiration
Biochemical coupling efficiency: from 0 to <1
- More details: ETS coupling efficiency
