Difference between revisions of "Template:SUIT-005"

Latest revision as of 16:01, 2 April 2019

Steps and respiratory states

Step	State	Pathway	Q-junction	Comment - Events (E) and Marks (M)
1OctM	OctM_L(n)	F(N)	FAO	1OctM Respiratory stimulation of the FAO-pathway, F, by fatty acid FA in the presence of malate M. Malate is a type N substrate (N), required for the F-pathway. In the presence of anaplerotic pathways (e.g., mitochondrial malic enzyme, mtME) the F-pathway capacity is overestimated, if there is an added contribution of NADH-linked respiration, F(N) (see SUIT-002). The FA concentration has to be optimized to saturate the FAO-pathway, without inhibiting or uncoupling respiration. Low concentration of malate, typically 0.1 mM, does not saturate the N-pathway; but saturates the F-pathway. Non-phosphorylating resting state (LEAK state); LEAK respiration L(n) in the absence of ADP, ATP, AMP (no adenylates).
2D	OctM_P	F(N)	FAO	1OCtM;2D Respiratory stimulation of the FAO-pathway, F, by fatty acid FA in the presence of malate M. Malate is a type N substrate (N), required for the F-pathway. In the presence of anaplerotic pathways (e.g., mitochondrial malic enzyme, mtME) the F-pathway capacity is overestimated, if there is an added contribution of NADH-linked respiration, F(N) (see SUIT-002). The FA concentration has to be optimized to saturate the FAO-pathway, without inhibiting or uncoupling respiration. Low concentration of malate, typically 0.1 mM, does not saturate the N-pathway; but saturates the F-pathway. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
2c	OctMc_P	F(N)	FAO	1OCtM;2D;2c Respiratory stimulation of the FAO-pathway, F, by fatty acid FA in the presence of malate M. Malate is a type N substrate (N), required for the F-pathway. In the presence of anaplerotic pathways (e.g., mitochondrial malic enzyme, mtME) the F-pathway capacity is overestimated, if there is an added contribution of NADH-linked respiration, F(N) (see SUIT-002). The FA concentration has to be optimized to saturate the FAO-pathway, without inhibiting or uncoupling respiration. Low concentration of malate, typically 0.1 mM, does not saturate the N-pathway; but saturates the F-pathway. Addition of cytochrome c yields a test for integrity of the mtOM (cytochrome c control efficiency). Stimulation by added cytochrome c would indicate an injury of the mtOM and limitation of respiration in the preceding state without added c due to loss of cytochrome c. Typically, cytochrome c is added immediately after the earliest ADP-activation step (OXPHOS capacity P with saturating [ADP]). OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
3P	OctPM_P	FN	F&CI	1OctM;2D;2c;3P Respiratory stimulation by simultaneous action of the F-pathway and N-pathway with convergent electron flow in the FN-pathway for evaluation of an additive or inhibitory effect of F. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
4S	OctPMS_P	FNS	F&CI&II	1OctM;2D;2c;3P;4S Respiratory stimulation by simultaneous action of the F-pathway, N-pathway, and S-pathway, with convergent electron flow in the FNS-pathway for reconstitution of TCA cycle function and additive or inhibitory effect of F. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
5U	OctPMS_E	FNS	F&CI&II	1OctM;2D;2c;3P;4S;5U Respiratory stimulation by simultaneous action of the F-pathway, N-pathway, and S-pathway, with convergent electron flow in the FNS-pathway for reconstitution of TCA cycle function and additive or inhibitory effect of F. Uncoupler titration (avoiding inhibition by high uncoupler concentrations) to obtain electron transfer (ET) capacity E (noncoupled ET-state). Test for limitation of OXPHOS capacity P by the phosphorylation system (ANT, ATP synthase, phosphate transporter) relative to ET capacity E in mt-preparations: E-P control efficiency and E-L coupling efficiency. In living cells: E-R control efficiency and E-L coupling efficiency. Noncoupled electron transfer state, ET state, with ET capacity E.
6Rot	S_E	S	CII	1OctM;2D;3P;4S;5U;6Rot Succinate pathway control state (S-pathway) after inhibiting CI with rotenone, which also inhibits the F-pathway. Noncoupled electron transfer state, ET state, with ET capacity E.
7Ama	ROX			1OctM;2D;3P;4S;5U;6Rot;7Ama Rox is the residual oxygen consumption in the ROX state, due to oxidative side reactions, estimated either after inhibition of CIII (e.g. antimycin A, myxothiazol), CIV (e.g. Cyanide) or in the absence of endogenous fuel-substrates. Rox is subtracted from oxygen flux as a baseline for all respiratory states, to obtain mitochondrial respiration.

Step	Respiratory state	Pathway control	ET-Complex	Comment
## AsTm	AsTm_E	CIV	CIV
## Azd	CHB

Bioblast links: SUIT protocols - >>>>>>> - Click on [Expand] or [Collapse] - >>>>>>>

Coupling control

» Coupling control state

» ET capacity

» OXPHOS capacity

» LEAK respiration

Pathway control

» Electron transfer pathway

» Fatty acid oxidation pathway control state, F

» NADH electron transfer-pathway state, N

» Succinate pathway control state, S

» NS-pathway control state, NS

» Glycerophosphate pathway control state, Gp

» Complex IV single step, CIV

» Anaplerotic pathway control state

Main fuel substrates

» Glutamate, G

» Glycerophosphate, Gp

» Malate, M

» Octanoylcarnitine, Oct

» Pyruvate, P

» Succinate, S

Glossary

» List of SUIT states

» SUIT concept

@@ Line 1: / Line 1: @@
 [[Image:SUIT-MitoFit.png|right|190px|link=http://www.bioblast.at/index.php/MitoPedia:_SUIT |MitoPedia: SUIT]]
 == Steps and respiratory states ==
-[[File:1OctM;2D;2c;3P;4S;5U;6Rot;7Ama-.png|300px]]
+[[File:1OctM;2D;2c;3P;4S;5U;6Rot;7Ama;8AsTm;9Azd.png|400px]]
-[[File:SUIT-005 O2 pfi D11.png|500px]]
 {| class="wikitable" border="1"
@@ Line 9: / Line 8: @@
 |-
 | 1OctM
-| [[OctM]]<sub>''L''</sub>
+| [[OctM]]<sub>''L''(n)</sub>
 | [[Fatty acid oxidation pathway control state| F(N)]]
 | FAO
-| OctM<sub>''L''</sub> or OctM_L: Octanoylcarnitine & low malate, N-LEAK respiration, N<sub>''L''</sub>
+| 1OctM
-{{Template:SUIT F}} {{Template:SUIT M low}} {{Template: SUIT L n}}
+*{{Template:SUIT F(N)}}
+*{{Template:SUIT M low}}
+*{{Template: SUIT L(n)}}
 |-
@@ Line 23: / Line 24: @@
 | 1OCtM;2D
-{{Template:SUIT F}} {{Template:SUIT M low}} {{Template:SUIT OXPHOS}}
+*{{Template:SUIT F(N)}}
+*{{Template:SUIT M low}}
+*{{Template:SUIT OXPHOS}}
 |-
@@ Line 32: / Line 35: @@
 | 1OCtM;2D;2c
-{{Template:SUIT F}} {{Template:SUIT M low}} {{Template:SUIT OXPHOS}} {{Template:SUIT c}}
+*{{Template:SUIT F(N)}}
+*{{Template:SUIT M low}}
+*{{Template:SUIT c}}
+*{{Template:SUIT OXPHOS}}
 |-
 | 3P
 | [[OctPM]]<sub>''P''</sub>
-| [[Fatty acid oxidation pathway control state| F(N)]]
+| [[FN]]
 | F&CI
 | 1OctM;2D;2c;3P
-{{Template:SUIT N}} {{Template:SUIT F}} {{Template:SUIT OXPHOS}}
+*{{Template:SUIT FN}}
+*{{Template:SUIT OXPHOS}}
 |-
@@ Line 50: / Line 57: @@
 | 1OctM;2D;2c;3P;4S
-{{Template:SUIT NS}} {{Template:SUIT F}} {{Template:SUIT OXPHOS}}
+*{{Template:SUIT FNS}}
+*{{Template:SUIT OXPHOS}}
 |-
@@ Line 59: / Line 67: @@
 | 1OctM;2D;2c;3P;4S;5U
-{{Template:SUIT NS}} {{Template:SUIT F}} {{Template:SUIT ET}}
+*{{Template:SUIT FNS}}
+*{{Template:SUIT U*}}
+*{{Template:SUIT ET}}
 |-
@@ Line 68: / Line 78: @@
 | 1OctM;2D;3P;4S;5U;6Rot
-{{Template:SUIT Rot}} {{Template:SUIT ET}}
+*{{Template:SUIT Rot}}
+*{{Template:SUIT ET}}
 |-
@@ Line 76: / Line 87: @@
 |
 |  1OctM;2D;3P;4S;5U;6Rot;7Ama
-{{Template:SUIT ROX}}
+*{{Template:SUIT ROX}}
 |}
+{{Template:SUIT CIV}}
 {{Template:Keywords in SUIT protocols}}