Difference between revisions of "Template:SUIT-019"

Revision as of 15:31, 28 January 2019

Steps and respiratory states

Step	State	Pathway	Q-junction	Comment - Events (E) and Marks (M)
1PalM	PalM_L	F(N)	CETF	1PalM 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. Non-phosphorylating resting state (LEAK state); LEAK respiration L(n) in the absence of ADP, ATP, AMP (no adenylates).
2D	PalM_P	F(N)	CETF	1PalM;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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
2c	PalM_P	F(N)	CETF	1PalM;2D;2c 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]). 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
3Oct	PalOctM_P	F(N)	CETF	1PalM;2D;2c;3Oct 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. OXPHOS capacity P (with saturating [ADP]), active OXPHOS state.
4P	PalOctPM_P	FN	CETF&I	1PalM;2D;2c;3Oct;4P 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. & NADH-linked substrates (type N-pathway to Q). 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.
5G	PalOctPGM_P	FN	CETF&I	1PalM;2D;2c;3Oct;4P;5G 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. & NADH-linked substrates (type N-pathway to Q). 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.
6U	PalOctPGM_E	FN	CETF&CI&II	1PalM;2D;2c;3Oct;4P;5G;6U 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. & NADH-linked substrates (type N-pathway to Q). 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. 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.
7S	PalOctPGMS_E	FNS	CI&CII	1PalM;2D;2c;3Oct;4P;5G;6U;7S 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. The FA concentration has to be optimized to saturate the F-pathway, without inhibiting or uncoupling respiration. & NADH-linked substrates (type N-pathway to Q). 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. Succinate, S ( type S-pathway to Q). Noncoupled electron transfer state, ET state, with ET capacity E.
8Rot	S_E	S	CII	1PalM;2D;2c;3Oct;4P;5G;6U;7S;8Rot Succinate pathway control state (S-pathway) after inhibiting CI with rotenone, which also inhibits the F-pathway. Succinate, S ( type S-pathway to Q). Noncoupled electron transfer state, ET state, with ET capacity E.
9Ama	ROX			1PalM;2D;2c;3Oct;4P;5G;6U;7S;8Rot;9Ama Rox is the residual oxygen consumption in the ROX state, due to oxidative side reactions, estimated after addition of antimycin A (inhibitor of CIII). Rox is subtracted from oxygen flux as a baseline for all respiratory states, to obtain mitochondrial respiration (mt).

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 8: / Line 8: @@
 |-
 | 1PalM
-| [[PalM]]<sub>''L''</sub>
+| [[PalM]]<sub>''[[L]]''</sub>
 | [[Fatty acid oxidation pathway control state| F(N)]]
 | CETF
@@ Line 18: / Line 18: @@
 |-
 | 2D
-| [[PalM]]<sub>''P''</sub>
+| [[PalM]]<sub>''[[OXPHOS|P]]''</sub>
 | [[Fatty acid oxidation pathway control state| F(N)]]
 | CETF
@@ Line 28: / Line 28: @@
 |-
 | 2c
-| [[PalM]]<sub>''P''</sub>
+| [[PalM]]<sub>''[[OXPHOS|P]]''</sub>
 | [[Fatty acid oxidation pathway control state| F(N)]]
 | CETF
@@ Line 39: / Line 39: @@
 |-
 | 3Oct
-| [[PalOctM]]<sub>''P''</sub>
+| [[PalOctM]]<sub>''[[OXPHOS|P]]''</sub>
 | [[Fatty acid oxidation pathway control state| F(N)]]
 | CETF
@@ Line 49: / Line 49: @@
 |-
 | 4P
-| [[PalOctPM]]<sub>''P''</sub>
+| [[PalOctPM]]<sub>''[[OXPHOS|P]]''</sub>
 | [[FN]]
 | CETF&I
@@ Line 60: / Line 60: @@
 |-
 | 5G
-| [[PalOctPGM]]<sub>''P''</sub>
+| [[PalOctPGM]]<sub>''[[OXPHOS|P]]''</sub>
 | [[FN]]
 | CETF&I
@@ Line 71: / Line 71: @@
 |-
 | 6U
-| [[PalOctPGM]]<sub>''E''</sub>
+| [[PalOctPGM]]<sub>''[[E]]''</sub>
 | [[FN]]
 | CETF&CI&II
@@ Line 83: / Line 83: @@
 |-
 | 7S
-| [[PalOctPGMS]]<sub>''E''</sub>
+| [[PalOctPGMS]]<sub>''[[E]]''</sub>
 | [[FNS]]
 | CI&CII
@@ Line 95: / Line 95: @@
 |-
 | 8Rot
-| [[S]]<sub>''E''</sub>
+| [[S]]<sub>''[[E]]''</sub>
 | [[S]]
 | CII
@@ Line 106: / Line 106: @@
 |-
 | 9Ama
-| ROX
+| [[ROX]]
 |
 |