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Electron Transport Chain (Respiratory Chain) - exercise -. Vladimíra Kvasnicová. Respiratory chain (RCH). is found in all cells is located in a mitochondrion includes enzymes integrated in the inner mitochondrial membrane produces reducing equivalents (NADH+H + , FADH 2 ).
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Electron Transport Chain(Respiratory Chain)- exercise - Vladimíra Kvasnicová
Respiratory chain (RCH) • is found in all cells • is located in a mitochondrion • includes enzymes integrated in the inner mitochondrial membrane • produces reducing equivalents (NADH+H+, FADH2)
Respiratory chain (RCH) • is found in all cells • is located in a mitochondrion • includes enzymes integrated in the inner mitochondrial membrane • produces reducing equivalents (NADH+H+, FADH2)
The figure is found at http://plaza.ufl.edu/tmullins/BCH3023/cell%20respiration.html (December 2006)
Respiratory chain (RCH) • belongs among oxidative pathways • can proceed under both aerobic and anaerobic conditions • is a reversible pathway • needs oxygen (O2) for its function
Respiratory chain (RCH) • belongs among oxidative pathways • can proceed under both aerobic and anaerobic conditions • is a reversible pathway • needs oxygen (O2) for its function
reducing properties Redox potential „E“ Gibbs energy„G“ oxidizing properties The figure is found at http://www.grossmont.net/cmilgrim/Bio220/Outline/ECB2Figures&Tables_Ed2-Ed1/Chapter14_13/REDOX_POTENTIALS_ElectronTransportChain_Fig14-21.htm (December 2006)
The figure is found at http://academic.brooklyn.cuny.edu/biology/bio4fv/page/mito_ox.htm (December 2006)
Enzymes of the RCH • belongs among oxidoreductases • can transfer either H or electrons • are called Complex I, II, III and IV • transfer protons and electrons in the same direction
Enzymes of the RCH • belongs among oxidoreductases • can transfer either H or electrons • are called Complex I, II, III and IV • transfer protones and electrones in the same direction
proton= H+ electron= e- Cytochrome c is drawn wrongly! It is found in the intermembrane space, bound to the inner mitochondrial membrane The figure is adopted from the book: Devlin, T. M. (editor): Textbook of Biochemistry with Clinical Correlations, 4th ed. Wiley‑Liss, Inc., New York, 1997. ISBN 0‑471‑15451‑2
The function of the RCH • is to regenerate NAD+ from NADH • is to regenerate NADP+ from NADPH • is to regenerate FAD from FADH2 • is to finish oxidation of energy substrates and conserve their energy in a form of ATP
The function of the RCH • is to regenerate NAD+ from NADH • is to regenerate NADP+ from NADPH • is to regenerate FAD from FADH2 • is to finish oxidation of energy substrates and conserve their energy in a form of ATP
In reactions of the RCH • oxygen is reduced to H2O • protons (H+) are transfered into an intermembrane space • ATP is produced by the Complex I • all reduced coenzymes (NADH+H+ and FADH2) are reoxidized by the same mechanism
In reactions of the RCH • oxygen is reduced to H2O • protons (H+) are transfered into an intermembrane space • ATP is produced by the Complex I • all reduced coenzymes (NADH+H+ and FADH2) are reoxidized by the same mechanism
The figure is found at http://www.cellml.org/examples/images/metabolic_models/the_electron_transport_chain.gif (December 2006)
Choose correct statement • Complex I transfers H+ into an intermembrane space • Complex II transfers H+ into an intermembrane space • Coenzyme Q accepts e- from both Complex I and Complex II • Complex IV transfers electrones to oxygen
Choose correct statement • Complex I transfers H+ into an intermembrane space • Complex II transfers H+ into an intermembrane space • Coenzyme Q accepts e- from both Complex I and Complex II • Complex IV transfers electrones to oxygen
proton= H+ electron= e- Cytochrome c is drawn wrongly! It is found in the intermembrane space, bound to the inner mitochondrial membrane The figure is adopted from the book: Devlin, T. M. (editor): Textbook of Biochemistry with Clinical Correlations, 4th ed. Wiley‑Liss, Inc., New York, 1997. ISBN 0‑471‑15451‑2
Citrate cycle (CC) and the RCH are interconnected • by CO2 (produced by CC, used by RCH) • by NADH (produced by CC, used by RCH) • an enzyme succinate dehydrogenase • ATP (produced by RCH, used by CC)
Citrate cycle (CC) and the RCH are interconnected • by CO2 (produced by CC, used by RCH) • by NADH (produced by CC, used by RCH) • an enzyme succinate dehydrogenase • ATP (produced by RCH, used by CC)
Citrate cycle succinate DH The figure is found at http://www.cellml.org/examples/images/metabolic_models/the_electron_transport_chain.gif (December 2006)
Adenosine triphosphate (ATP) • can be produced only in a cooperation with the RCH • can be synthesized only under aerobic conditions • is formed from ADP by addition of one phosphate • is transported from a mitochondrion into a cytoplasm by exchange with ADP
Adenosine triphosphate (ATP) • can be produced only in a cooperation with the RCH • can be synthesized only under aerobic conditions • is formed from ADP by addition of one phosphate • is transported from a mitochondrion into a cytoplasm by exchange with ADP
ATP-ADP translocase The figure is adopted from the book: Devlin, T. M. (editor): Textbook of Biochemistry with Clinical Correlations, 4th ed. Wiley‑Liss, Inc., New York, 1997. ISBN 0‑471‑15451‑2
When the term is used it always means „ATP synthesis“ • phosphorylation • oxidative phosphorylation • aerobic phosphorylation • substrate level phosphorylation
When the term is used it always means „ATP synthesis“ • phosphorylation • oxidative phosphorylation • aerobic phosphorylation • substrate level phosphorylation
Oxidative phosphorylation • needs proton gradient on the inner mitochondrial membrane • is catalyzed by ATP synthase • can be interrupted by uncoupling proteins (UCP) • means ATP synthesis in any oxidative metabolic pathway
Oxidative phosphorylation • needs proton gradient on the inner mitochondrial membrane • is catalyzed by ATP synthase • can be interrupted by uncoupling proteins (UCP) • means ATP synthesis in any oxidative metabolic pathway
The figure is adopted from the book: Devlin, T. M. (editor): Textbook of Biochemistry with Clinical Correlations, 4th ed. Wiley‑Liss, Inc., New York, 1997. ISBN 0‑471‑15451‑2
inner mitochondrial membrane ATP synthase The figure is found at http://plaza.ufl.edu/tmullins/BCH3023/cell%20respiration.html (December 2006)
Uncoupling proteins(UCP) = separate RCH from ATP synthesis(the synthesis is interrupted) energy from H+ gradient is released as a heat The figure is found at http://departments.oxy.edu/biology/Franck/Bio222/Lectures/March23_lecture_shuttles.htm (December 2006)
ATP can be formed by the reactions • glucose-6-P + ADP → glucose + ATP • succinyl~CoA + GDP → succinate + GTP • GTP + ADP → GDP + ATP • ADP + ADP → ATP + AMP
ATP can be formed by the reactions • glucose-6-P + ADP → glucose + ATP • succinyl~CoA + GDP → succinate + GTP • GTP + ADP → GDP + ATP • ADP + ADP → ATP + AMP(adenylate kinase = myokinase)
Oxidation of NADH+H+ in the RCH produces more ATP than oxidation of FADH2 because • higher proton gradien is made by oxidation of NADH+H+ • NADH+H+ transfers H to different Complex of the RCH than FADH2 • more protons are transported to the intermembrane space if NADH+H+ is oxidized • more e- are transfered from NADH+H+ to O2
Oxidation of NADH+H+ in the RCH produces more ATP than oxidation of FADH2 because • higher proton gradien is made by oxidation of NADH+H+ • NADH+H+ transfers H to different Complex of the RCH than FADH2 • more protons are transported to the intermembrane space if NADH+H+ is oxidized • more e- are transfered from NADH+H+ to O2
FADH2 The figure is found at http://web.indstate.edu/thcme/mwking/oxidative-phosphorylation.html (December 2006)
Choose correct statement(s) about regulation of RCH and ATP synthesis • O2 decreases the pathways • uncoupling proteins increases ATP synthesis • ADP increses ATP synthesis • NADH+H+/NAD+ increases the pathways
Choose correct statement(s) about regulation of RCH and ATP synthesis • O2 decreases the pathways • uncoupling proteins increases ATP synthesis • ADP increses ATP synthesis • NADH+H+/NAD+ increases the pathways
