Deck 20: Electron Transport and Oxidative Phosphorylation

A) substrate-level phosphorylation
B) oxidative phosphorylation
C) photophosphorylation
D) none of these

A) The synthesis of ATP in mitochondria is driven by a proton or pH gradient.
B) The synthesis of ATP is directly linked to the oxidation of NADH
C) The reoxidation of NADH and FADH₂ indirectly creates a proton gradient that is involved in ATP synthesis
D) All of these are true

A) one
B) two
C) four
D) eight

A) NAD
B) FAD
C) coenzyme Q
D) cytochrome C

A) coenzyme Q; cytochrome c ; pumps
B) coenzyme Q; cytochrome c ; doesn't pump
C) cytochrome c ; coenzyme Q; pumps
D) cytochrome c ; coenzyme Q; doesn't pump

A) NADH
B) FADH₂
C) coenzyme Q
D) coenzyme A

A) O₂
B) H₂O
C) cytochrome c
D) coenzyme Q
E) none of these

A) It is measured by comparison with the partial pressure of oxygen in the bloodstream rather than 1 atmosphere pressure.
B) It is measured by comparison with a standard hydrogen electrode.
C) It is related to Δ G ° by a well known equation.
D) It cannot be determined for electron-transfer reactions involving coenzyme Q.

A) coenzyme Q; cytochrome c ; pumps
B) cytochrome c ; coenzyme Q; pumps
C) cytochrome c ; O₂; doesn't pump
D) cytochrome c ; O₂; pumps

A) NAD⁺.
B) FAD.
C) oxygen.
D) ADP.
E) none of these

A) NADH to coenzyme Q via Complex I.
B) FADH₂ to coenzyme Q via Complex II.
C) coenzyme Q to cytochrome c via Complex III.
D) coenzyme Q to NADH.
E) none of these

A) FADH₂; coenzyme Q; doesn't pump
B) FADH₂; coenzyme Q; pumps
C) NADH; coenzyme Q; doesn't pump
D) NADH; coenzyme Q; pumps

A) FADH₂; coenzyme Q; doesn't pump
B) FADH₂; coenzyme Q; pumps
C) NADH; coenzyme Q; doesn't pump
D) NADH; coenzyme Q; pumps

A) higher than
B) lower than
C) the same as

A) Complex I
B) Complex II
C) Complex III
D) Complex IV

A) the reduction potential (E ° ) of the half reactions
B) the Faraday constant
C) the number of electrons involved in the transfer
D) none of these
E) all of these

A) By using several steps the net − Δ G is higher (more energy is released).
B) More heat can be generated by using small steps.
C) More energy can be captured to synthesize ATP by using small steps.
D) Small steps allow for both more heat generation and more ATP synthesis.
E) All of these statements are advantages of using multiple steps.

A) the pH of the matrix is greater than the pH of the intermembrane space.
B) the pH of the matrix is less than the pH of the intermembrane space.
C) the pH of the matrix is about the same as the pH of the intermembrane space.
D) the pH of the matrix versus the intermembrane space has nothing to do with whether not aerobic respiration is occurring.

A) malate to oxalosuccinate.
B) succinate to fumarate.
C) isocitrate to α -ketoglutarate.
D) α -ketoglutarate to succinyl-CoA.

A) Cytochrome C oxidase.
B) NADH-CoQ oxidoreductase.
C) succinate-CoQ reductase.
D) Cytochrome A oxidase.
E) Cytochrome bc₁ complex.

A) coenzyme Q and FADH₂
B) NADH and FADH₂
C) cytochrome b and cytochrome c
D) coenzyme Q and NADH

A) all the components of the citric acid cycle and the electron transport chain
B) all the components of the citric acid cycle but none of the components of the electron transport chain
C) all the components of the electron transport chain but none of the components of the citric acid cycle
D) all the components of the electron transport chain and one of the components of the citric acid cycle, namely the succinate dehydrogenase complex

A) Cytochrome C oxidase.
B) NADH-CoQ reductase.
C) succinate-CoQ reductase.
D) Cytochrome A oxidase.
E) Cytochrome bc₁ complex.

A) the succinate dehydrogenase complex.
B) Complex I.
C) cytochrome c oxidase.
D) Complex III.

A) Complex I
B) Complex II
C) Complex III
D) Complex IV
E) It is not known where succinate dehydrogenase is located.

A) Complex I.
B) Complex II.
C) Complex III.
D) Complex IV.
E) It is not known where oxygen is used.

A) on the outer membrane
B) on the inner membrane.
C) in the mitochondrial matrix.
D) in the intermembrane space.
E) in the cytosol.

A) the cytochrome a\a ₃ complex.
B) cytochrome b .
C) cytochrome c .
D) cytochrome c _1.

A) cytochrome c oxidase.
B) NADH-CoQ oxidoreductase.
C) cytochrome bc₁ complex.
D) succinate-CoQ oxidoreductase.

A) Complex I
B) Complex II
C) Complex III
D) Complex IV
E) It is not known where cytochrome oxidase is located.

A) cytochrome a
B) cytochrome b
C) cytochrome c
D) cytochrome c ₁

A) NADH → FMN → Coenzyme Q → Cyt A → Cyt B → Cyt C → O₂
B) NADH → FMN → Cyt B → Coenzyme Q → Cyt C → Cyt A → O₂
C) FMNH₂ → NAD → Coenzyme Q → Cyt B → Cyt C → Cyt A → O₂
D) NADH → FMN → Coenzyme Q → Cyt B → Cyt C → Cyt A → O₂
E) NADH → FMN → Cyt B → Cyt C → Coenzyme Q → Cyt A → O₂

A) iron-sulfur proteins.
B) cytochrome b .
C) cytochrome c .
D) coenzyme Q.

A) Complex I → complex II → complex III → complex IV.
B) Complex IV → complex III → complex II → complex I.
C) Complex I → complex III → complex IV.
D) Complex II → complex III → complex IV.
E) Both complex I → III → IV and complex II → III → IV.

A) in the oxidized and reduced forms only.
B) in the oxidized, reduced, and semiquinone forms.
C) in the oxidized and semiquinone forms only.
D) in the reduced and semiquinone forms only.

A) Cytochrome C oxidase.
B) NADH-CoQ reductase.
C) succinate-CoQ reductase.
D) Cytochrome A oxidase.
E) Cytochrome bc₁ complex.

A) Interruption of electron flow.
B) Stopping electron flow but not stopping ATP synthesis.
C) Stopping ATP synthesis but not stopping electron flow.
D) Blocking the electrons from NADH from entering the electron transport system.
E) All of these describe uncoupling.

A) it shuttles NADH across the mitochondrial membrane to yield 5 ATP\NADH
B) it shuttles the electrons from NADH across the mitochondrial membrane to FADH₂, yielding 5 ATP\NADH
C) it only operates efficiently at high levels of NADH
D) malate is a key component in the shuttle process

A) Complexes I, II, and III
B) Complexes I, II, and IV
C) Complexes I, III, and IV
D) all four respiratory complexes

A) They block the flow of electrons, so protons aren't pumped, and ATP synthesis ceases.
B) They remove electrons from the chain, so less protons are pumped, and ATP synthesis decreases.
C) They block the flow of protons through the ATP synthase, so ATP synthesis ceases. Electron flow and proton pumping are also halted as a result.
D) They provide an alternative path for protons to re-enter the mitochondrial matrix, so ATP synthesis decreases. Electron flow and proton pumping are not affected.

A) by enhancing the proton gradient across the outer mitochondrial membrane.
B) by enhancing the proton gradient across the inner mitochondrial membrane.
C) because they are transmembrane proteins in the outer mitochondrial membrane.
D) without affecting electron transport.

A) a protein oligomer
B) a protein monomer
C) gramicidin A
D) valinomycin

A) Uncoupling agents can work by disrupting the flow of protons during ATP synthesis.
B) Uncoupling agents prevent the flow of electrons during electron transport
C) Uncoupling agents always block the flow of protons through the ATPase
D) none of these is true

A) protons flow into the mitochondrial matrix through ion channels in the ATP synthase
B) the F₀ part of the ATP synthase serves as a proton channel
C) the F₁ part of the ATP synthase is the site of ATP formation
D) iron-sulfur proteins bind to the ATP synthase

A) Using an electron gradient to synthesize ATP.
B) Using a proton gradient to synthesize ATP.
C) Using oxygen flow to synthesize ATP.
D) Using a proton gradient to make water from oxygen.
E) These are all chemiosmotic processes.

A) mitochondrial membrane fragments without compartmentalization can carry out oxidative phosphorylation
B) submitochondrial preparations that contain closed vesicles can carry out oxidative phosphorylation
C) many different kinds of substances can serve as uncouplers
D) it has proved impossible to duplicate the process in model systems

A) to inhibit conformational changes in the ATP synthase
B) to create more sites for ATP synthesis
C) the release of tightly bound ATP from the synthase
D) all of these
E) none of these

A) use of respiratory inhibitors
B) spectroscopy
C) isolation of intact mitochondria
D) none of these have anything to do with determining the order

A) oxygen atoms consumed in electron transport
B) oxygen molecules consumed in electron transport
C) NADH reoxidized in electron transport
D) FADH₂ reoxidized in electron transport

A) Complex I.
B) Complex II.
C) Complex III.
D) Complex IV.
E) All four complexes pump protons.

A) Closed vessicles were required. Phosphorylation did not occur in a completely soluble environment.
B) Vessicles could be prepared from mitochondria and the assymetric location of electron transport protein could be shown.
C) The existence of the pH gradient could be demonstrated
D) The transfer of electrons from complex I to oxygen was shown
E) none of these

A) 2
B) 4
C) 6
D) 30 − 32, dependent on the shuttle system used.

A) fat in the muscle cells
B) muscle glycogen
C) liver glycogen
D) muscle creatine-phosphate
E) all of these would be exhausted simultaneously

A) reduction coefficient
B) reduction standard
C) reduction potential
D) standard potential

A) there are fewer mitochondria in muscle and brain cells
B) muscle and brain cells have a lower requirement for ATP
C) different shuttle mechanisms operate to transfer electrons from the cytosol to the mitochondrion in the two sets of tissues
D) none of the above

A) heme
B) hemin
C) corrin
D) chlorin

A) Outer mitochondrial membrane
B) Inner mitochondrial membrane
C) Cristae
D) Matrix