Deck 14: Electron Transport and Oxidative Phosphorylation

A) contains ATP synthase complex.
B) is the location of specific transporter proteins.
C) is a barrier to protons.
D) is not rich in proteins.
E) is rich in proteins.

A) -6.85 kJ mol^-1
B) -12.6 kJ mol^-1
C) 38.6 kJ mol^-1
D) 57.9 kJ mol^-1

A) NADH and QH₂ to O₂
B) O₂ to NAD⁺ and Q
C) O₂ to NADH
D) ATP to O₂

A) H⁺
B) acetate
C) CO₂
D) ATP

A) ATP synthase in the correct position in the membrane.
B) enzyme complexes embedded in a membrane.
C) the flow of electrons from NADH and QH₂ in the membrane.
D) a matrix more positively charged than the intermembrane space.
E) a terminal electron acceptor which is H₂O in mitochondria.

A) The uncoupler allows the oxidation of fats from adipose tissue without the production of ATP. This allows the oxidation to proceed continuously and use up the fats.
B) The uncoupler causes ATP to be produced at a much higher rate than normal and this causes weight loss.
C) The uncoupler inhibits the transport of pyruvate into the matrix of the mitochondria. Fats are then degraded to glycerol and subsequently to pyruvate to provide the necessary energy. Thereby depleting fat stores.
D) The uncoupler is an allosteric activator of ATP synthase. This increases the rate of translocation of H⁺ and the oxidation of fuels, including fats.

A) One reaction will normally not occur without the other.
B) One is always exergonic and the other is always endergonic.
C) Only oxidation-reduction reactions can be coupled.
D) Coupled reactions are always driven by the ATP to ADP conversion.

A) the phosphorylation of ADP.
B) the electron transport chain.
C) the differences between inner and outer mitochondrial membranes.
D) the source of energy for formation of mitochondrial ATP.
E) aerobic respiration.

A) matrix
B) intermembrane space
C) intracellular fluid
D) ATP synthase complex

A) the transport of Na⁺ and K⁺ across cell membranes is by active transport
B) explains how transport by facilitated diffusion reaches a saturation limit
C) explains the blood-brain barrier
D) a proton gradient that drives the formation of ATP

A) outer mitochondrial membrane - permeable to ions and water
B) inner mitochondrial membrane - permeable to O₂ and CO₂
C) outer mitochondrial membrane - folded into cristae
D) inner mitochondrial membrane - location of ATP synthase
E) matrix - some ATP synthase subunits extend here

A) The substrate will be oxidized until the addition of the 2,4-dinitrophenol, which blocks further oxidation.
B) There is no effect; oxidation of the substrate continues at the same rate before and after the addition of 2,4-dinitrophenol.
C) The substrate cannot be oxidized either with or without 2,4-dinitrophenol unless ADP is also present.
D) Oxidation of the substrate does not occur until the 2,4-dinitrophenol is added. Afterward, oxidation proceeds rapidly until all of the substrate is consumed.

A) protons; water
B) cations; anions
C) charged molecules; uncharged molecules
D) uncharged molecules; charged molecules

A) carbon dioxide
B) hydrogen peroxide
C) ozone
D) oxygen

A) integral membrane
B) peripheral membrane
C) lipid-anchored membrane
D) water-soluble
E) Both A and C

A) oxygen consumption even in the absence of ADP
B) a rise in temperature to dissipate energy that would otherwise have been used to generate ATP
C) the flow of protons into the mitochondria matrix
D) All of the above
E) None of the above

A) The pH is lower in the matrix.
B) The pH in both regions is the same.
C) The pH is lower in the inner membrane space.
D) The comparison of pH varies from moment to moment depending on energy needs of the cell.

A) the flow of electrons from the matrix to the inner membrane space
B) a combination of an electrical potential and a chemical potential
C) the flow of protons within the inner mitochondrial membrane
D) All of the above

A) 15%
B) 27%
C) 73%
D) 85%

A) Q
B) Fe-S
C) FAD
D) cytochrome c

A) strongest; highest
B) strongest; lowest
C) weakest; highest
D) weakest; lowest

A) 0
B) 1
C) 2
D) 4

A) NADH
B) complex I
C) complex II
D) O₂

A) I
B) II
C) III
D) IV
E) V

A) I
B) II
C) III
D) IV
E) V

A) Q
B) QH₂
C) cytochrome c
D) O₂
E) FMN

A) FADH₂
B) Fe-S
C) succinate
D) QH₂

A) Converts a two-electron transfer to a one-electron transfer.
B) Converts a one-electron transfer to a two-electron transfer.
C) Transports four H⁺ across the membrane.
D) None, there is no FMN in complex I.

A) A binuclear center that contains an iron ion and heme-a₃ is the site of the reduction of molecular oxygen to water.
B) Bacterial and eukaryotic forms of complex IV have very similar structures and number of subunits per functional unit.
C) The core structure of the cytochrome c oxidase in complex IV has three conserved subunits.
D) Copper ions shift from a +2 oxidation state to a +1 oxidation state as electrons are passed through the complex.

A) FAD
B) FMN
C) Q
D) TPP

A) I
B) II and III
C) I, II and III
D) I, II, III and IV

A) ubiquinone Q)
B) Fe-S
C) cytochrome c
D) FADH₂

A) 0
B) 1
C) 2
D) 3
E) 4

A) 1; 1
B) 1; 2
C) 2; 1
D) 2; 2

A) An L-shaped structure that spans the membrane and partially extends into the mitochondrial matrix.
B) A structure firmly anchored to the membrane by many a-helices that span the lipid-bilayer.
C) Three identical multisubunit enzymes that associate to form a mushroom-shaped structure.
D) Has a core structure of three conserved subunits, one of which forms a b-barrel on the exterior surface of the membrane.

A) Fe-S clusters
B) FAD
C) heme
D) cytochrome b
E) All of the above are components of complex II.

A) 4; 2
B) 2; 1
C) 1; 1
D) 1; 2
E) 4; 4

A) aspartate residues in the active site
B) the porphyrin ring
C) the multiple α-helices
D) the iron ion

A) 1
B) 2
C) 3
D) 4
E) 5

A) FAD.
B) iron clusters.
C) ubiquinone.
D) menaquinone.
E) NADH.

A) superoxide anion ·O₂^-).
B) H₂O_2.
C) Copper.
D) O_2.
E) All of the above

A) 1
B) 1.5
C) 2
D) 2.5
E) 3

A) one proton
B) three protons
C) hundreds of protons
D) 1 mole of protons

A) ·O₂^-
B) O₃^2-
C) H₂O₂
D) H₃O⁺

A) F₀
B) F₁
C) F₂
D) b subunit
E) g subunit

A) increased ATP production by ATP synthase
B) uncoupling by thermogenin
C) a greater pH gradient across the inner mitochondrial membrane by complex IV
D) insufficient NADH production during the citric acid cycle due to less active pyruvate translocase.

A) It is accomplished by adenine nucleotide translocase.
B) The same enzyme that transports ATP also transport ADP in the opposite direction.
C) It is complexed with Mg²⁺ to reduce the draw on the electrical part of the protonmotive force.
D) The transport causes the loss of a net charge of -1 in the matrix.

A) a
B) b
C) c
D) e
E) g