Deck 14: Bioenergetics and Oxidative Metabolism

A) undergoing oxygenation and deoxygenation.
B) undergoing oxidation and reduction.
C) combining with phosphate.
D) undergoing dehydration and hydration.
E) interchanging with the iron of adrenodoxin.

A) are generally endergonic.
B) are typified by that catalyzed by pyruvate kinase.
C) are defined as reactions which produce pyruvate.
D) increase the concentrations of intermediates of the Krebs cycle.
E) are typified by those catalyzed by pyruvate dehydrogenase and alpha-ketoglutarate dehydrogenase.

A) noncompetitive inhibition.
B) competitive inhibition.
C) irreversible inhibition.
D) uncompetitive inhibition.
E) no inhibition; it is the product of the reaction.

A) catalyzes the conversion of pyruvate to acetyl-CoA and carbon dioxide.
B) catalyzes the conversion of pyruvate to oxaloacetate.
C) functions as a tetramer made up of two types of subunits which are identical to those of either muscle (M) or heart (H) origin.
D) utilizes NAD as the only required coenzyme.
E) catalyzes the oxidation of lactate to pyruvate.

A) skeletal muscle cells
B) liver parenchymal cells
C) adipose cells
D) renal tubular epithelium
E) erythrocytes

A) the mitochondrial genome is a circular DNA.
B) the mitochondrial genome codes for several essential proteins for oxidative phosphorylation.
C) the mitochondrial genome exhibits maternal inheritance.
D) the mitochondrial genome uses the same genetic code as the nuclear genome.
E) a mitochondrial DNA mutation results in Leber's Hereditary Optic Neuropathy.

A) + 5.3
B) - 5.3
C) + 7.3
D) - 7.3
E) + 9.3

A) in the cytosol.
B) on the outer membrane of the mitochondria.
C) on the inner membrane of the mitochondria.
D) in the mitochondrial matrix.
E) in the lysosomes.

A) biotin
B) lipoic acid
C) thiamine pyrophosphate
D) coenzyme A
E) flavin adenine dinucleotide

A) alpha-ketoglutarate.
B) ADP.
C) NADH.
D) acetyl-CoA.
E) glucose 6-phosphate.

A) Action of thyroid hormone on a mitochondrial thyroid receptor
B) Activation of UCP-1 by fatty acids
C) Induction of ATPase
D) Synthesis of a small non-protein uncoupling molecule
E) Transfer of protons out of the mitochondrial matrix

A) cis-aconitate.
B) pyruvate.
C) fumarate.
D) succinyl-CoA.
E) malate.

A) hydration of cis-aconitate to isocitrate
B) dehydration of citric acid to form cis-aconitic acid
C) oxidative decarboxylation of alpha-ketoglutaric acid to form succinyl-CoA
D) hydration of fumaric acid to form malic acid
E) decarboxylation of citric acid to form oxalosuccinic acid

A) FeS
B) NAD
C) heme
D) flavin
E) ADP

A) alpha-ketoglutarate dehydrogenase
B) isocitrate dehydrogenase
C) succinate dehydrogenase
D) malate dehydrogenase
E) citrate synthase

A) one proton.
B) one electron and one proton.
C) two electrons.
D) two protons.
E) two electrons and two protons.

A) Binding to cytochromes
B) Channeling protons
C) Binding to coenzyme Q
D) Oxidizing FAD
E) Inhibiting phosphorylation

A) less than 1.
B) zero.
C) greater than 1.
D) equal to -RT 1n Keq.
E) can be utilized to do work in the cell.

A) succinyl-CoA synthase
B) citrate synthase
C) alpha-ketoglutarate dehydrogenase
D) aconitase
E) succinate dehydrogenase

A) positive standard free energy change only.
B) positive standard free energy change and high activation energy.
C) negative standard free energy change and high activation energy.
D) positive standard free energy change and low activation energy.
E) negative standard free energy change.

A) inhibits electron transport and oxidative phosphorylation
B) allows electron transport to proceed without ATP synthesis
C) blocks the transfer of electrons from NADH to O2
D) stimulates ATP synthesis
E) blocks the transfer of electrons from complex I to complex II.

A) ATP synthesis is driven by a pH gradient and a membrane potential.
B) ATP synthase translocates ATP through mitochondrial membrane.
C) the respiratory chain consists of three enzyme complexes linked by two mobile electron carriers.
D) the process can be uncoupled by 2,4-dinitrophenol.

A) blocks the oxidation of reduced cytochrome c by cytochrome oxidase.
B) prevents formation of ATP by interacting with and blocking proton transport through the proton translocating ATPase.
C) acts to conduct protons back into the mitochondrial matrix without accompanying formation of ATP.
D) blocks proton conductance and slows oxygen uptake rates.

A) aconitase.
B) citrate synthase.
C) succinate thiokinase.
D) pyruvate dehydrogenase.
E) isocitric dehydrogenase.

A) blocks the oxidation of reduced cytochrome c by cytochrome oxidase.
B) prevents formation of ATP by interacting with and blocking proton transport through the proton translocating ATPase.
C) acts to conduct protons back into the mitochondrial matrix without accompanying formation of ATP.
D) blocks proton conductance and slows oxygen uptake rates.

A) oxaloacetate dehydrogenase
B) succinate dehydrogenase
C) fumarase
D) isocitrate dehydrogenase
E) alpha-ketoglutarate dehydrogenase

A) FMN
B) coenzyme Q
C) heme a3
D) FeS cluster
E) FAD

A) after conversion to glycerol phosphate.
B) by passive diffusion.
C) after reaction with carnitine.
D) after oxidation to pyruvate.
E) after reduction to malate.

A) "Flipping" of orientation of F1Fo-ATP synthase in the membrane
B) A one-step rotation of 180o
C) Change in the binding constant for ATP on the T subunit
D) Conformation change of the b subunit resulting in release of protons
E) Rotation of the g subunit in 120o steps

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

A) ATP.
B) oxygen.
C) inorganic phosphate.
D) pyruvate.
E) acetyl CoA.

A) proton gradient across the membrane.
B) a high energy phosphate bond.
C) a different conformational form of the electron carriers.
D) a protonated form of coenzyme Q.
E) a reduced non-heme iron protein.

A) outer membrane.
B) intermembrane space.
C) inner membrane.
D) matrix.
E) tonoplast.

A) Age spots
B) Cataracts
C) Dental caries
D) Hair loss
E) Osteoporosis

A) with a high chemical bond energy.
B) which is highly unstable.
C) which is highly exergonic.
D) with a high phosphate group transfer potential.
E) with a large negative free energy change on hydrolysis.

A) O2
B) Glucose
C) ADP
D) ATP
E) electrons

A) Glucose production from glycogen
B) Lactate production from glucose
C) Malate production from succinyl CoA
D) pyruvate production from fructose
E) Succinate production from succinyl CoA

A) FAD
B) NADPH
C) NADH
D) ATP
E) Fe2+

A) phosphoglycerate kinase.
B) pyruvate kinase.
C) pyruvate carboxylase.
D) creatine kinase.
E) succinate thiokinase.

A) cytochrome c
B) cytochrome oxidase
C) NADH dehydrogenase
D) Succinate dehydrogenase
E) Ubiquinone

A) the reaction involves only the transfer of a hydrogen atom.
B) NAD+ is the oxidant.
C) FMNH2 is the electron acceptor.
D) FMN is the reducing agent.
E) NADH is the electron donor.

A) isocitrate dehydrogenase
B) succinate dehydrogenase
C) fumarase
D) citrate synthase
E) aconitase

A) Consumes ATP
B) Consumes NADH
C) Is catalyzed by a flavoprotein
D) Produces coenzyme A
E) Produces fumarate

A) acetyl CoA + oxaloacetate ----> citrate
B) citrate ----> isocitrate
C) isocitrate ----> alpha-ketoglutarate
D) alpha-ketoglutarate ----> succinyl CoA
E) succinyl CoA ----> succinate

A) phosphorolysis.
B) oxidation.
C) oxidative phosphorylation.
D) reduction.
E) substrate level phosphorylation.

A) Mitochondrial protein synthesis is inhibited by chloramphenicol.
B) The enzymes of the respiratory chain are all coded by mitochondrial genes.
C) Mitochondrial protein synthesis is initiated by N-formylmet-tRNA fmet.
D) The mitochondrial genome codes for only certain proteins of the inner mitochondrial membrane.
E) Protein synthesis in mitochondria is closely integrated with cytoplasmic protein synthesis.

A) as the concentration of acetyl CoA decreases.
B) as the concentration of NAD increases.
C) when the dephospho-enzyme is converted to its phospho form.
D) as the concentration of pyruvate increases.
E) as the concentration of AMP increases.

A) succinate dehydrogenase.
B) NADH-dehydrogenase.
C) phosphorylase.
D) pyruvate dehydrogenase.
E) cytochrome oxidase.

A) synthesis of lactic acid from pyruvate is inhibited
B) increased malonyl CoA inhibits carnitine acyl transferase I.
C) electron transport cannot be used to regenerate NAD+
D) epinephrine levels are increased
E) glycogenolysis is decreased, causing less requirement for the TCA cycle.

A) can continue in the presence of dinitrophenol.
B) requires inorganic phosphate.
C) forms GTP as the immediate product.
D) requires a proton gradient.
E) is characterized by all of the above.

A) Alpha-ketoglutarate
B) Isocitrate
C) Malate
D) pyruvate
E) Succinate

A) isocitrate dehydrogenase
B) succinate dehydrogenase
C) carbonic anhydrase
D) citrate synthase
E) aconitase

A) allows storage of nutrients.
B) produces water.
C) increases carbon dioxide level in the blood.
D) produces heat.
E) raises the oxygen level in the blood.

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

A) Fe2+
B) K+
C) Mg2+
D) Mn2+
E) Na+

A) microsomes.
B) mitochondria.
C) nucleus.
D) cytosol.

A) succinate dehydrogenase.
B) citrate synthase.
C) succinyl CoA synthase.
D) malate dehydrogenase.
E) aconitase.

A) Lipoamide functions in the decarboxylation of pyruvate.
B) Coenzyme A is covalently bound to a lysine residue in one of the proteins of the complex.
C) phosphorylation catalyzed by a kinase results in decreased activity.
D) NADH is an allosteric activator of pyruvate oxidation.
E) The function of FAD is to oxidize NADH.

A) isocitrate dehydrogenase
B) succinate dehydrogenase
C) alpha-ketoglutarate dehydrogenase
D) citrate synthase
E) aconitase

A) acetyl CoA.
B) NADH.
C) cyclic AMP.
D) ingestion of ethanol.
E) ATP.

A) High levels of ATP relative to ADP
B) Depletion of NADH by its conversion to NAD+
C) Limited availability of oxaloacetate
D) High levels of citrate
E) Depletion of acetyl-CoA

A) oxaloacetate
B) succinate
C) alpha-ketoglutarate
D) citrate
E) acetate

A) H2O
B) H2O2
C) O2
D) O2.-
E) OH.

A) 3
B) 4
C) 5
D) 6
E) 7

A) catalase.
B) invertase.
C) peroxide mutase.
D) a cytochrome.
E) glutathione peroxidase.

A) citrate
B) malate
C) oxaloacetate
D) acetyl CoA
E) pyruvate

A) cytochromes.
B) coenzyme Q (ubiquinone).
C) proteins containing non_heme iron and sulfur.
D) proteins containing FMN.
E) substrate level phosphorylation.

A) A pair of electrons
B) A proton
C) Another electron
D) Loss of a protein
E) Loss of the single electron

A) The reduced form of the protein participates in electron transport by directly donating electrons to oxygen.
B) Unlike the other mitochondrial cytochromes, it is water soluble.
C) It contains iron which undergoes reversible oxidation and reduction during electron transport.
D) It is visibly colored.
E) It is reduced by the reduced form of the cytochrome bc1 complex.

A) 3
B) 9
C) 12
D) 15
E) 36

A) a topologically closed, proton impermeable membrane.
B) an ATPase which can be driven in reverse by a proton gradient across the membrane.
C) a proton translocating system oriented asymmetrically across the membrane.
D) a direct coupling of electron transport to phosphorylation.

A) Acetyl-CoA
B) Pi
C) ADP
D) ATP
E) NADPH

A) ATP
B) phosphoenolpyruvate
C) ADP
D) 1,3-bisphosphoglycerate
E) glyceraldehyde 3-phosphate

A) glutamate
B) lactate
C) malate
D) oxaloacetate
E) pyruvate

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

A) phosphomonoester.
B) phosphodiester.
C) phosphoamide.
D) phosphoanhydride.
E) phosphoenol.

A) the adenine nucleotide exchange protein.
B) ATP synthase.
C) site I of the respiratory chain.
D) site II of the respiratory chain.
E) site III of the respiratory chain.

A) NAD+
B) FADH2
C) FAD
D) NADPH
E) NADP+

A) microsomes
B) mitochondrial matrix
C) Golgi apparatus
D) inner membrane of the mitochondrion
E) cytosol