Deck 4: Bioenergetics

A) glycolysis.
B) ATP-CP system.
C) aerobic metabolism.
D) glycogenolysis.

A) 32 ATP.
B) 36 ATP.
C) 38 ATP.
D) 39 ATP.

A) mitochondria in a process called glycolysis.
B) mitochondria (i.e., electron transport chain) in a process called oxidative phosphorylation.
C) mitochondria in a process called beta oxidation.
D) cytoplasm.

A) 0%.
B) 34%.
C) 100%.
D) 66%.

A) phospholipids.
B) cholesterol.
C) triglycerides.
D) lipoproteins.

A) glucose.
B) fructose.
C) glycogen.
D) cellulose.

A) NAD and ATP.
B) FAD and ATP.
C) NAD and FAD.
D) NAD and LDH.

A) pulling two substrates together.
B) lowering the energy of activation.
C) binding to a substrate and producing energy.
D) binding to a substrate and releasing protons.

A) 2.
B) 3.
C) 32.
D) 33.

A) enzymes that catalyze reactions that result in the rearrangement of the structure of molecules
B) enzymes that catalyze reactions in which groups of elements are removed to form a double bond or are added to an existing double bond
C) enzymes that catalyze reactions in which the cleavage of bonds is accomplished by adding water
D) enzymes that catalyze the transfer of elements from one molecule to another

A) the amount of lactate dehydrogenase in the muscle.
B) the amount of NAD in the sarcoplasm of the muscle.
C) ADP concentration in the cytoplasm.
D) the pH of the interstitial fluid.

A) NAD.
B) FAD.
C) ATP.
D) GTP.

A) reactions that are linked together via the same enzyme.
B) reactions that are linked together, with the liberation of free energy in one reaction being used to drive the second reaction.
C) reactions that are not directly linked together but are related to the same enzyme.
D) reactions that are linked via common substrates.

A) 1.5 ATP.
B) 2.5 ATP.
C) 5.0 ATP.
D) 10.0 ATP.

A) complete the oxidation of carbohydrates, fats, and proteins (i.e., form NADH and FADH).
B) produce ATP via substrate-level phosphorylation.
C) prime glycolysis for the production of ATP.
D) produce H₂O and ATP.

A) glycolysis occurs in the mitochondrial matrix.
B) glycolysis ends with the production of pyruvic acid or lactic acid.
C) glycolysis can start with glucose of fatty acids.
D) glycolysis doesn't produce any ATP.

A) lactate dehydrogenase.
B) hexokinase.
C) phosphofructokinase.
D) pyruvate kinase.

A) cannot be created nor destroyed.
B) cannot be stored.
C) cannot be converted into other forms.
D) transformations result in an increase in entropy.

A) Paget's disease
B) pancreatitis
C) muscular dystrophy
D) myocardial infarction

A) 4 kcal/g.
B) 7 kcal/g.
C) 9 kcal/g.
D) the same as that of one gram of fat.

A) aerobic energy production.
B) anaerobic energy production.
C) the Krebs cycle to the production of ATP.
D) the electron transport chain to the production of ATP.

A) adenylate cyclase.
B) myosin ATPase.
C) creatine kinase.
D) lactate dehydrogenase.

A) ADP
B) ATP
C) P_i
D) none of these

A) isocitrate dehydrogenase.
B) hexokinase.
C) succinate dehydrogenase.
D) cytochrome oxidase.

A) greater
B) lesser

A) breaking down stored triglycerides to FFA.
B) the addition of oxygen to a fatty acid.
C) the breakdown of a fatty acid to acetyl-CoA.
D) none of these.

A) the net production of ATP is higher than previously thought.
B) it accounts for the fact that an additional H⁺ is required to move ATP into the cytoplasm.
C) it eliminates the ATP derived from NADH and FADH₂.
D) of all of these.

A) increasing enzyme activity.
B) decreasing enzyme activity.
C) denaturing enzymes.
D) none of these.

A) complete the oxidation of foodstuffs using NAD and FAD as hydrogen (electron) carriers.
B) catalyze the phosphorylation of ADP from creatine phosphate.
C) oxidize foodstuffs and transfer those electrons to pyruvic acid.
D) consume lactate.

A) phosphofructokinase.
B) isocitrate dehydrogenase.
C) myosin ATPase.
D) ATP synthase.

A) best described by the lock and key model.
B) not influenced by pH.
C) a terminal point for both the enzyme and substrate (neither can be reused).
D) more likely to occur in a 20 degrees C environment than a 40 degrees C one.

A) the enzyme LDH.
B) NADH + H^+.
C) both of these.
D) neither of these.

A) The associated oxidation and reduction reactions provide the energy needed to pump H⁺ ions into the mitochondrial matrix
B) The flow of H⁺ ions from the inter-membrane space back into the mitochondrial matrix powers the (aerobic) production of ADP
C) The electrons passed down the chain will eventually be used to help form water
D) The end result of the electron transport chain is the formation of oxygen