Deck 8: Aerobic and Anaerobic Forms of Metabolism

A) walking for 5 km
B) jogging slowly for 5 km
C) running quickly for 5 km
D) sprinting 200 m

A) cytosol; 4
B) cytosol; 2
C) mitochondria; 2
D) mitochondria; 4

A) hexokinase
B) phosphofructokinase
C) glyceraldehyde-3-phosphate dehydrogenase
D) pyruvate kinase

A) pyruvate
B) glucose
C) acetyl coenzyme A
D) NADH₂

A) hexokinase
B) phosphofructokinase
C) pyruvate kinase
D) isomerase

A) glucose
B) fructose-1,6-diphosphate
C) 2-phosphoglyceric acid
D) glyceraldehyde-3-phosphate

A) pyruvate.
B) glucose.
C) acetyl coenzyme A.
D) citrate.

A) CO₂
B) Lactic acid
C) CO₂ and lactic acid
D) CO₂ and H₂O

A) Succinate  fumarate
B) Citrate  isocitrate
C) Fumarate  malate
D) Isocitrate  -ketoglutarate

A) Citrate  isocitrate
B) Succinate  fumarate
C) Fumarate  malate
D) Isocitrate  -ketoglutarate

A) Succinate  fumarate
B) Fumarate  malate
C) Isocitrate  -ketoglutarate
D) Succinyl coenzyme A  succinate

A) enhance the production of NADH in glycolysis.
B) promote oxidation of FADH₂.
C) act as an energy source for ATP production.
D) act as a final electron acceptor.

A) The Krebs cycle would accelerate
B) The electron transport chain would be halted
C) NADH recycling to NAD⁺ would accelerate
D) FADH₂ recycling will be directly inhibited

A) NADH-Q oxidoreductase
B) Succinate dehydrogenase
C) Cytochrome b-c₁
D) Cytochrome oxidase

A) NADH-Q oxidoreductase.
B) ubiquinone.
C) cytochrome b-c₁.
D) cytochrome oxidase.

A) 5
B) 10
C) 20
D) 43

A) 20
B) 36
C) 46
D) 86

A) 2.
B) 4.
C) 21.
D) 29.

A) 2; 10
B) 10; 2
C) 12; 3
D) 3; 12

A) 2
B) 6
C) 29
D) 31

A) Catalase
B) Phosphofructokinase
C) Pyruvate kinase
D) Isomerase

A) Superoxide dismutase
B) cytochrome c oxidase
C) succinate dehydrogenase
D) coenzyme A

A) an oxidative state.
B) a reduced state.
C) redox balance.
D) oxygen deficiency.

A) ATP it produces.
B) pyruvate available.
C) protons available.
D) lactate dehydrogenase available.

A) not affect glycolysis.
B) halt the ETC that was functioning.
C) halt glycolysis.
D) allow two ATP molecules to be produced from each glycolysis cycle.

A) NAD.
B) NADH.
C) oxygen.
D) pyruvate.

A) carbon dioxide.
B) acetyl coenzyme A.
C) lactic acid.
D) glucose.

A) electrons.
B) protons.
C) bicarbonate.
D) oxygen.

A) partly coupled.
B) uncoupled.
C) loosely coupled.
D) tightly coupled.

A) NADH-Q oxidoreductase
B) Succinate dehydrogenase
C) Cytochrome oxidase
D) ATP synthase

A) It is generated during aerobic conditions.
B) It is produced in the mitochondrial matrix.
C) It is produced in the presence of oxygen.
D) It is an organic molecule.

A) 2:27.
B) 27:2.
C) 2:31.
D) 31:2.

A) Creatine
B) Arginine
C) ATP
D) ADP

A) glycolysis.
B) the citric acid cycle.
C) phosphagen production.
D) pyruvate oxidation.

A) Myoglobin
B) Hemoglobin
C) Calmodulin
D) Arginine

A) Creatine phosphate (the phosphagen system)
B) Anaerobic glycolysis
C) Aerobic catabolism using glucose
D) Aerobic catabolism using lipids

A) slow oxidative
B) fast glycolytic
C) a combination of oxidative and glycolytic
D) fast glycolytic first and after few seconds slow oxidative

A) Lactate dehydrogenase
B) Mitochondria
C) Myoglobin
D) ETC proteins

A) slow oxidative
B) fast glycolytic
C) a combination of oxidative and glycolytic
D) fast glycolytic first and after few seconds slow oxidative

A) electron transport chain activity.
B) glycolysis levels.
C) burst exercise performance.
D) citric acid cycle productivity.

A) Slow oxidative, because of their endurance
B) Fast glycolytic, because of their intensity
C) Slow glycolytic, because of their intensity
D) Fast oxidative, because of their endurance

A) the physiology of energy production.
B) the fatigability rate.
C) motion of the muscle.
D) the type of physical activity to be undertaken.

A) the physiology of energy production.
B) the motion of the muscle.
C) low resistance to fatigue.
D) the type of physical activity to be undertaken.

A) the physiology of energy production.
B) the fatigability rate.
C) motion of the muscle.
D) the type of physical activity to be undertaken.

A) increases.
B) decreases.
C) does not change.
D) increases first and then decreases after 2 hours.

A) jogging.
B) speed skating.
C) weight lifting.
D) sprinting.

A) walking.
B) running.
C) weight lifting.
D) standing.

A) NADH-dehydrogenase.
B) ATP synthase.
C) coenzyme A.
D) creatine kinase.

A) Exercise intensity
B) Oxygen consumption
C) Rate of oxygen demand or supply
D) Theoretical oxygen demand

A) A
B) B
C) C
D) B and C

A) oxygen deficit.
B) hyperoxygenation region.
C) postexercise oxygen consumption.
D) theoretical Vo₂ max.

A) None
B) One
C) Two
D) All three

A) The horizontal dashed line
B) The shaded area at the beginning of the solid line curve
C) The shaded area at the end of the solid line curve
D) The solid curve line

A) Submaximal
B) Maximal
C) Supramaximal
D) Oxygen deficit

A) The rabbit would clear lactic acid faster than the lizard.
B) The lizard would clear lactic acid faster than the rabbit.
C) Both the lizard and the rabbit would clear lactic acid at the same rate.
D) Both the lizard and the rabbit would be in oxygen deficiency.

A) Snowshoe hares that are better runners are better at evading predators.
B) Snowshoe hares that are slower runners are more efficient users of ATP.
C) Snowshoe hares that are better runners are better able to find food.
D) Exercise proficiency does not significantly affect natural selection snowshoe hares.

A) During anoxia, there is less oxygen available than the tissue demands.
B) During anoxia, vertebrates rely on anaerobic catabolism.
C) During anoxia, vertebrates generate a large amount of lactic acid.
D) During anoxia, vertebrates excrete excess lactic acid.

A) Mean rates of oxygen consumption of different species
B) Individual measurements of rate of oxygen consumption in one species
C) Death rates
D) Individual measurements of oxygen consumption in many species

A) Animals go from becoming oxygen regulators to oxygen conformers.
B) Animals become physiologically compromised.
C) Animals go from becoming oxygen conformers to oxygen regulators.
D) Animals increase their metabolic rate.

A) Species in top graph
B) Species in bottom graph
C) Both species have the same tolerance for hypoxic water.
D) Neither species can tolerate hypoxic water.

A) ATP concentration in brain tissues falls drastically.
B) Na⁺-K⁺-ATPase pumps ions across the cell membrane to reverse the effects of hypoxia.
C) Action potentials cease.
D) The release of neurotransmitters is interrupted.

A) Sea turtle
B) Slack-water darter
C) Clam
D) Leopard frog

A) Decreased usage of alanine
B) Decreased usage of succinic acid
C) Decreased production of ATP
D) Decreased buffering mechanisms

A) their body fluid will become more acidic.
B) their body fluid will become less acidic.
C) they will gain organic by-products.
D) their body fluid will remain neutral.