Deck 25: Metabolism, Nutrition, and Energetics

A) removal of hydrogen atoms from a substrate molecule by coenzymes.
B) ionization of hydrogen atoms.
C) decreasing the energy level of electrons passing through the electron transport chain.
D) the breaking of carbon-carbon covalent bonds.
E) the acceptance of electrons by oxygen atoms.

A) nutrients.
B) organics.
C) ketones.
D) metabolites.
E) coenzymes.

A) inner membrane
B) plasma membrane
C) outer membrane
D) matrix
E) cristae

A) carbohydrate craving.
B) the Atkins diet.
C) carbohydrate loading.
D) glycolysis reaction.
E) overeating.

A) begins with the formation of a molecule of citric acid.
B) directly produces most of the ATP from the catabolism of glucose.
C) consumes two moles of carbon dioxide.
D) contains enzymes called cytochromes.
E) forms acetyl-CoA from glucose-6-phosphate.

A) 2
B) 4
C) 30
D) 36
E) 38

A) energetics.
B) glycolysis.
C) cellular respiration.
D) thermodynamics.
E) metabolism.

A) mitochondria.
B) plasma membrane.
C) nucleus.
D) endoplasmic reticulum.
E) cytosol.

A) cytoplasm
B) the plasma membrane
C) the mitochondria
D) the endoplasmic reticulum
E) nucleus

A) remove hydrogen atoms from organic molecules and transfer them to coenzymes.
B) transfer the acetyl group gained from glycolysis to molecules of pyruvate.
C) hydrolyze glucose in the presence of oxygen to obtain two pyruvate molecules.
D) produce carbon dioxide to balance the oxygen requirement for cellular respiration.
E) produce water.

A) glycogen
B) glucose
C) protein
D) fat
E) an amino acid

A) convert pyruvic acid into acetyl-coA
B) produce bicarbonate ions for a pH buffer
C) transport hydrogen atoms to coenzymes
D) produce carbon dioxide
E) phosphorylate ADP into ATP

A) H2 + O2 ? H2O.
B) 2 H2 + O2 ? 2 H2O.
B) P + 3 O ? PO3.
C) 3 H? + 2O? ? 3 H?O + 2 O.

A) glycolysis.
B) the citric acid cycle.
C) electron transport.
D) the formation of pyruvic acid.
E) the formation of water.

A) nutrient storehouse.
B) nutrient reserve.
C) nutrient pool.
D) energy reserve.
E) organic storehouse.

A) glucose
B) acetyl-CoA
C) ATP
D) NAD
E) ADP

A) phosphorylated; deaminated
B) reduced; oxidized
C) made; recycled
D) phosphorylated; dephosphorylated
E) oxidized; reduced

A) a hydrogen ion
B) a coenzyme
C) the acetyl group
D) ADP
E) NAD

A) glycolysis.
B) oxidative phosphorylation.
C) catabolism.
D) anabolism.
E) metabolism.

A) inhibits the kinase that phosphorylates ATP.
B) inhibits the ATP synthase.
C) blocks substrate-level phosphorylation.
D) blocks the final electron acceptor in the ETS.
E) binds NAD preventing it from being reduced.

A) substrate-level phosphorylation.
B) oxidative phosphorylation.
C) decarboxylation.
D) cellular respiration.
E) aerobic metabolism.

A) ATP and ADP.
B) FAD and FMN.
C) NAD and ATP.
D) NAD and FAD.
E) ATP and GTP.

A) fructose-1, 6-bisphosphate.
B) carbon dioxide.
C) pyruvic acid.
D) NADH.
E) citric acid.

A) ATP, water, and carbon dioxide.
B) ATP, NADH, and pyruvic acid.
C) ADP and ATP.
D) pyruvic acid and citric acid.
E) NADH and FADH2.

A) produce Acetyl CoA so that the citric acid cycle can continue.
B) produce proteins for energy storage.
C) phosphorylate glucose molecules.
D) supply hydrogen atoms to the Electron Transport System.
E) produce citric acid to make vitamin C in the mitochondria.

A) glycolysis.
B) gluconeogenesis.
C) cellular respiration.
D) glycemia.
E) glycogenesis.

A) lose; oxidized
B) gain; oxidized
C) lose; reduced
D) gain; reduced
E) gain; ATP

A) citric acid cycle.
B) electron transport system.
C) cytosol.
D) mitochondrial matrix.
E) glycolysis.

A) glycolysis
B) gluconeogenesis
C) cellular respiration
D) glycemia
E) glycogenesis

A) splitting of oxygen molecules.
B) breaking of the covalent bonds in glucose.
C) movement of hydrogen ions through channels in the inner mitochondrial membrane.
D) combination of two atoms of hydrogen and one atom of oxygen to form water.
E) oxidation of acetyl-CoA.

A) substrate-level phosphorylation.
B) chemiosmosis.
C) anaerobic metabolism.
D) decarboxylation.
E) deamination.

A) anabolism.
B) decarboxylation.
C) deamination.
D) oxidative phosphorylation.
E) substrate-level phosphorylation.

A) carbon dioxide, water, and ATP.
B) pyruvic acid and carbon dioxide.
C) carbon dioxide and alcohol.
D) oxygen and water.
E) NADH and FADH2.

A) citric acid cycle and ETS
B) glycolysis, citric acid cycle, and ETS
C) citric acid cycle only
D) glycolysis only
E) ETS only

A) cytosol.
B) golgi apparatus.
C) mitochondrial intermembrane space.
D) mitochondrial matrix.
E) ribosome.

A) 2-4 ATP
B) 6 ATP
C) 30-32 ATP
D) 100-120 ATP
E) 150 ATP

A) glycolysis.
B) gluconeogenesis.
C) cellular respiration.
D) glycemia.
E) glycogenesis.

A) phosphoglyceric acid
B) citric acid
C) pyruvate
D) NADH
E) FADH2

A) ADP is phosphorylated.
B) FADH2 is produced.
C) citric acid molecules have oxygen atoms.
D) oxygen is needed to remove carbon atoms as carbon dioxide.
E) NAH+ is converted into NADH.

A) oxidative
B) metabolic
C) essential
D) vital
E) non-metabolic

A) hydrogen atoms
B) citric acid
C) NADH
D) carbon dioxide
E) FADH2

A) Very-low-density lipoproteins (VLDLs)
B) Low-density lipoproteins (LDLs)
C) Micelles
D) High-density lipoproteins (HDLs)
E) Very-high-density lipoproteins (VHDLs)

A) chylomicrons.
B) very-low-density lipoproteins.
C) micelles.
D) low-density lipoproteins.
E) high-density lipoproteins.

A) chylomicrons.
B) very-low-density lipoproteins.
C) micelles.
D) low-density lipoproteins.
E) high-density lipoproteins.

A) ADP
B) carbon dioxide
C) NADH
D) hydrogen atoms
E) pyruvate

A) triglycerides are converted into molecules of acetyl-CoA.
B) triglycerides are broken down into glycerol and fatty acids.
C) lipids are converted into glucose molecules.
D) lipids are formed from excess carbohydrates.
E) lipids are metabolized to yield ATP.

A) hydrogen atoms
B) citric acid
C) 4 carbon molecule
D) NADH
E) FADH2

A) cholesterol.
B) bile salts.
C) phospholipids and proteins.
D) triglycerides.
E) glycerol.

A) it occurs in the mitochondria.
B) fatty acids break down into two-carbon fragments.
C) lipids are converted into glycogen molecules.
D) it requires coenzyme A, NAD, and FAD.
E) it yields large amounts of ATP.

A) lipogenesis.
B) glycolysis.
C) beta-oxidation.
D) glycogenolysis.
E) adipogenesis.

A) hydrogen atoms
B) citric acid
C) 4 carbon molecule
D) NADH
E) FADH2

A) glucose.
B) amino acids.
C) fatty acids.
D) acetyl-CoA.
E) succinyl-CoA.

A) pyruvate
B) acetyl-CoA
C) glycerol
D) glucose
E) lipoprotein

A) HDLs.
B) VLDLs.
C) LDLs.
D) chylomicrons.
E) coenzymes.

A) Very-low-density lipoproteins (VLDLs)
B) Low-density lipoproteins (LDLs)
C) Micelles
D) High-density lipoproteins (HDLs)
E) Chylomicrons

A) deliver somewhat less energy than an equivalent mass of glucose.
B) are difficult to store since they are not water soluble.
C) yield quick bursts of energy.
D) provide energy for cells with modest energy demands.
E) are the primary nutrient metabolized in cells.

A) chylomicrons.
B) very-low-density lipoproteins.
C) micelles.
D) low-density lipoproteins.
E) high-density lipoproteins.

A) transport proteins.
B) lipoproteins.
C) essential fatty acids.
D) essential amino acids.
E) vitamins.

A) total cholesterol level.
B) HDL level.
C) triglyceride level.
D) triglyceride and monoglyceride levels.
E) total cholesterol level, HDL level, and triglyceride level.

A) the liver forms glycogen.
B) adipocytes release fatty acids to the circulation.
C) skeletal muscle breaks down glycogen.
D) insulin levels are low.
E) skeletal muscle fibers release glucose.

A) transamination.
B) deamination.
C) decarboxylation.
D) amination.
E) beta-oxidation.

A) glucocorticoids
B) androgens
C) insulin
D) glucagon
E) gastrin

A) acetyl-CoA.
B) glycerol.
C) some amino acids.
D) lactate.
E) pyruvate.

A) a build up of urea
B) excess ammonia production
C) lipoprotein metabolism
D) excess ketone formation
E) increased glycolysis

A) increased levels of urea in the blood.
B) ketosis and a decreased blood pH.
C) increased gluconeogenesis in the liver.
D) lipid metabolism.
E) glycogenesis.

A) essential amino acids.
B) nonessential amino acids.
C) urea.
D) ammonia.
E) keto acids.

A) converted to ammonia.
B) converted to urea.
C) transferred to a keto acid.
D) absorbed by water.
E) transferred to acetyl-CoA.

A) more energy than lipid metabolism.
B) more energy than carbohydrate metabolism.
C) approximately the same energy as lipid metabolism.
D) approximately the same energy as carbohydrate metabolism.
E) more energy than lipid and carbohydrate metabolism combined.

A) gout.
B) rheumatoid arthritis.
C) anorexia nervosa.
D) lupus.
E) ketosis.

A) A.
B) C.
C) B12.
D) B6.
E) B9.

A) insulin.
B) growth hormone.
C) glucagon.
D) epinephrine.

A) carbohydrate utilization increases.
B) gluconeogenesis ceases.
C) there is a decline in circulating ketone bodies.
D) muscle proteins are used as an energy source.
E) carbohydrate reserves maintained by metabolizing inorganic compounds.

A) proteins are more difficult to break apart than lipids or carbohydrates.
B) the energy yield from protein is less than the yield from lipids.
C) one of the by-products of protein catabolism is ammonia.
D) most individuals have little protein to spare before harming vital organs.
E) extensive catabolism of protein threatens homeostasis.

A) 30 minutes.
B) 2 hours.
C) 4 hours.
D) 8 hours.
E) 12 hours.

A) postabsorptive
B) absorptive
C) starvation
D) deprivation
E) preabsorptive

A) amino acids.
B) oxaloacetate.
C) creatine.
D) porphyrin.
E) purines.

A) ketone bodies.
B) urea.
C) nitrate.
D) acetyl-CoA.
E) water.

A) glycogenolysis occurs in the liver.
B) levels of blood glucose are elevated above normal.
C) ketone bodies may be formed.
D) fat mobilization occurs.
E) gluconeogenesis occurs in the liver.

A) liver.
B) stomach.
C) kidneys.
D) small intestine.
E) large intestine.