Deck 12: Gluconeogenesis, the Pentose Phosphate Pathway, and Glycogen Metabolism

A) acetyl CoA
B) lactate
C) citric acid
D) succincyl CoA

A) pyruvate kinase catalyzed step
B) 4 irreversible reactions in glycolysis
C) 3 irreversible reactions in glycolysis
D) 2 irreversible reactions in glycolysis

A) glucose-1-phosphate
B) sorbitol
C) ribose
D) aldose reductase

A) alanine
B) glycerol
C) oxaloacetate
D) acetate
E) ethanol

A) stored glycogen.
B) starch.
C) dextrin.
D) A and B
E) A, B and C

A) result of amylase activity
B) formation of glycogen
C) formation of starches
D) formation of glucose from simple two and three-carbon precursors
E) formation of glucose from other carbohydrates

A) lactate and pyruvate
B) dihydroxyacetone phosphate and glyceraldehyde-3-phosphate
C) fructose 1,6-bisphosphate and fructose 6-phosphate
D) phosphoenolpyruvate and 2-phosphoglycerate

A) the Cori cycle.
B) catabolism.
C) transamination.
D) dehydrogenation.

A) dihydroxyacetone phosphate
B) phosphoenolpyruvate
C) oxaloacetate
D) 3-phosphoglycerate

A) liver
B) pancreas
C) cytosol of all cells
D) small intestine

A) 2-phosphoglycerate.
B) oxaloacetate.
C) phosphoenolpyruvate.
D) fructose 1,6-bisphosphate.

A) glucagons
B) starch
C) glycogen
D) NADPH

A) glucagon concentration.
B) insulin concentration.
C) the level of PEPCK gene transcription.
D) the elevation of cAMP concentration on fasting.

A) glyoxylate cycle
B) Krebʹs cycle
C) Cori cycle
D) gluconeogenesis cycle

A) stimulates; stimulates
B) stimulates; inhibits
C) inhibits; stimulates
D) inhibits; inhibits

A) The reactions where enzymes differ occur in different parts of the cell for glycolysis versus gluconeogenesis.
B) Enzymes can catalyze a reaction only in one direction, so naturally the two pathways have some enzymes that differ.
C) In tissues where gluconeogenesis occurs, the glycolytic enzymes are present at extremely low concentrations.
D) Three of the reaction steps in gluconeogenesis would have prohibitively large, positive free energies if they used glycolytic enzymes for their catalysis.

A) is a good point for regulation of the pathway
B) includes only diffusion-controlled reactions
C) allows for substrates to be passed to alternative pathways
D) is a point that starts a cascade effect

A) liver; muscle
B) liver; liver
C) muscle; muscle
D) muscle; liver

A) citrate
B) pyruvate
C) oxaloacetate
D) All of the above
E) B or C

A) It polymerizes free glucose to glycogen in the liver.
B) It requires UTP-glucose for chain lengthening.
C) It can both lengthen glycogen chains as well as form new branches.
D) It requires a primer of four to eight linked glucose residues.

A) pyruvate carboxylase
B) transaldolase
C) debranching enzyme
D) ribose-5-phosphate isomerase

A) muscle.
B) liver.
C) muscle and liver.
D) saliva.
E) brain cells.

A) thiamine pyrophosphate
B) biotin
C) pyridoxal phosphate
D) NAD⁺

A) high; high
B) high; low
C) low; low
D) low; high

A) Limit dextrin contains additional molecules.
B) The debranching enzyme releases free glucose.
C) The glucose is already phosphorylated after glycogen phosphorylase action.
D) The glucose from glycogen degradation bypasses glycolysis.
E) All of the above

A) varying degrees of hemolytic anemia.
B) increased resistance to malaria.
C) lack of NADPH in many cells.
D) All of the above
E) A and B

A) Accumulation of sorbitol and protein precipitation in the lens.
B) Precipitation of glucose not oxidized by glycolysis in the lens.
C) The absence of membrane transport proteins for pyruvate in the lens cells.
D) Lack of regulation of gluconeogenesis in the lens and the accumulation of fructose.

A) glycogen synthase.
B) glycogenin.
C) branching enzyme.
D) phosphoglucomutase.
E) UDP-glucose pyrophosphorylase.

A) produces NADPH and releases CO₂
B) consists entirely of near-equilibrium reactions
C) contains two reactions whose enzymes are allosterically inhibited by NADPH
D) consumes four ATP molecules

A) glycolysis
B) the citric acid cycle
C) the Cori cycle
D) glycogenolysis

A) reduction followed by oxidation
B) two sequential hydrolysis reactions
C) hydrolysis followed by isomerization rearrangement)
D) phosphorylation followed by dephosphorylation

A) transaldolase
B) phosphofructokinase-1
C) glucose 6-phosphate dehydrogenase
D) ribose 5-phosphate isomerase

A) ATP and NADPH
B) oxaloacetate and acetyl CoA
C) sorbitol and fructose
D) ribose-5-phosphate and NADPH

A) Glucose 6-phosphate is more stable.
B) Glucose 6-phosphate is converted to free glucose.
C) Glucose 6-phosphate is an intermediate in several pathways, including glycolysis.
D) Glucose 6-phosphate can be transported to the liver.
E) All of the above

A) glucose 6-phosphate
B) NADP⁺
C) carbon dioxide
D) phosphate
E) UDP

A) its large negative free energy change
B) the formation of an energy-rich product
C) the subsequent hydrolysis of pyrophosphate
D) the change in concentration of UTP

A) phosphorylation.
B) ATP.
C) glucose 6-phosphate.
D) protein subunit separation.
E) All of the above

A) ATP
B) ADP
C) UTP
D) UDP
E) All of the above

A) To maintain the reduced form of iron in hemoglobin.
B) To provide reducing power for the synthesis of fatty acids.
C) To serve as precursors in the biosynthesis of RNA and DNA.
D) To raise the concentration of cAMP.

A) activates; activates
B) activates; inactivates
C) inactivates; inactivates
D) inactivates; activates

A) elevates the degradation rate of glycogen
B) activates protein kineses A
C) lowers the rate of glycogen synthesis
D) reduces the effects of insulin
E) All of the above

A) It forms a protein scaffold for glycogen.
B) It is a hormone that contains 29 amino acids.
C) Elevated levels are associated with a fasting state.
D) It is produced in the pancreas.

A) Aids in the release of glucose from stored glycogen in the liver.
B) Uses alanine to restore blood glucose levels.
C) Produces products that slow the oxidation of pyruvate.
D) Helps transport glucose across the blood-brain barrier to maintain brain glucose levels.

A) Calmodulin.
B) Ca²⁺.
C) cAMP.
D) Inhibitor-1.

A) the enzymes are different.
B) there is no effect of glucagon.
C) there is no effect of insulin.
D) inhibitor-1 controls protein phosphatase-1.
E) there is no role for cyclic AMP.

A) glucagon.
B) insulin.
C) epinephrine.
D) cyclic AMP.
E) adrenergic receptors.

A) phosphorylase kinase, glycogen phosphorylase b, protein kinase A, glucagon
B) glucagon, phosphorylase kinase, glycogen phosphorylase b, protein kinase A
C) glucagon, Protein kinase A, phosphorylase kinase~P, glycogen phosphorylase a~P
D) glucagon, protein kinase A, glycogen phosphorylase a~P, phosphorylase kinase~P

A) 5 μM
B) 5 mM
C) 50 mM
D) 5 M

A) 10 minutes
B) 4 hours
C) 24 hours
D) 1 week

A) more; activated
B) less; activated
C) more; inhibited
D) less; inhibited