Deck 11: Glycolysis

A)phosphoenolpyruvate.
B)NAD.
C)NADH.
D)ADP.

A)Glucose.
B)Pyruvate.
C)ATP.
D)Coenzyme A.

A)0;ATP is produced,not consumed,by glycolysis.
B)1
C)2
D)3
E)4

A)Fructose 1,6-bisphosphate → dihydroxyacetone phosphate and glyceraldehyde 3-phosphate.
B)Fructose 6-phosphate → fructose 1,6-bisphosphate.
C)Glucose 6- phosphate → fructose 6- phosphate.
D)Glucose → glucose 6- phosphate.

A)little or no glucose- 6-phospate remaining.
B)about equal amounts of glucose- 6-phosphate and fructose -6-phospate.
C)an accumulation of fructose 6-phosphate.
D)All of the above.

A)hexokinase I.
B)glucokinase.
C)hexokinase II.
D)All of the above
E)A and C only

A)0%
B)25%
C)50%
D)100%

A)describes the conversion of ADP into ATP with the addition of inorganic phosphate every place throughout the cell.
B)describes the formation of ADP by phosphoryl group transfer from 1,3 bisphosphoglycerate.
C)is the formation of ATP by phosphoryl group transfer from a higher energy compound.
D)Both A and C.

A)from one species that catalyze the same reaction.
B)from different species that catalyze the same reaction.
C)that have isomers as substrates.
D)that have products that are isomers.

A)1,3-bisphosphoglycerate → 3-phosphoglycerate.
B)phosphoenolpyruvate (PEP)→ pyruvate.
C)3-phosphoglycerate → 2-phosphoglycerate.
D)Both A and B.
E)None of the above.

A)Phosphorylating glucose for entry into the glycolytic pathway.
B)Saturating glucokinase with glucose.
C)Phosphorylating glucose for entry into the glycogen synthesis pathways.
D)A and B only.
E)A and C only.

A)Glucose 6-phosphate isomerase.
B)Aldolase.
C)Both A and B.
D)Neither A nor B.

A)the reduction and phosphorylation of glyceraldehyde 3-phosphate to produce 1,3-bisphosphoglycerate.
B)the oxidation of a molecule of NAD+ to NADH.
C)Neither A nor B.
D)Both A and B.

A)ATP production proceeds via a reaction that involves 1,3-bisphosphoglycerate.
B)glycolysis is interrupted.
C)a net production of 2 molecules of ATP occurs.
D)All of the above.
E)None of the above.

A)competes with NAD+ for the binding site in 1,3-bisphosphoglycerate.
B)competes with phosphate for its binding site in glyceraldehyde 3-phosphate dehydrogenase.
C)produces a stable analog of 1,3-bisphosphoglycerate.
D)All of the above.

A)triose phosphate isomerase is written left to right.
B)triosephosphate isomerase is complexed to phosphoglycerate kinase,the next step in the sequence of reactions.
C)there are too few molecules of dihydroxyacetone phosphate available.
D)there are allosteric stimulants of triose phosphate isomerase.

A)an overproduction of Fructose 6-phosphate.
B)an overproduction of Fructose 1,6-bisphosphate.
C)fructose 1,6-bisphosphate deficiency.
D)A and C only.
E)All of the above.

A)an essential component of glycolysis for ATP production.
B)converted to 3-phosphoglycerate with formation of ATP.
C)essential for the efficient release of O² from hemoglobin.
D)a product of the enzyme phosphofructokinase.

A)poisons by the same mechanism as arsenate.
B)is less toxic than arsenate.
C)binds tightly to lipoamide sulfur atoms.
D)None of the above.

A)Muscle phosphoglycerate mutases.
B)Plant phosphoglycerate mutases.
C)Yeast phosphoglycerate mutases.
D)A and C only.
E)All of the above.

A)Potassium.
B)Calcium.
C)Magnesium.
D)Manganese.

A)lactate reductase
B)pyruvate kinase
C)lactoenolpyruvate
D)lactate dehydrogenase

A)oxidation of NADH
B)production of ADP
C)consumption of O²
D)generation of an ion gradient across mitochondrial membranes

A)polymerases that catalyze phosphoryl group transfers.
B)isomerases that catalyze the transfer of phosphoryl groups from one part of a substrate molecule to another.
C)forming intermediate free phosphate (Pi).
D)All of the above.

A)Lactate dehydrogenase is inactive.
B)Transport of glucose into cells is accelerated.
C)Oxygen supply to tissues is inadequate.
D)PFK-1 is over-activated.

A)isozymes
B)complementary enzymes
C)cofactors
D)catalytes

A)anaerobic yeasts.
B)lactic acid bacteria.
C)kidney medulla cells.
D)A and B.
E)A,B and C.

A)a mutase reaction.
B)isomerization.
C)dehydrogenase.
D)substrate-level phosphorylation.

A)are more reduced
B)are more oxidized
C)are equally as oxidized
D)carry more charge

A)It is converted to carbon dioxide and acetaldehyde.
B)It is converted to ethanol.
C)It is converted to lactate.
D)Nothing,pyruvate enters the citric acid cycle directly.

A)Pyruvic acid.
B)Lactose dehydrogenase.
C)Lactate ion.
D)Lactic acid.

A)lysine
B)glycine
C)alanine
D)all of the above

A)Pyruvate kinase reaction.
B)PFK-1 reaction.
C)Hexokinase/Glucokinase reaction.
D)None of the above.

A)Pyruvate kinase.
B)Phosphoglycerate kinase.
C)Hexokinase.
D)PFK-1.

A)Conversion to lactate.
B)Further reduction by the citric acid cycle.
C)Conversion to ethanol.
D)All of the above.

A)the membrane associated electron transport chain.
B)only ethanol.
C)ethanol and other organic compounds.
D)oxygen.

A)Conversion to ethanol releases more NAD+ per mole than the conversion to lactate.
B)The carbon atoms are more oxidized in ethanol than in lactate.
C)Ethanol is neutral,but lactate production is accompanied by a sharp decrease in pH.
D)Ethanol production is not better.Yeast normally produces ethanol and lactate in equimolar amounts.

A)Leucine.
B)Lysine.
C)Alanine.
D)Histidine.

A)No,not enough NAD+ can be regenerated for glycolysis to continue at a high rate.
B)No,the defective gene will cause a rapid decline in pH in the muscles used for running.
C)Yes,the defective enzyme has no effect on the glycolytic pathway.
D)Yes,the enzyme alcohol dehydrogenase will supply the needed NAD+ if the lactose dehydrogenase cannot.

A)It is one of very few enzymes that can catalyze both the forward and reverse reactions.
B)The enzyme is a monomer when catalyzing the phosphorylation reaction and a dimer when catalyzing the reverse reaction.
C)The forward and reverse reactions occur in different compartments within the cell,so a different name is used for each activity.
D)The enzyme is bifunctional.The forward and reverse reactions are catalyzed by different sites on the same enzyme.

A)Each step in the pathway has an actual free energy change that is either negative or zero.
B)The overall actual free energy change is negative.
C)The net enthalpy is endothermic.
D)A and B above.
E)All of the above.

A)Inhibition of PFK-1 allows for the complete oxidation of pyruvate via the citric acid cycle.
B)Slowing glycolysis slows the rate of decrease in pH.A low pH can be harmful and potentially fatal.
C)The less active form of PFK-1 is a potent allosteric activator of creatine,so even though glycolysis is slowed,ATP production is actually increased by the activation of creatine.
D)As PFK-1 is inhibited,its isozyme,PFK-2 is activated.PFK-2 is functional at a much lower pH than PFK-1.

A)They are near equilibrium reactions.
B)They are not control points for pathway regulation.
C)They are reversible reactions.
D)All of the above.
E)None of the above.

A)At this high blood glucose level all four hexokinases are saturated with substrate.
B)Hexokinases I,II and III are catalyzing at their maximum rate,but glucokinase can still respond to increases in blood glucose levels.
C)None of the enzymes is saturated.All of them help to increase the rate of glycolysis.
D)The flux through glucokinase will be extremely low.The only significant catalysis is done by hexokinases I,II and III.

A)Phosphorylates PFK-2;dephosphorylated pyruvate kinase;both enzymes are inhibited.
B)Phosphorylates both enzymes;inhibits both enzymes.
C)Dephosphorylates both enzymes;inhibits both enzymes.
D)Dephosphorylates PFK-2;phosphorylates pyruvate kinase;activates PFK-2;inhibits pyruvate kinase.

A)Avoid all strenuous exercise.
B)Eat a fat-free diet.
C)Increase intake of vitamin C.
D)Avoid ingestion of milk and milk products.

A)Activator of pyruvate kinase.
B)Product of PFK-1 catalyzed step in glycolysis.
C)Isomer of glucose 1,6-bisphosphate.
D)All of the above.

A)To keep glucose inside the cell.
B)To form a high-energy compound.
C)To activate PFK-1.
D)To prevent mutarotation.

A)Some sugars can enter the glycolytic pathway beyond the first step.If steps other than step one were not regulated,the breakdown of these sugars would be essentially uncontrolled.
B)Having more than one regulated step in the pathway allows for feedback inhibition.
C)Control of a single step in a reaction pathway is difficult because the concentrations of enzymes in cells are very low.It's easier to control more than one enzyme.
D)All the ATP in a cell would be depleted very quickly if only the first step of glycolysis were regulated.

A)Fructose produces one less ATP than glucose.
B)Fructose and glucose produce the same number of ATPs.
C)Fructose produces one more ATP than glucose.
D)Fructose produces twice the number of ATP compared to glucose.

A)The value of △G0' is also -72 kJ/mol since the cytosol pH is close to 7.
B)The free energy of glycolysis is found as the sum of the standard free energy changes for the individual pathway reactions.
C)The negative sign of △G shows that this pathway will proceed toward product (pyruvate)under normal cellular conditions.
D)All of the above.

A)forming more GLUT 4 vesicles.
B)stimulating hexokinase.
C)stimulating GLUTs 1,3 and others of the GLUT family.
D)stimulating GLUT 4 vesicles to fuse with the plasma membrane.

A)glucose-1-phosphate
B)glucose-1,6-bisphosphate
C)fructose-6-phosphate
D)glucose-6-phosphate

A)The step catalyzed by phosphoglycerate kinase is one of the ATP producing steps of glycolysis.Using only the two-step reaction sequence would reduce the number of ATP's produced.
B)There is no disadvantage to the two-step sequence other than having to use more than one enzyme.
C)The molecule 2,3-BPG is also a potent inhibitor of PFK-1.Even transient production of 2,3-BPG will significantly slow glycolysis.
D)Too much 2,3-BPG would be produced which would cause clumping of red blood cells.

A)The standard free energy for these steps is not the same as the actual free energy change in cells.The actual free energy change must be negative or zero.
B)The reaction steps with positive standard free energy changes are likely to be regulatory steps for the pathway.
C)The steps with a positive standard free energy change are the fastest steps in the pathway.
D)The steps with a positive standard free energy change must be coupled to an ATP →ADP conversion.

A)PFK-1.
B)Pyruvate kinase.
C)Triose phosphate isomerase.
D)Hexokinase.

A)Adrenaline.
B)Insulin.
C)Protein kinase A.
D)PFK-2.

A)PFK-1 must be phosphorylated by ATP in the active site and the phosphorylated PFK-1 must be the less active form.
B)There must be another cofactor interacting with ATP at high concentrations to achieve inhibition of PFK-1.
C)ATP actually activates the reverse of the reaction preceding the PFK-1 step in the pathway.It likely has no direct effect on PFK-1.
D)There are two sites on PFK-1 that bind ATP.One is the active site;the other is the regulatory site where inhibition occurs.

A)Bohr
B)Michaelis-Menton
C)Pasteur
D)Pauling

A)Consumption of ATP.
B)The enzyme gluconolactonase.
C)An unusual dehydrase reaction from 6-phosphogluconate to KDPG.
D)The production of pyruvate.
E)The production of NADPH.

A)inability to properly digest milk due to its galactose content
B)jaundice
C)damage to the nervous system
D)liver damage
E)All of the above

A)Embden-Meyeroff-Parnas.
B)Entner-Doudoroff.
C)Pentose phosphate.
D)Gycolytic.

A)It cleaves lactose into galactose and glucose.
B)It converts glucose into fructose.
C)It interconverts glucose between its R and S enantiomers.
D)It cleaves sucrose into glucose and fructose.

A)It is converted mannose 6-phosphate and then isomerized to fructose 6-phosphate which enters the pathway.
B)It can enter directly into the first step of glycolysis because hexokinase converts mannose to glucose 6-phosphate.
C)Mannose is first split into two trioses that are directly converted to glyceraldehyde 3-phosphate.
D)Mannose is not metabolized via glycolysis.It enters a separate pathway.

A)It produces less ATP per glucose molecule than glycolysis.
B)Organisms that have this pathway use it only under conditions of low glyceraldehyde 3-phosphate isomerase concentrations.
C)It is useful for bacteria that do not have PFK-1.
D)The pathway produces pyruvate and glyceraldehyde 3-phosphate.
E)It enables some bacteria to survive on gluconate and other organic acids that cannot be metabolized via glycolysis.