Deck 8: Energy, Enzymes, and Metabolism

A) Raising the temperature may reduce the activity of an enzyme.
B) Raising the temperature may increase the activity of an enzyme.
C) Raising the temperature may denature an enzyme.
D) Some enzymes are stable at the boiling point of water.
E) All enzymes have the same optimal temperature.

A) the rate depends on the value of G.
B) the rate depends on the activation energy.
C) the entropy change depends on the activation energy.
D) the activation energy depends on the value of G.
E) the change in free energy depends on the activation energy.

A) Entropy
B) Energy
C) Free energy only
D) Thermal energy only
E) Potential energy only

A) Chemical bonds
B) Concentration gradient
C) Electric charge imbalance
D) Both a and b
E) All of the above

A) A competitive inhibitor binds the active site of the enzyme.
B) An allosteric inhibitor binds a site on the active form of the enzyme.
C) A noncompetitive inhibitor binds a site other than the active site.
D) Noncompetitive inhibition cannot be completely overcome by the addition of more substrate.
E) Competitive inhibition can be completely overcome by the addition of more substrate.

A) a component of most proteins.
B) high in energy because of the presence of adenine.
C) required for many energy-transforming biochemical reactions.
D) a catalyst.
E) used in some exergonic reactions to provide energy.

A) inability to hydrolyze polysaccharides.
B) body's ability to digest lactose but inability to absorb the resulting products.
C) gaseous side products produced in the small intestine.
D) inability to produce the enzyme lactase.
E) inability to oxidate luciferase.

A) As energy transformations occur, free energy increases and unusable energy decreases.
B) To maintain order, life requires a constant input of energy.
C) The potential energy of ATP is converted to kinetic energy such as muscle contractions.
D) Reactions occur only with an input of energy.
E) It does not apply to organisms; the complexity of organisms contradicts the second law.

A) never changes shape.
B) forms no chemical bonds with substrates.
C) determines, by its structure, the specificity of the enzyme.
D) looks like a lump projecting from the surface of the enzyme.
E) changes the $\Delta$ G of the reaction.

A) They usually consist of proteins.
B) They change the rate of the catalyzed reaction.
C) They change the G of the reaction.
D) They are sensitive to heat.
E) They are sensitive to pH.

A) energetics.
B) activity.
C) digestive power.
D) entropy.
E) metabolism.

A) Hydroelectric
B) Irrigation
C) Potential
D) Kinetic
E) At times, all of the above

A) a substrate does not change.
B) the rate decreases as substrate concentration increases.
C) the enzyme can be permanently changed.
D) strain may be added to a substrate.
E) the rate is not affected by substrate concentration.

A) decreasing.
B) increasing.
C) constant.
D) being converted to free energy.
E) being converted to matter.

A) increasing entropy.
B) chemical equilibrium.
C) the first law of thermodynamics.
D) the second law of thermodynamics.
E) a spontaneous reaction.

A) temperature.
B) entropy.
C) pressure.
D) Both a and b
E) All of the above

A) Free energy is used up in an exergonic reaction.
B) Free energy cannot be used to do work.
C) The total amount of energy can change after a chemical transformation.
D) Free energy can be kinetic but not potential energy.
E) Entropy has a tendency to increase.

A) free energy.
B) entropy.
C) enthalpy.
D) thermodynamics.
E) equilibrium.

A) It is usually exerted through allosteric effects.
B) It is directed at the enzyme that catalyzes the commitment step in a metabolic pathway.
C) It affects the rate of reaction, not the concentration of enzyme.
D) It acts by permanently modifying the active site.
E) It is an example of reversible inhibition.

A) release a considerable amount of energy as heat.
B) light up to signal danger.
C) use ATP to begin luciferin oxidation.
D) are constantly converting light energy into chemical energy.
E) have a short life cycle due to rapid depletion of ATP.

A) lower than either the reactants or the products.
B) higher than either the reactants or the products.
C) lower than the reactants, but higher than the products.
D) higher than the reactants, but lower than the products.
E) lower than the reactants, but the same as the products.

A) The reaction never reaches equilibrium.
B) The reaction is spontaneous.
C) There is a large decrease in free energy.
D) The reaction is endergonic.
E) Temperature will not affect the rate constant of the reaction.

A) The reaction requires the input of free energy.
B) The free energy of glucose is larger than the free energy of maltose.
C) The reaction is not spontaneous.
D) The reaction releases free energy.
E) At equilibrium, the concentration of maltose is higher than the concentration of glucose.

A) requires energy.
B) is endergonic.
C) is exergonic.
D) will not reach equilibrium.
E) decreases the disorder in the system.

A) free energy is released by the loss of a phosphate.
B) energy is consumed.
C) the reaction ends.
D) chemical energy is converted to light energy.
E) ribose loses an oxygen to become deoxyribose.

A) often the reaction occurs.
B) quickly the reaction reaches equilibrium.
C) much energy must be added for the reaction to occur.
D) much activation energy is required for the reaction to occur.
E) easily the reaction is inhibited.

A) An enzyme changes shape when it binds to a substrate.
B) Enzymes lower the activation energy.
C) Enzymes are highly specific.
D) An enzyme may orient substrates, induce strain, or temporarily add chemical groups.
E) Most enzymes are much smaller than their substrates.

A) RNAse.
B) ribonuclease.
C) an allosteric enzyme.
D) a regulatory enzyme.
E) a ribozyme.

A) reaction will never reach equilibrium.
B) free energy of ADP and phosphate is higher than the free energy of ATP.
C) reaction requires energy.
D) reaction is endergonic.
E) reaction is exergonic.

A) the equilibrium point of the reaction.
B) the rate of the reaction.
C) how fast equilibrium will be reached.
D) the optimum temperature for the reaction.
E) the activation energy.

A) is a dynamic state.
B) represents a state of negative energy change.
C) represents a state of positive energy change.
D) cannot exist in nature.
E) is a state in which $\Delta$ G = 0.

A) The hydrolysis of ATP is exergonic.
B) ATP consists of adenine bonded to deoxyribose.
C) ATP releases a relatively small amount of energy when hydrolyzed.
D) An active cell requires about 100 molecules of ATP per second.
E) On average, ATP is consumed within one second of its formation.

A) The beating cilia of a protozoan
B) Cellular respiration
C) Phagocytosis
D) Receptor-mediated endocytosis
E) The Na⁺- K⁺ pump

A) 2
B) 3
C) 5
D) 10
E) 20

A) receive phosphate groups.
B) donate phosphate groups.
C) convert molecules to nucleic acids.
D) store a large amount of energy when hydrolyzed.
E) All of the above

A) substrates.
B) endergonic.
C) kinetic.
D) activated.
E) coupled.

A) slightly negative $\Delta$ G.
B) change in free energy.
C) negative $\Delta$ G.
D) $\Delta$ G near zero.
E) large positive $\Delta$ G.

A) The place where a substrate molecule binds to an enzyme
B) A reactant with high potential energy
C) The combination of a substrate and an enzyme
D) The state at which the bonds of reactants are unstable
E) The active site where reactants are oriented

A) they enhance the taste.
B) they act as preservatives.
C) they detect bacterial contamination by "lighting up."
D) luciferase speeds up the release of monosaccharides.
E) they hydrolyze disaccharides.

A) increasing the amount of free energy of the reaction.
B) lowering the activation energy of the reaction.
C) decreasing the equilibrium constant of the reaction.
D) supplying energy to speed up the reaction.
E) changing the shape of the active site.

A) the part of the substrate that binds with an enzyme.
B) the part of the enzyme that binds with a substrate.
C) the site where energy is added to an enzyme catalyst.
D) the site where enzymes are found in cells.
E) None of the above

A) enzymes are found in certain cells.
B) reactions involving certain substrates are catalyzed by specific enzymes.
C) enzymes require certain concentrations of substrates.
D) reactions with certain activation energies are catalyzed by certain enzymes.
E) concentrations of substrates work with certain enzymes.

A) All the alcohol dehydrogenase molecules are bound to acetaldehyde molecules.
B) At high concentrations of acetaldehyde, the activation energy of the reaction increases.
C) At high concentrations of acetaldehyde, the activation energy of the reaction decreases.
D) The enzyme is no longer specific for acetaldehyde.
E) At high concentrations of acetaldehyde, the change in free energy of the reaction decreases.

A) induced fit.
B) enzyme flex.
C) the lock-and-key paradox.
D) substrate-induced active site shaping.
E) enzyme retrofit.

A) transition state.
B) activation groove.
C) catalyst.
D) enzyme-substrate complex.
E) energy barrier.

A) a metal ion bound to a side chain.
B) a prosthetic group.
C) a coenzyme.
D) acidic or basic amino acid side chains (R groups) in the active site.
E) a covalently activated active site.

A) hydrogen bonds.
B) covalent bonds.
C) ionic attractions.
D) hydrophobic interactions.
E) All of the above

A) free energy of the transition state.
B) activation energy of the reaction.
C) change in free energy of the reaction.
D) three-dimensional shape and structure of the active site.
E) rate constant of the reaction.

A) The change in free energy of the reaction is positive.
B) The activation energy of the reaction is high.
C) The change in free energy of the reaction is negative.
D) This is a condensation reaction.
E) The free energy of the products is higher than the free energy of the reactants.

A) amount of activation energy required.
B) overall energy change, or $\Delta$ G.
C) energy of the reactants.
D) energy of the products.
E) free energy of the transition state.

A) reversible.
B) irreversible.
C) noncompetitive.
D) coupled.
E) allosteric.

A) $\Delta$ S
B) $\Delta$ G
C) $\Delta$ H
D) The activation energy
E) The overall change in free energy

A) Trypsin is a protein, and elastase is not.
B) $\Delta$ G for the two reactions is different.
C) The shape of the active site for the two enzymes is different.
D) One of the reactions is endergonic, and the other is exergonic.
E) Hydrolysis of lysine bonds requires water; hydrolysis of alanine bonds does not.

A) decreasing the equilibrium constant
B) increasing the change in free energy
C) decreasing the change in free energy
D) increasing the change in entropy
E) lowering the activation energy

A) Manganese dioxide
B) Hemoglobin
C) Catalase
D) Hydrogen peroxide
E) Malathion

A) Enzymes are proteins.
B) Enzymes have a specific amino acid sequence.
C) Enzymes are highly specific.
D) Enzymes lower the energy barrier.
E) All of the above

A) orienting
B) inducing strain in
C) adding chemical groups to
D) adding charges to
E) All of the above

A) products.
B) substrates.
C) carriers.
D) prosthetics.
E) effectors.

A) acid-base catalysis.
B) covalent catalysis.
C) metal cofactor redox catalysis.
D) induced strain.
E) unknown.

A) adding more mevalonate.
B) adding more HMG-CoA.
C) lowering the temperature of the reaction.
D) adding a prosthetic group.
E) lowering the rate constant of the reaction.

A) inhibitor.
B) substrate.
C) product.
D) enzyme.
E) free energy.

A) ribozymes.
B) abzymes.
C) isozymes.
D) enzymes that can no longer function.
E) coenzymes.

A) decreasing the number of enzyme molecules.
B) increasing the number of enzyme molecules.
C) decreasing the amount of the inactive form of the enzyme.
D) decreasing the amount of the active form of the enzyme.
E) increasing the amount of substrate.

A) decreases the concentration of an inactive enzyme.
B) changes the shape of an enzyme.
C) increases the concentration of a product.
D) changes the shape of a substrate.
E) increases the concentration of an enzyme-substrate complex.

A) a side chain.
B) coenzymes.
C) a coupled reaction.
D) a prosthetic group.
E) cofactors.

A) enzymes have the maximum possible number of hydrogen atoms attached to them.
B) the concentration of substrate reaches a point at which it cannot increase any further.
C) substrates are inhibitors of enzymes.
D) the activation energy of the reaction reaches a point at which it cannot be lowered further.
E) there are a limited number of the enzyme molecules present.

A) late; inhibits an earlier
B) early; inhibits a later
C) early; activates a later
D) late; activates an earlier
E) late; inhibits a later

A) Irreversible
B) Noncompetitive
C) Competitive
D) Prosthetic
E) Isotonic

A) Competitive inhibitors bind to the active site, whereas noncompetitive inhibitors change the shape of the active site.
B) Competitive inhibitors have a higher energy of activation than noncompetitive inhibitors have.
C) They function at different pH values.
D) Noncompetitive enzyme inhibitors contain magnesium, whereas competitive inhibitors contain iron.
E) Noncompetitive enzyme inhibitors are reversible, whereas competitive inhibitors are irreversible.

A) by decreasing the concentration of allosteric enzymes.
B) by decreasing the concentration of substrate.
C) by increasing the concentration of competitive inhibitor.
D) by increasing the concentration of substrate.
E) only when they become unbound.

A) changes in the environment raise their activation energy.
B) changes in temperature and pH readily break their hydrogen bonds.
C) of their three-dimensional structure and side chains.
D) at extreme temperatures and pH levels, coenzymes add chemical groups to the substrate.
E) extremes of temperature and pH level change the ionization rate.

A) binding to the substrate.
B) binding to the active site.
C) lowering the activation energy.
D) increasing the $\Delta$ G of the reaction.
E) changing the shape of the active site.

A) fitting into the active site.
B) fitting into a site other than the active site.
C) altering the shape of the enzyme.
D) changing the enzyme into an inactive form.
E) increasing the activation energy of the enzyme-catalyzed reaction.

A) The plot for allosteric regulators often has a sigmoid curve.
B) All enzymes are allosterically regulated.
C) Enzymes that are allosterically regulated are made of multiple polypeptide subunits.
D) Both the active site and the regulatory site are present on the same subunit.
E) Allosteric regulators bind to the active site, blocking enzyme function.

A) feedback activation.
B) feedback inhibition.
C) positive feedback.
D) concerted activation.
E) competitive inhibition.

A) temperature.
B) pH.
C) irreversible inhibitors such as DIPF.
D) allosteric effectors.
E) All of the above

A) block specific chemical transformations by inactivating specific enzymes.
B) have reversible effects on animals.
C) are proteins with a primary structure.
D) block the energy coupling cycle of ATP.
E) bond covalently to the active site of the enzyme.

A) allosteric inhibition.
B) denaturation.
C) branch pathway inhibition.
D) feedback inhibition.
E) binary inhibition.

A) temperature.
B) pH.
C) CO₂ concentration.
D) Both a and b
E) All of the above