Chapter 8
Which term most precisely describes the cellular process of breaking
down large molecules into smaller ones?
A) catalysis
B)
metabolism
C) anabolism
D) dehydration
E) catabolism
Answer: E
Which of the following is (are) true for anabolic pathways?
A)
They do not depend on enzymes.
B) They are usually highly
spontaneous chemical reactions.
C) They consume energy to build
up polymers from monomers.
D) They release energy as they
degrade polymers to monomers.
E) They consume energy to decrease
the entropy of the organism and its environment.
Answer: C
Which of the following is a statement of the first law of
thermodynamics?
A) Energy cannot be created or destroyed.
B) The entropy of the universe is decreasing.
C) The
entropy of the universe is constant.
D) Kinetic energy is stored
energy that results from the specific arrangement of matter.
E)
Energy cannot be transferred or transformed.
Answer: A
For living organisms, which of the following is an important
consequence of the first law of thermodynamics?
A) The energy
content of an organism is constant.
B) The organism ultimately
must obtain all of the necessary energy for life from its environment.
C) The entropy of an organism decreases with time as the
organism grows in complexity.
D) Organisms grow by converting
energy into organic matter.
E) Life does not obey the first law
of thermodynamics.
Answer: B
Living organisms increase in complexity as they grow, resulting in a
decrease in the entropy of an organism. How does this relate to the
second law of thermodynamics?
A) Living organisms do not obey
the second law of thermodynamics, which states that entropy must
increase with time.
B) Life obeys the second law of
thermodynamics because the decrease in entropy as the organism grows
is exactly balanced by an increase in the entropy of the universe.
C) Living organisms do not follow the laws of thermodynamics.
D) As a consequence of growing, organisms cause a greater
increase in entropy in their environment than the decrease in entropy
associated with their growth.
E) Living organisms are able to
transform energy into entropy.
Answer: D
Whenever energy is transformed, there is always an increase in the
A) free energy of the system.
B) free energy of the
universe.
C) entropy of the system.
D) entropy of the
universe.
E) enthalpy of the universe.
Answer: D
Which of the following statements is a logical consequence of the
second law of thermodynamics?
A) If the entropy of a system
increases, there must be a corresponding decrease in the entropy of
the universe.
B) If there is an increase in the energy of a
system, there must be a corresponding decrease in the energy of the
rest of the universe.
C) Every energy transfer requires
activation energy from the environment.
D) Every chemical
reaction must increase the total entropy of the universe.
E)
Energy can be transferred or transformed, but it cannot be created or destroyed.
Answer: D
Which of the following statements is representative of the second law
of thermodynamics?
A) Conversion of energy from one form to
another is always accompanied by some gain of free energy.
B)
Heat represents a form of energy that can be used by most organisms to
do work.
C) Without an input of energy, organisms would tend
toward decreasing entropy.
D) Cells require a constant input of
energy to maintain their high level of organization.
E) Every
energy transformation by a cell decreases the entropy of the universe.
Answer: D
Which of the following types of reactions would decrease the entropy
within a cell?
A) anabolic reactions
B) hydrolysis
C) respiration
D) digestion
E) catabolic reactions
Answer: A
Biological evolution of life on Earth, from simple prokaryote-like
cells to large, multicellar eukaryotic organisms,
A) has
occurred in accordance with the laws of thermodynamics.
B) has
caused an increase in the entropy of the planet.
C) has been
made possible by expending Earth's energy resources.
D) has
occurred in accordance with the laws of thermodynamics, by expending
Earth's energy resources and causing an increase in the entropy of the
planet.
E) violates the laws of thermodynamics because Earth is
a closed system.
Answer: A
Which of the following is an example of potential rather than kinetic
energy?
A) the muscle contractions of a person mowing grass
B) water rushing over Niagara Falls
C) light flashes
emitted by a firefly
D) a molecule of glucose
E) the
flight of an insect foraging for food
Answer: D
Which of the following is the smallest closed system?
A) a cell
B) an organism
C) an ecosystem
D) Earth
E) the universe
Answer: E
Which of the following is true of metabolism in its entirety in all
organisms?
A) Metabolism depends on a constant supply of energy
from food.
B) Metabolism depends on an organism's adequate
hydration.
C) Metabolism uses all of an organism's resources.
D) Metabolism consists of all the energy transformation
reactions in an organism.
E) Metabolism manages the increase of
entropy in an organism.
Answer: D
The mathematical expression for the change in free energy of a system
is ΔG =ΔH - TΔS. Which of the following is (are) correct?
A) ΔS
is the change in enthalpy, a measure of randomness.
B) ΔH is the
change in entropy, the energy available to do work.
C) ΔG is the
change in free energy.
D) T is the temperature in degrees Celsius.
Answer: C
A system at chemical equilibrium
A) consumes energy at a steady
rate.
B) releases energy at a steady rate.
C) consumes or
releases energy, depending on whether it is exergonic or endergonic.
D) has zero kinetic energy.
E) can do no work.
Answer: E
Which of the following is true for all exergonic reactions?
A)
The products have more total energy than the reactants.
B) The
reaction proceeds with a net release of free energy.
C) The
reaction goes only in a forward direction: all reactants will be
converted to products, but no products will be converted to reactants.
D) A net input of energy from the surroundings is required for
the reactions to proceed.
E) The reactions are rapid.
Answer: B
Chemical equilibrium is relatively rare in living cells. Which of the
following could be an example of a reaction at chemical equilibrium in
a cell?
A) a reaction in which the free energy at equilibrium is
higher than the energy content at any point away from equilibrium
B) a chemical reaction in which the entropy change in the
reaction is just balanced by an opposite entropy change in the cell's
surroundings
C) an endergonic reaction in an active metabolic
pathway where the energy for that reaction is supplied only by heat
from the environment
D) a chemical reaction in which both the
reactants and products are not being produced or used in any active
metabolic pathway
E) no possibility of having chemical
equilibrium in any living cell
Answer: D
Which of the following shows the correct changes in thermodynamic
properties for a chemical reaction in which amino acids are linked to
form a protein?
A) +ΔH, +ΔS, +ΔG
B) +ΔH, -ΔS, -ΔG
C)
+ΔH, -ΔS, +ΔG
D) -ΔH, -ΔS, +ΔG
E) -ΔH, +ΔS, +ΔG
Answer: C
When glucose monomers are joined together by glycosidic linkages to
form a cellulose polymer, the changes in free energy, total energy,
and entropy are as follows:
A) +ΔG, +ΔH, +ΔS.
B) +ΔG, +ΔH,
-ΔS.
C) +ΔG, -ΔH, -ΔS.
D) -ΔG, +ΔH, +ΔS.
E) -ΔG,
-ΔH, -ΔS
Answer: B
A chemical reaction that has a positive ΔG is correctly described
as
A) endergonic.
B) endothermic.
C) enthalpic.
D) spontaneous.
E) exothermic.
Answer: A
Which of the following best describes enthalpy (H)?
A) the
total kinetic energy of a system
B) the heat content of a
chemical system
C) the system's entropy
D) the cell's
energy equilibrium
E) the condition of a cell that is not able
to react
Answer: B
For the hydrolysis of ATP to ADP + Pi, the free energy change is -7.3
kcal/mol under standard conditions (1 M concentration of both
reactants and products). In the cellular environment, however, the
free energy change is about -13 kcal/mol. What can we conclude about
the free energy change for the formation of ATP from ADP and Pi under
cellular conditions?
A) It is +7.3 kcal/mol.
B) It is less
than +7.3 kcal/mol.
C) It is about +13 kcal/mol.
D) It is
greater than +13 kcal/mol.
E) The information given is
insufficient to deduce the free energy change.
Answer: C
Why is ATP an important molecule in metabolism?
A) Its
hydrolysis provides an input of free energy for exergonic reactions.
B) It provides energy coupling between exergonic and endergonic
reactions.
C) Its terminal phosphate group contains a strong
covalent bond that, when hydrolyzed, releases free energy.
D)
Its terminal phosphate bond has higher energy than the other two.
E) It is one of the four building blocks for DNA synthesis.
Answer: B
When 10,000 molecules of ATP are hydrolyzed to ADP and Pi in a test
tube, about twice as much heat is liberated as when a cell hydrolyzes
the same amount of ATP. Which of the following is the best explanation
for this observation?
A) Cells are open systems, but a test tube
is a closed system.
B) Cells are less efficient at heat
production than nonliving systems.
C) The hydrolysis of ATP in a
cell produces different chemical products than does the reaction in a
test tube.
D) The reaction in cells must be catalyzed by
enzymes, but the reaction in a test tube does not need enzymes.
E) Reactant and product concentrations in the test tube are
different from those in the cell.
Answer: E
Which of the following is most similar in structure to ATP?
A)
a pentose sugar
B) a DNA nucleotide
C) an RNA nucleotide
D) an amino acid with three phosphate groups attached
E) a phospholipid
Answer: C
Which of the following statements is true concerning catabolic
pathways?
A) They combine molecules into more energy-rich
molecules.
B) They supply energy, primarily in the form of ATP,
for the cell's work.
C) They are endergonic.
D) They are
spontaneous and do not need enzyme catalysis.
E) They build up
complex molecules such as protein from simpler compounds.
Answer: B
When chemical, transport, or mechanical work is done by an organism,
what happens to the heat generated?
A) It is used to power yet
more cellular work.
B) It is used to store energy as more ATP.
C) It is used to generate ADP from nucleotide precursors.
D) It is lost to the environment.
E) It is transported to
specific organs such as the brain.
Answer: D
When ATP releases some energy, it also releases inorganic phosphate.
What purpose does this serve (if any) in the cell?
A) The
phosphate is released as an excretory waste.
B) The phosphate
can only be used to regenerate more ATP.
C) The phosphate can be
added to water and excreted as a liquid.
D) The phosphate may be
incorporated into any molecule that contains phosphate.
E) It
enters the nucleus to affect gene expression.
Answer: D
A number of systems for pumping ions across membranes are powered by
ATP. Such ATP-powered pumps are often called ATPases although they
don't often hydrolyze ATP unless they are simultaneously transporting
ions. Because small increases in calcium ions in the cytosol can
trigger a number of different intracellular reactions, cells keep the
cytosolic calcium concentration quite low under normal conditions,
using ATP-powered calcium pumps. For example, muscle cells transport
calcium from the cytosol into the membranous system called the
sarcoplasmic reticulum (SR). If a resting muscle cell's cytosol has a
free calcium ion concentration of 10⁻⁷ while the concentration in the
SR is 10⁻², then how is the ATPase acting?
A) ATPase activity
must be powering an inflow of calcium from the outside of the cell
into the SR.
B) ATPase activity must be transferring Pi to the
SR to enable this to occur.
C) ATPase activity must be pumping
calcium from the cytosol to the SR against the concentration gradient.
D) ATPase activity must be opening a channel for the calcium
ions to diffuse back into the SR along the concentration gradient.
E) ATPase activity must be routing calcium ions from the SR to
the cytosol, and then to the cell's environment.
Answer: C
What is the difference (if any) between the structure of ATP and the
structure of the precursor of the A nucleotide in RNA?
A) The
sugar molecule is different.
B) The nitrogen-containing base is
different.
C) The number of phosphates is three instead of one.
D) The number of phosphates is three instead of two.
E)
There is no difference.
Answer: E
Which of the following statements is true about enzyme-catalyzed
reactions?
A) The reaction is faster than the same reaction in
the absence of the enzyme.
B) The free energy change of the
reaction is opposite from the reaction that occurs in the absence of
the enzyme.
C) The reaction always goes in the direction toward
chemical equilibrium.
D) Enzyme-catalyzed reactions require
energy to activate the enzyme.
E) Enzyme-catalyzed reactions
release more free energy than noncatalyzed reactions.
Answer: A
Reactants capable of interacting to form products in a chemical
reaction must first overcome a thermodynamic barrier known as the
reaction's
A) entropy.
B) activation energy.
C)
endothermic level.
D) equilibrium point.
E) free-energy content.
Answer: B
A solution of starch at room temperature does not readily decompose
to form a solution of simple sugars because
A) the starch
solution has less free energy than the sugar solution.
B) the
hydrolysis of starch to sugar is endergonic.
C) the activation
energy barrier for this reaction cannot be surmounted.
D) starch
cannot be hydrolyzed in the presence of so much water.
E) starch
hydrolysis is nonspontaneous.
Answer: C
Which of the following statements regarding enzymes is true?
A)
Enzymes increase the rate of a reaction by making the reaction more
exergonic.
B) Enzymes increase the rate of a reaction by
lowering the activation energy barrier.
C) Enzymes increase the
rate of a reaction by reducing the rate of reverse reactions.
D)
Enzymes change the equilibrium point of the reactions they catalyze.
E) Enzymes make the rate of a reaction independent of substrate concentrations.
Answer: B
During a laboratory experiment, you discover that an enzyme-catalyzed
reaction has a ∆G of -20 kcal/mol. If you double the amount of enzyme
in the reaction, what will be the ∆G for the new reaction?
A)
-40 kcal/mol
B) -20 kcal/mol
C) 0 kcal/mol
D) +20
kcal/mol
E) +40 kcal/mol
Answer: B
The active site of an enzyme is the region that
A) binds
allosteric regulators of the enzyme.
B) is involved in the
catalytic reaction of the enzyme.
C) binds noncompetitive
inhibitors of the enzyme.
D) is inhibited by the presence of a
coenzyme or a cofactor.
Answer: B
According to the induced fit hypothesis of enzyme catalysis, which of
the following is correct?
A) The binding of the substrate
depends on the shape of the active site.
B) Some enzymes change
their structure when activators bind to the enzyme.
C) A
competitive inhibitor can outcompete the substrate for the active
site.
D) The binding of the substrate changes the shape of the
enzyme's active site.
E) The active site creates a
microenvironment ideal for the reaction.
Answer: D
Mutations that result in single amino acid substitutions in an enzyme
A) can have no effect on the activity or properties of the
enzyme.
B) will almost always destroy the activity of the
enzyme.
C) will often cause a change in the substrate
specificity of the enzyme.
D) may affect the physicochemical
properties of the enzyme such as its optimal temperature and pH.
E) may, in rare cases, cause the enzyme to run reactions in reverse.
Answer: D
Increasing the substrate concentration in an enzymatic reaction could
overcome which of the following?
A) denaturization of the enzyme
B) allosteric inhibition
C) competitive inhibition
D) saturation of the enzyme activity
E) insufficient cofactors
Answer: C
Which of the following is true of enzymes?
A) Nonprotein
cofactors alter the substrate specificity of enzymes.
B) Enzyme
function is increased if the 3-D structure or conformation of an
enzyme is altered.
C) Enzyme function is independent of physical
and chemical environmental factors such as pH and temperature.
D) Enzymes increase the rate of chemical reaction by lowering
activation energy barriers.
E) Enzymes increase the rate of
chemical reaction by providing activation energy to the substrate.
Answer: D
Zinc, an essential trace element for most organisms, is present in
the active site of the enzyme carboxypeptidase. The zinc most likely
functions as a(n)
A) competitive inhibitor of the enzyme.
B) noncompetitive inhibitor of the enzyme.
C) allosteric
activator of the enzyme.
D) cofactor necessary for enzyme
activity.
E) coenzyme derived from a vitamin.
Answer: D
In order to attach a particular amino acid to the tRNA molecule that
will transport it, an enzyme, an aminoacyl-tRNA synthetase, is
required, along with ATP. Initially, the enzyme has an active site for
ATP and another for the amino acid, but it is not able to attach the
tRNA. What must occur in order for the final attachment to occur?
A) The ATP must first have to attach to the tRNA.
B) The
binding of the first two molecules must cause a 3-D change that opens
another active site on the enzyme.
C) The ATP must be hydrolyzed
to allow the amino acid to bind to the synthetase.
D) The tRNA
molecule must have to alter its shape in order to be able to fit into
the active site with the other two molecules.
E) The 3' end of
the tRNA must have to be cleaved before it can have an attached amino acid.
Answer: B
Some of the drugs used to treat HIV patients are competitive
inhibitors of the HIV reverse transcriptase enzyme. Unfortunately, the
high mutation rate of HIV means that the virus rapidly acquires
mutations with amino acid changes that make them resistant to these
competitive inhibitors. Where in the reverse transcriptase enzyme
would such amino acid changes most likely occur in drug-resistant
viruses?
A) in or near the active site
B) at an allosteric
site
C) at a cofactor binding site
D) in regions of the
protein that determine packaging into the virus capsid
E) such
mutations could occur anywhere with equal probability
Answer: A
Protein kinases are enzymes that transfer the terminal phosphate from
ATP to an amino acid residue on the target protein. Many are located
on the plasma membrane as integral membrane proteins or peripheral
membrane proteins. What purpose may be served by their plasma membrane
localization?
A) ATP is more abundant near the plasma membrane.
B) They can more readily encounter and phosphorylate other
membrane proteins.
C) Membrane localization lowers the
activation energy of the phosphorylation reaction.
D) They flip
back and forth across the membrane to access target proteins on either
side.
E) They require phospholipids as a cofactor.
Answer: B
When you have a severe fever, what grave consequence may occur if the
fever is not controlled?
A) destruction of your enzymes' primary
structure
B) removal of amine groups from your proteins
C)
change in the tertiary structure of your enzymes
D) removal of
the amino acids in active sites of your enzymes
E) binding of
your enzymes to inappropriate substrates
Answer: C
How does a noncompetitive inhibitor decrease the rate of an enzyme
reaction?
A) by binding at the active site of the enzyme
B) by changing the shape of the enzyme's active site
C) by
changing the free energy change of the reaction
D) by acting as
a coenzyme for the reaction
E) by decreasing the activation
energy of the reaction
Answer: B
The mechanism in which the end product of a metabolic pathway
inhibits an earlier step in the pathway is most precisely described as
A) metabolic inhibition.
B) feedback inhibition.
C)
allosteric inhibition.
D) noncooperative inhibition.
E)
reversible inhibition.
Answer: B
Which of the following statements describes enzyme
cooperativity?
A) A multienzyme complex contains all the enzymes
of a metabolic pathway.
B) A product of a pathway serves as a
competitive inhibitor of an early enzyme in the pathway.
C) A
substrate molecule bound to an active site of one subunit promotes
substrate binding to the active site of other subunits.
D)
Several substrate molecules can be catalyzed by the same enzyme.
E) A substrate binds to an active site and inhibits cooperation
between enzymes in a pathway.
Answer: C
Allosteric enzyme regulation is usually associated with
A) lack
of cooperativity.
B) feedback inhibition.
C) activating
activity.
D) an enzyme with more than one subunit.
E) the
need for cofactors.
Answer: D
Which of the following is an example of cooperativity?
A) the
binding of an end product of a metabolic pathway to the first enzyme
that acts in the pathway
B) one enzyme in a metabolic pathway
passing its product to act as a substrate for the next enzyme in the
pathway
C) a molecule binding at one unit of a tetramer,
allowing faster binding at each of the other three
D) the effect
of increasing temperature on the rate of an enzymatic reaction
E) binding of an ATP molecule along with one of the substrate
molecules in an active site
Answer: C
Protein kinases are enzymes that catalyze phosphorylation of target
proteins at specific sites, whereas protein phosphatases catalyze
removal of phosphate(s) from phosphorylated proteins. Phosphorylation
and dephosphorylation can function as an on-off switch for a protein's
activity, most likely through
A) the change in a protein's
charge leading to a conformational change.
B) the change in a
protein's charge leading to cleavage.
C) a change in the optimal
pH at which a reaction will occur.
D) a change in the optimal
temperature at which a reaction will occur.
E) the excision of
one or more peptides.
Answer: A
Besides turning enzymes on or off, what other means does a cell use
to control enzymatic activity?
A) cessation of cellular protein
synthesis
B) localization of enzymes into specific organelles or
membranes
C) exporting enzymes out of the cell
D)
connecting enzymes into large aggregates
E) hydrophobic interactions
Answer: B
An important group of peripheral membrane proteins are enzymes such
as the phospholipases that cleave the head groups of phospholipids.
What properties must these enzymes exhibit?
A) resistance to
degradation
B) independence from cofactor interaction
C)
water solubility
D) lipid solubility
E) membrane-spanning domains
Answer: C
In experimental tests of enzyme evolution, where a gene encoding an
enzyme is subjected to multiple cycles of random mutagenesis and
selection for altered substrate specificity, the resulting enzyme had
multiple amino acid changes associated with altered substrate
specificity. Where in the enzyme were these amino acid changes
located?
A) only in the active site
B) only in the active
site or near the active site
C) in or near the active site and
at surface sites away from the active site
D) only at surface
sites away from the active site
E) only in the hydrophobic
interior of the folded protein
Answer: C
How might an amino acid change at a site distant from the active site
of the enzyme alter the enzyme's substrate specificity?
A) by
changing the enzyme's stability
B) by changing the enzyme's
location in the cell
C) by changing the shape of the protein
D) by changing the enzyme's pH optimum
E) an amino acid
change away from the active site cannot alter the enzyme's substrate specificity
Answer: C
For the enzyme-catalyzed reaction shown in the figure, which of these
treatments will cause the greatest increase in the rate of the
reaction, if the initial reactant concentration is 1.0 micromolar?
A) doubling the activation energy needed
B) cooling the
reaction by 10°C
C) doubling the concentration of the reactants
to 2.0 micromolar
D) doubling the enzyme concentration
E)
increasing the concentration of reactants to 10.0 micromolar, while
reducing the concentration of enzyme by 1/2
Answer: D
In the figure, why does the reaction rate plateau at higher reactant
concentrations?
A) Feedback inhibition by product occurs at high
reactant concentrations.
B) Most enzyme molecules are occupied
by substrate at high reactant concentrations.
C) The reaction
nears equilibrium at high reactant concentrations.
D) The
activation energy for the reaction increases with reactant
concentration.
E) The rate of the reverse reaction increases
with reactant concentration.
Answer: B
Which curve(s) on the graphs may represent the temperature and pH
profiles of an enzyme taken from a bacterium that lives in a mildly
alkaline hot springs at temperatures of 70°C or higher?
A)
curves 1 and 5
B) curves 2 and 4
C) curves 2 and 5
D) curves 3 and 4
E) curves 3 and 5
Answer: E
Which temperature and pH profile curves on the graphs were most
likely generated from analysis of an enzyme from a human stomach where
conditions are strongly acid?
A) curves 1 and 4
B) curves
1 and 5
C) curves 2 and 4
D) curves 2 and 5
E)
curves 3 and 4
Answer: A
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following terms best describes the forward reaction
in Figure 8.1?
A) endergonic, ∆G > 0
B) exergonic, ∆G
< 0
C) endergonic, ∆G < 0
D) exergonic, ∆G > 0
E) chemical equilibrium, ∆G = 0
Answer: B
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the ΔG of the reaction in
Figure 8.1?
A) a
B) b
C) c
D) d
E) e
Answer: D
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following in Figure 8.1 would be the same in either
an enzyme-catalyzed or a noncatalyzed reaction?
A) a
B) b
C) c
D) d
E) e
Answer: D
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the activation energy needed
for the enzyme-catalyzed reverse reaction, C + D → A + B, in Figure
8.1?
A) a
B) b
C) c
D) d
E) e
Answer: A
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the difference between the
free-energy content of the reaction and the free-energy content of the
products in Figure 8.1?
A) a
B) b
C) c
D) d
E) e
Answer: D
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the activation energy required
for the enzyme-catalyzed reaction in Figure 8.1?
A) a
B) b
C) c
D) d
E) e
Answer: B
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the activation energy required
for a noncatalyzed reaction in Figure 8.1?
A) a
B) b
C) c
D) d
E) e
Answer: C
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Which of the following represents the activation energy needed
for the noncatalyzed reverse reaction, C + D → A + B, in Figure 8.1?
A) a
B) b
C) c
D) d
E) e
Answer: E
This question is based on the reaction A + B ↔ C + D shown in the
figure.
Assume that the reaction in Figure 8.1 has a ΔG of -5.6
kcal/mol. Which of the following would be true?
A) The reaction
could be coupled to power an endergonic reaction with a ΔG of +6.2
kcal/mol.
B) The reaction could be coupled to power an exergonic
reaction with a ΔG of +8.8 kcal/mol.
C) The reaction would
result in a decrease in entropy (S) and an increase in the total
energy content (H) of the system.
D) The reaction would result
in an increase in entropy (S) and a decrease in the total energy
content (H) of the system.
E) The reaction would result in
products (C + D) with a greater free-energy content than in the
initial reactants (A + B).
Answer: D
Which of the following is the most correct interpretation of the
figure?
A) Inorganic phosphate is created from organic
phosphate.
B) Energy from catabolism can be used directly for
performing cellular work.
C) ADP + Pi are a set of molecules
that store energy for catabolism.
D) ATP is a molecule that acts
as an intermediary to store energy for cellular work.
E) Pi acts
as a shuttle molecule to move energy from ATP to ADP.
Answer: D
How do cells use the ATP cycle shown in the figure?
A) Cells
use the cycle to recycle ADP and phosphate.
B) Cells use the
cycle to recycle energy released by ATP hydrolysis.
C) Cells use
the cycle to recycle ADP, phosphate, and the energy released by ATP
hydrolysis.
D) Cells use the cycle to generate or consume water
molecules as needed.
E) Cells use the cycle primarily to
generate heat.
Answer: A
Succinate dehydrogenase catalyzes the conversion of succinate to
fumarate. The reaction is inhibited by malonic acid, which resembles
succinate but cannot be acted upon by succinate dehydrogenase.
Increasing the ratio of succinate to malonic acid reduces the
inhibitory effect of malonic acid.
Based on this information, which of the following is correct?
A) Succinate dehydrogenase is the enzyme, and fumarate is the
substrate.
B) Succinate dehydrogenase is the enzyme, and malonic
acid is the substrate.
C) Succinate is the substrate, and
fumarate is the product.
D) Fumarate is the product, and malonic
acid is a noncompetitive inhibitor.
E) Malonic acid is the
product, and fumarate is a competitive inhibitor.
Answer: C
Succinate dehydrogenase catalyzes the conversion of succinate to
fumarate. The reaction is inhibited by malonic acid, which resembles
succinate but cannot be acted upon by succinate dehydrogenase.
Increasing the ratio of succinate to malonic acid reduces the
inhibitory effect of malonic acid.
What is malonic acid's role with respect to succinate
dehydrogenase?
A) It is a competitive inhibitor.
B) It
blocks the binding of fumarate.
C) It is a noncompetitive
inhibitor.
D) It is able to bind to succinate.
E) It is an
allosteric regulator.
Answer: A
A series of enzymes catalyze the reaction X → Y → Z → A. Product A
binds to the enzyme that converts X to Y at a position remote from its
active site. This binding decreases the activity of the enzyme.
What is substance X?
A) a coenzyme
B) an allosteric
inhibitor
C) a substrate
D) an intermediate
E) the product
Answer: C
A series of enzymes catalyze the reaction X → Y → Z → A. Product A
binds to the enzyme that converts X to Y at a position remote from its
active site. This binding decreases the activity of the enzyme.
With respect to the enzyme that converts X to Y, substance A
functions as
A) a coenzyme.
B) an allosteric inhibitor.
C) the substrate.
D) an intermediate.
E) a
competitive inhibitor.
Answer: B
Choose the pair of terms that correctly completes this sentence:
Catabolism is to anabolism as ________ is to ________.
A)
exergonic; spontaneous
B) exergonic; endergonic
C) free
energy; entropy
D) work; energy
E) entropy; enthalpy
Answer: B
Most cells cannot harness heat to perform work because
A) heat
is not a form of energy.
B) cells do not have much heat; they
are relatively cool.
C) temperature is usually uniform
throughout a cell.
D) heat can never be used to do work.
E) heat must remain constant during work.
Answer: C
Which of the following metabolic processes can occur without a net
influx of energy from some other process?
A) ADP + Pi → ATP +
H₂O
B) C₆H₁₂O₆ + 6 O₂ → 6 CO₂ + 6 H₂O
C) 6 CO₂ + 6 H₂O →
C₆H₁₂O₆ + 6 O₂
D) amino acids → protein
E) glucose +
fructose → sucrose
Answer: B
If an enzyme in solution is saturated with substrate, the most
effective way to obtain a faster yield of products is to
A) add
more of the enzyme.
B) heat the solution to 90°C.
C) add
more substrate.
D) add an allosteric inhibitor.
E) add a
noncompetitive inhibitor.
Answer: A
Some bacteria are metabolically active in hot springs because
A) they are able to maintain a lower internal temperature.
B) high temperatures make catalysis unnecessary.
C) their
enzymes have high optimal temperatures.
D) their enzymes are
completely insensitive to temperature.
E) they use molecules
other than proteins or RNAs as their main catalysts.
Answer: C
If an enzyme is added to a solution where its substrate and product
are in equilibrium, what will occur?
A) Additional product will
be formed.
B) Additional substrate will be formed.
C) The
reaction will change from endergonic to exergonic.
D) The free
energy of the system will change.
E) Nothing; the reaction will
stay at equilibrium.
Answer: E