Chapter 19 - Oxidative Phosphorylation
For mitochondria where an uncoupler for oxidative phosphorylation is
present, which statement is TRUE?
A) The rate of NADH reoxidation
will decrease relative to coupled mitochondria.
B) The citric
acid cycle will be inhibited relative to uncoupled
mitochondria.
C) The P:O ratio for FADH2 will increase relative
to uncoupled mitochondria.
D) The amount of ATP generated from
FADH2 will be less than the amount of ATP generated from NADH.
E)
None of the statements is true.
D) The amount of ATP generated from FADH2 will be less than the amount of ATP generated from NADH.
Which statement regarding oxidative phosphorylation is TRUE?
A)
The rate of electron transport is independent of the magnitude of the
proton electrochemical gradient.
B) ATP synthase utilizes
oxidized cofactors.
C) Proton transfer through the Fo subunit of
ATP synthase is required in order for ATP synthesis to occur.
D)
The addition of an uncoupler decreases the rate of re-oxidation of
NADH and FADH2, therefore decreasing the rate of
the citric acid
cycle.
E) All of the statements are true.
C) Proton transfer through the Fo subunit of ATP synthase is required in order for ATP synthesis to occur.
The consumption of acetyl-CoA by the citric acid cycle is DECREASED
under which condition?
A) the concentration of NAD+ being
high
B) the concentration of oxaloacetate being high
C) NADH
being rapidly re-oxidized via the electron-transport chain
D) the
mitochondrial ATP synthase being inactive
E) the concentration of
both NAD+ and oxaloacetate being high
D) the mitochondrial ATP synthase being inactive
Which molecule can reduce the proton gradient in
mitochondria?
A) Pi-H+ symporter
B) ATP synthase
C)
pyruvate translocase
D) All of the answers are correct.
E)
None of the answers is correct.
D) All of the answers are correct.
How many molecules of water are produced by the electron-transport
chain during the complete aerobic oxidation of one
molecule of
pyruvate?
A) 3 H2O
B) 4 H2O
C) 5 H2O
D) 8
H2O
E) 10 H2O
C) 5 H2O
The electron-transport chain and ATP synthase are effectively
coupled. Which statement BEST describes how this occurs?
A) The
electron-transport chain reoxidizes reduced cofactors.
B) The
electron-transport chain generates an electrochemical gradient that
provides energy for the production of ATP.
C) ATP synthase
utilizes oxidized cofactors.
D) Through a series of
conformational changes, ATP synthase generates ATP.
B) The electron-transport chain generates an electrochemical gradient that provides energy for the production of ATP.
Which statement is NOT true of electron transport?
A) The mobile
electron carrier coenzyme A is located in the inner mitochondrial
membrane.
B) Electrons flow from redox centers with a lower
reduction potential to redox centers with a higher reduction
potential.
C) The electron transport chain oxidizes reduced
cofactors.
D) Cytochrome C has a higher reduction potential than
FADH2.
E) None of the statements is true.
A) The mobile electron carrier coenzyme A is located in the inner mitochondrial membrane.
During oxidative phosphorylation, the proton motive force
(electrochemical gradient) that is generated by electron
transport
is used to:
A) create a pore in the inner
mitochondrial membrane.
B) generate the substrates (ADP and Pi)
for ATP synthase.
C) drive transport processes essential to
oxidative phosphorylation.
D) reduce NAD+ to NADH.
E) reduce
O2 to H2O.
C) drive transport processes essential to oxidative phosphorylation.
Coenzyme Q is a prosthetic group for which of the following complexes
in the electron transport chain?
A) Complex I
B) Complex
II
C) Complex III
D) All of the answers are correct.
E)
None of the answers is correct.
E) None of the answers is correct.
Which statement does NOT describe a difference between the inner and
outer mitochondrial membranes?
A) The outer mitochondrial
membrane contains porins, whereas the inner mitochondrial membrane
does not.
B) The outer mitochondrial membrane is permeable to
large proteins (Mr > 10,000), whereas the inner
mitochondrial
membrane is not.
C) A pH gradient exists
across the inner mitochondrial membrane but not the outer
mitochondrial membrane.
D) The inner mitochondrial membrane
contains a smaller percentage of lipid relative to protein compared
with the outer
mitochondrial membrane.
E) The outer
mitochondrial membrane has a smaller surface area than the inner
mitochondrial membrane.
B) The outer mitochondrial membrane is permeable to large proteins
(Mr > 10,000), whereas the inner mitochondrial
membrane is not.
What factor makes the outer mitochondrial membrane permeable to
protons?
A) proton symports
B) proton antiports
C)
porins
D) the presence of proton ionophores
E) the presence
of negatively charged lipids
C) porins
Which cofactor is MOST commonly involved as a cosubstrate in
catabolic reactions where a metabolite is oxidized?
A)
NAD+
B) FAD
C) NADPH
D) NADH
E) coenzyme Q
A) NAD+
Which statement is FALSE regarding flavoproteins?
A) They may
contain either FMN or FAD.
B) The reduction potential of the
flavin will depend on the amino acids in the polypeptide
chain.
C) They will need at least two substrates in order to
function as enzymes.
D) They are always integral membrane
proteins.
E) Most flavoproteins in electron transport have a
lower reduction potential than coenzyme Q.
D) They are always integral membrane proteins.
Complex III contains which cofactor as a prosthetic group?
A)
iron-sulfur clusters
B) FAD
C) FMN
D) coenzyme
Q
E) copper
A) iron-sulfur clusters
Which characteristic describes heme a but not heme c?
A)
noncovalently associated prosthetic group
B) contains an
isoprenoid structure
C) contains an aldehyde substituent on the
porphyrin ring
D) contains two propionate substituents on the
porphyrin ring
E) contains a vinyl substituent on the porphyrin ring
D) contains two propionate substituents on the porphyrin ring
Which component of the electron-transport chain is NOT an integral
membrane protein?
A) NADH dehydrogenase
B) cytochrome
c
C) cytochrome oxidase
D) ubiquinone:cytochrome c
oxidoreductase
E) succinate dehydrogenase
B) cytochrome c
Which protein associated with electron transport below is NOT a
flavoprotein?
A) NADH dehydrogenase
B) mitochondrial
glycerol-3-phosphate dehydrogenase
C) cytochrome oxidase
D)
succinate dehydrogenase
E) acyl-CoA dehydrogenase
C) cytochrome oxidase
If a drug that specifically prevented the interaction of cytochrome c
with other proteins was added to respiring mitochondria
in a test
tube, what effects would be observed?
A) ATP synthesis would
immediately stop.
B) Oxygen consumption would increase.
C)
Reduced cofactors (NADH/FADH2) would accumulate.
D) Coenzyme Q
would become oxidized.
E) Proton export from the matrix would increase.
C) Reduced cofactors (NADH/FADH2) would accumulate.
Which statement is FALSE concerning Complex III and the Q
cycle?
A) Both Q and QH2 are substrates for Complex III.
B)
Four protons are released on the P side of the membrane for every two
electrons transferred to cytochrome c.
C) This protein contains
both iron-sulfur clusters and heme as prosthetic groups.
D) Two
protons from the matrix side are used to generate QH2 from the
semiquinone radical.
E) Overall, in each cycle one cytochrome c
is reduced for every QH2 oxidized (net).
E) Overall, in each cycle one cytochrome c is reduced for every QH2 oxidized (net).
How many of cytochrome c need to be reoxidized for every oxygen
molecule (O2) converted to water?
A) one
B) two
C)
three
D) four
E) eight
D) four
Which list shows the proteins in the CORRECT order from highest to
lowest reduction potential?
A) acyl-CoA dehydrogenase → ETF:Q
oxidoreductase → ETF
B) ETF → ETF:Q oxidoreductase → acyl-CoA
dehydrogenase
C) ETF:Q oxidoreductase → acyl-CoA dehydrogenase →
ETF
D) ETF:Q oxidoreductase → ETF → acyl-CoA
dehydrogenase
E) ETF → acyl-CoA dehydrogenase → ETF:Q oxidoreductase
D) ETF:Q oxidoreductase → ETF → acyl-CoA dehydrogenase
What is the P:O ratio for electrons entering the electron-transport
chain that originate from reoxidation of
acyl-CoA
dehydrogenase?
A) greater than the P:O ratio for
NADH reoxidation
B) approximately the same as the P:O ratio for
NADH reoxidation
C) less than the P:O ratio for NADH reoxidation
but more than the P:O ratio for Complex II reoxidation
D)
approximately the same as the P:O ratio for Complex II
reoxidation
E) less than the P:O ratio for Complex II reoxidation
D) approximately the same as the P:O ratio for Complex II reoxidation
Which complex in the electron-transport chain contains copper
ions?
A) Complex I
B) Complex II
C) Complex III
D)
Complex IV
E) None of these complexes contains copper ions.
D) Complex IV
Cytochrome c can be reduced directly by small molecules such as
ascorbate (vitamin C). If ascorbate is added to an
oxygenated
solution containing purified cytochrome c and cytochrome oxidase, what
would you predict would occur?
A) ATP synthesis would
occur.
B) Cytochrome c would become reduced and remain
reduced.
C) Oxygen would be reduced to water.
D) Ascorbate
would become more reduced.
E) No apparent change would be observed.
C) Oxygen would be reduced to water.
What compound is a product of the reaction involving the superoxide
free radical catalyzed by superoxide dismutase?
A) water
B)
hydrogen peroxide
C) reduced glutathione
D) oxidized
glutathione
E) NADPH
B) hydrogen peroxide
In some organisms, an alternative oxidase will accept electrons from
ubiquinol and reduce oxygen to water with no
associated proton
translocation. What would be a consequence of having this oxidase
active?
A) decreased rate of NADH reoxidation
B) decreased
P:O ratio
C) decreased rate of oxygen consumption
D)
inhibition of oxidative pathways like the citric acid cycle
E)
increased sensitivity to cyanide poisoning
B) decreased P:O ratio
During the operation of the malate-aspartate shuttle, what process
does NOT occur?
A) net movement of reducing potential from the
cytosol to the matrix
B) transfer of amino groups from glutamate
to oxaloacetate in the cytosol
C) transport of two different
amino acids through an antiport
D) simultaneous transport of
malate and oxaloacetate through an antiport
E) reduction of
oxaloacetate to malate in the cytosol
B) transfer of amino groups from glutamate to oxaloacetate in the cytosol
Which statement is TRUE regarding the reduction potential of
mitochondrial glycerol 3 phosphate dehydrogenase?
A) It will be
higher than those of both NADH and Complex III.
B) It will be
lower than those of both NADH and Complex III.
C) It will be
higher than that of NADH but lower than that of Complex III.
D)
It will be lower than that of NADH but higher than that of Complex
III.
E) No conclusion can be drawn regarding its reduction potential.
C) It will be higher than that of NADH but lower than that of Complex III.
Which statement is FALSE regarding 2,4-dinitrophenol?
A) It is a
proton carrier ionophore.
B) It may be either neutral or
negatively charged.
C) It is soluble in the lipid core of
membranes.
D) It requires a specific transporter to enter
mitochondria.
E) It decreases ATP synthesis will increasing
oxygen consumption.
D) It requires a specific transporter to enter mitochondria.
What effect will increasing the number of c subunits in ATP synthase
have on the P:O ratio?
A) It will increase for both NADH and
FADH2.
B) It will increase for NADH and decrease for
FADH2.
C) It will decrease for NADH and increase for
FADH2.
D) It will decrease for both NADH and FADH2.
E) It
will remain unchanged for both NADH and FADH2.
D) It will decrease for both NADH and FADH2.
Which statement is FALSE regarding ATP synthase?
A) The active
site contains multiple positive charges that interact with the
substrates.
B) The energy difference between bound substrate and
bound product is close to zero.
C) As an enzyme, ATP synthase is
classified as a hydrolase.
D) ATP synthase can be classified as a
primary active transporter.
E) ADP binds more tightly to the
active site than ATP.
E) ADP binds more tightly to the active site than ATP.
Which statement is TRUE regarding the gamma (γ) subunit of ATP
synthase?
A) It contains mostly α-helical regular secondary
structure.
B) It exists as a dimer in the F1 portion of ATP
synthase.
C) It prevents the F1 portion from rotating relative to
the FO portion.
D) It interacts with the a and b subunits of the
FO portion.
E) It binds protons as part of the proton
translocation process.
A) It contains mostly α-helical regular secondary structure.
Which step is NOT part of the proton-translocation process in ATP
synthase?
A) A negatively charged amino acid in each c subunit
becomes neutral upon proton binding.
B) A positively charged
amino acid in the a subunit forms an ion pair with a charged amino
acid in a c subunit.
C) Deprotonated c subunits are able to
interact only with the a subunit.
D) An arginine in the a subunit
is reversibly protonated and deprotonated in each proton binding
event.
E) Proton direction is determined by the relative
concentrations of protons on either side of the membrane.
D) An arginine in the a subunit is reversibly protonated and deprotonated in each proton binding event.
In which pairing are both transporters symports?
A) adenine
nucleotide translocase and phosphate translocase
B) phosphate
translocase and pyruvate translocase
C) pyruvate translocase and
adenine nucleotide translocase
D) adenine nucleotide translocase
and glutamate-aspartate transporter
E) glutamate-aspartate
transporter and phosphate translocase
B) phosphate translocase and pyruvate translocase
Which statement explains why the [ATP]/[ADP][Pi] ratio is relatively
stable in a cell?
A) [ATP] is always relatively low.
B) ATP
consumption is balanced by ATP synthase activity.
C) ATP is used
to regulate protein kinases.
D) ATPases ensure that ATP
concentration does not become too large.
E) Energy consumption is
minimized to ensure ATP is not consumed.
B) ATP consumption is balanced by ATP synthase activity.
Which statement does NOT describe characteristics of the protein
inhibitor IF1?
A) This protein is relatively small (<100 amino
acids).
B) This protein has very little ordered structure at pH
7.0.
C) This protein will bind to the FO portion of ATP
synthase.
D) This protein functions as a dimer when it is
inhibiting ATP synthesis.
E) This protein inhibits ATP hydrolysis
by ATP synthase.
C) This protein will bind to the FO portion of ATP synthase.
What will NOT occur when 2,4-dinitrophenol (an uncoupler of oxidative
phosphorylation) is added to actively
respiring
mitochondria?
A) The P:O ratio will
increase.
B) The rate of NADH reoxidation at Complex I will
increase.
C) The rate of oxidation of intermediates in the citric
acid cycle will increase.
D) Proton export from the matrix will
occur.
E) Heat will be released.
A) The P:O ratio will increase.
Cytochrome P-450 gets its name from what characteristic?
A) It
is a protein that is 450 amino acids long.
B) It fluoresces at
450 nm.
C) It absorbs light at 450 nm.
D) It has a reduction
potential of –450 mV.
E) It contains a 450 Dalton prosthetic group.
C) It absorbs light at 450 nm.
What is the role of cytochrome c in apoptosis?
A) It acts as an
allosteric effector for caspase-3.
B) It transports electrons
from mitochondria to the cytosol.
C) It acts as a protease to
activate various zymogens.
D) It forms a complex with other
proteins to generate an apoptosome.
E) It activates pores in the
outer mitochondrial membrane.
D) It forms a complex with other proteins to generate an apoptosome.
Which protein is NOT portion encoded in human mitochondrial
DNA?
A) Complex I (NADH dehydrogenase)
B) Complex II
(succinate dehydrogenase)
C) Complex III (ubiquinone:cytochrome c
oxidoreductase)
D) cytochrome c
E) Complex IV (cytochrome oxidase)
D) cytochrome c
What mechanism accounts for mitochondrial inheritance in sexual
reproduction in animals?
A) Male gametes do not contain
mitochondria.
B) Mitochondria from male gametes do not enter the
ovum.
C) Female mitochondria are able to outcompete male
mitochondria.
D) Male mitochondria are degraded after
fertilization.
E) Male and female mitochondria merge after
fertilization to form hybrids.
D) Male mitochondria are degraded after fertilization.
Almost all of the oxygen (O2) one consumes in breathing is converted
to:
A) acetyl-CoA.
B) carbon dioxide (CO2).
C) carbon
monoxide and then to carbon dioxide.
D) water.
E) None of
the answers is correct.
D) water.
Which of the following electron carriers is NOT able to transfer one
electron at a time?
A) NADH
B) FMN
C) FAD
D)
ubiquinone
E) heme
A) NADH
A new compound isolated from mitochondria is claimed to represent a
previously unrecognized carrier in the electron
transfer chain.
It is given the name coenzyme Z. Which line of evidence do you feel is
the LEAST conclusive in assigning
this compound a position in the
electron transfer chain?
A) Alternate oxidation and reduction of
the mitochondrion-bound coenzyme Z can be readily
demonstrated.
B) Removal of coenzyme Z from the mitochondria
results in a decreased rate of oxygen consumption.
C) The rate of
oxidation and reduction of mitochondrion-bound coenzyme is of the same
order of magnitude as the overall
rate of electron transfer in
mitochondria as measured by oxygen consumption.
D) The reduction
potential of Z is between that of two compounds known to participate
in the electron transport chain
E) When added to a mitochondrial
suspension, coenzyme Z is taken up very rapidly and specifically by
the mitochondria.
E) When added to a mitochondrial suspension, coenzyme Z is taken up very rapidly and specifically by the mitochondria.
Antimycin A blocks electron transfer between cytochromes b and c1. If
intact mitochondria were incubated with antimycin
A, excess NADH,
and an adequate supply of O2, which compound would be found in the
oxidized state?
A) coenzyme Q
B) cytochrome a3
C)
cytochrome b
D) cytochrome e
E) cytochrome f
B) cytochrome a3
Reduced QH2 is NOT formed by which of the following?
A) Complex
I and NADH
B) Complex II and succinate
C) Complex III and
cytochrome c
D) fatty acid oxidation
E) oxidation of glycerol-3-phosphate
C) Complex III and cytochrome c
In the reoxidation of QH2 by purified ubiquinone-cytochrome c
reductase (Complex III) from heart muscle, the
overall
stoichiometry of the reaction requires 2 mol of
cytochrome c per mole of QH2 because:
A) cytochrome c is a
one-electron acceptor, whereas QH2 is a two-electron donor.
B)
cytochrome c is a two-electron acceptor, whereas QH2 is a one-electron
donor.
C) cytochrome c is water soluble and operates between the
inner and outer mitochondrial membranes
D) heart muscle has a
high rate of oxidative metabolism, and therefore requires twice as
much cytochrome c as QH2 for
electron transfer to proceed
normally.
E) two molecules of cytochrome c must first combine
physically before they are catalytically active.
A) cytochrome c is a one-electron acceptor, whereas QH2 is a two-electron donor.
Which statement is NOT a feature of Complex IV?
A) Cytochrome c
is a one-electron donor.
B) Oxygen is a substrate.
C) Copper
is an essential metal for the reaction.
D) For every electron
passed to Complex IV, two protons are consumed from the matrix (N)
side.
E) In order to generate two water molecules, Complex IV
must go through the catalytic cycle two times.
E) In order to generate two water molecules, Complex IV must go through the catalytic cycle two times.
Which statement is NOT true of the proton motive force (pmf)?
A)
One component of the pmf is the chemical gradient of protons.
B)
One component of the pmf is the charge gradient of protons.
C)
Generation of the pmf in mitochondria requires succinate.
D) The
pmf is generated by the electron transport chain in
mitochondria.
E) The pmf drives ATP synthesis in mitochondria.
C) Generation of the pmf in mitochondria requires succinate.
Cyanide, oligomycin, and 2,4-dinitrophenol (DNP) are inhibitors of
mitochondrial aerobic phosphorylation. Which statement
CORRECTLY
describes the mode of action of the three inhibitors?
A) Cyanide
and 2,4-dinitrophenol inhibit the respiratory chain, and oligomycin
inhibits the synthesis of ATP.
B) Cyanide inhibits the
respiratory chain, whereas oligomycin and 2,4-dinitrophenol inhibit
the synthesis of ATP.
C) Cyanide, oligomycin, and
2,4-dinitrophenol compete with O2 for cytochrome oxidase (Complex
IV).
D) Oligomycin and cyanide inhibit synthesis of ATP;
2,4-dinitrophenol inhibits the respiratory chain.
E) Oligomycin
inhibits the respiratory chain, whereas cyanide and 2,4-dinitrophenol
prevent the synthesis of ATP.
B) Cyanide inhibits the respiratory chain, whereas oligomycin and 2,4-dinitrophenol inhibit the synthesis of ATP.
If electron transfer in tightly coupled mitochondria is blocked (with
antimycin A) between cytochrome b and cytochrome
c1,
then:
A) all ATP synthesis will stop.
B) ATP
synthesis will continue, but the P/O ratio will drop to one.
C)
electron transfer from NADH will cease, but O2 uptake will
continue.
D) electron transfer from succinate to O2 will continue
unabated.
E) energy diverted from the cytochromes will be used to
make ATP, and the P/O ratio will rise.
A) all ATP synthesis will stop.
In normal mitochondria, the rate of NADH consumption (oxidation)
will:
A) be increased in active muscle, decreased in inactive
muscle.
B) be very low if the ATP synthase is inhibited, but
increase when an uncoupler is added.
C) decrease if mitochondrial
ADP is depleted.
D) decrease when cyanide is used to prevent
electron transfer through the cytochrome a + a3 complex.
E) All
of the answers are correct.
E) All of the answers are correct.
Which statement about the chemiosmotic theory is CORRECT?
A)
Electron transfer in mitochondria is accompanied by an asymmetric
release of protons on one side of the inner
mitochondrial
membrane.
B) It predicts that oxidative phosphorylation can
occur, even in the absence of an intact inner mitochondrial
membrance.
C) The effect of uncoupling reagents is a consequence
of their ability to carry electrons through membranes.
D) The
membrane ATP synthase has no significant role in the chemiosmotic
theory.
E) All of the statements are correct.
A) Electron transfer in mitochondria is accompanied by an asymmetric
release of protons on one side of the inner
mitochondrial membrane.
Which statement about the chemiosmotic theory is FALSE?
A)
Electron transfer in mitochondria is accompanied by an asymmetric
release of protons on one side of the inner
mitochondrial
membrane.
B) Energy is conserved as a transmembrane pH
gradient.
C) Oxidative phosphorylation cannot occur in
membrane-free preparations.
D) The effect of uncoupling reagents
is a consequence of their ability to carry protons through
membranes.
E) The membrane ATPase, which plays an important role
in other hypotheses for energy coupling, has no significant role
in
the chemiosmotic theory.
E) The membrane ATPase, which plays an important role in other
hypotheses for energy coupling, has no significant role in
the
chemiosmotic theory.
Upon the addition of 2,4-dinitrophenol (DNP) to a suspension of
mitochondria carrying out oxidative phosphorylation linked
to the
oxidation of malate, what does NOT occur?
A) Oxygen consumption
decreases.
B) Oxygen consumption increases.
C) The P/O ratio
drops from a value of approximately 2.5 to 0.
D) The proton
gradient dissipates.
E) The rate of transport of electrons from
NADH to O2 becomes maximal.
A) Oxygen consumption decreases.
Uncoupling of mitochondrial oxidative phosphorylation:
A) allows
continued mitochondrial ATP formation but halts O2
consumption.
B) halts all mitochondrial metabolism.
C) halts
mitochondrial ATP formation but allows continued O2
consumption.
D) slows down the citric acid cycle.
E) slows
the conversion of glucose to pyruvate by glycolysis.
C) halts mitochondrial ATP formation but allows continued O2 consumption.
2,4-Dinitrophenol and oligomycin inhibit mitochondrial oxidative
phosphorylation. 2,4-Dinitrophenol is an uncoupling
agent;
oligomycin blocks the ATP synthesis reaction itself. Therefore,
2,4-dinitrophenol will:
A) allow electron transfer in the
presence of oligomycin.
B) allow oxidative phosphorylation in the
presence of oligomycin.
C) block electron transfer in the
presence of oligomycin.
D) diminish O2 consumption in the
presence of oligomycin.
E) None of the answers is correct.
A) allow electron transfer in the presence of oligomycin.
Which statement about energy conservation in the mitochondrion is
FALSE?
A) Drugs that inhibits the ATP synthase will also inhibit
the flow of electrons down the chain of carriers.
B) For
oxidative phosphorylation to occur, it is essential to have a closed
membranous structure with an inside and an
outside.
C) The
yield of ATP per mole of oxidizable substrate depends on the
substrate.
D) Uncouplers (such as dinitrophenol) have exactly the
same effect on electron transfer as inhibitors such as cyanide;
both
block further electron transfer to oxygen.
E)
Uncouplers “short circuit” the proton gradient, thereby dissipating
the proton motive force as heat.
D) Uncouplers (such as dinitrophenol) have exactly the same effect on
electron transfer as inhibitors such as cyanide; both
block
further electron transfer to oxygen.
Which statement is CORRECT concerning the mitochondrial ATP
synthase?
A) It can synthesize ATP after it is extracted from
broken mitochondria.
B) It catalyzes the formation of ATP even
though the reaction has a large positive ΔG'°.
C) It consists of
Fo and F1 subunits, which are transmembrane (integral)
polypeptides.
D) It is actually an ATPase and only catalyzes the
hydrolysis of ATP.
E) When it catalyzes the ATP synthesis
reaction, the ΔG'° is actually close to zero.
E) When it catalyzes the ATP synthesis reaction, the ΔG'° is actually close to zero.
When the ΔG'° of the ATP synthesis reaction is measured on the
surface of the ATP synthase enzyme, it is found to be close
to
zero. This is thought to be due to:
A) a very low energy of
activation.
B) enzyme-induced oxygen exchange.
C)
stabilization of ADP relative to ATP by enzyme binding.
D)
stabilization of ATP relative to ADP by enzyme binding.
E) None
of the answers is correct.
D) stabilization of ATP relative to ADP by enzyme binding.
During oxidative phosphorylation, the proton motive force that is
generated by electron transport is used to:
A) create a pore in
the inner mitochondrial membrane.
B) generate the substrates (ADP
and Pi) for the ATP synthase.
C) induce a conformational change
in the ATP synthase.
D) oxidize NADH to NAD+.
E) reduce O2
to H2O.
C) induce a conformational change in the ATP synthase.
The oxidation of a particular hydroxy substrate to a keto product by
mitochondria has a P/O ratio of less than 2. The
initial
oxidation step is very likely directly coupled to
the:
A) oxidation of a flavoprotein.
B) oxidation of a
pyridine nucleotide.
C) reduction of a flavoprotein.
D)
reduction of a pyridine nucleotide.
E) reduction of cytochrome a3.
C) reduction of a flavoprotein.
The relative concentrations of ATP and ADP control the cellular rates
of:
A) glycolysis.
B) oxidative phosphorylation.
C)
pyruvate oxidation.
D) the citric acid cycle.
E) All of the
answers are correct.
E) All of the answers are correct.
The rate of oxidative phosphorylation in mitochondria is controlled
primarily by:
A) feedback inhibition by CO2.
B) the
availability of NADH from the TCA cycle.
C) the concentration of
citrate (or) the glycerol-3-phosphate shuttle.
D) the mass-action
ratio of the ATD-ADP system.
E) the presence of thermogenin.
D) the mass-action ratio of the ATD-ADP system.
Which factor is NOT controlled by hypoxia-inducible factor
(HIF-1)?
A) glucose transport
B) glycolysis
C) citric
acid cycle
D) Compex I of the respiratory chain
E) Complex
IV of the respiratory chain
D) Compex I of the respiratory chain
Mammals produce heat by using which endogenous uncoupling
agent?
A) the small molecule 2-4-dinitrophenol synthesized by the
cell
B) the protein thermogenin
C) the protein
thioredoxin
D) the protein cytochrome c
E) a modified form
of the FoF1 ATPase
B) the protein thermogenin
Which phrase BEST describes the role of mitochondria in
apoptosis?
A) escape of cytochrome c into the cytoplasm
B)
increased rate of fatty acid β oxidation
C) an increase in
permeability of outer membrane
D) uncoupling of oxidative
phosphorylation
E) both escape of cytochrome c into the cytoplasm
and an increase in permeability of outer membrane
E) both escape of cytochrome c into the cytoplasm and an increase in permeability of outer membrane
Mutations in mitochondrial genes do NOT play a role in:
A) adult
onset diabetes.
B) cystic fibrosis.
C) hypertrophic
cardiomyopathy.
D) Leber's hereditary optic neuropathy.
E)
myoclonic epilepsy.
B) cystic fibrosis.
Which statement about human mitochondria is TRUE?
A) About 900
mitochondrial proteins are encoded by nuclear genes.
B)
Mitochondrial genes are inherited from both maternal and paternal
sources.
C) rRNA and tRNA are imported from the cytoplasm and
used in mitochondrial protein synthesis.
D) The mitochondrial
genome codes for all proteins found in mitochondria.
E) The
mitochondrial genome is not subject to mutations.
A) About 900 mitochondrial proteins are encoded by nuclear genes.