If you want more challenge, there are problems associated with cell metabolism and can be done better understood, it will be usefull thank you. Fight!
Which step in Figure 9.1 shows a split of one molecule into two smaller molecules?
Which step in Figure 9.1 shows a split of one molecule into two smaller molecules?
A) A
B) B
C) C
D) D
E) E
Answer: B
In which step in Figure 9.1 is an inorganic phosphate
added to the reactant?
A) A
B) B
C) C
D) D
E) E
Answer: C
Which step in Figure 9.1 is a redox reaction?
A) A
B) B
C) C
D) D
E) E
Answer: C
Which portion of the pathway in Figure 9.1 involves an
endergonic reaction?
A) A
B) B
C) C
D) D
E) E
Answer: A
Which portion of the pathway in Figure 9.1 contains a
phosphorylation reaction in which ATP is the phosphate source?
A) A
B) B
C) C
D) D
E) E
Answer: A
Starting with one molecule of isocitrate and ending with
fumarate, how many ATP molecules can be made through substrate-level
phosphorylation (see Figure 9.2)?
A) 1
B) 2
C) 11
D) 12
E) 24
Answer: A
Carbon skeletons for amino acid biosynthesis are supplied
by intermediates of the citric acid cycle. Which intermediate would supply the
carbon skeleton for synthesis of a five-carbon amino acid (see Figure 9.2)?
A) succinate
B) malate
C) citrate
D) α-ketoglutarate
E) isocitrate
Answer: D
For each mole of glucose (C₆H₁₂O₆) oxidized by cellular
respiration, how many moles of CO₂ are released in the citric acid cycle (see
Figure 9.2)?
A) 2
B) 4
C) 6
D) 12
E) 3
Answer: B
If pyruvate oxidation is blocked, what will happen to the
levels of oxaloacetate and citric acid in the citric acid cycle shown in Figure
9.2?
A) There will be no change in the levels of oxaloacetate
and citric acid.
B) Oxaloacetate will decrease and citric acid will
accumulate.
C) Oxaloacetate will accumulate and citric acid will
decrease.
D) Both oxaloacetate and citric acid will decrease.
E) Both oxaloacetate and citric acid will accumulate.
Answer: C
Starting with citrate, which of the following
combinations of products would result from three acetyl CoA molecules entering
the citric acid cycle (see Figure 9.2)?
A) 1 ATP, 2 CO₂, 3 NADH, and 1 FADH₂
B) 2 ATP, 2 CO₂, 3 NADH, and 3 FADH₂
C) 3 ATP, 3 CO₂, 3 NADH, and 3 FADH₂
D) 3 ATP, 6 CO₂, 9 NADH, and 3 FADH₂
E) 38 ATP, 6 CO₂, 3 NADH, and 12 FADH₂
Answer: D
For each molecule of glucose that is metabolized by
glycolysis and the citric acid cycle (see Figure 9.2), what is the total number
of NADH + FADH₂ molecules produced?
A) 4
B) 5
C) 6
D) 10
E) 12
Answer: E
Figure 9.3 shows the electron transport chain. Which of
the following is the combination of substances that is initially added to the
chain?
A) oxygen, carbon dioxide, and water
B) NAD⁺, FAD, and electrons
C) NADH, FADH₂, and protons
D) NADH, FADH₂, and O₂
E) oxygen and protons
Answer: D
Which of the following most accurately describes what is
happening along the electron transport chain in Figure 9.3?
A) Chemiosmosis is coupled with electron transfer.
B) Each electron carrier alternates between being reduced
and being oxidized.
C) ATP is generated at each step.
D) Energy of the electrons increases at each step.
E) Molecules in the chain give up some of their potential
energy.
Answer: B
Which of the protein complexes labeled with Roman
numerals in Figure 9.3 will transfer electrons to O₂?
A) complex I
B) complex II
C) complex III
D) complex IV
E) All of the complexes can transfer electrons to O₂.
Answer: D
What happens at the end of the chain in Figure 9.3?
A) 2 electrons combine with a proton and a molecule of
NAD⁺.
B) 2 electrons combine with a molecule of oxygen and two
hydrogen atoms.
C) 4 electrons combine with a molecule of oxygen and 4
protons.
D) 4 electrons combine with four hydrogen and two oxygen
atoms.
E) 1 electron combines with a molecule of oxygen and a
hydrogen atom.
Answer: C
In the presence of oxygen, the three-carbon compound
pyruvate can be catabolized in the citric acid cycle. First, however, the
pyruvate
(1) loses a carbon, which is given off as a molecule of CO₂,
(2) is
oxidized to form a two-carbon compound called acetate, and
(3) is bonded to
coenzyme A.
These three steps result in the formation of
A) acetyl CoA, O₂, and ATP.
B) acetyl CoA, FADH₂, and CO₂.
C) acetyl CoA, FAD, H₂, and CO₂.
D) acetyl CoA, NADH, H⁺, and CO₂.
E) acetyl CoA, NAD⁺, ATP, and CO₂.
Answer: D
In the presence of oxygen, the three-carbon compound
pyruvate can be catabolized in the citric acid cycle. First, however, the
pyruvate
(1) loses a carbon, which is given off as a molecule of CO₂,
(2) is
oxidized to form a two-carbon compound called acetate, and
(3) is bonded to
coenzyme A.
Why is coenzyme A, a sulfur-containing molecule derived
from a B vitamin, added?
A) because sulfur is needed for the molecule to enter the
mitochondrion
B) in order to utilize this portion of a B vitamin which
would otherwise be a waste product from another pathway
C) to provide a relatively unstable molecule whose acetyl
portion can be readily transferred to a compound in the citric acid cycle
D) because it drives the reaction that regenerates NAD⁺
E) in order to remove one molecule of CO₂
Answer: C
Exposing inner mitochondrial membranes to ultrasonic
vibrations will disrupt the membranes. However, the fragments will reseal
"inside out." These little vesicles that result can still transfer
electrons from NADH to oxygen and synthesize ATP. If the membranes are agitated
further, however, the ability to synthesize ATP is lost.
After the first disruption, when electron transfer and
ATP synthesis still occur, what must be present?
A) all of the electron transport proteins as well as ATP
synthase
B) all of the electron transport system and the ability
to add CoA to acetyl groups
C) the ATP synthase system
D) the electron transport system
E) plasma membranes like those bacteria use for
respiration
Answer: A
Exposing inner mitochondrial membranes to ultrasonic
vibrations will disrupt the membranes. However, the fragments will reseal
"inside out." These little vesicles that result can still transfer
electrons from NADH to oxygen and synthesize ATP. If the membranes are agitated
further, however, the ability to synthesize ATP is lost.
After the further agitation of the membrane vesicles,
what must be lost from the membrane?
A) the ability of NADH to transfer electrons to the first
acceptor in the electron transport chain
B) the prosthetic groups like heme from the transport
system
C) cytochromes
D) ATP synthase, in whole or in part
E) the contact required between inner and outer membrane
surfaces
Answer: D
Exposing inner mitochondrial membranes to ultrasonic
vibrations will disrupt the membranes. However, the fragments will reseal
"inside out." These little vesicles that result can still transfer
electrons from NADH to oxygen and synthesize ATP. If the membranes are agitated
further, however, the ability to synthesize ATP is lost.
These inside-out membrane vesicles
A) will become acidic inside the vesicles when NADH is
added.
B) will become alkaline inside the vesicles when NADH is
added.
C) will make ATP from ADP and i if transferred to a pH 4
buffered solution after incubation in a pH 7 buffered solution.
D) will hydrolyze ATP to pump protons out of the interior
of the vesicle to the exterior.
E) will reverse electron flow to generate NADH from NAD⁺
in the absence of oxygen.
Answer: A
The immediate energy source that drives ATP synthesis by
ATP synthase during oxidative phosphorylation is the
A) oxidation of glucose and other organic compounds.
B) flow of electrons down the electron transport chain.
C) affinity of oxygen for electrons.
D) H⁺ concentration across the membrane holding ATP
synthase.
E) transfer of phosphate to ADP.
Answer: D
Which metabolic pathway is common to both fermentation
and cellular respiration of a glucose molecule?
A) the citric acid cycle
B) the electron transport chain
C) glycolysis
D) synthesis of acetyl CoA from pyruvate
E) reduction of pyruvate to lactate
Answer: C
In mitochondria, exergonic redox reactions
A) are the source of energy driving prokaryotic ATP
synthesis.
B) are directly coupled to substrate-level
phosphorylation.
C) provide the energy that establishes the proton
gradient.
D) reduce carbon atoms to carbon dioxide.
E) are coupled via phosphorylated intermediates to
endergonic processes.
Answer: C
The final electron acceptor of the electron transport
chain that functions in aerobic oxidative phosphorylation is
A) oxygen.
B) water.
C) NAD⁺.
D) pyruvate.
E) ADP.
Answer: A
What is the oxidizing agent in the following reaction?
Pyruvate + NADH + H⁺ → Lactate + NAD⁺
A) oxygen
B) NADH
C) NAD⁺
D) lactate
E) pyruvate
Answer: E
When electrons flow along the electron transport chains
of mitochondria, which of the following changes occurs?
A) The pH of the matrix increases.
B) ATP synthase pumps protons by active transport.
C) The electrons gain free energy.
D) The cytochromes phosphorylate ADP to form ATP.
E) NAD⁺ is oxidized.
Answer: A
Most CO₂ from catabolism is released during
A) glycolysis.
B) the citric acid cycle.
C) lactate fermentation.
D) electron transport.
E) oxidative phosphorylation
Answer : B.
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