biochem ch13
The citric acid cycle oxidizes pyruvate, and some of the pathway
intermediates are starting materials for many biosynthetic pathways.
This means that the citric acid cycle is ________.
A)
amplifying
B) catabolic
C) anabolic
D) amphibolic
D
Compounds like succinate, fumarate and α-ketoglutarate have a
catalytic effect on the consumption of oxygen in a cell suspension.
The rate of oxygen consumption is far more than that required for
their own oxidation. This is evidence that ________.
A) they are
intermediates in glycolysis
B) they act as enzymes to cause the
oxidation of other compounds
C) they are involved in a cyclic
pathway
D) they must be cofactors for enzymes that are oxidoreductases
C
Why were muscle cells and extracts the best choice for Krebs, Johnson
and Szent-Györgyi to elucidate the cyclic nature of the citric acid
cycle?
A) The reactions of the cycle in muscle cells are more
highly regulated, and therefore easier to study, than in other
tissues.
B) Muscle cells have an unusually high concentration of
the starting material, pyruvate.
C) In muscle the cycle
intermediates are used almost exclusively for energy metabolism by the
cycle and not for other reactions.
D) Muscle cells can more
easily uptake oxygen than other cells, so monitoring the consumption
of oxygen is easier for these cells
C
The net effect of the eight steps of the citric acid cycle is
to
A) completely oxidize an acetyl group to carbon
dioxide.
B) convert pyruvate to succinate.
C) produce NAD+
and Q.
D) produce 8 ATP for every pass through the cycle
A
In eukaryotes the enzymes of the citric acid cycle are found in the
________.
A) cytosol
B) mitochondria
C) nucleus
D) endoplasmic reticulum
B
The order of prosthetic groups as they act in the three proteins of
the PDH(pyruvate dehydrogenase) complex is:
A) FAD → thiamine
pyrophosphate → NAD+
B) FAD → thiamine pyrophosphate →
dihydrolipoamide
C) thiamine pyrophosphate → dihydrolipoamide →
FAD
D) NAD+ → FAD → dihydrolipoamide
C
The arrangement of subunits in the PDH(pyruvate dehydrogenase)
complex ensures that ________.
A) ATP is formed
B) the
product of one enzyme is delivered to the next in turn
C) the
dihydrolipoamide arm can react with NAD+
D) acetyl CoA enters
into the series of reactions
B
Some bacteria and anaerobic eukaryotes not using PDH(pyruvate
dehydrogenase) form acetyl CoA and CO2 from pyruvate with
________.
A) PDH modified with methyl groups
B)
pyruvate:ferredoxin oxidoreductase
C) 2-oxoacid
dehydrogenase
D) an isoenzyme of PDH
B
Pyruvate passes through the outer mitochondrial membrane by ________.
A) porin proteins
B) passive transport
C) pyruvate
translocase
D) simple diffusion through the lipid bilayer
A
The enzyme pyruvate translocase is located ________.
A) in the
cytosol
B) in the inner mitochondrial membrane
C) in the
mitochondrial matrix
D) in the endoplasmic reticulum
B
Pyruvate translocase is a(n) ________ protein that transports
________.
A) antiport; pyruvate and H+ in opposite directions
B) uniport; only pyruvate
C) symport; pyruvate and H+ in
the same direction
D) antiport; pyruvate and CO2 in opposite directions
C
Which is not a component of the pyruvate dehydrogenase complex?
A) Dihydrolipoamide dehydrogenase.
B) Isocitrate
dehydrogenase.
C) Pyruvate dehydrogenase.
D)
Dihydrolipoamide acetyltransferase
B
Which cofactor is not used by the pyruvate dehydrogenase complex?
A) Lipoamide.
B) Thiamine pyrophosphate.
C) FAD.
D) QH2.
D
Which carbon atom(s) of pyruvate is(are) first converted to carbon
dioxide by pyruvate dehydrogenase complex?
A) The carboxylate
carbon (#1).
B) The carbonyl carbon (#2).
C) The methyl
carbon (#3).
D) Both carbons #1 and #3 in equal amounts.
A
Pyruvate dehydrogenase kinase catalyzes
A) the
dephosphorylation and activation of E1.
B) the dephosphorylation
and inactivation of E1.
C) the phosphorylation and inactivation
of E1.
D) the phosphorylation and activation of E1
C
The pyruvate dehydrogenase complex is larger than a ribosome. In
bacteria these complexes are located in the cytosol while they are
found in ________ of eukaryotes
A) cell membranes
B)
mitochondrial membranes
C) mitochondrial matrices
D) nuclei
C
A deficiency in thiamine causes the disease beriberi. Which might you
expect to have a higher than normal blood concentration in an
individual with this condition?
A) Isocitrate.
B)
Pyruvate.
C) Oxaloacetate.
D) Acetyl CoA
B
Most of the energy released in citric acid cycle reactions is
conserved in ________.
A) GTP
B) ATP
C) NADH and
QH2
D) ADP
C
What are the fewest number of turns of the citric acid cycle needed
before carbon radioactive in both carbons of the acetyl group in
acetyl Co A are incorporated into all 4 carbons in every molecule of
oxaloacetate produced?
A) 1
B) 2
C) 3
D) none
C
When energy-rich acetyl CoA is oxidized to carbon dioxide, eight
electrons are released. Most often, electrons are released in such
reactions because
A) double bonds formed in CO2 share electron
pairs.
B) there are more electrons in the reactants than in the
products.
C) water is not available in the reaction.
D) an
electron acceptor is linked to the reaction.
A
Citrate can react asymmetrically in the citric acid cycle because the
enzyme aconitase
A) binds citrate asymmetrically.
B) binds
either form of citrate.
C) binds both forms of
isocitrate.
D) does not distinguish the -CH2COO- group
A
What type of reaction is the conversion of fumarate to
malate?
A) Oxidative decarboxylation.
B) Hydration.
C)
Dehydrogenation.
D) Condensation
B
Carbons from acetyl CoA are transferred to the citric acid cycle.
Which is the first round of the citric acid cycle that could possibly
release a carbon atom originating from this acetyl CoA?
A) First
round.
B) Second round.
C) Third round.
D) Fourth round
B
Which enzyme is the same in both the pyruvate dehydrogenase and
α-ketoglutarate complexes?
A) Dihydrolipoamide dehydrogenase.
B) Aconitase.
C) Pyruvate decarboxylase.
D) The two
complexes have no components that are similar.
A
Which step in the citric acid cycle is a rearrangement reaction?
A) Succinyl CoA to succinate.
B) Fumarate to L-malate.
C) Citrate to isocitrate.
D) Glucose 1,6-bisphosphate to
fructose 1,6-bisphosphate
C
Which is not produced by the citric acid cycle?
A) NADH
B) FMN
C) CO2
D) QH2
B
Which enzyme does not catalyze a reaction that releases carbon
dioxide?
A) α-ketoglutarate dehydrogenase complex.
B)
Pyruvate dehydrogenase.
C) Malate dehydrogenase.
D)
Isocitrate dehydrogenase
C
After passing through pyruvate dehydrogenase and the citric acid
cycle, one mole of pyruvate will result in the formation of ________
moles of carbon dioxide and ________ mole(s) of ATP (or GTP).
A)
2; 2
B) 2; 1
C) 3; 2
D) 3; 1
D
Which statement is true about lactate dehydrogenase and malate
dehydrogenase?
A) Both enzymes are highly specific for their own
substrates.
B) A single amino acid change can convert lactate
dehydrogenase to a malate dehydrogenase.
C) The naturally
occurring enzymes do not have much sequence similarity, but do have
closely related three-dimensional structures.
D) All of the above
D
Which intermediate of the citric acid cycle has a plane of symmetry?
A) Succinate.
B) Citrate.
C) Succinyl CoA.
D) α-ketoglutarate
A
The step at which acetyl CoA enters the citric acid cycle is
classified as a ________ reaction.
A) condensation
B)
substrate-level phosphorylation
C) decarboxylation
D) dehydrogenation
A
Which enzyme catalyzes the conversion of citrate to isocitrate?
A) Aldolase.
B) Citrate synthase.
C) Citrate
isomerase.
D) Aconitase
D
Which 5-carbon intermediate of the citric acid cycle is converted to
a 4-carbon molecule with the release of carbon dioxide?
A)
Fumarase.
B) α-ketoglutarate.
C) Succinate.
D) Isocitrate
B
A carbon atom that has single bond to four substituents with exactly
two of the four substituents identical is called a ________.
A)
prochiral carbon atom
B) tetrahedral stereocenter
C)
divalent carbon atom
D) anomeric carbon atom
A
Which of the following enzymatic reactions are examples of substrate
level phosphorylation?
A) Succinyl Co-A synthetase.
B)
Pyruvate kinase.
C) Phosphoglycerate kinase.
D) All of the above
D
During catalysis, succinyl CoA synthetase generates
A) an
energy deficient, unstable phosphoenzyme intermediate.
B) an
energy rich, unstable phosphoenzyme intermediate.
C) an energy
rich, stable phosphoenzyme intermediate.
D) All of the above.
C
The succinate dehydrogenase complex catalyzes
A) the formation
of a single hydrogen bond in the oxidation of succinate to
fumarate.
B) the formation of a double bond in the oxidation of
succinate to fumarate.
C) Both A and B.
D) None of the above
B
The succinate dehydrogenase reaction is unusual for a dehydrogenase
because it uses ________ as an electron acceptor (oxidizing agent)
that is regenerated by ubiquinone.
A) ATP
B) NADP
C)
Malonate
D) FAD
D
Which of the following is/are true statements about the succinate
dehydrogenase reactions?
A) It is stereospecific.
B) Only
the cis-isomer of the product is formed.
C) It is not
stereospecific.
D) Both B and C
A
Which of the following are components of the succinate dehydrogenase
complex?
A) FAD prosthetic group.
B) Iron-sulfur clusters.
C) Malonate.
D) All of the above.
E) A and B only
E
When fumarate is positioned in the active site of fumarase, the
double bond of the substrate can be attacked from only one side.
Therefore, fumarate is a ________ molecule.
A) asymmetric
B)
prochiral
C) isomeric
D) duplicate
B
Malonate
A) is a structural analog of succinate.
B) binds
to the substrate-binding site of the succinate dehydrogenase complex
but does not react.
C) undergoes an oxidation reaction.
D)
Both A and B.
E) All of the above
D
Aqueous channels in cell membranes that small molecules such as
pyruvate can pass through are formed by transmembrane proteins
called
A) openings.
B) porins.
C) pores.
D) locase
B
Metabolites moved across the mitochondrial membrane by transporters
include
A) pyruvate.
B) PEP.
C) citrate and
malate.
D) All of the above.
D
What is the role of mitochondrial PEPCK?
A) It converts
oxaloacetate to PEP, which can then be transported to the
cytoplasm.
B) It aids in the transport of pyruvate across the
inner mitochondrial membrane.
C) It converts oxaloacetate to
malate, which feeds into the malate-aspartate shuttle.
D) It
converts acetyl CoA to citrate, which can then be transported to the cytoplasm.
A
NAD-dependent malate dehydrogenase
A) catalyzes the oxidation
of malate to regenerate oxaloacetate.
B) catalyzes the conversion
of fumarase to malate.
C) catalyzes a reaction which results in
the formation of an NADH molecule.
D) All of the above.
E)
A and C only.
E
The pyruvate dehydrogenase complex is located inside mitochondria .
Pyruvate is formed by glycolysis in the cytoplasm. Pyruvate is brought
into the mitochondrion by
A) diffusion.
B) TCA
transporter.
C) PEP transporter.
D) Pyruvate transporter
D
About how many total ATP equivalents are generated by the complete
oxidation of one molecule of acetyl CoA?
A) 1.5
B)
2.5
C) 3
D) 10
E) 30
D
Which product of the citric acid cycle produces the most ATP
equivalents?
A) NADH.
B) QH2.
C) GTP.
D) CO2
A
Which of the following inhibit(s) pyruvate dehydrogenase kinase?
A) Pyruvate.
B) NADH.
C) Acetyl-CoA.
D) All of
the above
A
Pyruvate dehydrogenase is inactivated by phosphorylation. This can be
prevented by a chemical, dichloroacetate, and this disrupts many
cancer cells because they are
A) aerobic.
B)
anaerobic.
C) fast growing.
D) non-fermenting
B
Mammalian pyruvate dehydrogenase is inactivated when pyruvate
dehydrogenase kinase is activated by
A) NADH.
B)
ADP.
C) pyruvate.
D) AMP.
A
Each of the following catalyzed reactions of the citric acid cycle
appears to be regulated except
A) citrate synthase.
B)
fumarase.
C) isocitrate dehydrogenase.
D) a-ketoglutarate
dehydrogenase complex.
B
Which of the following allosterically activates mammalian isocitrate
dehydrogenase?
A) ADP.
B) NADH.
C) calcium.
D)
All of the above.
E) A and C only
E
Each of the following leads to a biosynthetic pathway except
A)
a-ketoglutarate.
B) succinyl CoA.
C) oxaloacetate.
D)
citrate.
E) None of the above
E
Which of the following is not a fate of a citric acid cycle
intermediate?
A) A-ketoglutarate reversibly converting to
glutamate.
B) The biosynthesis of porphyrins from succinyl CoA's
interaction with glycine.
C) Oxaloacetate as a carbohydrate
precursor.
D) None of the above.
D
A metabolic pathway that is both catabolic and anabolic is ________.
An example of such a pathway is ________.
A) ambibolic;
glycolysis
B) amphibolic; the citric acid cycle
C)
duplibolic; the pentose phosphate pathway
D) Pathways cannot be
both anabolic and catabolic, so there are no example
pathways.
Answer: B
B
The glyoxylate cycle is
A) a catabolic pathway in plants and
some microorganisms.
B) an anabolic pathway in plants and some
microorganisms.
C) regarded as a shunt within the citric acid
cycle.
D) A and C only.
E) B and C only
E
The following enzyme(s) is/are unique to the glyoxylate
cycle:
A) Malate synthase.
B) Malate dehydrogenase.
C) Isocitrate lyase.
D) All of the above.
E) A and C only.
E
True statements about the glyoxylate cycle include
A) four
carbon atoms of the acetyl group of acetyl CoA are released as carbon
dioxide during operation of the glyoxylate cycle.
B) the net
formation of a four carbon molecule from two acetyl CoA molecules
supplies a precursor that can be converted to glucose.
C) the
reaction catalyzed by malate synthase is the first bypass enzyme of
the glyoxylate cycle.
D) it is inactive in oily seed plants
B
The glyoxylate cycle leads from two carbon compounds to glucose in
each organism below except
A) animals.
B) plants.
C)
bacteria.
D) yeast.
E) None of the above.
A
Which statement is false about the glyoxylate cycle?
A) In
mammals the glyoxylate cycle is used to replenish citric acid cycle
intermediates.
B) It is an anabolic alternative for the
metabolism of acetyl CoA.
C) It can be regarded as a shunt in the
citric acid cycle.
D) In eukaryotes, metabolites must be
transferred from the mitochondria to the cytosol to be used in the
glyoxylate cycle.
A
Which process is not implicated in the evolution of the citric acid
cycle pathway?
A) Gene duplication.
B) Palindromic
inversion.
C) Pathway extension.
D) Pathway
reversal.
E) Enzyme theft
B