Deck 9: Cellular Respiration and Fermentation

A) hydrolyzed
B) hydrogenated
C) oxidized
D) reduced
E) an oxidizing agent

A) It produces much less ATP than does oxidative phosphorylation.
B) It does not involve organelles or specialized structures, does not require oxygen, and is present in most organisms.
C) It is found in prokaryotic cells but not in eukaryotic cells.
D) It relies on chemiosmosis, which is a metabolic mechanism present only in the first cells' prokaryotic cells.
E) It requires the presence of membrane-enclosed cell organelles found only in eukaryotic cells.

A) to reduce an electron acceptor molecule
B) to supply the cell with fixed carbon
C) to produce adenosine triphosphate (ATP)
D) to generate oxygen
E) to utilize glucose

A) anabolic pathways
B) catabolic pathways
C) fermentation pathways
D) thermodynamic pathways
E) bioenergetic pathways

A) early embryonic mortality
B) elevated blood-glucose levels in the dog's blood
C) an intolerance for exercise
D) a reduced life span

A) It both splits molecules and assembles molecules.
B) It attaches and detaches phosphate groups.
C) It uses glucose and generates pyruvate.
D) It shifts molecules from cytosol to mitochondrion.
E) It uses stored ATP and then forms a net increase in ATP.

A) NAD+ is reduced to NADH during glycolysis, pyruvate oxidation, and the citric acid cycle.
B) NAD+ has more chemical energy than NADH.
C) NAD+ is oxidized by the action of hydrogenases.
D) NAD+ can donate electrons for use in oxidative phosphorylation.
E) In the absence of NAD+, glycolysis can still function.

A) two molecules of ATP are used and two molecules of ATP are produced.
B) two molecules of ATP are used and four molecules of ATP are produced.
C) four molecules of ATP are used and two molecules of ATP are produced.
D) two molecules of ATP are used and six molecules of ATP are produced.
E) six molecules of ATP are used and six molecules of ATP are produced.

A) transferred to ADP, forming ATP
B) transferred directly to ATP
C) retained in the two pyruvates
D) stored in the NADH produced
E) used to phosphorylate fructose to form fructose 6-phosphate

A) an agent that reacts with oxygen and depletes its concentration in the cell
B) an agent that binds to pyruvate and inactivates it
C) an agent that closely mimics the structure of glucose but is not metabolized
D) an agent that reacts with NADH and oxidizes it to NAD+
E) an agent that blocks the passage of electrons along the electron transport chain

A) gains electrons and gains potential energy
B) loses electrons and loses potential energy
C) gains electrons and loses potential energy
D) loses electrons and gains potential energy
E) neither gains nor loses electrons but gains or loses potential energy

A) electron transport
B) glycolysis
C) the citric acid cycle
D) oxidative phosphorylation
E) chemiosmosis

A) 2 NAD+, 2 pyruvate, and 2 ATP
B) 2 NADH, 2 pyruvate, and 2 ATP
C) 2 FADH2, 2 pyruvate, and 4 ATP
D) 6 CO2, 2 pyruvate, and 2 ATP
E) 6 CO2, 2 pyruvate, and 30 ATP

A) CO2 and H2O
B) CO2 and pyruvate
C) NADH and pyruvate
D) CO2 and NADH
E) H2O, FADH2, and citrate

A) water
B) polar molecules
C) molecules with high potential energy
D) molecules with low potential energy
E) molecules in an excited state

A) C6H12O6 is oxidized and O2 is reduced.
B) O2 is oxidized and H2O is reduced.
C) CO2 is reduced and O2 is oxidized.
D) C6H12O6 is reduced and CO2 is oxidized.
E) O2 is reduced and CO2 is oxidized.

A) C-H bonds
B) C-N bonds
C) number of oxygen atoms
D) polar structure

A) 0 percent
B) 2 percent
C) 10 percent
D) 38 percent
E) 100 percent

A) 1
B) 3
C) 6
D) 12
E) 30

A) the breakdown of glucose into two pyruvate molecules
B) the breakdown of an acetyl group to carbon dioxide
C) the extraction of energy from high-energy electrons remaining from glycolysis and the citric acid cycle
D) substrate-level phosphorylation

A) yield energy in the form of ATP as it is passed down the respiratory chain
B) act as an acceptor for electrons and hydrogen, forming water
C) combine with carbon, forming CO2
D) combine with lactate, forming pyruvate
E) catalyze the reactions of glycolysis

A) The hydrogen ions (protons) are transferred to oxygen in an energy-releasing reaction.
B) The translocation of protons sets up the electrochemical gradient that drives ATP synthesis in the mitochondria.
C) The protons pick up electrons from the electron transport chain on their way through the inner mitochondrial membrane.
D) The protons receive electrons from the NAD+ and FAD that are accepted by electrons in glycolysis and the citric acid cycle.

A) glycolysis
B) accepting electrons at the end of the electron transport chain
C) the citric acid cycle
D) the oxidation of pyruvate to acetyl CoA
E) the phosphorylation of ADP to form ATP

A) low; activated
B) low; inhibited
C) high; activated
D) high; inhibited

A) NAD+ only
B) NADH and FADH2
C) the electron transport chain
D) ADP and ATP

A) Ubiquinone is a protein that begins the electron transport chain, so it accepts the highest-energy electrons.
B) Ubiquinone is a protein that serves as a regulator of the rate of redox reactions in the electron transport chain.
C) Ubiquinone is a protein that is a constituent of all cells, prokaryotic or eukaryotic; hence its name, originating from "ubiquitous."
D) Ubiquinone is not a protein, is lipid soluble, and can move through the inner mitochondrial membrane.

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

A) during glycolysis
B) in the citric acid cycle
C) during fermentation
D) in the electron transport chain

A) Glycolysis is inhibited when cellular energy levels are abundant.
B) Citric acid cycle activity is dependent solely on availability of substrate; otherwise, it is unregulated.
C) In the electron transport chain, electrons decrease in energy level as they are transferred from one electron carrier to the next.
D) Reactions of the citric acid cycle take place in the mitochondrial matrix.

A) directly enter the electron transport chain
B) directly enter the energy-yielding stages of glycolysis
C) are directly decarboxylated by pyruvate dehydrogenase
D) directly enter the citric acid cycle

A) There would be no change in ATP production, but we would observe an increased rate of carbon dioxide production.
B) The rates of ATP production and carbon dioxide production would both increase.
C) The rate of ATP production would decrease, but the rate of carbon dioxide production would increase.
D) Rates of ATP and carbon dioxide production would probably both decrease.

A) cytosol
B) mitochondrial outer membrane
C) mitochondrial inner membrane
D) mitochondrial intermembrane space
E) mitochondrial matrix

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.

A) photosynthetic cells in the light, while photosynthesis occurs concurrently
B) nonphotosynthesizing cells only
C) cells that are storing glucose only
D) all cells all the time
E) photosynthesizing cells in the light and in other tissues in the dark

A) acetyl CoA
B) glucose
C) pyruvate
D) NADH

A) inhibit the enzyme and thus slow the rates of glycolysis and the citric acid cycle.
B) activate the enzyme and thus slow the rates of glycolysis and the citric acid cycle.
C) inhibit the enzyme and thus increase the rates of glycolysis and the citric acid cycle.
D) activate the enzyme and thus increase the rates of glycolysis and the citric acid cycle.
E) inhibit the enzyme and thus increase the rate of glycolysis and the concentration of citrate.

A) glycolysis and the oxidation of pyruvate to acetyl CoA
B) oxidation of pyruvate to acetyl CoA and the citric acid cycle
C) the citric acid cycle and oxidative phosphorylation
D) oxidative phosphorylation and fermentation
E) fermentation and glycolysis

A) GDP is phosphorylated to produce GTP
B) NAD+ is phosphorylated to NADH
C) oxaloacetate is phosphorylated
D) acetylation of oxaloacetate takes place

A) glycolysis → NADH → oxidative phosphorylation → ATP → oxygen
B) citric acid cycle → FADH2 → electron transport chain → ATP
C) electron transport chain → citric acid cycle → ATP → oxygen
D) pyruvate → citric acid cycle → ATP → NADH → oxygen
E) citric acid cycle → NADH → electron transport chain → oxygen

A) all of the electron transport proteins and 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 used by bacteria for respiration

A) glycolysis
B) fermentation
C) oxidation of pyruvate to acetyl CoA
D) citric acid cycle
E) oxidative phosphorylation (chemiosmosis)

A) It allows for an increased rate of glycolysis.
B) It allows for an increased rate of the citric acid cycle.
C) It increases the surface for oxidative phosphorylation.
D) It increases the surface for substrate-level phosphorylation.
E) It allows the liver cell to have more peroxisomes.

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

A) the oxidation of pyruvate to acetyl CoA
B) the citric acid cycle
C) oxidative phosphorylation
D) glycolysis
E) chemiosmosis

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

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.

A) become acidic inside the vesicles when NADH is added
B) become alkaline inside the vesicles when NADH is added
C) make ATP from ADP and i if transferred to a pH 4 buffered solution after incubation in a pH 7 buffered solution
D) hydrolyze ATP to pump protons out of the interior of the vesicle to the exterior
E) reverse electron flow to generate NADH from NAD+ in the absence of oxygen

A) Electrons are transferred to ADP to generate ATP at each step in the process.
B) Each electron carrier alternates between being reduced and being oxidized.
C) ATP is generated at each step of the process.
D) Energy of the electrons increases at each step of the process.
E) Molecules in the chain give up some of their potential energy.

A) active transport
B) an endergonic reaction coupled to an exergonic reaction
C) a reaction with a positive ΔG
D) osmosis
E) allosteric regulation

A) the electron transport chain
B) substrate-level phosphorylation
C) chemiosmosis
D) oxidative phosphorylation
E) aerobic respiration

A) all cells but only in the presence of oxygen
B) only eukaryotic cells, in the presence of oxygen
C) only in mitochondria, using either oxygen or other electron acceptors
D) all respiring cells, both prokaryotic and eukaryotic, using either oxygen or other electron acceptors
E) all cells, in the absence of respiration

A) must use a molecule other than oxygen to accept electrons from the electron transport chain
B) is a normal eukaryotic organism
C) is photosynthetic
D) is an anaerobic organism
E) is a facultative anaerobe

A) be unable to grow anaerobically
B) grow anaerobically only when given glucose
C) be unable to metabolize glucose
D) die because they cannot regenerate NAD+ from NAD
E) metabolize only fatty acids

A) oxygen
B) water
C) NAD+
D) pyruvate
E) ADP

A) glycolysis and fermentation
B) fermentation and chemiosmosis
C) oxidation of pyruvate to acetyl CoA
D) citric acid cycle
E) oxidative phosphorylation

A) ATP, CO2, and ethanol (ethyl alcohol)
B) ATP, CO2, and lactate
C) ATP, NADH, and pyruvate
D) ATP, pyruvate, and oxygen
E) ATP, pyruvate, and acetyl CoA

A) glucose
B) ethanol
C) pyruvate
D) lactic acid
E) either ethanol or lactic acid

A) They produce alcohol, which enhances the permeability of their mitochondrial membranes to proton translocation.
B) They regenerate NAD+ so that glycolysis can continue to operate.
C) They allow the cell to conserve oxygen for the citric acid cycle.
D) They generate oxygen.

A) cytosol
B) mitochondrial outer membrane
C) mitochondrial inner membrane
D) mitochondrial intermembrane space
E) mitochondrial matrix

A) glucose
B) proteins
C) fatty acids
D) glucose, proteins, and fatty acids
E) Such yeast cells will not be capable of catabolizing any food molecules and, therefore, will die.