Chapter 9 Guided Reading Cellular Respiration Harvesting Chemical Energy
Fill in this summary equation for cellular respiration.
____ + 6 O2 → ____ + 6 H2O + ____
C6H12O6; 6 CO2; energy (ATP + heat)
Fill in the appropriate terms in this equation.
a. oxidized
b. reduced
c. donates (loses)
d. oxidizing agent
e. accepts (gains)
a. In the conversion of glucose and oxygen to carbon dioxide and water, which molecule becomes reduced?
b. Which molecule becomes oxidized?
c. What happens to the energy that is released in this redox reaction?
a. oxygen
b. glucose
c. Some is stored im ATP and some is released as heat.
a. NAD+ is called an ____.
b. Its reduced form is ____.
a. electron carrier (or acceptor) or oxidizing agent
b. NADH
Fill in the three stages of respiration (a-c).
Indicate whether ATP is produced by substrate-level or oxidative phosphorylation (d-f).
Label the arrows indicating electrons carried by NADH.
a. glycolysis: glucose → pyruvate (not technically considered part of cellular respiration)
b. citric acid cycle
c. oxidative phosphorylation: electron transport and chemiosmosis
d. substrate-level phosphorylation
e. substrate-level phosphorylation
f. oxidative phosphorylation
The top two arrows show electrons carried by NADH (and FADH2, another electron carrier) to the electron transport chain.
Fill in the blanks in this summary diagram of glycolysis.
a. 2 ATP
b. 2 three-carbon sugars (glyceraldehyde-3-phosphate)
c. 2 NAD+
d. 2 NADH + 2H+
e. 4 ATP
f. 2 pyruvate
Fill in the blanks in this diagram of the citric acid cycle. Balls represent carbon atoms.
a. pyruvate h. NADH + H+
b. CO2 i. CO2
c. NADH + H+ j. CO2
d. coenzyme A k. NADH + H+
e. acetyl CoA l. ATP
f. oxaloacetate m. FADH2
g. citrate n. NADH + H+
Label this diagram of oxidative phosphorylation in a mitochondrial membrane.
a. intermembrane space h. chemiosmosis
b. inner mitochondrial membrane i. 2 H+ + 1/2 O2
c. mitochondrial matrix j. H2O
d. electron transport chain k. ATP synthase
e. NADH + H+ l. ADP + ℗i
f. NAD+ m. ATP
g. FADH2
Fill in the tally for maximum ATP yield from the oxidation of one molecule of glucose to six molecules of carbon dioxide.
a. -2 f. 2
b. 4 g. 6
c. citric acid cycle h. 2
d. 32 or 34 i. 2
e. 38 j. 2
How much more ATP can be generated by respiration than by fermentation? Explain why.
Respiration yields up to 19 times more ATP than does fermentation. By oxidizing pyruvate to CO2 and passing electrons from NADH (and FADH2) through the electron transport chain, respiration can produce a maximum of 38 ATP compared to the 2 net ATP that are produced by fermentation.
This chapter describes how the catabolic pathways of glycolysis and respiration release chemical energy and store it in ATP.
Fill in the following table to summarize the major inputs and outputs of glycolysis, the citric acid cycle, oxidative phosphorylation, and fermentation. Base inputs and outputs on one glucose molecule.
See Interactive Questions 9.5, 9.6, 9.7 and 9.8.
This chapter describes how the catabolic pathways of glycolysis and respiration release chemical energy and store it in ATP.
Fill in the following table to summarize the major inputs and outputs of glycolysis, the citric acid cycle, oxidative phosphorylation, and fermentation. Base inputs and outputs on one glucose molecule.
See Interactive Questions 9.5, 9.6, 9.7 and 9.8.
This chapter describes how the catabolic pathways of glycolysis and respiration release chemical energy and store it in ATP.
Fill in the following table to summarize the major inputs and outputs of glycolysis, the citric acid cycle, oxidative phosphorylation, and fermentation. Base inputs and outputs on one glucose molecule.
See Interactive Questions 9.5, 9.6, 9.7 and 9.8.
This chapter describes how the catabolic pathways of glycolysis and respiration release chemical energy and store it in ATP.
Create a concept map to organize your understanding of oxidative phosphorylation.
When electrons move closer to a more electronegative atom,
a. energy is released.
b. energy is consumed.
c. a proton gradient is established.
d. water is produced.
e. ATP is synthesized.
a. energy is released.
In the reaction C6H12O6 + 6 O2 → 6 CO2 + 6 H20,
a. oxygen becomes reduced.
b. glucose becomes reduced.
c. oxygen becomes oxidized.
d. water is a reducing agent.
e. oxygen is a reducing agent.
a. oxygen becomes reduced.
Some prokaryotes use anaerobic respiration, a process that
a. does not involve an electron transport chain.
b. produces ATP solely by substrate-level phosphorylation.
c. uses a substance other than oxygen as the final electron acceptor.
d. does not rely on chemiosmosis for the production of ATP.
e. both a and b are correct.
c. uses a substance other than oxygen as the final electron acceptor.
Which of the following is not true of oxidative phosphorylation?
a. It produces approximately three ATP for every NADH that is oxidized.
b. It involves the redox reactions of the electron transport chain.
c. It involves an ATP synthase located in the inner mitochondrial membrane.
d. It uses oxygen as the initial electron donor.
e. It is an example of chemiosmosis.
d. It uses oxygen as the initial electron donor.
Substrate-level phosphorylation
a. involves the shifting of a phosphate group from ATP to a substrate.
b. can use NADH or FADH2 .
c. takes place on ly in the cytosol.
d. accounts for 10% of the ATP formed by fermentation.
e. is the energy source for facultative anaerobes under anaerobic conditions.
e. is the energy source for facultative anaerobes under anaerobic conditions.
The major reason that glycolysis is not as energy-productive as respiration is that
a. NAD+ is regenerated by alcohol or lactate production, without the high-energy electrons passing through the electron transport chain.
b. it is the pathway common to fermentation and respiration.
c. it does not take place in a specialized membrane-bound organelle.
d. pyruvate still contains much of the energy from glucose.
e. substrate-level phosphorylation is not as energy efficient as oxidative phosphorylation.
d. pyruvate still contains much of the energy from glucose.
Which of the following conversions represents a reduction reaction?
a. pyruvate → acetyl CoA + CO2
b. C6H12O6 → 6 CO2
c. NADH + H+ → NAD+ + 2 H
d. glucose → pyruvate
e. acetaldehyde (C2H4O) → ethanol (C2H6O)
e. acetaldehyde (C2H4O) → ethanol (C2H6O)
What is the role of oxygen in cellular respiration?
a. It is reduced in glycolysis as glucose is oxidized.
b. It provides electrons to the electron transport chain.
c. It provides the activation energy needed for oxidation to occur.
d. It is the final electron acceptor for the electron transport chain.
e. It combines with the carbon removed during the citric acid cycle to form CO2.
d. It is the final electron acceptor for the electron transport chain.
When pyruvate is converted to acetyl CoA,
a. CO2 and ATP are released.
b. a multienzyme complex removes a carboxyl group, transfers electrons to NAD+, and attaches a coenzyme.
c. one turn of the citric acid cycle is completed.
d. NAD+ is regenerated so that glycolysis can continue to produce ATP by substrate-level phosphorylation.
e. Phosphofructokinase is activated and glycolysis continues.
b. a multienzyme complex removes a carboxyl group, transfers electrons to NAD+, and attaches a coenzyme.
How many molecules of CO2 are generated for each molecule of acetyl CoA introduced into the citric acid cycle?
a. 1
b. 2
c. 3
d. 4
e. 6
b. 2
In the chemiosmotic mechanism,
a. ATP production is linked to the proton gradient established by the electron transport chain.
b. the difference in pH between the intermembrane space and the cytosol drives the formation of ATP.
c. the flow of H+ through ATP synthases from the matrix to the intermembrane space drives the phosphorylation of ADP.
d. the energy released by the reduction and subsequent oxidation of components of the electron transport chain is transferred as a phosphate to ADP.
e. the production of water in the matrix by the reduction of oxygen leads to a net flow of water of of a mitochondrion.
a. ATP production is linked to the proton gradient established by the electron transport chain.
Which of the following reactions is incorrectly paired with its location?
a. ATP synthesis — inner membrane of the mitrochondrion, matrix and cytosol.
b. fermentation — cell cytosol
c. glycolysis — cell cytosol
d. substrate-level phosphorylation — cytosol and matrix
e. citric acid cycle — cristae of mitochondrion
e. citric acid cycle — cristae of mitochondrion
When glucose is oxidized to CO2 and water, approximately 40% of its energy is transferred to
a. heat.
b. ATP.
c. acetyl CoA.
d. water.
e. the citric acid cycle.
b. ATP.
From an energetic viewpoint, what do muscle cells in oxygen deprivation gain from the reduction of pyruvate?
a. ATP
b. ATP and recycled NAD+
c. CO2 and NAD+
d. ATP, alcohol and NAD+
e. ATP and CO2
b. ATP and recycled NAD+
Glucose, made from six radioactively labeled carbon atoms, is fed to yeast cells in the absence of oxygen. How many molecules of radioactive alcohol (C2H5OH) are formed from each molecule of glucose?
a. 0
b. 1
c. 2
d. 3
e. 6
c. 2
Which of the following produces the most ATP per gram?
a. glucose, because it is the starting place for glycolysis
b. glycogen or starch, because they are polymers of glucose
c. fats, because they are highly reduced compounds
d. proteins, because of the energy stored in their tertiary structure
e. amino acids, because they can be fed directly into the citric acid cycle
c. fats, because they are highly reduced compounds
Chapter 9 Guided Reading Cellular Respiration Harvesting Chemical Energy
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