AP Biology : Cellular Respiration

Study concepts, example questions & explanations for AP Biology

varsity tutors app store varsity tutors android store

Example Questions

Example Question #12 : Understanding The Electron Transport Chain

What happens when electrons get transported along the electron transport chain?

Possible Answers:

It produces a proton gradient that helps generate ATP using substrate-level phosphorylation

Protons are pumped into the intermembrane space

Electrons are transferred from a protein of high electron affinity to a protein of low electron affinity

Protons are pumped into the matrix

Correct answer:

Protons are pumped into the intermembrane space

Explanation:

When electrons go through the electron transport chain, the protons in the matrix of the mitochondrion are pumped into the intermembrane space (the space between inner and outer membranes). This creates a proton gradient that is used by ATP synthase to create ATP through oxidative phosphorylation, not substrate-level phosphorylation. Remember that substrate-level phosphorylation is used by glycolysis and the Krebs cycle to generate ATP.

When electrons travel down the series of molecules in the electron transport chain they go from molecules of low electron affinity to molecules high electron affinity. The next molecule in the series must have higher affinity so that it can pull the electron away from its predecessor.

Example Question #12 : Understanding The Electron Transport Chain

What is the final electron acceptor in the electron transport chain?

Possible Answers:

NADH

Water

Oxygen

CO2

Correct answer:

Oxygen

Explanation:

Electrons from electron carriers, such as NADH and FADH2, go through the electron transport chain, which involves a series of molecules that accept and donate electrons. Transfer to the electron through these proteins results in the net movement of protons across the inner mitochondrial membrane and into the intermembrane space, generating the proton gradient that will drive ATP synthase.

The final molecule in the electron transport chain is oxygen. The oxygen molecule accepts the electron from the final protein in the chain and becomes water, one of the final products of metabolism. Remember that each subsequent molecule in the electron transport chain has a higher affinity for electrons than the molecule before it; therefore, the final electron acceptor will have the highest affinity for electrons. Oxygen has a very high electronegativity, making it a good electron acceptor.

Example Question #11 : Understanding The Electron Transport Chain

How does the cell generate the required energy to synthesize ATP from the electron transport chain?

Possible Answers:

Other metabolic pathways, such as glycogenolysis, provide energy

Hydrolysis of GTP provides chemical energy by breaking phosphate bonds

Protons are pumped into the intermembrane space as electrons travel down the electron transport chain, generating a chemiosmotic gradient

Energy is captured as the electrons travel down the electron transport chain, providing enough energy to synthesize ATP

Correct answer:

Protons are pumped into the intermembrane space as electrons travel down the electron transport chain, generating a chemiosmotic gradient

Explanation:

The direct purpose of moving electrons down the electron transport chain is to pump protons (hydrogen ions) into the intermembrane space. This creates a chemiosmotic gradient that the cell uses to generate ATP by selectively allowing hydrogen ions to move back into the mitochondrial matrix.

Energy is not directly captured as electrons travel down the electron transport chain to synthesize ATP. GTP is a product of the Krebs cycle and can be used to generate cellular energy, but is not involved in synthesizing ATP or the electron transport chain. Other metabolic processes are often used to regulate glucose concentrations in the blood, indirectly influencing the rate of glycolysis and cellular respiration, but these processes do not directly provide energy for the electron transport chain.

Example Question #12 : Understanding The Electron Transport Chain

Dinitrophenol (DNP) is a known uncoupling agent, which is capable of inhibiting the mitochondria's ability to maintain a proton gradient. How might this affect the function of the mitochondria?

Possible Answers:

Increased NADH production

Increased ATP production

Increased FADH2 production

No change to ATP production

Decreased ATP production

Correct answer:

Decreased ATP production

Explanation:

ATP synthase, the enzyme responsible for ATP production on the inner mitochondrial membrane, depends on the proton gradient produced by the electron transport chain (ETC). If the proton gradient is disrupted, not as many ATP can be produced.

NADH and FADH2 are essential to the function of the electron transport chain as electron donors, and are produced during glycolysis and the Krebs cycle to facilitate this process. Electron donation from these compounds is what fuels the formation of the proton gradient, while decreases in these compounds can cause uncoupling.

Example Question #91 : Cell Functions

Which of the following describes the role of chemiosmosis in cellular respiration?

Possible Answers:

Substrate-level phosphorylation generates ATP by movement of protons down their electrochemical gradient 

Substrate-level phosphorylation transports electrons between complexes I, II, III, and IV 

Glycolysis generates ATP by movement of protons down their electrochemical gradient 

Oxidative phosphorylation produces NADH

Oxidative phosphorylation generates ATP by movement of protons down their electrochemical gradient  

Correct answer:

Oxidative phosphorylation generates ATP by movement of protons down their electrochemical gradient  

Explanation:

Oxidative phosphorylation is composed of electron transport and chemiosmosis. Chemiosmosis occurs when ions cross a selectively permeable membrane down their concentration gradient. In cellular respiration, hydrogen ions (protons) move down their concentration gradient through a membrane protein to produce ATP. The gradient of protons is established by the electron transport portion of oxidative phosphorylation, which is used to transfer protons into the intermembrane space. Protein complexes I, II, III, and IV help protons to cross the membrane.

Substrate-level phosphorylation occurs during glycolysis, and does not utilize chemiosmosis.

Example Question #92 : Cell Functions

Why does a single molecule of NADH, on average, produce more ATP than a single molecule of FADH2?

Possible Answers:

More NADH is produced than FADH2 during cellular respiration

NADH stays in the mitochondrial matrix longer than FADH2

NADH donates more electrons than FADH2

FADH2 donates its electrons farther down the electron transport chain

Correct answer:

FADH2 donates its electrons farther down the electron transport chain

Explanation:

Both NADH and FADH2 donate two electrons to the electron transport chain, so theoretically they should make the same amount of ATP. However, NADH donates its electrons to complex I while FADH2 donates its electrons further "downstream" at complex II. Because complex I is a site for pumping protons into the intermembrane space, FADH2's electrons will not pump as many protons as those from NADH. This results in more ATP being generated from a single molecule of NADH than a single molecule of FADH2.

Example Question #97 : Cellular Respiration

The reason why we need glucose in our diet is to regenerate ATP from ADP. Once the body absorbs glucose, it is broken down to pyruvate via glycolysis. In the presence of oxygen, pyruvate is facilitated into the Krebs cycle within the inner mitochondrial membrane. During the Krebs cycle, protons are extracted and are then pumped into the intermembrane space of the mitochondria against its concentration gradient. Releasing protons into the intermembrane space creates a gradient between the intermembrane space and the inner mitochondrial membrane. This gradient provides the energy to regenerate the ATP from ADP by way of ATP synthase.

Which of the following best describes the primary consequence of injecting a base (eg. NaOH) into the intermembrane space of the mitochondria? 

Possible Answers:

The base will increase the ability of the ATP synthase to transform ADP to ATP because of a greater potential energy

The base will have no effect

The base will lower the ability of the ATP synthase to transform ADP to ATP because of an increased proton gradient

The base will increase the ability of the ATP synthase to transform ADP to ATP because of the presence of more molecules

The base will decrease the ability of the ATP synthase to transform ADP to ATP because of a diminished proton gradient

Correct answer:

The base will decrease the ability of the ATP synthase to transform ADP to ATP because of a diminished proton gradient

Explanation:

The Krebs cycle creates a proton gradient between the intermembrane space and the inner mitochondrial membrane. This proton gradient provides the energy necessary to drive the proton through the ATP synthase. As the protons are passively diffusing through the ATP synthase, the energy is coupled to phosphorylate ADP to ATP. If a base were injected into this space, then it would would consume these protons due to its electronegativity and decrease ATP synthase’s ability to transform ADP to ATP.

Example Question #11 : Understanding The Electron Transport Chain

The enzyme responsible for the generation of ATP through the proton potential in the inner mitochondrial membrane is known as __________.

Possible Answers:

ATP synthase

ATPase

succinate dehydrogenase

cytochrome c

aldolase

Correct answer:

ATP synthase

Explanation:

The enzyme ATP synthase uses the electromotive force generated by the unequal concentrations of protons across both sides of the membrane to attach a phosphate group to ADP, generating ATP. The passing of a proton from a high concentration to low concentration permits the formation of the ATP molecule. Cytochrome c is an enzyme embedded in the inner mitochondrial membrane, but is not directly associated with ATP synthesis. Succinate dehydrogenase and aldolase are enzymes involved in the Krebs cycle.

Example Question #21 : Understanding The Electron Transport Chain

What is the final electron acceptor in the electron transport chain?

Possible Answers:

Correct answer:

Explanation:

The final electron acceptor in the electron transport chain is oxygen. It gets reduced by accepting two electrons and two protons from the ATP synthase to form water via the following equation:

Example Question #201 : Cellular Biology

Based on the concentrations of hydrogen ions in the mitochondria, where would you expect to find the most acidic environment?

Possible Answers:

Cytoplasm

Cytoplasm

Intermembrane space

Inner mitochondrial membrane

Mitochondrial matrix

Correct answer:

Intermembrane space

Explanation:

The most acidic environment, or the lowest pH, would be found in the intermembrane space. This is because as  and  pass their electrons to the enzymes in the electron transport chain, protons are pumped into the intermembrane space. This is where a high concentration protons is generated, which is considered acidic. The low concentration of protons is generated in the mitochondrial matrix rendering it basic.

Learning Tools by Varsity Tutors