All AP Biology Resources
Example Questions
Example Question #1 : Understanding The Electron Transport Chain
How many potential ATP can be produced when one molecule of glyceraldehyde-3-phosphate is put through glycolysis?
4
2.5
2
4.5
3.5
3.5
Glyceraldehyde-3-phosphate is converted to 1,3-bisphosphoglycerate, and one NADH is also produced during that step. NADH enters the electron transport chain, and is therefore worth ATP. Normally, an NADH is worth about 2.5 ATP; however, an NADH produced in glycolysis is only worth 1.5 ATP because it costs 1 ATP to move that NADH from the cytoplasm into the mitochondria. So, in this first step, we have a total of 1.5 ATP.
As the molecule continues on its path to become pyruvate, it will also produce two ATP directly; therefore, we have a net total of 3.5 potential ATP.
Example Question #4 : Understanding The Electron Transport Chain
What happens to the electron transport chain when oxygen is not available?
Oxidative phosphorylation will utilize carbon dioxide instead of oxygen
Oxidative phosphorylation ceases and the cell reverts to fermentation after glycolysis
Oxidative phosphorylation utilizes alternative fuel sources, such as fats
Oxidative phosphorylation can continue without any noticeable impact
Oxidative phosphorylation will produce oxygen from available carbon dioxide
Oxidative phosphorylation ceases and the cell reverts to fermentation after glycolysis
Oxygen is the final electron acceptor in the electron transport chain, which allows for oxidative phosphorylation. Without oxygen, the electrons will be backed up, eventually causing the electron transport chain to halt. This will cause the products of glycolysis to go through fermentation instead of going to the citric acid cycle. Without oxygen, oxidative phosphorylation (the electron transport chain) is impossible, but substrate-level phosphorylation (glycolysis) continues.
Example Question #5 : Understanding The Electron Transport Chain
Most of the ATP produced in cellular respiration comes from which of the following processes?
Glycolysis
Citric acid cycle
Oxidative phosphorylation
Substrate-level phosphorylation
Krebs cycle
Oxidative phosphorylation
Cellular respiration typically follows three steps, under aerobic conditions. Glycolysis generates NADH and converts glucose to pyruvate, while producing small amounts of ATP through substrate-level phosphorylation. The citric acids cycle, or Krebs cycle, uses pyruvate to generate more NADH and FADH2. These NADH and FADH2 molecules donate electrons to the electron transport chain, which are used to pump protons into the intermembrane space of the mitochondrion. The protons in the intermembrane space then flow through ATP synthase to generate large amounts of ATP via oxidative phosphorylation.
Example Question #6 : Understanding The Electron Transport Chain
Why is oxygen essential for the electron transport chain?
It serves as the primary electron donor
It serves as the terminal electron acceptor
It is essential for transporting pyruvate into the mitochondria
It is part of the chemiosmotic gradient
It serves as the terminal electron acceptor
Oxygen serves as the terminal electron acceptor for the electron transport chain. Electrons are donated by NADH molecules and passed through several different proteins to generate the proton gradient in the intermembrane space. Upon reaching the final protein, the electron is bonded to an oxygen molecule to create water. Without oxygen, there would be nowhere for the electrons to go after being pumped through the electron transport chain, and aerobic cellular respiration would be impossible.
Example Question #2 : Understanding The Electron Transport Chain
Which of the following processes requires an electron acceptor?
The citric acid cycle requires an oxygen electron acceptor
The electron transport chain requires a nitrogen electron acceptor
Glycolysis requires a nitrogen electron acceptor
The electron transport chain requires an oxygen electron acceptor
The electron transport chain requires an oxygen electron acceptor
Oxygen acts as the terminal electron acceptor in the electron transport chain (ETC). This accounts for the reason as to why, when cells are starved of oxygen, the ETC "backs up" and the cell will divert to using anaerobic respiration, such as fermentation. At the end of the electron transport chain, the electron and a proton are passed to an oxygen molecule to produce water.
The citric acid cycle depends on oxygen in an indirect sense. The main purpose of the cycle is to produce electron donors for the electron transport chain. If the chain is not functional (due to lack of oxygen), the citric acid cycle also stops functioning. Glycolysis is not dependent on oxygen, and can function in anaerobic environments.
Example Question #8 : Understanding The Electron Transport Chain
The chemical compound 2,4-dinitrophenol can disrupt the process of oxidative phosphorylation in the mitchondrial electron transport chain by causing which effect?
Dispersion of the proton gradient
Binding to ubiquinone
Binding to nucleotide carriers
Removing the F0 subunit from the ATP synthase complex
Oxidative inhibition
Dispersion of the proton gradient
In ATP synthesis, the proton gradient is an interconvertible form of energy in electron transport. 2,4-dinitrophenol is an inhibitor of ATP production in cells with mitochondria. Its mechanism of action involves carrying protons across the mitochondrial membrane, which leads to the consumption of energy without ATP production.
The other answer choices are not directly related to the generation of the proton gradient.
Example Question #3 : Understanding The Electron Transport Chain
If cellular respiration were 100% efficient, the process should produce around eighty ATP, however, the actual yield is around thirty ATP. What happens to the rest of the chemical energy in glucose?
It is released as carbon dioxide and water
It is converted to heat
It is converted to starch
It is used to make water from hydrogen ions and oxygen
It is stored as fat
It is converted to heat
Cellular respiration is only about 38% efficient, with the rest of the energy in glucose lost as heat.
Water and carbon dioxide are not used to store energy. Fats can be synthesized from acetyl CoA and glycerol, but are not generally created in large quantities during cellular respiration. Starches are generally used for energy storage in plants, but can be synthesized from glucose; however, starches are not a standard product of cellular respiration.
Most of the reactions in cellular respiration are exothermic, in order to support spontaneous reaction. The result is release of heat energy with most steps.
Example Question #10 : Understanding The Electron Transport Chain
Along what structure do electrons in the electron transport chain (ETC) move?
The inner membrane of the mitochondria
The mitochondrial matrix
The cytoplasm
The outer membrane of the mitochondria
The inner membrane of the mitochondria
The events of the electron transport chain take place on the inner membrane of the mitochondria. The transmembrane proteins used to shuttle electrons through the electron transport chain are embedded on the inner membrane. Electrons are donated to these proteins and used to transfer protons into the intermembrane space from the matrix. After reaching the final inner membrane protein in the chain, the electron is transferred to oxygen to form water.
The mitochondrial matrix is where the ATP eventually is eventually synthesized, as well as the site of the citric acid cycle. The cytoplasm is the site of glycolysis. The outer mitochondrial membrane is not directly involved in cellular respiration.
Example Question #11 : Understanding The Electron Transport Chain
What is the function of the molecules NADH and FADH2 during the electron transport chain (ETC)?
Donate electrons to electron transport proteins
They are products of glycolysis and the Krebs cycle and are not used by the electron transport chain
Accept electrons at the end of the electron transport chain
Directly synthesize ATP
Donate electrons to electron transport proteins
NADH and FADH2 are electron carriers that have the important function of actually bringing electrons to the electron transport chain. Proteins embedded in the inner membrane of the mitochondria oxidize these molecules. The proteins then transfer the electrons through a series of processes in order to pump protons into the intermembrane space, creating an electrochemical gradient. The final protein in the chain passes the electron to an oxygen molecule to generate water, and the protons in the intermembrane space can then be used to drive the function of ATP synthase to create ATP/
NADH and FADH2 are not directly involved in ATP synthesis and oxygen is the ultimate electron acceptor in the electron transport chain.
Example Question #12 : Understanding The Electron Transport Chain
ATP synthase is found in the region of mitochondria with the highest concentration of __________.
carbohydrates
lipids
proteins
nucleic acids
lipids
ATP synthase is an enzyme that facilitates the generation of energy (ATP) in cells. It uses the proton gradient created by the electron transport chain to create ATP through oxidative phosphorylation. ATP synthase is an integral membrane protein in the inner membrane of mitochondria. Recall that all membranes are mostly made up of phospholipids (a type of lipid).