Oxidative Phosphorylation, Schemes and Mind Maps of Cell Biology

The final phase of cellular respiration is oxidative phosphorylation. Both the electron transport chain and chemiosmosis make up oxidative phosphorylation.

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Oxidative Phosphorylation 1
Oxidative Phosphorylation
How are the electrons in NADH and FADH2 used to make ATP during cellular respiration?
Why?
The final phase of cellular respiration is oxidative phosphorylation. Both the electron transport chain
and chemiosmosis make up oxidative phosphorylation. During this phase of cellular respiration, all of the
NADH and FADH2 that were produced in other phases of cellular respiration (glycolysis, the link reac-
tion, and Krebs cycle) are used to make ATP. The process occurs in the protein complexes embedded in
the inner mitochondrial membrane.
Model 1 – Electron Transport Chain
H+
H+
H+
H+
H+H+
H+
H+
H+
H+
H+
H+
H+
H+
H+H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
H+H+
H+
H+
H+
H+H+
H+
H+
H+
H+
H+
H+
H+
H+
H+
Outer
Mitochondrial
Membrane
Intermembrane
Space
Mitochondrial
Matrix
Inner
Mitochondrial
Membrane
High potential
energy electron
NADH
FADH2
2H2O
NAD+ + H+
FAD+ + 2H+O2 + 4H+
Embedded
protein channels
H+
H+H+
1. Consider the membranes illustrated in Model 1. Circle a section of the mitochondria below
where this site might be located.
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Oxidative Phosphorylation 1

Oxidative Phosphorylation

How are the electrons in NADH and FADH 2 used to make ATP during cellular respiration?

Why?

The final phase of cellular respiration is oxidative phosphorylation. Both the electron transport chain and chemiosmosis make up oxidative phosphorylation. During this phase of cellular respiration, all of the NADH and FADH 2 that were produced in other phases of cellular respiration (glycolysis, the link reac- tion, and Krebs cycle) are used to make ATP. The process occurs in the protein complexes embedded in the inner mitochondrial membrane.

Model 1 – Electron Transport Chain

H+ H+ H+ H+ H +^ H + H + H+ H + H+ H + H+ H+ H + H +^ H + H+ H + H + H + H+ H+ H + H+ H + H + H+ H + H+ H +^ H + H + H+ H + H +^ H + H+ H+ H + H+ H+ H+ H+ H + H+ Outer Mitochondrial Membrane Intermembrane Space Mitochondrial Matrix Inner Mitochondrial Membrane High potential energy electron NADH FADH 2 NAD+^ + H+ 2H^2 O FAD+^ + 2H+^ O^2 + 4H+ Embedded protein channels H+^ H+ H +

  1. Consider the membranes illustrated in Model 1. Circle a section of the mitochondria below where this site might be located.

2 POGIL™^ Activities for AP* Biology

  1. Refer to Model 1. a. Describe the region in Model 1 where the highest concentration of hydrogen ion (H+) is located. b. According to Model 1, how do the hydrogen ions reach this area?
  2. Explain why energy is required to move the hydrogen ions across the membrane in the direction indicated in Model 1.
  3. High potential energy electrons provide the energy necessary to pump hydrogen ions across the inner mitochondrial membrane. a. What molecules carry these high potential energy electrons? b. Where did these electron acceptor molecules come from? c. When the electrons are released from the electron acceptor molecules, what else is produced? d. Is the release of an electron from one of these electron acceptor molecules oxidation or reduction?
  4. Refer to Model 1. a. What molecule is the final electron acceptor after the electron has moved through the electron transport chain? b. What compound is formed as a final product of the electron transport chain?
  5. Is any ATP produced in the electron transport chain?
  6. Is any ATP used in the electron transport chain?

4 POGIL™^ Activities for AP* Biology

Read This!

The embedded protein complex, ATP synthase, is more of a machine than a chemical enzyme. Research has shown that a protein “rotor” down the middle of the ATP synthase complex turns as hydrogen ions flow through. This rotates other proteins, which then “squeeze” the ADP and inorganic phosphate groups together to form ATP.

  1. During oxidative phosphorylation, what molecule is being phosphorylated?
  2. Under ideal conditions each NADH molecule will result in three ATP molecules, and each FADH 2 molecule will result in two ATP molecules during oxidative phosphorylation. Calculate the total number of ATP molecules that might be produced in this phase of cellular respiration from one glucose molecule.
  3. Considering all the stages of cellular respiration (glycolysis, link, Krebs cycle, and oxidative phos- phorylation) how many ATP molecules are produced from one glucose molecule, assuming ideal circumstances?
  4. Because of its role in aerobic respiration, oxygen is essential for most living things on Earth. In complete sentences, describe the role of molecular oxygen (O 2 ) in aerobic respiration.
  5. Consider the overall chemical reaction for cellular respiration. C 6 H 12 O 6 + 6O 2 ⎯→ 6CO 2 + 6H 2 O Complete the table below to identify the phase of cellular respiration where each of the reactants are used, the products are produced, and the location in the cell where that phase occurs. You may need to refer back to previous activities on cellular respiration. Reactants Products C 6 H 12 O 6 6O 2 6CO 2 6H 2 O 38ATP Phase(s) at which it is used or produced Location

Oxidative Phosphorylation 5

Extension Questions

  1. Substrate level phosphorylation is the term used for phosphorylation that removes a phosphate from one molecule and joins it to another molecule. Oxidative phosphorylation is the term used for the attachment of free inorganic phosphate to a molecule. Identify the phases of cellular respiration that use substrate level phosphorylation and that use oxidative phosphorylation.
  2. Which side of the inner mitochondrial membrane would have a higher pH?
  3. During glycolysis the enzyme hexokinase uses ATP to transfer a phosphate to glucose to form fructose-diphosphate. Suppose that a cell has only glucose available for energy and that the activ- ity of hexokinase is suddenly stopped. Explain in detail what is most likely to occur in the cell.
  4. Prokaryote cells must have energy for cellular processes just like eukaryote cells do. Yet, they have no mitochondria. a. Which phase(s) of cellular respiration would be unaffected by the lack of mitochondria in a cell? b. The link reaction and Krebs cycle occur in the cytoplasm of prokaryotes in the same way that they occur in the mitochondria of eukaryotes. However, a concentration gradient across a membrane is a requirement of the electron transport chain. Propose an alternate site for this phase of cellular respiration in prokaryotic cells.