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18.3E: Theoretical ATP Yield

  • Page ID
    3415
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    The theoretical maximum yield of ATP for the oxidation of one molecule of glucose during aerobic respiration is 38. In terms of substrate-level phosphorylation, oxidative phosphorylation, and the component pathways involved, briefly explain how this number is obtained.

    Determining the exact yield of ATP for aerobic respiration is difficult for a number of reasons. In addition to generating ATP by oxidative phosphorylation in prokaryotic cells, proton motive force is also used for functions such as transporting materials across membranes and rotating flagella. Also, some bacteria use different carriers in their electron transport chain than others and the carriers may vary in the number of protons they transport across the membrane. Furthermore, the number of ATP generated per reduced NADH or FADH2 is not always a whole number. For every pair of electrons transported to the electron transport chain by a molecule of NADH, between 2 and 3 ATP are generated. For each pair of electrons transferred by FADH2, between 1 and 2 ATP are generated. In eukaryotic cells, unlike prokaryotes, NADH generated in the cytoplasm during glycolysis must be transported across the mitochondrial membrane before it can transfer electrons to the electron transport chain and this requires energy. As a result, between 1 and 2 ATP are generated from these NADH.

    For simplicity, however, we will look at the theoretical maximum yield of ATP per glucose molecule oxidized by aerobic respiration. We will assume that for each pair of electrons transferred to the electron transport chain by NADH, 3 ATP will be generated; for each electron pair transferred by FADH2, 2 ATP will be generated. Keep in mind, however, that less ATP may actually be generated.

    As seen above, one molecule of glucose oxidized by aerobic respiration in prokaryotes yields the following:

    Glycolysis

    2 net ATP from substrate-level phosphorylation
    2 NADH yields 6 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation

    Transition Reaction

    2 NADH yields 6 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation

    Citric Acid Cycle

    2 ATP from substrate-level phosphorylation
    6 NADH yields 18 ATP (assuming 3 ATP per NADH) by oxidative phosphorylation
    2 FADH2 yields 4 ATP (assuming 2 ATP per FADH2) by oxidative phosphorylation

    Total Theoretical Maximum Number of ATP Generated per Glucose in Prokaryotes

    38 ATP: 4 from substrate-level phosphorylation; 34 from oxidative phosphorylation.

    In eukaryotic cells, the theoretical maximum yield of ATP generated per glucose is 36 to 38, depending on how the 2 NADH generated in the cytoplasm during glycolysis enter the mitochondria and whether the resulting yield is 2 or 3 ATP per NADH.


    This page titled 18.3E: Theoretical ATP Yield is shared under a CC BY 4.0 license and was authored, remixed, and/or curated by Gary Kaiser via source content that was edited to the style and standards of the LibreTexts platform; a detailed edit history is available upon request.