ATP synthesis
Cards (13)
- ATP SynthaseCatalyzes the synthesis of ATP from ADP and inorganic phosphate (Pi) using the energy from a proton gradient
- ATP Synthase
- F0 Component: Embedded in the inner mitochondrial membrane, forms a proton channel
- F1 Component: Extends into the mitochondrial matrix, contains the catalytic sites for ATP synthesis
- Central Stalk (Rotor): Connects F0 and F1 components and rotates during proton flow
- Peripheral Stalks (Stator): Stabilize the structure and prevent rotation of the F1 component
- ATP Synthesis ReactionADP+Pi→ATP
- ΔG for ATP Hydrolysis
- 50 kJ/mol, indicating that ATP synthesis requires input of free energy
- Mechanism of ATP Synthase1. Proton Transfer and Rotation:2. Proton Flow: Protons move through the F0 component from the intermembrane space to the mitochondrial matrix3. Torque Effect: Protons cause the central stalk (rotor) to rotate due to the torque effect, driven by the electrochemical gradient4. Rotation and Conformational Changes:5. Central Stalk Rotation: As the central stalk rotates, it induces conformational changes in the α and β subunits of the F1 component6. Binding and Catalysis: These conformational changes bring ADP and Pi into close proximity, positioning them for the synthesis of ATP
- Energy Conversion in ATP Synthesis
- Flow of Protons: Protons move from the intermembrane space into the mitochondrial matrix through the F0 component, driven by the electrochemical gradient
- Kinetic Energy: The movement of protons causes the rotor to turn, converting potential energy into kinetic energy
- Conformational Work: The rotation induces conformational changes in the F1 component, which facilitates the binding of ADP and Pi and the release of ATP
- Conditions for Reverse ATP Synthase Activity (ATP Hydrolysis)1. High ATP Concentration: Abundant ATP provides the energy for reverse rotation2. Low Proton Concentration (Low H⁺ Gradient): Reduced proton gradient in the intermembrane space
- Function of Reverse ATP Synthase ActivityATP synthase can hydrolyze ATP to pump protons back into the intermembrane space
- Role of Oxygen
- Final Electron Acceptor: Oxygen is essential as the final electron acceptor in the electron transport chain, enabling the creation of the proton gradient
- Production of Water: Reduction of oxygen to water, which is coupled with proton pumping
- ATP Yield
- Glycolysis: 2 ATP (net) via substrate-level phosphorylation
- Citric Acid Cycle: 2 ATP (or GTP) via substrate-level phosphorylation
- Oxidative Phosphorylation: Approximately 26-32 ATP from the electron transport chain and ATP synthase
- Total ATP Yield per Glucose Molecule: Around 30-36 ATP
- Evolutionary Significance of Oxidative Phosphorylation
- Increased ATP Availability: Higher Oxygen Levels and Complex Organisms
- Efficiency: Oxidative phosphorylation is far more efficient than anaerobic glycolysis, providing a competitive advantage
- Energy Demands: Enabled the development of energy-intensive processes and structures, supporting larger and more complex life forms
- Visual Protocol for ATP Synthase Function1. Setup:2. Reaction Components: Prepare a system with isolated mitochondria or reconstituted membrane vesicles containing ATP synthase3. Conditions: Adjust proton gradient and ATP/ADP concentrations to observe ATP synthesis or hydrolysis4. Observation:5. Proton Flow: Monitor proton movement using pH indicators or proton-sensitive dyes6. ATP Production: Measure ATP levels using luminescent or colorimetric assays7. Data Analysis:8. Kinetics: Plot proton flow rate and ATP synthesis/hydrolysis rate9. Efficiency: Calculate the efficiency of energy conversion based on proton gradient and ATP yield
- Energy Conversion in ATP Synthase
- Potential Energy: Stored in the proton gradient
- Kinetic Energy: Rotation of the central stalk
- Conformational Work: Changes in F1 subunits leading to ATP synthesis
- Chemical Energy: Stored in the high-energy phosphate bonds of ATP