Untitled Flashcards Set
Chapter Summaries and Key Points
Section 3.2: ATP - Energy Currency of the Cell
Key Concepts:
ATP’s Role in Cellular Work:
ATP (Adenosine Triphosphate) supplies energy for cellular functions like DNA synthesis, protein synthesis, and muscle contractions. It’s known as the “energy currency” due to its universal role across all organisms.
Types of work by ATP include mechanical (e.g., muscle contractions), transport (e.g., active transport across membranes), and chemical (e.g., protein synthesis).
ATP Hydrolysis and Free Energy:
Hydrolysis of ATP (breaking a phosphate bond) releases energy, converting ATP to ADP and inorganic phosphate (ΔG=−30.5 kJ/mol\Delta G = -30.5 \, kJ/molΔG=−30.5kJ/mol).
This process releases energy used in endergonic (energy-requiring) reactions through energy coupling.
ATP Cycle:
ATP is continuously regenerated from ADP and inorganic phosphate, requiring energy input from food molecules.
Cycle Purpose: To efficiently harness energy and avoid dependence on glucose or other specific molecules alone.
Key Questions to Review:
Question 3: Structure of ATP, with an emphasis on how the phosphate bonds store energy.
Question 4: ATP hydrolysis and energy release.
Question 12: Advantage of ATP as an energy source over direct use of glucose or lipids.
Section 3.3: Enzymes and Activation Energy
Key Concepts:
Role of Enzymes:
Enzymes speed up reactions by lowering activation energy (Ea), allowing cellular reactions to proceed faster.
Enzymes do not affect the overall ∆G of reactions, only the energy pathway.
Mechanisms of Enzyme Action:
Mechanisms include bringing substrates close together, altering charge environments, and bending substrates to weaken bonds (induced-fit model).
Enzymes are sensitive to environmental conditions; high temperatures, for example, can denature them.
Activation Energy and Reaction Rate:
Activation energy is required to initiate reactions. For instance, the hydrolysis of sucrose is exergonic but needs an enzyme to proceed efficiently at biological temperatures.
Key Questions to Review:
Question 2: Why some spontaneous reactions do not occur immediately.
Question 4: Draw and explain enzyme effects on activation energy graphs for exergonic and endergonic reactions.
Question 6: Three main mechanisms by which enzymes lower activation energy.
Section 3.4: Food as Fuel
Key Concepts:
Energy in Fuels:
Glucose and fats are high-energy molecules because of C–H bonds, which store potential energy.
Oxidation-Reduction (Redox) Reactions are central to cellular respiration, involving the transfer of electrons (e.g., glucose oxidation in cells).
Controlled Oxidation:
Controlled oxidation in cells (e.g., glucose breakdown) occurs in multiple steps, releasing energy gradually and efficiently, unlike rapid combustion.
NAD+ as an Electron Carrier:
NAD+ accepts electrons (becoming NADH), which temporarily stores energy for later ATP synthesis.
Key Questions to Review:
Question 2 (a-c): Write the equation for glucose combustion, identifying oxidizing and reducing agents.
Question 3: Energy release due to electron positioning changes in redox reactions.
Question 9: Benefits of controlled oxidation over rapid combustion.
Untitled Flashcards Set
Chapter Summaries and Key Points
Section 3.2: ATP - Energy Currency of the Cell
Key Concepts:
ATP’s Role in Cellular Work:
ATP (Adenosine Triphosphate) supplies energy for cellular functions like DNA synthesis, protein synthesis, and muscle contractions. It’s known as the “energy currency” due to its universal role across all organisms.
Types of work by ATP include mechanical (e.g., muscle contractions), transport (e.g., active transport across membranes), and chemical (e.g., protein synthesis).
ATP Hydrolysis and Free Energy:
Hydrolysis of ATP (breaking a phosphate bond) releases energy, converting ATP to ADP and inorganic phosphate (ΔG=−30.5 kJ/mol\Delta G = -30.5 \, kJ/molΔG=−30.5kJ/mol).
This process releases energy used in endergonic (energy-requiring) reactions through energy coupling.
ATP Cycle:
ATP is continuously regenerated from ADP and inorganic phosphate, requiring energy input from food molecules.
Cycle Purpose: To efficiently harness energy and avoid dependence on glucose or other specific molecules alone.
Key Questions to Review:
Question 3: Structure of ATP, with an emphasis on how the phosphate bonds store energy.
Question 4: ATP hydrolysis and energy release.
Question 12: Advantage of ATP as an energy source over direct use of glucose or lipids.
Section 3.3: Enzymes and Activation Energy
Key Concepts:
Role of Enzymes:
Enzymes speed up reactions by lowering activation energy (Ea), allowing cellular reactions to proceed faster.
Enzymes do not affect the overall ∆G of reactions, only the energy pathway.
Mechanisms of Enzyme Action:
Mechanisms include bringing substrates close together, altering charge environments, and bending substrates to weaken bonds (induced-fit model).
Enzymes are sensitive to environmental conditions; high temperatures, for example, can denature them.
Activation Energy and Reaction Rate:
Activation energy is required to initiate reactions. For instance, the hydrolysis of sucrose is exergonic but needs an enzyme to proceed efficiently at biological temperatures.
Key Questions to Review:
Question 2: Why some spontaneous reactions do not occur immediately.
Question 4: Draw and explain enzyme effects on activation energy graphs for exergonic and endergonic reactions.
Question 6: Three main mechanisms by which enzymes lower activation energy.
Section 3.4: Food as Fuel
Key Concepts:
Energy in Fuels:
Glucose and fats are high-energy molecules because of C–H bonds, which store potential energy.
Oxidation-Reduction (Redox) Reactions are central to cellular respiration, involving the transfer of electrons (e.g., glucose oxidation in cells).
Controlled Oxidation:
Controlled oxidation in cells (e.g., glucose breakdown) occurs in multiple steps, releasing energy gradually and efficiently, unlike rapid combustion.
NAD+ as an Electron Carrier:
NAD+ accepts electrons (becoming NADH), which temporarily stores energy for later ATP synthesis.
Key Questions to Review:
Question 2 (a-c): Write the equation for glucose combustion, identifying oxidizing and reducing agents.
Question 3: Energy release due to electron positioning changes in redox reactions.
Question 9: Benefits of controlled oxidation over rapid combustion.
