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© 2007 McGraw-Hill Higher Education. All rights reserved.
Chapter 3Bioenergetics
EXERCISE PHYSIOLOGY
Theory and Application to Fitness and Performance, 6th edition
Scott K. Powers & Edward T. Howley
© 2007 McGraw-Hill Higher Education. All rights reserved.
Introduction
• Metabolism: total of all chemical reactions that occur in the body– Anabolic reactions
• Synthesis of molecules– Catabolic reactions
• Breakdown of molecules• Bioenergetics
– Converting foodstuffs (fats, proteins, carbohydrates) into energy
© 2007 McGraw-Hill Higher Education. All rights reserved.
Objectives
• Discuss the function of cell membrane, nucleus, and mitochondria
• Define: endergonic, exergonic, coupled reactions, and bioenergetics
• Describe how enzymes work• Discuss nutrients used for energy • Identify high-energy phosphates
© 2007 McGraw-Hill Higher Education. All rights reserved.
Objectives
• Discuss anaerobic and aerobic production of ATP
• Describe how metabolic pathways are regulated
• Discuss the interaction of anaerobic and aerobic ATP production during exercise
• Identify the rate limiting enzymes
© 2007 McGraw-Hill Higher Education. All rights reserved.
Cell Structure
• Cell membrane
– Protective barrier between interior of cell and extracellular fluid
• Nucleus
– Contains genes that regulate protein synthesis
• Cytoplasm
– Fluid portion of cell
– Contains organelles (mitochondria)
© 2007 McGraw-Hill Higher Education. All rights reserved.
Structure of a Typical Cell
Fig 3.1
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Cellular Chemical Reactions
• Endergonic reactions– Require energy to be added
• Exergonic reactions– Release energy
• Coupled reactions– Liberation of energy in an exergonic
reaction drives an endergonic reaction
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The Breakdown of Glucose: An Exergonic Reaction
Fig 3.3
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Coupled Reactions
Fig 3.4
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Oxidation-Reduction Reactions
• Oxidation: removing an electron • Reduction: addition of an electron• Oxidation and reduction are always coupled
reactions• In cells, often involve the transfer of hydrogen
atoms rather than free electrons– Hydrogen atom contains one electron– A molecule that loses a hydrogen also loses an
electron and, therefore, is oxidized
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Enzymes
• Catalysts that regulate the speed of reactions– Lower the energy of activation
• Factors that regulate enzyme activity– Temperature– pH
• Interact with specific substrates– Lock and key model
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Enzymes Lower the Energy of Activation
Fig 3.6
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Enzyme-Substrate Interaction
Fig 3.7
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Fuels for Exercise
• Carbohydrates – Glucose
• Stored as glycogen• Fats
– Primarily fatty acids• Stored as triglycerides
• Proteins– Not a primary energy source during exercise
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High-Energy Phosphates
• Adenosine triphosphate (ATP)– Consists of adenine, ribose, and three
linked phosphates• Formation
• Breakdown
ADP + Pi ATP
ADP + Pi + EnergyATP ATPase
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Structure of ATP
Fig 3.8
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Model of ATP as the Universal Energy Donor
Fig 3.9
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Bioenergetics
• Formation of ATP – Phosphocreatine (PC) breakdown– Degradation of glucose and glycogen (glycolysis)– Oxidative formation of ATP
• Anaerobic pathways
– Do not involve O2
– PC breakdown and glycolysis• Aerobic pathways
– Require O2
– Oxidative phosphorylation
© 2007 McGraw-Hill Higher Education. All rights reserved.
Anaerobic ATP Production
• ATP-PC system– Immediate source of ATP
• Glycolysis– Energy investment phase
• Requires 2 ATP– Energy generation phase
• Produces ATP, NADH (carrier molecule), and pyruvate or lactate
PC + ADP ATP + CCreatine kinase
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The Two Phases of Glycolysis
Fig 3.10
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Glycolysis Energy Investment Phase
Fig 3.11
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Glycolysis Energy Generation Phase
Fig 3.11
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Oxidation-Reduction Reactions
• Oxidation– Molecule accepts electrons (along with H+)
• Reduction– Molecule donates electrons
• Nicotinomide adenine dinucleotide (NAD)
• Flavin adenine dinucleotide (FAD)FAD + 2H+ FADH2
NAD + 2H+ NADH + H+
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Production of Lactic Acid
• Normally, O2 is available in the mitochondria to accept H+ (and electrons) from NADH produced in glycolysis
– In anaerobic pathways, O2 is not available
• H+ and electrons from NADH are accepted by pyruvic acid to form lactic acid
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Conversion of Pyruvic Acid to Lactic Acid
Fig 3.12
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Aerobic ATP Production• Krebs cycle (citric acid cycle)
– Completes the oxidation of substrates and produces NADH and FADH to enter the electron transport chain
• Electron transport chain – Oxidative phosphorylation– Electrons removed from NADH and FADH are
passed along a series of carriers to produce ATP
– H+ from NADH and FADH are accepted by O2 to form water
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The Three Stages of Oxidative
Phosphorylation
Fig 3.13
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The Krebs Cycle
Fig 3.14
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Relationship Between the Metabolism of Proteins, Fats, and Carbohydrates
Fig 3.15
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Electron Transport Chain
Fig 3.17
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The Chemiosmotic Hypothesis of ATP Formation
• Electron transport chain results in pumping of H+ ions across inner mitochondrial membrane– Results in H+ gradient across membrane
• Energy released to form ATP as H+ diffuse back across the membrane
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The Chemiosmotic Hypothesis of ATP Formation
Fig 3.16
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Metabolic Process High-Energy Products
ATP from Oxidative Phosphorylation
ATP Subtotal
Glycolysis 2 ATP 2 NADH
— 5
2 (if anaerobic) 7 (if aerobic)
Pyruvic acid to acetyl-CoA 2 NADH 5 12
Krebs cycle 2 GTP 6 NADH 2 FADH
— 15 3
14 29 32
Grand Total
32
Aerobic ATP Tally
Table 3.1
2.5 ATP per NADH1.5 APT per FADH
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Efficiency of Oxidative Phosphorylation
• Aerobic metabolism of one molecule of glucose– Yields 32 ATP
• Aerobic metabolism of one molecule of glycogen– Yields 33 ATP
• Overall efficiency of aerobic respiration is 34%– 66% of energy released as heat
© 2007 McGraw-Hill Higher Education. All rights reserved.
Control of Bioenergetics
• Rate-limiting enzymes– An enzyme that regulates the rate of a
metabolic pathway
• Levels of ATP and ADP+Pi
– High levels of ATP inhibit ATP production– Low levels of ATP and high levels of
ADP+Pi stimulate ATP production
• Calcium may stimulate aerobic ATP production
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Action of Rate-Limiting Enzymes
Fig 3.19
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Control of Metabolic Pathways
Pathway Rate-LimitingEnzyme
Stimulators Inhibitors
ATP-PC system Creatine kinase ADP ATP
Glycolysis Phosphofructokinase AMP, ADP, Pi, pH ATP, CP, citrate, pH
Krebs cycle Isocitratedehydrogenase
ADP, Ca++, NAD ATP, NADH
Electron transportchain
Cytochrome Oxidase ADP, Pi ATP
Table 3.2
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Control of Bioenergetics
Glycogen
Glucose 6-phosphate
Phosphoglyceraldehyde
Pyruvic Acid
Acetyl CoA Amino Acids Proteins
Ketonebodies
Fatty acids
Triglycerides
Glycerol
Lactic Acid
Krebs Cycle
C6
C5
C4
Urea
Glucose
2
Rate Limiting Enzymes1. Creatine kinase2. Phosphofructokinase 3. Iscitrate dehydrogenase 4. Cytochrome oxidase
-ox
3 ETSNADHFADH
4
Glycolysis
1PC + ADP C + ATP
ATP-PC System
Table 3.2
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Interaction Between Aerobic and Anaerobic ATP Production
• Energy to perform exercise comes from an interaction between aerobic and anaerobic pathways
• Effect of duration and intensity– Short-term, high-intensity activities
• Greater contribution of anaerobic energy systems
– Long-term, low to moderate-intensity exercise• Majority of ATP produced from aerobic sources
© 2007 McGraw-Hill Higher Education. All rights reserved.
Chapter 3Bioenergetics
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