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Chapter 7 How Cells Release Chemical Energy
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7.2 Overview of Carbohydrate Breakdown Pathways
Photosynthetic organisms capture solar energy and store it in sugars Energy stored in sugars must be converted to molecular energy (in the form of ATP) for use in energy-requiring reactions Most eukaryotes and some bacteria breakdown carbohydrates via aerobic respiration
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Cycle of Photosynthesis and Aerobic Respiration
energy S Y N T H O E T S O I S H P CO2 H2O sugar O2 Figure 7.2 The global connection between photosynthesis and aerobic respiration. note the cycling of materials, and the one-way flow of energy N A O E I R T O A B I C I R R E S P energy
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Overview of Aerobic Respiration
C6H12O6 (glucose) + O2 (oxygen) → CO2 (carbon dioxide) + H2O (water) Three stages Glycolysis Acetyl-CoA formation and Krebs cycle Electron transfer phosphorylation (ATP formation) Coenzymes NADH and FADH2 carry electrons and hydrogen
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Aerobic Respiration vs. Anaerobic Fermentation
Aerobic respiration and fermentation both begin with glycolysis, which converts one molecule of glucose into two molecules of pyruvate After glycolysis, the two pathways diverge Fermentation is completed in the cytoplasm, yielding 2 ATP per glucose molecule Aerobic respiration is completed in mitochondria, yielding 36 ATP per glucose molecule
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Comparison of Aerobic Respiration and Fermentation
cytoplasm ATP GLYCOLYSIS cytoplasm ATP GLYCOLYSIS mitochondrion KREBS CYCLE ATP additional reactions in cytoplasm ATP Figure 7.3 Comparison of aerobic respiration and fermentation. ATP ATP ELECTRON TRANSFER PHOSPHORYLATION B Fermentation A Aerobic respiration.
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7.3 Glycolysis—Sugar Breakdown Begins
Glycolysis begins the sugar breakdown pathway in both aerobic respiration and fermentation Occurs in cytoplasm of cells Requires initial investment of 2 ATP molecules Produces 4 ATP total, for a net yield of 2 ATP
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Glycolysis – ATP-Requiring Steps
glucose ATP-Requiring Steps An enzyme transfers a phosphate group from ATP to glucose, forming glucose-6-phosphate. (You learned about this enzyme, hexokinase, in FIGURE 5.10 and Section 5.4.) ADP glucose-6-phosphate A phosphate group from a second ATP is transferred to the glucose-6-phosphate. The resulting molecule is unstable, and it splits into two three-carbon molecules. The molecules are interconvertible, so we will call them both PGAL (phosphoglyceraldehyde). Two ATP have now been invested in the reactions. ADP fructose-1,6-bisphosphate Glycolysis ATP-Requiring Steps 1 An enzyme transfers a phosphate group from ATP to glucose, forming glucose-6-phosphate. (You learned about this enzyme, hexokinase, in Figure 5.10 and Section 5.4). 2 A phosphate group from a second ATP is transferred to the glucose-6-phosphate. The resulting molecule is unstable, and it splits into two three-carbon molecules. The molecules are interconvertible, so we will call them both PGAL (phosphoglyceraldehyde). Two ATP have now been invested in the reactions. ATP-Generating Steps 3 An enzyme attaches a phosphate to each PGAL , so two PGA (phosphoglycerate) form. Two electrons and a hydrogen ion (not shown) from each PGAL are accepted by NAD+, so two NADH form. 4 An enzyme transfers a phosphate group from each PGA to ADP, forming two ATP and two intermediate molecules (PEP). The original energy investment of two ATP has now been recovered. 5 An enzyme transfers a phosphate group from each PEP to ADP, forming two more ATP and two molecules of pyruvate. 6 Summing up, glycolysis yields two NADH, two ATP (net), and two pyruvate for each glucose molecule. Depending on the type of cell and environmental conditions, the pyruvate may enter the second stage of aerobic respiration or it may be used in other ways, such as in fermentation. 2 PGAL ATP-Generating Steps 2 NAD+ An enzyme attaches a phosphate to each PGAL, so two PGA (phospho- glycerate) form. Two electrons and a hydrogen ion (not shown) from each PGAL are accepted by NAD+, so two NADH form. 2 coenzymes reduced
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Glycolysis – ATP-Requiring Steps
2 PGA 2 ADP An enzyme transfers a phosphate group from each PGA to ADP, forming two ATP and two intermediate molecules (PEP). The original energy investment of two ATP has now been recovered. 2 ATP produced by substrate-level phosphorylation 2 PEP 2 ADP An enzyme transfers a phosphate group from each PEP to ADP, forming two more ATP and two molecules of pyruvate. Glycolysis ATP-Requiring Steps 1 An enzyme transfers a phosphate group from ATP to glucose, forming glucose-6-phosphate. (You learned about this enzyme, hexokinase, in Figure 5.10 and Section 5.4). 2 A phosphate group from a second ATP is transferred to the glucose-6-phosphate. The resulting molecule is unstable, and it splits into two three-carbon molecules. The molecules are interconvertible, so we will call them both PGAL (phosphoglyceraldehyde). Two ATP have now been invested in the reactions. ATP-Generating Steps 3 An enzyme attaches a phosphate to each PGAL , so two PGA (phosphoglycerate) form. Two electrons and a hydrogen ion (not shown) from each PGAL are accepted by NAD+, so two NADH form. 4 An enzyme transfers a phosphate group from each PGA to ADP, forming two ATP and two intermediate molecules (PEP). The original energy investment of two ATP has now been recovered. 5 An enzyme transfers a phosphate group from each PEP to ADP, forming two more ATP and two molecules of pyruvate. 6 Summing up, glycolysis yields two NADH, two ATP (net), and two pyruvate for each glucose molecule. Depending on the type of cell and environmental conditions, the pyruvate may enter the second stage of aerobic respiration or it may be used in other ways, such as in fermentation. 2 ATP produced by substrate-level phosphorylation Summing up, glycolysis yields two NADH, two ATP (net), and two pyruvate for each glucose molecule. Depending on the type of cell and environmental conditions, the pyruvate may enter the second stage of aerobic respiration or it may be used in other ways, such as in fermentation. 2 pyruvate Net 2 ATP + 2 NADH to second stage of aerobic respiration or fermentation
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7.4 Second Stage of Aerobic Respiration
The second stage of aerobic respiration completes the breakdown of glucose that began in glycolysis Occurs in mitochondria Includes two sets of reactions: acetyl-CoA formation and the Krebs cycle (each occurs twice in the breakdown of one glucose molecule)
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Second Stage of Aerobic Respiration – In the Matrix
cytoplasm outer membrane inner membrane The breakdown of 2 pyruvate to 6 CO2 yields 2 ATP and 10 reduced coenzymes (8 NADH, 2 FADH2). The coenzymes will carry their cargo of electrons and hydrogen ions to the third stage of aerobic respiration. matrix Figure 7.6 Animated The second stage of aerobic respiration, acetyl–CoA formation and the Krebs cycle, occurs inside mitochondria. Left, an inner membrane divides a mitochondrion’s interior into two fluid-filled compartments. Right, the second stage of aerobic respiration takes place in the mitochondrion’s innermost compartment, or matrix.
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Acetyl-CoA Formation In the inner compartment of the mitochondrion, enzymes split pyruvate, forming acetyl-CoA and CO2 (which diffuses out of the cell) NADH is formed
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The Krebs Cycle A sequence of enzyme-mediated reactions that break down 1 acetyl-CoA into 2 CO2 Oxaloacetate is used and regenerated 3 NADH and 1 FADH2 are formed 1 ATP is formed
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Acetyl–CoA Formation and the Krebs Cycle
An enzyme splits a pyruvate coenzyme A NAD+ molecule into a two-carbon acetyl group and CO2. Coenzyme A binds the acetyl group (forming acetyl–CoA). NAD+ combines with released hydrogen ions and electrons, forming NADH. 1 The Krebs cycle starts as one carbon atom is transferred from acetyl–CoA tooxaloacetate. Citrate forms, and coenzyme A is regenerated. 2 The final steps of the Krebs cycle regenerate oxaloacetate. 8 A carbon atom is removed from an intermediate and leaves the cell as CO2. NAD+ combines with released hydrogen ions and electrons, forming NADH. 3 NAD+ combines with hydrogen ions and electrons, forming NADH. 7 Krebs Cycle Figure 7.7 Acetyl–CoA and the Krebs cycle. It takes two cycles of Krebs reactions to break down two pyruvate molecules that formed during glycolysis of one glucose molecule. After two cycles, all six carbons that entered glycolysis in one glucose molecule have left the cell, in six CO2. Electrons and hydrogen ions are released as each carbon is removed from the backbone of intermediate molecules; ten coenzymes will carry them to the third and final stage of aerobic respiration. Not all reactions are shown; Appendix V has more details. The coenzyme FAD combines with hydrogen ions and electrons, forming FADH2. 6 A carbon atom is removed from another intermediate and leaves the cell as CO2, and another NADH forms. Pyruvate’s three carbon atoms have now exited the cell, in CO2. 4 One ATP forms by substrate-level phosphorylation. 5 Stepped Art
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Acetyl–CoA and the Krebs Cycle
An enzyme splits a pyruvate molecule into a two-carbon acetyl group and CO2 binds the acetyl group, forming acetyl–CoA. NAD+ combines with released electrons and a hydrogen ion, forming NADH. pyruvate coenzyme A CO2 acetyl–CoA coenzyme A The final steps regenerate oxaloacetate. The Krebs cycle starts as two carbon atoms are transferred from acetyl–CoA oxaloacetate to oxaloacetate. Citrate forms, citrate and coenzyme A is regenerated. NAD combines with hydrogen ions and electrons, forming NADH. + One carbon atom is removed from an intermediate and Figure 7.7 Acetyl–CoA and the Krebs cycle. It takes two cycles of Krebs reactions to break down two pyruvate molecules that formed during glycolysis of one glucose molecule. After two cycles, all six carbons that entered glycolysis in one glucose molecule have left the cell, in six CO2. Electrons and hydrogen ions are released as each carbon is removed from the backbone of intermediate molecules; ten coenzymes will carry them to the third and final stage of aerobic respiration. Not all reactions are shown; Appendix V has more details. KREBS CYCLE leaves the cell as CO2. CO2 NAD+ combines with released electrons and a hydrogen ion, forming NADH. The coenzyme FAD combines with electrons and hydrogen ions, forming FADH2. Another carbon atom is removed from another inter- succinate mediate and leaves the cell as CO2. CO2 ADP + Pi NAD+ combines with released electrons and a hydrogen ion, forming NADH. Pyruvate’s three carbon atoms have now exited the cell, in CO2. One ATP forms by substrate-level phosphorylation.
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7.5 Aerobic Respiration’s Big Energy Payoff
Many ATP are formed during the third and final stage of aerobic respiration Electron transfer phosphorylation Occurs in mitochondria Results in attachment of phosphate to ADP to form ATP
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Electron Transfer Phosphorylation
Coenzymes NADH and FADH2 donate electrons and H+ to electron transfer chains Active transport forms a H+ concentration gradient in the outer mitochondrial compartment H+ follows its gradient through ATP synthase, which attaches a phosphate to ADP Finally, oxygen accepts electrons and combines with H+, forming water
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Electron Transfer Phosphorylation
GLYCOLYSIS NADH and FADH2 deliver electrons to electron transfer chains in the inner mitochondrial membrane. Electron flow through the chains causes hydrogen ions (H+) to be pumped from the matrix to the intermembrane space. The activity of the electron transfer chains causes a hydrogen ion gradient to form across the inner mitochondrial membrane. Hydrogen ion flow back to the matrix through ATP synthases drives the formation of ATP from ADP and phosphate (Pi). Oxygen combines with electrons and hydrogen ions at the end of the electron transfer chains, so water forms. KREBS CYCLE ELECTRON TRANSFER PHOSPHORYLATION ELEC TRON TRANSFER PHOSPHORYLATION electron transfer chain Figure 7.8 In eukaryotes, the third and final stage of aerobic respiration, electron transfer phosphorylation, occurs at the inner mitochondrial membrane. 1 NADH and FADH2 deliver electrons to electron transfer chains in the inner mitochondrial membrane. 2 Electron flow through the chains causes hydrogen ions (H+) to be pumped from the matrix to the intermembrane space. 3 The activity of the electron transfer chains causes a hydrogen ion gradient to form across the inner mitochondrial membrane. 4 Hydrogen ion flow back to the matrix through ATP synthases drives the formation of ATP from ADP and phosphate (Pi ). 5 Oxygen combines with electrons and hydrogen ions at the end of the electron transfer chains, so water forms. matrix ADP + Pi Inner membrane O2 2H2O intermembrane space outer membrane cytoplasm
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Summary: The Energy Harvest
Typically, the breakdown of one glucose molecule yields 36 ATP Glycolysis: 2 ATP Acetyl-CoA formation and Krebs cycle: 2 ATP Electron transfer phosphorylation: 32 ATP
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Aerobic Respiration 2 ATP
glucose STAGE Glycolysis splits a glucose molecule into 2 pyruvate; 2 NADH and 4 ATP also form. An investment of 2 ATP began the reactions, so the net yield is 2 ATP. 2 ATP GLYCOLYSIS 4 ATP (2 net) 2 NADH 2 pyruvate STAGE Acetyl–CoA formation and the Krebs cycle break down the pyruvate to CO2, which 2 NADH leaves the cell. Ten additional coenzymes are reduced, and two ATP form. 2 NADH 2 CO2 2 acetyl–CoA 4 CO2 KREBS CYCLE STAGE In electron transfer phosphorylation, the reduced coenzymes give up electrons and hydrogen ions to electron transfer chains. Energy lost by the electrons as 6 NADH 2 FADH2 2 ATP Figure 7.9 Summary of the three stages of aerobic respiration, pictured in a mitochondrion. ATP they move through the chains is used to move H+ across ATP ATP the membrane. The resulting gradient causes H+ to flow through ATP synthases, which drives ATP synthesis. ATP 32 ELECTRON TRANSFER PHOSPHORYLATION oxygen H2O
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7.6 Fermentation Glycolysis is the first stage of fermentation
Forms 2 pyruvate, 2 NADH, and 2 ATP Pyruvate is converted to other molecules, but is not fully broken down to CO2 and water Regenerates NAD+ but does not produce ATP Provides enough energy for some single-celled anaerobic species
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Two Fermentation Pathways – Alcoholic Fermentation
Pyruvate is split into acetaldehyde and CO2 Acetaldehyde receives electrons and hydrogen from NADH, forming NAD+ and ethanol Carried out by single-celled organisms such as fungi Used to make beer, wine, and bread
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Alcoholic Fermentation
GLYCOLYSIS glucose 2 ATP 2 NAD+ e– e– e– e– 4 ATP 2 NADH pyruvate Figure 7.10 Alcoholic fermentation A Alcoholic fermentation begins with glycolysis, and the final steps regenerate NAD+. The reactions yield two ATP per molecule of glucose (from glycolysis). ALCOHOLIC 2 CO2 FERM ENTATION acetaldehyde 2 NADH 2 NAD+ ethanol
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Two Fermentation Pathways – Lactate Fermentation
Pyruvate receives electrons and hydrogen directly from NADH, forming NAD+ and lactate Carried out be beneficial bacteria Used to make yogurt Also carried out by animal white skeletal muscle cells Useful for quick, strenuous activities Does not support prolonged activity
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Lactate Fermentation e– e– e– e– ATP NADH NADH GLYCOLYSIS
glucose 2 ATP 2 NAD+ e– e– e– e– 4 ATP 2 NADH pyruvate Figure 7.11 Lactate fermentation A Lactate fermentation begins with glycolysis, and the final steps regenerate NAD+. The reactions yield two ATP per molecule of glucose (from glycolysis). LACTATE FERM ENTATION 2 NADH 2 NAD+ lactate
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7.7 Alternative Energy Sources in Food
Aerobic respiration can produce ATP from the breakdown of complex carbohydrates, fats, and proteins As in glucose metabolism, many coenzymes are reduced The energy of the electrons the coenzymes carry ultimately drives the synthesis of ATP in electron transfer phosphorylation
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Energy From Complex Carbohydrates
Enzymes break starch and other complex carbohydrates down to monosaccharide subunits Monosaccharides are taken up by cells and converted to glucose-6-phosphate, which continues in glycolysis A high concentration of ATP causes glucose-6-phosphate to be diverted from glycolysis and into a pathway that forms glycogen
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Complex Carbohydrates are Broken Down into Monosaccharides
starch (a complex carbohydrate) glucose (a simple sugar) CH2OH HO O Figure 7.12 A variety of organic compounds from food can enter the reactions of aerobic respiration. A Complex carbohydrates are broken down to their monosaccharide subunits, which can enter glycolysis.
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Energy From Fats Enzymes cleave fats into glycerol and fatty acids
Glycerol products enter glycolysis Fatty acids are converted to acetyl-CoA and enter the Krebs cycle Fatty acid breakdown yields more ATP per carbon atom than carbohydrates When blood glucose level is high, acetyl-CoA is diverted from the Krebs cycle and into a pathway that makes fatty acids
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Fats are Broken Down by Separating the Glycerol Head and Fatty Acid Tails
a triglyceride (fat) glycero l head fatty acid tails Figure 7.12 A variety of organic compounds from food can enter the reactions of aerobic respiration. B Fats are broken down by separating the glycerol head from the fatty acid tails. The fatty acids are converted to acetyl-CoA, and the glycerol is converted to PGAL.
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Energy from Proteins Enzymes split dietary proteins into amino acid subunits, which are used to build proteins or other molecules The amino group is removed and converted into ammonia (NH3), a waste product eliminated in urine Acetyl–CoA, pyruvate, or an intermediate of the Krebs cycle forms, depending on the amino acid
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Amino Acids Are Converted
Figure 7.12 A variety of organic compounds from food can enter the reactions of aerobic respiration. C Amino acids are converted to acetyl-CoA, pyruvate, or an intermediate of the Krebs cycle. alanine (an amino acid) pyruvate
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Alternate Energy Sources in Foods
Fats Complex Carbohydrates Proteins fatty acids glycerol glucose, other sugars amino acids 2 acetyl– CoA 3 PGA L 1 4 acetyl–CoA GLYCOLYSIS NADH pyruvate intermediate of Krebs cycle Figure 7.12 A variety of organic compounds from food can enter the reactions of aerobic respiration. KREBS CYCLE NADH, FADH2 ATP ATP ATP ATP ELECTRON TRANSFER PHOSPHORYLATION
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