Fig. 7.1 NAD + 2H oxidationreduction 2H 2e – + 2H + NADH + H + 2e – + 2H +
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114 ATP P glucose water C 6 H 12 O 6 + 6O 2 oxygen 6CO 2 + 6H 2 O
ADP + carbon dioxide Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Fig. 7.1 NAD + 2H
oxidationreduction 2H 2e + 2H + NADH + H + 2e + 2H + Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig Electron transport chain 2 ADP 22 total net gain
Cytoplasm ATP ++ = 36 or 38 ee ee 2. Preparatory reaction 3. Citric
acid cycle 32 ADP or or 34 ATP 2 ADP 2 ATP 4 ADP4 ATP 1. Glycolysis
glucose pyruvate ee NADH + H + and FADH 2 ee ee ee ee ee ATP energy
for synthesis of ee electron transport chain high-energy electrons
low-energy electrons Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Fig. 7.3 Copyright
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reproduction or display. Page 116 enzyme P P P ADP ATP Copyright
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reproduction or display. Fig. 7.4a 2 ADP 4 ADP 2net glucose
Cytoplasm ee 2 ADP NADH + H + Glycolysis ATP 2 Electron transport
chain and chemiosmosis Citric acid cycle ee ee ee NADH + H + and
FADH 2 NADH + H + ee pyruvate Preparatory reaction 2 ATP 4 ATP
total ee ee 32 ADP or or 34 Copyright The McGraw-Hill Companies,
Inc. Permission required for reproduction or display. Fig. 7.4b
Cytoplasm Copyright The McGraw-Hill Companies, Inc. Permission
required for reproduction or display. Fig. 7.4c Cytoplasm Copyright
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reproduction or display. Fig. 7.4d Cytoplasm Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig. 7.4left Cytoplasm a. 2 ADP 32 ADP or or 34 4 ADP 2net
glucose Cytoplasm ee 2 ADP NADH + H + Glycolysis ATP 2 Electron
transport chain and chemiosmosis Citric acid cycle ee ee ee NADH +
H + and FADH 2 NADH + H + ee pyruvate Preparatory reaction 2 ATP 4
ATP total ee ee Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Fig. 7.4right-a PP
ADP Steps PP Energy-Investment Steps - 2 G3P ATP 1. Two ATP are
used to activate glucose. 2. A resulting C 6 molecule breaks down
into 2 C 3 molecules. glucose Copyright The McGraw-Hill Companies,
Inc. Permission required for reproduction or display. Fig.
7.4right-b ATP + 2 (net gain) 2 NAD + P P ADP H2OH2O P NADH + H + P
P pyruvate H2OH2O ATP NADH + H + Energy-Harvesting Steps 3. NAD +
takes an electron becoming NADH + H +, with addition of a second
phosphate to the sugar. 4. Removal of high-energy phosphate from 2
BPG by 2 ADP produces 2 ATP and 2 3PG molecules. 6. Removal of
high-energy phosphate from 2 PEP by 2 ADP produces 2 ATP and 2
pyruvate molecules. 5. Oxidation of 2 3PG by removal of water
results in 2 high-energy PEP molecules. BPG PP ADP PP ATP BPG 3PG P
ADP PEP Copyright The McGraw-Hill Companies, Inc. Permission
required for reproduction or display. Fig. 7.4right-1 ADP Steps
Energy-Investment Steps - 2 ATP 1. Two ATP are used to activate
glucose. glucose PP Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Fig. 7.4right-2
ADP Steps Energy-Investment Steps - 2 ATP 1. Two ATP are used to
activate glucose. 2. A resulting C 6 molecule breaks down into 2 C
3 molecules. glucose P G3P P PP Copyright The McGraw-Hill
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Fig. 7.4right-3 glucose PP ADP Steps NAD + PP P PP P NADH + H + PP
Energy-Investment Steps - 2 NADH + H + Energy-Harvesting Steps ATP
1. Two ATP are used to activate glucose. 2. A resulting C 6
molecule breaks down into 2 C 3 molecules. 3. NAD + takes an
electron becoming NADH + H +, with addition of a second phosphate
to the sugar. BPG G3P Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Fig. 7.4right-4
glucose PP ADP Steps + 2 NAD + 3PG NAD + PP P PP ADP P NADH + H +
PP P P Energy-Investment Steps - 2 ATP NADH + H + Energy-Harvesting
Steps ATP 1. Two ATP are used to activate glucose. 2. A resulting C
6 molecule breaks down into 2 C 3 molecules. 3. NAD + takes an
electron becoming NADH + H +, with addition of a second phosphate
to the sugar. 4. Removal of high-energy phosphate from 2 BPG by 2
ADP produces 2 ATP and 2 3PG molecules. BPG G3P Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig. 7.4right-5 glucose PP ADP Steps + 2 NAD + PP P PP ADP
P H2OH2O P NADH + H + PP P P P Energy-Investment Steps - 2 H2OH2O
ATP NADH + H + Energy-Harvesting Steps ATP 1. Two ATP are used to
activate glucose. 2. A resulting C 6 molecule breaks down into 2 C
3 molecules. 3. NAD + takes an electron becoming NADH + H +, with
addition of a second phosphate to the sugar. 4. Removal of
high-energy phosphate from 2 BPG by 2 ADP produces 2 ATP and 2 3PG
molecules. 5. Oxidation of 2 3PG by removal of water results in 2
high-energy PEP molecules. BPG 3PG PEP BPG 3PG PEP G3P Copyright
The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig. 7.4right PP ADP Steps ATP + 2 (net
gain) 2 NAD + PP P PP ADP P H2OH2O P NADH + H + PP P P P b.
Energy-Investment Steps - 2 H2OH2O ATP NADH + H + Energy-Harvesting
Steps ATP 1. Two ATP are used to activate glucose. 2. A resulting C
6 molecule breaks down into 2 C 3 molecules. 3. NAD + takes an
electron becoming NADH + H +, with addition of a second phosphate
to the sugar. 4. Removal of high-energy phosphate from 2 BPG by 2
ADP produces 2 ATP and 2 3PG molecules. 6. Removal of high-energy
phosphate from 2 PEP by 2 ADP produces 2 ATP and 2 pyruvate
molecules. 5. Oxidation of 2 3PG by removal of water results in 2
high-energy PEP molecules. glucose G3P BPG 3PG PEP pyruvate
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reproduction or display. Page acetylCoA + 2 carbon dioxide2
pyruvate + 2 CoA 2 NADH + H + 2 NAD + Copyright The McGraw-Hill
Companies, Inc. Permission required for reproduction or display.
Fig. 7.5a 2 ADP2 2 ATP ee NADH ee ee Glycolysis glucosepyruvate
Preparatory reaction 2 ATP 2 ADP 4 ADP4 ATP total ATP net Matrix
Citric acid cycle NADH and FADH 2 Electron transport chain and
chemiosmosis 32 ADP or or 34 ATP ee ee ee ee Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig. 7.5b ATP 1. The C 2 acetyl group combines with a C 4
molecule to produce citrate, a C 6 molecule. NADH + H + NAD + NADH
+ H + CO 2 NADH + H + CO 2 2.Oxidation reactions produce two NADH +
H +. citrate The loss of two CO 2 results In a new C 4 molecule.
C4C4 C4C4 One ATP is produced by substrate-level ATP synthesis. NAD
+ CoA Additional oxidation reactions produce an FADH 2 and another
NADH + H + and regenerate original C 4 molecule. 4. FAD C4C4 FADH 2
NAD + C5C Citric acid cycle Preparatory reaction CoA acetyl CoA
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig The C 2 acetyl group combines with a C
4 molecule to produce citrate, a C 6 molecule. C4C4 CoA Citric acid
cycle Preparatory reaction CoA acetyl CoA Copyright The McGraw-Hill
Companies, Inc. Permission required for reproduction or display.
Fig The C 2 acetyl group combines with a C 4 molecule to produce
citrate, a C 6 molecule. NAD + CO 2 NADH + H + 2.Oxidation
reactions produce two NADH + H +. citrate C4C4 CoA C5C5 Citric acid
cycle Preparatory reaction CoA acetyl CoA Copyright The McGraw-Hill
Companies, Inc. Permission required for reproduction or display.
Fig ATP 1. The C 2 acetyl group combines with a C 4 molecule to
produce citrate, a C 6 molecule. NAD + NADH + H + CO 2 NADH + H +
CO 2 2.Oxidation reactions produce two NADH + H +. citrate The loss
of two CO 2 results In a new C 4 molecule. C4C4 One ATP is produced
by substrate-level ATP synthesis. CoA 4. C4C4 NAD + C5C5 3. Citric
acid cycle Preparatory reaction CoA acetyl CoA Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig ATP 1. The C 2 acetyl group combines with a C 4
molecule to produce citrate, a C 6 molecule. NADH + H + NAD + NADH
+ H + CO 2 NADH + H + CO 2 2.Oxidation reactions produce two NADH +
H +. citrate The loss of two CO 2 results In a new C 4 molecule.
C4C4 C4C4 One ATP is produced by substrate-level ATP synthesis. NAD
+ CoA Additional oxidation reactions produce an FADH 2 and another
NADH + H + and regenerate original C 4 molecule. 4. FAD C4C4 FADH 2
NAD + C5C Citric acid cycle Preparatory reaction CoA acetyl CoA
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig. 7.5 ATP 2 ADT2 2 ATP ee NADH ee ee
Glycolysis glucosepyruvate Preparatory reaction 2 ATP 2 ADP 4 ADP4
ATP total ATP net 1. The C 2 acetyl group combines with a C 4
molecule to produce citrate, a C 6 molecule. NADH + H + Matrix
Citric acid cycle NADH and FADH 2 Electron transport chain and
chemiosmosis 32 ADP or or 34 ATP NAD + NADH + H + CO 2 NADH + H +
CO 2 2.Oxidation reactions produce two NADH + H +. citrate The loss
of two CO 2 results In a new C 4 molecule. C4C4 C4C4 One ATP is
produced by substrate-level ATP synthesis. NAD + CoA Additional
oxidation reactions produce an FADH 2 and another NADH + H + and
regenerate original C 4 molecule. 4. FAD C4C4 FADH 2 NAD + C5C5 ee
ee ee ee Citric acid cycle Preparatory reaction CoA acetyl CoA Page
119 inputsoutputs 6 NAD + 2 ADP + 2 P ATP 2 Citric acid cycle 2
acetyl groups 4 CO 2 6 NADH + H + 2 FADH 2 2 FAD Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig. 7.6a 2 ADT 2 2 ATP NADH ee Glycolysis glucose
pyruvate Preparatory reaction 2 ATP 2 ADP 4 ADP 4 ATP total ATP net
Citric acid cycle NADH NADH and FADH 2 Electron transport chain and
chemiosmosis 32 or ADP or 34 ATP ee ee ee ee ee ee Copyright The
McGraw-Hill Companies, Inc. Permission required for reproduction or
display. Fig. 7.6b H2OH2O 2H + ADP + P O2O2 1 2 P P ATP FADH 2 FAD
+ 2H + 2e ee ee electron carrier 2e made by chemiosmosis made by
chemiosmosis made by chemiosmosis NAD + + 2H + NADH + H + electron
carrier electron carrier electron carrier electron carrier
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig. 7.6 H2OH2O 2H + ADP + P O2O2 1 2 P P
ATP FADH 2 FAD + 2H + 2e ee ee electron carrier 2e made by
chemiosmosis made by chemiosmosis made by chemiosmosis NAD + + 2H +
NADH + H + electron carrier electron carrier electron carrier
electron carrier 2 ADT 2 2 ATP NADH ee Glycolysis glucose pyruvate
Preparatory reaction 2 ATP 2 ADP 4 ADP 4 ATP total ATP net Citric
acid cycle NADH NADH and FADH 2 Electron transport chain and
chemiosmosis 32 or ADP or 34 ATP ee ee ee ee ee ee Fig. 7.7a
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reproduction or display. cristae intermembrane spacematrix Fig.
7.7b Copyright The McGraw-Hill Companies, Inc. Permission required
for reproduction or display. 2 ADP + H2OH2O NAD + H+H+ H+H+ H+H+
H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ P 2 + O2O2 1 2
Electron transportchain protein complex e-e- FADH 2 matrix ATP
synthase complex H+H+ H+H+ ATP channel protein intermembrane space
chemiosmosis FAD NADH + H + ATP e-e- e-e- e-e- e-e- Fig. 7.7
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. cristae 2 ADP + H2OH2O NAD + H+H+ H+H+
H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ H+H+ P 2 + O2O2 1
2 intermembrane spacematrix Electron transportchain protein complex
e-e- FADH 2 matrix ATP synthase complex H+H+ H+H+ ATP channel
protein intermembrane space chemiosmosis FAD NADH + H + ATP e-e-
e-e- e-e- e-e- Copyright The McGraw-Hill Companies, Inc. Permission
required for reproduction or display. Fig. 7.8 Cytoplasm Mito c
hondrion Electron transport chain 2 net 2 glucose subtotal 2 CO 2 4
CO 2 FADH or O 2 ATP or 34 ATP 2 pyruvate 2 acetyl CoA Citric acid
cycle NADH + H + glycolysis 6 H 2 O 36 or 38 total Copyright The
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display. Fig ADP 2 glucose G3P P ATP 2 2 Copyright The McGraw-Hill
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Fig ADP NAD + 2 glucose G3P BPG P P P P ATP 2 2 NADH + H + ATP 2
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig ADP 2 ADP NAD + 2 glucose G3P BPG P PP
P ATP NADH + H + ATP - 2 ATP + 4 ATP pyruvate 2 NADH + H +
Copyright The McGraw-Hill Companies, Inc. Permission required for
reproduction or display. Fig ADP 2 ADP NAD + 2 or glucose G3P BPG
alcohol P PP P ATP NADH + H ATP - 2 ATP + 4 ATP (net gain) lactate
pyruvate 2 NADH + H + CO 2 Copyright The McGraw-Hill Companies,
Inc. Permission required for reproduction or display. Fig ADP 2 ADP
NAD + 2 or glucose G3P BPG alcohol P PP P ATP NADH + H ATP - 2 ATP
+ 4 ATP (net gain) lactate pyruvate 2 NADH + H + CO 2 Page 122
inputsoutputs glucose 4 ADP +2 P ATP Fermentation 2 lactate or 2
alcohol and 2 CO 2 2 ADP net gain Copyright The McGraw-Hill
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Page 123 Cytoplasm NADH + H + and FADH 2 NADH + H + 4. Electron
transport chain 3. Citric acid cycle 1. Glycolysis glucose pyruvate
2. Preparatory reaction Copyright The McGraw-Hill Companies, Inc.
Permission required for reproduction or display. Page 124 a. b.
c.d. ATP e. ATP NADH + H +
