1. Oxidation and Reduction Reactions
Electron transfer from an electron donor to an electron acceptor
simultaneously
Cells use electron carriers to carry electrons (often in H atoms)
Two important electron carriers
Nicotinamide adenine dinucleotide (NAD+)
3 ATP per Molecule
Flavine adenine dinucleotide (FAD) → FADH2
2 ATP Per Molecule
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2. Figure 5.2 Oxidation-reduction, or redox, reactions
Electron donor
Oxidized donor
Electron acceptor
Reduced acceptor
Oxidation

3. Carbohydrate Catabolism
Many organisms oxidize carbohydrates as primary energy source
Remove electrons
Glucose most commonly used
Glucose catabolized by two processes: cellular respiration and fermentation
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4. Figure 5.12 Summary of glucose catabolism
Respiration
G L Y C O L Y S I S
Glucose
Fermentation
2 Pyruvic acid
Pyruvic acid (or derivative)
Formation of fermentation end-products
Acetyl-CoA
KREBS CYCLE
ELECTRON TRANSPORT
Electrons

5. Carbohydrate Catabolism
Glycolysis Overview
Occurs in cytoplasm of most cells
Involves splitting of a six-carbon glucose into two three-carbon sugar molecules
Net gain of two ATP molecules
Two molecules of NADH
Precursor metabolite pyruvic acid
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6. Carbohydrate Catabolism
Glycolysis
Divided into three stages involving 10 total steps
Energy-investment stage
2 ATP are used to phosphorylate glucose
Lysis stage
Fructose, 1,6-bipohsphate is cleaved
Energy-conserving stage
Pyruvic acid is produced
4 ATP are produced
2 NADH are produced
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7. Figure 5.13 Glycolysis-overview

8. Carbohydrate Catabolism
Cellular Respiration
Resultant pyruvic acid completely oxidized to produce ATP by series of redox reactions
Three stages of cellular respiration
1. Synthesis of acetyl-CoA
2. Krebs cycle
3. Final series of redox reactions (electron transport chain)
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9. Carbohydrate Catabolism
Cellular Respiration
1) Synthesis of acetyl-CoA
Pyruvic acid is converted into acetyl-coenzyme A (acetyl-CoA)
Happens to both pyruvic acid molecules
2 molecules of acetyl-CoA
2 molecules of CO2
2 molecules of NADH
Cytoplasm
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10. Figure 5.15 Formation of acetyl-CoA
Respiration
Fermentation
Pyruvic acid
Decarboxylation
Acetate
Coenzyme A
Acetyl-coenzyme A (acetyl-CoA)

11. Carbohydrate Catabolism
Cellular Respiration
2) The Krebs cycle
Great amount of energy remains in bonds of acetyl-CoA
Transfers much of this energy to coenzymes NAD+ and FAD
Occurs in cytosol of prokaryotes and in matrix of mitochondria in eukaryotes
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12. Figure 5.16 The Krebs cycle Acetyl-CoA OOH OOH OOH OOH
Respiration
Fermentation
Acetyl-CoA
OOH
OOH
OOH
OOH
Oxaloacetic acid
OOH
Citric acid
OOH
OOH
OOH
Malic acid
OOH
OOH
Isocitric acid
KREBS CYCLE
OOH
HOO
Fumaric acid
OOH
OOH
-Ketoglutaric acid
OOH
OOH
OOH
Succinic acid
Succinyl-CoA

13. Carbohydrate Catabolism
Cellular Respiration
The Krebs cycle
Results in
Two molecules of ATP
Two molecules of FADH2
Six molecules of NADH
Four molecules of CO2
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14. Carbohydrate Catabolism
Cellular Respiration
3) Electron transport Chain
Most significant ATP production
Carrier molecules pass electrons from one to another to final electron acceptor
Energy from electrons used to pump protons (H+) across the membrane, establishing a proton gradient
Located in cristae of eukaryotes and in cytoplasmic membrane of prokaryotes
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15. Figure 5.17 An electron transport chain
Respiration
Fermentation
Path of electrons
Reduced
FMN
Oxidized
Oxidized
FeS
Reduced
Reduced
CoQ
Oxidized 2
Oxidized
Cyt
Reduced
Reduced
Cyt
Oxidized 2
Oxidized
Cyt
Reduced 2 2
Final electron acceptor

16. Carbohydrate Catabolism
Cellular Respiration
Electron transport
Four categories of carrier molecules
Flavoproteins- NADH enters here
Ubiquinones- FADH2 enters here
Metal-containing proteins
Cytochromes
Aerobic respiration: oxygen serves as final electron acceptor
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17. Electron transport chain
Figure 6.11a
Space
between
membranes H H H H H H H H
Electron
carrier H H H H H
Protein
complex
Inner
mitochondrial
membrane – –
FADH2
FAD H
Electron
flow 1 2 O2 2 H
H2O – –
Figure 6.11 How electron transport drives ATP synthase machines (part 1)
NADH
NAD
ADP P
ATP H H H H H
Matrix
Electron transport chain
ATP synthase

18. Figure 5.18 One possible arrangement of an electron transport chain
Bacterium
Mitochondrion
Intermembrane space
Matrix
Exterior
Cytoplasmic membrane
Cytoplasm
Exterior of prokaryote or intermembrane space of mitochondrion
FMN
Ubiquinone
Cyt b
Phospholipid membrane
Cyt a3
Cyt c
Cyt a
NADH from glycolysis, Krebs cycle, pentose phosphate pathway, and Entner-Doudoroff pathway
Cyt c2
FADH2 from Krebs cycle
ATP synthase
Cytoplasm of prokaryote or matrix of mitochondrion

19. Carbohydrate Catabolism
Cellular Respiration Summary
In glycolysis and the Krebs cycle
Electrons are taken from glucose and transferred to NADH and FADH2
NADH and FADH2 pass their electron to the ETC
As the electron move down the chain, proton pumps use energy to move protons across the membrane
Creating a proton gradient
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20. Carbohydrate Catabolism
Cellular Respiration
Chemiosmosis
Use of electrochemical (ion) gradients to generate ATP
Create proton gradient from energy released in redox reactions of ETC
“Water held behind a dam”
Protons flow down electrochemical gradient through ATP synthases that phosphorylate ADP to ATP
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21. Carbohydrate Catabolism
Cellular Respiration
Chemiosmosis
Pumps three protons per NADH
3 ATP per NADH
30 ATP
Pumps two protons per FADH2
FADH2 delivers electrons further down the chain
Transfers 1/3 fewer protons
2 ATP per FADH2
4 ATP
34 ATP from ECT
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22. Carbohydrate Catabolism
Cellular Respiration
Glycolysis- net 2 ATP
Krebs cycle- 2 ATP
ETC- 34 ATP
38 ATP total
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23. Respiration Review

24. Practice
Label the diagram of respiration with the proper terms.

25. Carbohydrate Catabolism
Fermentation
Sometimes cells cannot completely oxidize glucose by cellular respiration
Cells require constant source of NAD+
Cannot be obtained simply using glycolysis and Krebs cycle
Fermentation pathways provide cells with source of NAD+
Uses organic molecule within cell as final electron acceptor
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26. Carbohydrate Catabolism
Fermentation
Any spoilage of food by microorganisms
Any process that produces alcoholic beverages or acidic dairy products
Scientific definition:
Releases energy from oxidation of organic molecules
Does not require oxygen
Does not use the Krebs cycle or ETC
Uses an organic molecule as the final electron acceptor
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27. Carbohydrate Catabolism
Fermentation
Allows ATP production to continue in the absence of cellular respiration
Not as efficient as cellular respiration
Most of the energy remains in the bonds of the fermentation product
Products include: ethanol and lactic acid
Fermentation can be used to identify mos
Proteus ferment lactose
E. coli ferments glucose and lactose
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28. Carbohydrate Catabolism
Fermentation
Contains single carbohydrate and a source of protein
Used to identify what carbon source a microbe can use
If sugar is used, acidic end products and gas are produced
pH indicator changes color
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29. Figure 5.21 Fermentation Pyruvic acid Lactic acid Acetaldehyde Ethanol
Respiration
Fermentation
Pyruvic acid
Lactic acid
Acetaldehyde
Ethanol

30. Figure 5.22 Representative fermentation products and the organisms that produce them
Glucose
Pyruvic acid
Aspergillus Lactobacillus Streptococcus
Organisms
Propionibacterium
Saccharomyces
Clostridium
Fermentation
CO2, propionic acid
Lactic acid
CO2, ethanol
Acetone, isopropanol
Fermentation products
Swiss cheese
Cheddar cheese, yogurt, soy sauce
Wine, beer
Nail polis remover, rubbing alcohol