1. Clicker Question #1
1. What compound directly provides energy for cellular work?
A. DNA
B. C6H12O6
C. glucose
D. ATP
E. fat 1

2. Energy Conversion Energy conversion Fuel rich in chemical energy
Waste products
poor in chemical
energy
Energy conversion
Heat
energy
Gasoline 
Oxygen
Carbon dioxide 
Water
Combustion
Kinetic
energy
of movement
Energy conversion in a car
Heat
energy
Cellular
respiration
Carbon dioxide 
Water
Food 
Oxygen
ATP
Energy for cellular work
Energy conversion in a cell 2

3. Cellular Respiration
Cellular respiration: A catabolic energy yielding pathway in which oxygen and organic fuels are consumed and ATP is produced
An aerobic process—it requires oxygen
Summary equations:
Organic Oxygen Carbon + Water + Energy
Compounds
Dioxide 3

4. Glucose loses electrons Oxygen gains electrons (and hydrogens)
Cellular Respiration
•By oxidizing glucose, energy is taken out of “storage” and made available for ATP synthesis
Oxidation
Glucose loses electrons
(and hydrogens)
C6H12O6
 6 O2 6
CO2
 6
H2O
Glucose
Oxygen
Carbon
dioxide
Water
Reduction
Oxygen gains electrons (and hydrogens)

5. *Substrate-level phosphorylation
Cellular Respiration
*Substrate-level phosphorylation
3 metabolic stages:
*glycolysis *Krebs cycle
*electron transport chain and oxidative phosphorylation
*Oxidative phosphorylation

6. 2 2 ~34 ~38 ATP per glucose Mitochondrion Cytoplasm Cytoplasm
Animal cell
Plant cell
Animal cell
Plant cell
Cytoplasm
Cytoplasm
Mitochondrion
Mitochondrion
High-energy
electrons
carried
by NADH
High-energy
electrons
carried
by NADH
High-energy
electrons carried
mainly by
NADH
High-energy
electrons carried
mainly by
NADH
Glycolysis
Citric
Acid
Cycle
Citric
Acid
Cycle 2
Pyruvic
acid
Glycolysis
Electron
Transport
Glucose
Electron
Transport
~38 ATP per glucose 2
ATP 2
ATP
~34
ATP
ATP
ATP
ATP
Figure 6.6 6

7. Metabolic Disequilibrium
*Multi-step open system

8. Glycolysis harvests chemical energy by oxidizing glucose to pyruvate

9. Glycolysis: Energy Investment Phase
3) Addition of another phosphate group
1) Glucose is phosphorylated
4) Cleavage into carbon sugars
2) G-6-P is rearranged
5) Conversion b/w the 2 3-carbon sugars

10. Glycolysis: Energy Payoff Phase
6) Two components: *electron transfer *Phosphate group addition
Glycolysis: Energy Payoff Phase
9) Loss of water
7) ATP production
10) ATP production
8) Rearrangement of phosphate group

11. Fermentation enables cell to produce ATP w/o O2
aerobic
anaerobic
*Fermentation generates ATP by substrate-level phosphorylation

12. The presence or absence of O2 dictates the fate of pyruvate
aerobic
anaerobic

13. The Krebs cycle: energy-yielding oxidation
The junction b/w glycolysis and the Krebs cycle:
Multienzyme complex:
1) Removal of CO ) Electron transfer *pyruvate dehydrogenase ) Addition of CoA

14. The Krebs cycle: energy-yielding oxidation
8) electron transfer Malate dehydrogenase
1) Addition of 2 Carbons Citrate synthase
2) Isomerization Aconitase
3) *Loss of CO2 *electron transfer Isocitrate dehydrogenase
7) Rearrangement of bonds Fumarase
4) *Loss of CO2 *electron transfer a-ketoglutarate dehydrogenase
6) electron transfer Succinate dehydrogenase
5) substrate-level phosphorylation Succinyl CoA-synthetase

15. Electron transport and ATP synthesis
*Multi-step open system

16. Generation and maintenance of an H+ gradient
*Exergonic flow of e-, pumps H+ across the membrane
*chemiosmosis
high energy electrons

17. ATP synthase
*How does the mitochondrion couple electron transport and ATP synthesis?

18. Versatility of Cellular Respiration
In addition to glucose, cellular respiration can “burn”:
Diverse types of carbohydrates
Fats
Proteins
Food
Polysaccharides
Fats
Proteins
Sugars
Glycerol
Fatty
acids
Amino acids
Citric
Acid
Cycle
Acetyl
CoA
Glycolysis
Electron
Transport
ATP 18