1. ENERGY YIELD 6 CO2 5 Total = 12 ATP 4 Citrate Isocitrate
CH3C O ~
S-CoA
Citrate
Isocitrate
a-ketoglutarate
Succinyl-CoA
Succinate
Fumarate
Malate
Oxaloacetate
CO2 6 5 4
ENERGY YIELD
NADH + H+
3 ATP
3 ATP
1 ATP
2 ATP
NADH + H+
3 ATP
FADH2
Total = 12 ATP
NADH + H+
GTP

2. Prochirality Ogston’s 3 Point Attachment Theory Aconitase CH2-COO
HO-C-COO
Prochirality
Symmetrical
CH2COO OH C C HO
CH2COO
OOC
COO
CH2COO
CH2-COO
Ogston’s 3 Point Attachment Theory

3. Ogston’s Three-point Attachment Theory of Aconitase
Test this yourself
Middle
Index
Right Hand
Thumb
Only your right hand will fit the pattern. Therefore, only one of the isomers of citrate will fit on the enzyme surface in the correct orientation

4. .. Glyoxysomes Glyoxylate Cycle Citrate Isocitrate a-ketoglutarate
CH3C O ~
S-CoA
Glyoxylate Cycle
(germinating plant seeds)
Glyoxysomes
(plant organelles)
Starch
H-C-COO
HO-C-COO H ..
Malate Synthase
CO2
Citrate
Isocitrate
a-ketoglutarate
Succinyl-CoA
Succinate
Fumarate
Malate
Oxaloacetate
CHO
COO
Isocitrate Lyase
Glyoxylate
All 6 carbons are
preserved
Bypass
COO-
CH2
Mitochondria

5. Glyoxysome Mitochondria P 625 Aspartate Aspartate Oxaloacetate
-Ketoglutarate
-Ketoglutarate
Glutamate
Glutamate
Oxaloacetate
Oxaloacetate
NAD+
NADH
Acetyl-CoA
HS-CoA
Malate
Citrate
Fumarate
Isocitrate
Isocitrate lyase
FAD
FADH2
Glyoxylate
Succinate
Succinate
Malate synthase
Acetyl-CoA
HS-CoA
Malate
NAD+
NADH
P 625
OAA
Gluconeogenesis
Starch

6. Summary of Reactions

7. 6 4 2
1 ATP
9 ATPs
2 ATPs

8. Where do we get all that energy?
1. How energetic is citrate?
6 Carbons
= 3 Cycle Turns
= 3 x 12 ATP per cycle
= 36 ATPs
2. How energetic is oxaloacetate
4 Carbons
to Citrate
= 2 Cycle turns
= 24 ATPs
3. How energetic is malate
4 Carbons = 2 Cycle turns + 1 NADH
= 27 ATPs

9. Regulation of the Kreb’s Cycle
Pyruvate Dehydrogenase complex
Pyruvate + TPP  Acetal-TPP + CO2
Acetal-TPP + S-S  Ac-S ^ SH + TPP
Ac-S ^ SH + HS-CoA  AcS-CoA + HS ^ SH
HS ^ SH + FAD  S-S + FADH2
FADH2 + NAD+  FAD + NADH + H+
Pyruvate + HS-CoA + NAD+  Acetyl-CoA + NADH + H+
Regulators-Activators
Regulators- Inhibitors
and AMP
Fatty acids and ATP

10. Key Regulatory Points:
1. Pyruvate dehydrogenase Complex
Inhibited by NADH and Acetyl-CoA
NADH
[NAD+]
Acetyl-CoA
HS-CoA
High NADH means that the cell is experiencing a
surplus of oxidative substrates and should not produce
more. Carbon flow should be redirected towards synthesis.
High Acetyl-CoA means that carbon flow into the Krebs cycle is abundant and should be shut down and rechanneled towards biosynthesis

11. Mechanism: 1. Competitive Inhibition
Text p621
1. Competitive Inhibition
NADH and acetyl-CoA reverse the pyruvate dehydrogenase
reaction by competing with NAD+ and HS-CoA
2. Covalent Modification (second level regulation)
E-1 subunits of PDH complex is subject to phosphorylation
TPP
FAD 1 2 3
Epinephrine
Glucagon
E1-OH
E1-OPO3
H2O
HPO4=
ATP
ADP
PDH
kinase
phosphatase
Active
Inactive
Cyclic-AMP
protein kinase
Insulin
ATP

12. All regulatory enzymes occur in the first half of the cycle
Regulation of Cycle Enzymes
Go’
(kJ/mol)
Enzyme
Citrate Synthase
Aconitase ~5
Isocitrate dehydrogenase -21
-Ketoglutarate dehydrogenase -33
Succinyl-CoA Synthase
Succinate dehydrogenase +6
Fumarase
Malate dehydrogenase
All regulatory enzymes occur in the first half of the cycle

13. Regulation of the Citric Acid Cycle
Primary modes:
1. Substrate availability (key enzymes are subsaturated)
2. Product inhibition
Allostery is not a primary mode
3. Feedback inhibition (competitive)
Key regulators:
1. Acetyl-CoA (controls citrate synthase)
2. OAA (controls citrate synthase, regulated by NADH)
3. NADH (controls citrate synthase, isocitrate dehydrogenase
4. Calcium (stimulates NADH production)

14. Controls NADH and is controlled by NADH
Equilibria to Consider
O2 consumption
NADH oxidation
ATP production
Controls NADH and is controlled by NADH
Tightly coupled: affect one is to affect all
Malate + NAD+
OAA + NADH
A working muscle will increase respiration and oxidize NADH. This stimulates OAA synthesis which stimulates citrate synthase and isocitrate dehydrogenase reactions.

15. Citrate Malate + NAD+ OAA + NADH Substrate limited K = [OAA][NADH]
-Kg dehydrogenase
Isocitrate dehydrogenase
K [Malate][NAD+]
[OAA][NADH]
Respiration (O2)
Respiration Increases

16. P 621 Pyruvate Dehydrogenase Citrate Synthase No Regulation Isocitrate
-Ketoglutarate
Dehydrogenase