1. Fatty Acid Handling Beta-oxidation FA transport
Integration of metabolic signaling

2. Fatty Acid/b-oxidation Cycle
1x FADH2
1x NADH
Acetyl-CoA
3x NADH+
1xFADH2
Acyl(n)-CoA + NAD+ + FAD Acyl(n-2)-CoA + Acetyl-CoA + NADH +FADH2
Carnitine palmitoyltransferase
Fatty acid elongation
Acyl-CoA
Acyl-CoA synthase
FAD
Acyl-CoA dehydrogenase
Acyl-CoA
FADH2
acetyl-CoA acyltransferase
Acetyl-CoA
Didehydroacyl-CoA
Acyl-CoA hydrase
CoA-SH
3-hydroxyacyl-CoA dehydrogenase
Hydroxyacyl-CoA
Oxoacyl-CoA
NADH
NAD+

3. Fatty acid/carbohydrate oxidation
Oxygen
CnH2n + 3/2 n O2  n CO2+ n H2O
CnH2nOn +n O2 n CO2 + n H2O
Respiratory Quotient CO2/O2
0.67 Fatty acids
1.00 Carbohydrates
Adenine electron transporters
6-C glucose6 NADH + 2 FADH2 (3:1)
16-C FA  32 NADH + 16 FADH2 (2:1)

4. Reactive oxygen FADH2 oxidative stress
Succinate; saturated FA
FADH2 + Fe3+  FADH • + H+ + Fe2+
Fe2+ + H2O2Fe3+ + OH- + OH•
FADH2 more completely reduces UQ than does NADH
Acyl-CoA
Acyl-CoA
FAD
FADH2 UQ O2
Acyl-CoA dehydrogenase
Acyl-CoA oxidase
ETF:QO oxidoreductase
FADH2
FAD
UQH2
H2O2
Didehydroacyl-CoA
Didehydroacyl-CoA

5. Lipogenesis De novo synthesis of fatty acid Malonyl-CoA
Mostly liver (human; diet)
Cytoplasmic – ACC expression
Malonyl-CoA
Carboxylation of Acetyl-CoA
Working substrate for FAS
Fatty acid synthase
Sequentially transfers 2x C of Malonyl-CoA to fatty acid chain
16-C palmitoyl-CoA
Acetyl-CoA
Acetyl-CoA
Carboxylase
Malonyl-CoA
Fatty Acid
Synthase
Fatty acid
Fatty Acid
Synthase

6. Free fatty acids from triglycerides
FFA cleavage from circulating lipoproteins
Protein/cholesterol carriers: Lipoprotein
Density inversely correlates with lipid
Correlates with cholesterol/FA (except HDL)
VLDL & LDL to IDL
Lipoprotein lipase (LPL)
HDL scavenges cholesterol & facilitates IDL breakdown
Triglycerides are retained in intracellular droplets
Don’t fit in membrane (no phosphate)
Not water soluble

7. Mitochondrial import of fatty acids
FAAcyl-CoA Acyl-Carnitine Acyl-CoA
Cytoplasm
Intermembrane
Matrix
Working substrate
Boron & Boulpaep

8. Mitochondrial Transport
Carrier protein (FABP)
Long chain acyl-CoA synthetase (LCAS)
Cross outer membrane via porin
Convert to acylcarnitine in intermembrane
Cross inner membrane via carnitine:acylcarnitine transferase
Convert back to acyl-CoA in matrix

9. Regulation of lipid metabolism
Substrate/Allosteric
Palmitate inhibits insulin signaling
Malonyl-CoA inhibits FA transport to mt
Esp muscle, where ACC is mitochondrial
Citrate activates acetyl-CoA carboxylase
Palmitoyl-CoA inhibits ACC
Phosphorylation
AMP dependent kinase inhibits ACC
FAT/CD36 translocation

10. Allosteric regulation of FA metabolism
Carnitine Palmitoyltransferase
Fatty Acid Synthetase
ACC
Malonyl-CoA
Palmitoyl-CoA
Citrate
B-oxidation
NADH
Citric Acid Cycle
Acetyl-CoA
Citric acid cycle products promote FA synthesis
FA synthesis intermediaries inhibit FA import

11. Metabolic substrate selection
Fatty acids
Energy dense (37 kJ/g)
Abundant (95%)
O2 delivery limit
Diffusion limit
CHO
Low density (17 kJ/g)
Limited supply (5%)
Hydrated (67 wt%)
Lower O2 requirement
Readily available
Substrate selection is an issue for fed/fasted state and for overall activity
Lipolysis rate (%VO2)
Glcolysis rate (%VO2)
Total metabolic rate (%VO2 max)
McClelland, 2004

12. Signaling integration
Insulin/IGF-1
GLUT4 translocation
InsRIRS-1PI3KPDKPKB
--|GSK--|GS
mTORp70S6k/4EBP1
Fatty acids
Inhibit pyruvate dehydrogenase
Inhibit insulin signaling
FADAGPKC--|IRS-1
Activate glycogen synthase

13. AMP kinase Allosterically activated by AMP PFKglycolysis
Adenylate kinase: 2 ADP  AMP + ATP
ADP levels insensitive to energy state
PFKglycolysis
--|GSGlyconeogenesis
--|ACCMalonyl CoA--|CPTFA oxidation
--|ACClipogenesis
TSC2--|mTOR…protein synthesis
--|HMGCoAcholesterol synthesis

14. Hormonal Regulation Insulin Glucagon
Thyroid hormone (Triiodothyronine )
Steroid
T3TR
?CaMKKβ AMPK
Complex III/IV proteins, PGC-1
GLUT4
Epinepherine (adrenaline)
Tissue specific: muscle/liver
AdbARGsACcAMPPKA
GPglycogenolysis
lipolysis

15. Peroxisome Proliferator
PPAR-a/b/g (nuclear hormone, fatty acid sensor)
Transcriptional complex
PPAR(a/b/g), PGC-1(a/b), NRF-1/2, CREB
Subunits of Complex I-V; FAT; GLUT4
Mitochondrial biogenesis
Transcriptional Pathways
InsulinAkt--|FOXO--|PGC-1
Ca2+CaMKCREBPGC-1
Glucagon/stressPKACREBPGC-1
AMPK?PGC-1
Post-Translational, too
FADH2 O2
Peroxisome
FAD
H2O2
FADH2 UQ
Mitochondria
FAD
UQH2

16. Visceral FA subcutaneous ↑ congestive heart failure
PPAR/PGC signaling
↓ plasma NEFA
Visceral FA subcutaneous
↑ insulin sensitivity
↑ mitochondria
↑ congestive heart failure
↑ fluid retention
Fernandez-Marcos & Auwerx, 2011

17. Close relation between nutritive status and growth
Insulin/IGF via PI3K
Glycolysis/lipolysis
Protein synthesis
Differentiation
AMP-Kinase
IGF inhibition
AcetylCoA/CoA
Inhibit pyruvate dehydrogenase
NADH converts oxaloacetate to malate, reduces TCA intermediaries, including citrate
Growth hormone release
NAD+/NADH increases with cell confluence