1. Ex Nutr c7-fat

2. Ex Nutr c7-fat

3. Ex Nutr c7-fat
Lipoproteins 脂蛋白

4. Ex Nutr c7-fat

5. Ex Nutr c7-fat

6. Ex Nutr c7-fat

7. Ex Nutr c7-fat

8. Ex Nutr c7-fat

9. Fat Metabolism during Exercise
Ex Nutr c7-fat
Fat Metabolism during Exercise
Adipose Tissue - Triacylglycerol
Fatty Acid + Glycerol  circulation
Re-esterification 再酯化: FA not released into circulation, but used to form new TG within adipose tissue
Intramuscular Triacylglycerol (IMTG)
Hormone Sensitive Lipase (HSL)
Circulation Triacylglycerol
Via Lipoprotein Lipase

10. Ex Nutr c7-fat

11. Ex Nutr c7-fat
Fig 6.1 overview of fat metabolism

12. What Limits Fat Oxidation
Ex Nutr c7-fat
What Limits Fat Oxidation
Lipolysis in Adipocytes
Removal of FAs from fat cell
Transport of fat by the bloodstream
Transport of FAs into the muscle cell
Transport of FAs into the Mitochondria
Oxidation of FAs in the β-oxidation pathway and TCA cycle

13. Lipolysis in Adipocytes
Ex Nutr c7-fat
Lipolysis in Adipocytes
HSL – inactive form and active form
Sympathetic nervous system
Epinephrine
Insulin
Fate of glycerol
bloodstream – Liver for gluconeogenesis
Not used in adipocytes, because glycerolkinase very low (glycerol  glycerolphosphate  glycolysis)

14. Lipolysis in adipocytes
Ex Nutr c7-fat
Lipolysis in adipocytes
Fate of fatty acid
Re-esterification: 70% at rest
FA-binding proteins (FABP), transport FA to cell membrane
Exercise:↓re-esterification, ↑lipolysis  ↑ FA in blood
Lipolysis in excess of demand for FA at rest and during exercise
Glycerol-P for re-esterification in adipocytes from glycolysis pathway

15. Ex Nutr c7-fat

16. Ex Nutr c7-fat

17. Removal of FAs from fat cell and Transport of fat by the bloodstream
Ex Nutr c7-fat
Removal of FAs from fat cell and Transport of fat by the bloodstream
Blood flow to adipose tissue
Albumin concentration and available binding sites
A transporter of FAs
3 site for FAs
Typical plasma concentration 0.7 mM (45 g/L)
Albumin bind to albumin-binding proteins in target tissue, facilitate FA release and uptake
Maximal FA concentration in blood – 2 mM
Free FA toxic
Protective mechanism: incorporated into VLDL in liver
Lipoprotein TG <3% energy during prolonged ex
LPL activity ↑after training, ↑fat oxidation

18. Transport of FAs into the muscle cell
Ex Nutr c7-fat
Transport of FAs into the muscle cell
Plasma membrane FA binding protein (FABPpm)
FA transporter – FAT/CD36
Fatty acid translocase
Saturated at 1.5 mmol/l - FA
Muscle contraction – translocation FAT/CD36
Cytoplasmic FA binding protein (FABPc)

19. Ex Nutr c7-fat
Fig 7.4 transport of glucose and FA

20. Intramuscular Triacylglycerol
Ex Nutr c7-fat
Intramuscular Triacylglycerol
Lipid droplets, usually located adjacent to mitochondria
Important energy source during exercise
Located closer to Mitochondria in trained muscle
HSL
FA released bound to FABPc until transported into mitochondria

21. Ex Nutr c7-fat
Fig 7.5 Electromyograph of skeletal muscle. Lipid droplet (li); mitochondria (mi); glycogen (gl)

22. Transport of FAs into Mitochondria
Ex Nutr c7-fat
Transport of FAs into Mitochondria
Acyl-CoA Synthetase
CPT I & CPT II
Carnitine Palmitoyl Transferase I & II
Short- and Medium-Chain FAs diffuse freely into mitochondrial matrix
Fatty acyl-CoA in mitochondrial matrix is subjected to beta-oxidation
Acetyl-CoA for TCA cycle

23. Ex Nutr c7-fat
Fig 7.6 Transport of FA into mitochondria

24. Ex Nutr c7-fat
Fig 7.7 beta-oxidation

25. Ex Nutr c7-fat

26. Fat As A Fuel During Exercise
Ex Nutr c7-fat
Fat As A Fuel During Exercise
At Rest
Lipolysis regulated by hormones
FA concentration mM in blood
During moderate exercise
↑Lipolysis ~3X, ↑ blood to adipose tissue 2X, ↓re-esterification 0.5X, ↑ blood flow to muscle
FA in blood decrease in the first 15 min: rate of uptake by muscle > rate of appearance by lipolysis
FA increase thereafter, may reach 1 mM
Higher intensity exercise
Rise in plasma FA very small or absent
Lactate ↑re-esterification in adipocyte, ↓FA release

27. Lactate ↑re-esterification in adipocyte, ↓FA release
Ex Nutr c7-fat
Lactate ↑re-esterification in adipocyte, ↓FA release

28. Fat Oxidation, Exercise Duration and intensity
Ex Nutr c7-fat
Fat Oxidation, Exercise Duration and intensity
↑ Fat oxidation when exercise duration ↑
Fat Oxidation rate at 1.0 g/min after 6 hr running
Fat oxidation rate can reach 1.5 g/min after high-fat meal
Low to moderate intensity – Fat dominated
>75%VO2max – Fat oxidation rate inhibited
Maximal fat oxidation rate usually 62-63% VO2max

29. Ex Nutr c7-fat
Fig 7.8 Fat oxidation as function of exercise intensity

30. Fat Oxidation and Exercise Intensity
Ex Nutr c7-fat
Fat Oxidation and Exercise Intensity
Infusion of TG (Intralipid) and heparin 肝素during higher intensity exercise ↑FA oxidation rate
But still lower than at moderate intensity
Even plasma FA concentration same as that at moderate intensity
During higher intensity exercise, oxidation of long-chain FA impaired, but oxidation of medium-chain FA unaffected
↑glycolytic flux, ↑pyruvate and acetyl-CoA, inhibit CPT-1
Carnitine-dependent FA transport may be limiting factor for FA oxidation during exercise
Medium-chain FA do not need transport system across mitochondria

31. Ex Nutr c7-fat
Fig 7.9 substrate utilization at different exercise intensities

32. Ex Nutr c7-fat
Fig 7.10 Lipid-heparin infusion significantly ↑plasma [FA] and fat oxidation rate at 85% VO2max.
The fat oxidation rate with infusion is still lower than that in 65% VO2max (not shown), Fat infusion ↓CHO oxidation rate by ↓ muscle glycogen utilization (not shown)

33. Fat Oxidation and Aerobic Capacity
Ex Nutr c7-fat
Fat Oxidation and Aerobic Capacity
Endurance training↑fat oxidation contribute to total energy expenditure
↑ Mitochondria density, ↑ Oxidative enzyme
↑ Capillary density  ↑FAs, oxygen to muscle
↑ FABP
↑ CPT
After training, rate of lipolysis at same absolute exercise intensity NOT affected
After training, rate of lipolysis at same relative exercise intensity NOT affected
↑IMTG lipolysis contribute to ↑whole-body lipolysis

34. Fig 7.11 Whole-body lipolysis in trained and untrained subjects
Ex Nutr c7-fat
Fig 7.11 Whole-body lipolysis in trained and untrained subjects

35. Fat Oxidation and Diet High CHO, low fat diet : ↓fat oxidation
Ex Nutr c7-fat
Fat Oxidation and Diet
High CHO, low fat diet : ↓fat oxidation
High fat, low CHO diet: ↑fat oxidation
Fat oxidation still higher after 5 days of high-fat diet and then 1- day high-CHO diet
Compared to 6-day high-CHO diet
1-day high-CHO diet replenish muscle glycogen, similar levels in both groups
Not due to substrate availability
Adaptations at muscular level may occur within 5 days
Chronic diet may affect metabolism

36. Response to Carbohydrate Feeding
Ex Nutr c7-fat
Response to Carbohydrate Feeding
Ingestion of CHO before exercise, ↑ Insulin secretion
↑CHO oxidation, ↓Fat oxidation
FA availability only partially responsible
Glucose feeding 1 hr before exercise ↓plasma FA concentration and ↓ Fat oxidation
Infusion of Intralipid and heparin only partially restored fat oxidation
Study using labeled Long- and Medium-chain FA indicated carnitine-dependent FA transport into mitochondria also responsible

37. Ex Nutr c7-fat

38. Regulation of CHO & Fat Metabolism
Ex Nutr c7-fat
Regulation of CHO & Fat Metabolism
↓Muscle glycogen breakdown with ↑plasma FA concentration
Infusion of intralipid
Fat feeding in combination with heparin infusion (↑lipoprotein lipase and hepatic lipase activities)
Problems in control group
FA concentration very low, <0.2 mM
↑glycogen breakdown in control group, rather than observed glycogen-sparing effect in high-fat group

39. Ex Nutr c7-fat

40. Regulation of CHO & Fat Metabolism – glucose- fatty acid cycle
Ex Nutr c7-fat
Regulation of CHO & Fat Metabolism – glucose- fatty acid cycle
↑plasma FA, ↑FA uptake, ↑acetyl-CoA and citrate
↑acetyl-CoA/CoA inhibit pyruvate dehydrogenase
↓pyruvate  acetyl-CoA
↑citrate  inhibit phosphofructokinase
After citrate diffuse into sarcoplasma
↓glycolysis  accumulation of glucose-6-P in sarcoplasma  ↓hexokinase, ↓muscle glucose uptake
↑FA availability ↑NADH  ↓intramuscular Pi and AMP
Pi and AMP stimulate glycogen phosphorylase
↑FA availability  ↓muscle glycogen breakdown

41. Fig 6.14 Glucose-FA cycle, or Randle cycle
Ex Nutr c7-fat
Fig 6.14 Glucose-FA cycle, or Randle cycle

42. Regulation of CHO & Fat Metabolism – recent theory
Ex Nutr c7-fat
Regulation of CHO & Fat Metabolism – recent theory
Fat dose NOT regulate CHO metabolism
It is CHO that regulates fat metabolism
↑glycolysis ↓fat oxidation
↑acetyl-CoA in muscle during high-intensity ex
Some acetyl-CoA  malonyl-CoA by acetyl-CoA carboxylase
CPT1 inhibition  ↓FA transport to mitochondria
By ↑ Malonyl-CoA
Also by ↓ intramuscular pH during high-intensity ex
↑acetyl-CoA bind to carnitine  ↓free carnitine, ↓cartinine for FA transportation
Fat oxidation mainly influenced by fat availability and rate of CHO oxidation

43. Fig 6.15 Glucose FA cycle reversed
Ex Nutr c7-fat
Fig 6.15 Glucose FA cycle reversed

44. Fat Supplementation and Exercise
Ex Nutr c7-fat
Fat Supplementation and Exercise
Ingestion of Long-Chain Triacylglyerols
Dietary LCFA  TG in chylomicron
Breakdown of TG in chylomicron very low by muscle during exercise, should avoid fat intake
Replenishment of IMTG stores AFTER exercise
Some sports bars or energy bars contain high fat
Ingestion of Medium-Chain Triacylglyerols
C8 or C10, very low in natural foods, mainly used as supplements
Most studies showed no effect on performance
Large ingestion (> 15 g/h) may cause GI problems
Ingestion of Fish Oil
Omega-3 FAs
More omega-3 FAs incorporated into membrane, may improve membrane characteristics and function

45. Effects of Diet on Fat Metabolism and Exercise Performance
Ex Nutr c7-fat
Effects of Diet on Fat Metabolism and Exercise Performance
Fasting
↑lipolysis, ↑plasma FA
↓ endurance performance, even with CHO ingestion during exercise
Effects of Short-term high-fat diet
↑lipolysis, ↑plasma FA ,↑Fat oxidation rate, ↑ Ketone bodies 酮體(5X after 5 days of high-fat diet)
↓ endurance performance, ↓ muscle glycogen

46. Effects of long term high-fat diet (several weeks) on performance
Ex Nutr c7-fat
Effects of long term high-fat diet (several weeks) on performance
60-65% VO2max, may be impractical
Maintain time to exhaustion at 60-65% VO2max, despite muscle glycogen ↓by 50%
CPT↑ 44%, hexokinase ↓46%
Relatively low intensity, reduced CHO stores may not be limiting factor
7 wk high-fat + 1 wk high-CHO vs 8 wk high-CHO
Time to exhaustion at 81% VO2max↑from wk7 to wk 8
Still less than 8-wk high-CHO group
Suboptimal adaptation to training
High-fat diet
may only helpful in low-intensity exercise
Negative effect on general health
Not recommended for athletes

47. Ex Nutr c7-fat

48. Fig 7.17 high-fat diets and performance during training in humans
Ex Nutr c7-fat
Fig 7.17 high-fat diets and performance during training in humans

49. Fat adaptation impair glycogenolysis
Ex Nutr c7-fat
Fat adaptation impair glycogenolysis
Most fat adaptation studies (days or weeks of high-fat diet) show no effect on endurance performance
Despite ↑fat oxidation, ↓CHO oxidation
High-fat diet ↑pyruvate dehydrogenase kinase,  ↓pyruvate dehydrogenase
At rest, throughout 70% VO2max exercise, 1-min sprint
‘glycogen sparing’ effect of high-fat diet actually impairment of glycogenolysis

50. Ex Nutr c7-fat
Spriet LL, JSS 2004

51. Pyruvate DH kinase inactivate PDH
Ex Nutr c7-fat
Pyruvate DH kinase inactivate PDH

52. Ex Nutr c7-fat
Stellingwerff T, AJP 2006

53. Ex Nutr c7-fat
Stellingwerff T, AJP 2006

54. Post-exercise IMTG recovery?
Ex Nutr c7-fat
Post-exercise IMTG recovery?
Post-ex high-fat diet ↑IMTG recovery
IMTG is NOT limiting factor for performance
Inhibit glycogen recovery
Spriet LL, JSS 2004

55. Gender difference in fat use
Ex Nutr c7-fat
Gender difference in fat use
Women oxidized more fat at 65-75% VO2max
Lower RER at same exercise intensity
Men improved performance after CHO loading but women did NOT
Even ↑muscle glycogen
Estrogen? Other factors?