1. Amino Acid Metablism

2. Overview of AA metabolism
Ex Biochem c8-AA metabolism
Overview of AA metabolism
Principal source of AA from food protein
Broken down to free AA, absorbed into blood
>50% dietary AA taken up by liver
Essential AA: can not synthesized by body, arg, his, Isoleu, leu, lys, met, phenylala, threonine, tryptophan, val
AA pool: AA in blood and extracellular fluids
No ability to store AA, extra AA used as fuels
Very small compared to total protein in body
AA and protein turnover very quickly
Liver responsible for much of AA metabolism
Kidney in smaller extent
Skeletal muscle the largest repository of free and protein-bound AA in body

3. Ex Biochem c8-AA metabolism

4. Overview of AA metabolism
Ex Biochem c8-AA metabolism
Overview of AA metabolism

5. Ex Biochem c8-AA metabolism
AA transporters
AA have charged groups, they need protein transporters to transfer between extracellular and intracellular compartments
2 broad categories of AA transporters
Na-dependent: move into cell down Na concentration gradient, can be moved against AA concentration gradient
Na-independent
AA transporters may have broad specificity, recognizing several AA
Some have narrow specificity, recognizing only 1-2 closely related AA
Competition for the same transporters

6. Ex Biochem c8-AA metabolism
Degradation of AA
Balance among AA can be achieved by conversion reactions
One AA changed into another by transfer of amino group
18 AA are glucogenic: provide all or part of their carbon atom for gluconeogenesis
Ketogenic: leucine, lysine
AA undergo constant oxidative degradation:
Normal synthesis and degradation, not immediately used for protein synthesis
Ingest more AA than body can use to make proteins
Starvation
Overtaining, imbalance in protein turnover (testosterone/cortisol ratio)

7. Transamination reactions
Ex Biochem c8-AA metabolism
Transamination reactions
Transfer of amino groups in all AA except thr, lys
Aminotransferase enzyme, transaminase
Most transfer to a-ketoglutarate, making glutamate
Freely reversible, net direction depend on relative concentration of 4 reactants
Alanine aminotransferase (glutamate pyruvate transaminase, GPT)
Alanine + a-KG < pyruvate + glutamate
Aspartate aminotransferase (glutamate oxaloacetate transaminase, GOT)
Asp + a-KG < oxaloacetate + glutamate

8. Transamination reactions
Ex Biochem c8-AA metabolism
Transamination reactions

9. Ex Biochem c8-AA metabolism

10. Deamination reactions
Ex Biochem c8-AA metabolism
Deamination reactions
Nitrogen from amino groups in liver in the form of glutamate can be released as ammonia
Glutamate + H2O + NAD+  a-KG + NADH + H+ + NH4+
Glutamate dehydrogenase
Production of NH4 and its release from muscle proportional to exercise intensity
Glutamate DHase reactions
Deamination of AMP by AMP deaminase
NH4+ play a role in peripheral and central fatigue
Increased acidity in muscle
Cross blood brain barrier, increased NH4+ uptake by brain

11. Ex Biochem c8-AA metabolism
Glutamine
Special AA even though not essential
Important fuel for gut and immune system (macrophages, lymphocytes)
Free glutamine concentration high in variety of cells and in blood
~60% AA pool
Mostly synthesized from glutamate by glutamine synthetase
Deamination of glutamine
Glutaminase: glutamine + H2O  glutamate + NH4+

12. Ex Biochem c8-AA metabolism
Glutamine synthesis

13. Branched-chain amino acids, BCAA
Ex Biochem c8-AA metabolism
Branched-chain amino acids, BCAA
Most common essential AA in proteins
Metabolized mainly in skeletal muscle
Increased BCAA oxidation during exercise, used as fuel or provide carbon backbone for CAC intermediates
BCAA aminotransferease, branched chain ketoacid dehydrogenase (BCKAD), acyl-CoA DHase
BCKAD inhibited by BCKAD kinase, response to exercise
Glucose-alanine cycle: transfer amino group from muscle to liver for urea synthesis
Leucine can enhance protein synthesis by stimulating initiation of translation
mTOR

14. Ex Biochem c8-AA metabolism

15. Ex Biochem c8-AA metabolism
Metabolism of BCAA

16. Glucose-alanine cycle
Ex Biochem c8-AA metabolism
Glucose-alanine cycle

17. Ex Biochem c8-AA metabolism

18. Ex Biochem c8-AA metabolism
Urea cycle
NH4+ very toxic, especially to brain
Temporary safe forms: glutamate, glutamine
Converted to urea, secreted in urine
Muscle release alanine, glutamine
N from BCAA  glutamate  ala or gln
Nitrogen in liver
Ala  glu by alanine aminotransferease
Gln  glu by glutaminase
NH4+ taken up from blood
The above 3 provide NH4+ for urea synthesis
The other NH3 in urea from aspartate
Regulation point: carbamoyl phosphate synthetase
Metabolically expensive: 4 ATP for 1 urea

19. Ex Biochem c8-AA metabolism

20. Ex Biochem c8-AA metabolism

21. The Urea Cycle -Overview
Ex Biochem c8-AA metabolism
The Urea Cycle -Overview

22. Ex Biochem c8-AA metabolism
The Urea Cycle

23. Ex Biochem c8-AA metabolism
The Urea Cycle

24. Fate of AA carbon skeletons
Ex Biochem c8-AA metabolism
Fate of AA carbon skeletons
18 AA can be source for gluconeogenesis
Leucine and lysine only form acetoacetyl CoA and acetyl CoA: ketogenic
Many AA have carbon skeletons as CAC intermediates or substances directly related to CAC

25. Ex Biochem c8-AA metabolism

26. Ex Biochem c8-AA metabolism

27. AA metabolism during moderate-intensity exercise
Ex Biochem c8-AA metabolism
AA metabolism during moderate-intensity exercise
Study of AA metabolism during exercise is complex
Measurement of AA differences between arterial and venous blood
Muscle biopsy
Only see the equilibrium between AA synthesis and breakdown, unless use stable isotope
During ex in postabsorptive state, skeletal muscle is in net protein catabolic state
Most AA produced by net protein catabolism released into blood, except glutamate and alanine
Net uptake of glutamate at rest and even more during exercise, glutamate used as precursor for glutamine
Release of ala and gln far out of proportion to their content in skeletal muscle, synthesized in skeletal muscle at accelerated rate during exercise
Ala release decline with exercise duration, less glucose  pyruvate

28. AA metabolism during moderate-intensity exercise
Ex Biochem c8-AA metabolism
AA metabolism during moderate-intensity exercise
Exercise in low-glycogen, protein breakdown greater, corresponding increase in release of most AA from muscle
Induce protein breakdown to release BCAA, use BCAA as fuel
Decrease in total adenine nucleotide content during prolonged exercise
Prevent AMP accumulation, AMP  IMP by adenylate deaminase
Can reduce TAN by up to 50%, need to regenerate adenine
purine nucleotide cycle, use aspartate, cost GTP
Predominantly after exercise, activities of the enzymes involved too long to produce appreciable AMP during ex

29. Ex Biochem c8-AA metabolism

30. Purine nucleotide cycle
Ex Biochem c8-AA metabolism
Purine nucleotide cycle

31. Purine nucleotide cycle
Ex Biochem c8-AA metabolism
Purine nucleotide cycle

32. Purine nucleotide cycle
Ex Biochem c8-AA metabolism
Purine nucleotide cycle

33. AA metabolism during high-intensity exercise
Ex Biochem c8-AA metabolism
AA metabolism during high-intensity exercise
Only modest increase in glutamine and alanine release from muscle, when exercise intensity is high
Glutamine synthesis require ATP and glutamate
Glutamate is source of a-KG, CAC intermediate
Increased adenylate deaminase reaction during high-intensity exercise
Recruitment of type II muscle fiber, in which adenylate deaminase activity is high
Increase release of NH4+, IMP is trapped within muscle

34. Central fatigue theory
Ex Biochem c8-AA metabolism
Central fatigue theory
voluntary maximal work of the muscle < the work when motor nerve was electrically stimulated
Fatigue in central nervous system
Increased production of serotonin in brain
Increased ammonia entry to brain
Tryptophan as precursor for serotonin synthesis
Most tryptophan bind to albumin
↑ FFA during exercise compete for albumin, ↑free Trp
BCAA compete with trp for blood brain barrier
BCAA supplementation helpful? Endurance exercise?
most animal studies support the theory, but most human studies failed to show benefit effect
↑ammonia, combination use with arginine?

35. Central fatigue theory
Ex Biochem c8-AA metabolism
Central fatigue theory

36. Central fatigue – supplementation of CHO and BCAA
Ex Biochem c8-AA metabolism
Central fatigue – supplementation of CHO and BCAA

37. Ex Biochem c8-AA metabolism

38. Additional roles for AA
Ex Biochem c8-AA metabolism
Additional roles for AA
Precursors for many biologically active compounds
Neurotransmitters
Tyrosine: dopamine, norepinephrine, epinephrine
Histidine: histamine
Tryptophan: serotonin, role in central fatigue
Maintain cellular redox state: glutathione

39. Ex Biochem c8-AA metabolism
Glutathione

40. Ex Biochem c8-AA metabolism
Some Small Peptides

41. Ex Biochem c8-AA metabolism

42. Ex Biochem c8-AA metabolism
Tamaki et al, 1992
Aguiar et al, 2013