1. The Organic Chemistry of Amino Acids, Peptides, and Proteins
Chapter 16
The Organic Chemistry of
Amino Acids, Peptides, and Proteins

2. Amino Acids a-Amino carboxylic acids
The “building blocks” from which proteins are made
Note: except for glycine (R = H), all a-amino acids are chiral molecules
There are 20 naturally occuring R-groups *

3. Amino Acids
As with carbohydrates, it is traditional to use the D and L nomenclature with amino acids – based on the configuration of glyceraldehyde
Naturally occurring amino acids generally have the same configuration as L-glyceraldehyde (S-configuration at the a-carbon):
L-glyceraldehyde
L-alanine

4. Amino Acids Acid–Base Properties
Since amino acids have both an acidic functionality and a basic functionality, we should expect the following equilibrium:
In fact, the equilibrium lies to the right all amino acids are charged at any pH!
Such species that are overall neutral molecules but contain charged ends are called zwitterions

5. Amino Acids Acid–Base Properties
Amino acids can react as either acids or bases:

6. glutamic acid – acidic R
Amino Acids
Acid–Base Properties
Amino acids can also have side chains containing acidic or basic groups:
Deprotonated at physiological pH
Protonated at physiological pH
glutamic acid – acidic R
Lysine –basic R

7. Amino Acids
Classification - Amino acids are classified on the basis of the structure of R
Aliphatic side chains – hydrophobic
Polar side chains – text classifies as HO-, S-, and amide contining – hydrophilic
Acidic – hydrophilic
Basic – hydrophilic
Heterocyclic/Aromatic – hydrophilic or hydrophobic

8. Amino Acids
Classification - Amino acids are classified on the basis of the structure of R
Aliphatic side chains – hydrophobic

9. Amino Acids
Classification - Amino acids are classified on the basis of the structure of R
Polar side chains – text classifies as HO-, S-, and amide contining – hydrophilic

10. Amino Acids
Classification - Amino acids are classified on the basis of the structure of R
Acidic – hydrophilic
Basic – hydrophilic

11. Amino Acids
Classification - Amino acids are classified on the basis of the structure of R
Heterocyclic/Aromatic – hydrophilic or hydrophobic

12. Acid-Base Properties

13. Acid-Base Properties

14. Acidity of a-COOH Groups
The average pKa of an -carboxyl group is 2.19, which makes them considerably stronger acids than acetic acid (pKa 4.76)
The greater acidity is accounted for by the electron- withdrawing inductive effect of the adjacent -NH3+ group

15. Side Chain COOH Groups
Due to the electron-withdrawing inductive effect of the - NH3+ group, side chain -COOH groups are also stronger than acetic acid
the effect decreases with distance from the -NH3+ group-- compare:
-COOH group of alanine (pKa 2.35)
b-COOH group of aspartic acid (pKa 3.86)
g-COOH group of glutamic acid (pKa 4.07)

16. Acidity of -NH3+ Groups
The average value of pKa for an -NH3+ group is 9.47, compared with a value of for 1° alkylammonium ions

17. Basicity of Guanidine Group
the side chain of arginine contains a guanidine group

18. The Imidazole Groups of His
the imidazole group is a heterocyclic aromatic amine

19. Titration of Amino Acids
Titration of glycine with NaOH

20. Isoelectric Point (pI)
Isoelectric point, pI: the pH at which the majority of amino acid molecules in solution have no net charge
the pI for glycine, for example, falls between the pKa values for the carboxyl and amino groups
the following tables give isoelectric points for the 20 protein-derived amino acids

21. Isoelectric Point (pI)

22. Isoelectric Point (pI)

23. Electrophoresis
Electrophoresis: the process of separating compounds on the basis of their electric charge
electrophoresis of amino acids can be carried out using paper, starch, agar, certain plastics, and cellulose acetate as solid supports
In paper electrophoresis
a paper strip saturated with an aqueous buffer of predetermined pH serves as a bridge between two electrode vessels

24. Electrophoresis
Electrophoresis of a mixture of amino acids

25. Electrophoresis
a sample of amino acids is applied as a spot on the paper strip
an electric potential is applied to the electrode vessels and amino acids migrate toward the electrode with charge opposite their own
molecules with a high charge density move faster than those with low charge density
molecules at their isoelectric point remain at the origin
after separation is complete, the strip is dried and developed to make the separated amino acids visible

26. Electrophoresis
a reagent commonly used to detect amino acid is ninhydrin

27. Polypeptides and Proteins
In 1902, Emil Fischer proposed that proteins are long chains of amino acids joined by peptide bonds
Peptide bond: the special name given to the amide bond between the -carboxyl group of one amino acid and the -amino group of another

28. Peptides
peptide: the name given to a short polymer of amino acids joined by peptide bonds; they are classified by the number of amino acids in the chain
dipeptide: a molecule containing two amino acids joined by a peptide bond
tripeptide: a molecule containing three amino acids joined by peptide bonds
polypeptide: a macromolecule containing many amino acids joined by peptide bonds
protein: a biological macromolecule of molecular weight g/mol or greater, consisting of one or more polypeptide chains

29. glycylalanine = gly-ala
Peptides
Peptides are amino acid polymers containing 2–50 individual units
Peptides with >50 units are called proteins
By convention, peptide structures are written with the N-terminal amino acid on the left and the C-terminal amino acid on the right.
A dipeptide
glycylalanine = gly-ala

30. Peptides
glycylalanine = gly-ala
glycine
amino-terminal amino acid

31. Peptides
glycylalanine = gly-ala
alanine
carboxy-terminal amino acid

32. glycylalanine = gly-ala
Peptides
glycylalanine = gly-ala
peptide bond

33. glycylserylphenylalanylglycine gly-ser-phe-gly
Peptides
A tetrapeptide:
N-terminus
C-terminus
glycylserylphenylalanylglycine gly-ser-phe-gly

34. Peptides The Peptide (Amide) Bond
The amide nitrogen is sp2 hybridized and the lone pair is conjugated with the carbonyl group
There is considerable C–N double-bond character
Rotation about the C–N bond is difficult

35. Peptides The Peptide (Amide) Bond The amide groups are planar.
The R-groups are on opposite sides of the plane.
gly-ser-phe-gly

36. Peptides The Peptide (Amide) Bond The amide groups are planar.
The R-groups are on opposite sides of the plane.
gly-ser-phe-gly

37. Peptides
The only other type of covalent bond between amino acids in proteins and peptides is the disulfide linkage between two cysteine units:

38. Peptides Note: Thiols are readily oxidized to disulfides.
Disulfides are readily reduced to thiols.

39. Peptides
Disulfide links serve to connect polypeptide chains:

40. Peptides … or can form a macrocycle: bovine oxytocin
Copyright © 2010 Pearson Education, Inc.
… or can form a macrocycle:
bovine oxytocin

41. Peptides
Conotoxin G I
A peptide neurotoxin isolated from the venom of the fish- hunting cone snail Conus geographicus.
It is a paralytic toxin that blocks nicotinic cholinoreceptors.

42. Peptides
Conotoxin G I

43. Structure Determination of Peptides
Amino Acid Analysis. Find out which amino acids and how many make up the peptide
Terminal Residue Analysis. Find out what’s on the ends
N-Terminal Analysis
Edman degradation
C-Terminal Analysis
Carboxypeptidase

44. Structure Determination of Peptides
Partial Hydrolysis (enzymatic)
Hydrolyze the peptide into smaller fragments.
Trypsin - Cleaves at lys and arg
Chymotrypsin - Cleaves at phe, tyr, and trp
Pepsin - Cleaves at phe, tyr, trp, leu, asp, glu
Cyanogen bromide (not enzymatic) - Cleaves at met
Determine the sequence of the fragments.
Successive Edman degradations.

45. gly2ala4leu4phe3trp1lys2met2ser1arg1
Sample Problem
Give the sequence for a 20 amino acid polypeptide
with amino acid analysis:
gly2ala4leu4phe3trp1lys2met2ser1arg1
Step 1: Terminal residue analysis:
N-terminus = ala
C-terminus = phe

46. Sample Problem
Step 2: Trypsin hydrolysis (cleaves at lys and arg) gave four fragments:
trpphearg
alaleuglymetlys
leuglyleuleuphe
alaalasermetalaphelys

47. Sample Problem
Step 2: Trypsin hydrolysis (cleaves at lys and arg) gave four fragments:
trpphearg
alaleuglymetlys
leuglyleuleuphe
alaalasermetalaphelys
Fragment III represents the last five amino acids (trypsin does not cleave at phenylalanine).

48. Sample Problem
Step 2: Trypsin hydrolysis (cleaves at lys and arg) gave four fragments:
trpphearg
alaleuglymetlys
leuglyleuleuphe
alaalasermetalaphelys
Either fragment II or IV must be N-terminus (cannot know which).

49. Sample Problem Step 3: Cyanogen bromide cleavage gave three fragments:
alaleuglymet
alaphelysleuglyleuleuphe
lystrppheargalaalasermet

50. Sample Problem Step 3: Cyanogen bromide cleavage gave three fragments:
alaleuglymet
alaphelysleuglyleuleuphe
lystrppheargalaalasermet
Fragment 2 must be the C-terminus.

51. Sample Problem Step 3: Cyanogen bromide cleavage gave three fragments:
alaleuglymet
alaphelysleuglyleuleuphe
lystrppheargalaalasermet
Fragment 1 must be the N-terminus.

52. Sample Problem
Step 4: We can now assemble the peptide:

53. Sample Problem
Step 4: We can now assemble the peptide:

54. Proteins Protein function depends on structure.
Depends on various amino acids.
Primary Structure: The amino acid sequence.

55. Proteins Secondary Structure: The “local” hydrogen- bonding scheme.
a-Helix
Hydrogen bonds

56. Proteins Secondary Structure: The “local” hydrogen-bonding scheme.
a-Helix

57. Interchain hydrogen bonds
Proteins
Secondary Structure: The “local” hydrogen-bonding scheme.
b-Sheet
Interchain hydrogen bonds

58. Proteins
Tertiary Structure: How the protein, with all of its regions of secondary structure (a-helix, b-sheet) has folded over upon itself
Interaction between R-groups is important
All intermolecular forces we have studied are at play

59. Proteins Tertiary Structure: Chemical bonds between cysteines
Disulfide bonds

60. Hydrophobic interactions Hydrophilic interactions
Proteins
Tertiary Structure: Interaction between R-groups
Hydrophobic interactions
Hydrogen bonding
Ionic bonding
(“salt bridge”)
Hydrophilic interactions

61. Proteins
Tertiary Structure: How the protein, with all of its regions of secondary structure (a-helix, b-sheet) has folded over upon itself.
Crystal Structure Of Human Rab9 Gtpase
Courtesy of Protein Data Bank

62. Proteins
Tertiary Structure: How the protein, with all of its regions of secondary structure (a-helix, b-sheet) has folded over upon itself.
a-Helix regions

63. Proteins
Tertiary Structure: How the protein, with all of its regions of secondary structure (a-helix, b-sheet) has folded over upon itself.
b-Sheet regions

64. Proteins
Quaternary Structure: How protein subunits aggregate into a larger functional unit.
Hemoglobin has two  and two  subunits that fit together to form the whole hemoglobin molecule with four hemes and their associated iron atoms to transport O2 and CO2
Human deoxy hemoglobin
Courtesy of Protein Data Bank