1. Chapter Twenty Proteins

2. Ch 20 | 2 of 59 TypeExamples Structuraltendons, cartilage, hair, nails Contractile muscles Transporthemoglobin Storagemilk Hormonalinsulin, growth hormone Enzymecatalyzes reactions in cells Protection immune response Roles of Proteins

3. Ch 20 | 3 of 59 Roles of Proteins

4. Ch 20 | 4 of 59 Proteins are polymers of amino acids Contain a carboxylic acid group and an amino group on the alpha carbon Side group R gives unique characteristics Rside chain I H 2 N— C — COOH I H Amino Acids

5. Ch 20 | 5 of 59 Nonpolar –An amino acid that contains a nonpolar side chain –R = H, CH 3, alkyl groups, aromatic Polar –An amino acid with a side chain that is polar but neutral – O ll R = –CH 2 OH, –CH 2 SH, –CH 2 C–NH 2, (polar groups with –O-, -SH, -N-) Classifying Amino Acids

6. Ch 20 | 6 of 59 The 20 Standard Amino Acids, Grouped According to Side-Chain Polarity.

7. Ch 20 | 7 of 59 The 20 Standard Amino Acids, Grouped According to Side- Chain Polarity. (cont’d)

8. Ch 20 | 8 of 59 Polar/Acidic –An amino acid that contains a second carboxyl group in its side chain –R = –CH 2 COOH, or -COOH Polar/ Basic –An amino acid that contains a second amino group in its side chain –R = –CH 2 CH 2 NH 2 Classifying Amino Acids

9. Ch 20 | 9 of 59 The 20 Standard Amino Acids, Grouped According to Side-Chain Polarity. (cont’d)

10. Ch 20 | 10 of 59 10 amino acids not synthesized by the body Arg, His, Ile, Leu, Lys, Met, Phe, Thr, Trp, Val Must obtain from the diet All in diary products 1 or more missing in grains and vegetables Essential Amino Acids

11. Ch 20 | 11 of 59 Fischer Projections of Amino Acids All amino acids except glycine are chiral. Amino acids have stereoisomers In biological systems, only L amino acids are used in proteins D-Alanine L-AlanineL-CysteineD-Cysteine

12. Ch 20 | 12 of 59 Designation of handedness in standard amino acid structures involves aligning the carbon chain vertically and looking at the position of the horizontally aligned NH 2 group.

13. Ch 20 | 13 of 59 Ionization of the –NH 2 and the –COOH group –-COOH loses a proton (acid) –-NH 2 gains a proton (base) Zwitterion has both a + and – charge Zwitterion is neutral overall NH 2 –CH 2 –COOH H 3 N–CH 2 –COO – glycine Zwitterion of glycine Zwitterions +

14. Ch 20 | 14 of 59 H + OH – + + H 3 N–CH 2 –COOH H 3 N–CH 2 –COO – H 2 N–CH 2 –COO – Positive ion zwitterion Negative ion Low pH neutral pH High pH pH and Ionization In solution, at least three different forms of amino acids can exist: positive ion, zwitterion, and negative ion

15. Ch 20 | 15 of 59 pH and Ionization Acidic amino acids such as aspartic acid have a second carboxyl group that can donate and accept protons –Amino acids with ionizable side chains have 4 forms in solution -Cys, Tyr, Lys, Arg, His, Asp, Glu Whether a group is ionized or not depends on its pKa –If pH > pKa, the group has been deprotonated –If pH < pKa, the group is protonated

16. 16 Amino Acid  -carboxylic acid  -amino Side chain Alanine2.359.87 Arginine2.019.0412.48 Asparagine2.028.80 Aspartic Acid2.109.823.86 Cysteine2.0510.258.00 Glutamic Acid2.109.474.07 Glutamine2.179.13 Glycine2.359.78 Histidine1.779.186.10 Isoleucine2.329.76 Leucine2.339.74 Lysine2.188.9510.53 Methionine2.289.21 Phenylalanine2.589.24 Proline2.0010.60 Serine2.219.15 Threonine2.099.10 Tryptophan2.389.39 Tyrosine2.209.1110.07 Valine2.299.72

17. Ch 20 | 17 of 59 Step-wise Ionization of Amino Acids 1. Draw the amino acid in the fully protonated form –Low pH –All acid groups are protonated (-COOH) –All amino groups are protonated (-NH 3 + ) 2. Identify the protons that will come off (and the order in which they will come off) 3. Take the protons off 1 by 1 Example: Glutamic Acid

18. Ch 20 | 18 of 59 Ionization of Glutamic Acid Draw the step-wise ionization of glutamic acid to result in this form.

19. Ch 20 | 19 of 59 HomeWork Assignment What overall charge will the following amino acids have at pH 5.5? Glutamic Acid Lysine Phenylalanine

20. Ch 20 | 20 of 59 Electrophoresis Electrophoresis separates amino acids according to their charges –Positively charged amino acids move towards the negative electrode –Negatively charged amino acids move toward the positive electrode –Neutral amino acids will not move in either direction Amino acids are visualized as separate bands on filter paper or thin layer plate

21. Ch 20 | 21 of 59 Electrophoresis

22. Ch 20 | 22 of 59 Amide bond formed by the carboxylate group of an amino acid and the –amino group of the next amino acid O CH 3 + | | + | NH 3 –CH 2 –COH + H 3 N–CH–COO – O CH 3 + | | | NH 3 –CH 2 –C – N–CH–COO – | peptide bond H Peptide Bonds

23. Ch 20 | 23 of 59 Peptides Peptide –A sequence of amino acids in which the amino acids are joined together through amide (peptide) bonds Dipeptide –A peptide consisting of 2 amino acids Tripeptide –A peptide consisting of 3 amino acids Polypeptide –A peptide consisting of many amino acids

24. Ch 20 | 24 of 59 Amino acids linked by amide (peptide) bonds Gly Lys Phe Arg Ser H 2 N- -COOH endPeptide bonds end Name: Glycyllysylphenylarginylserine Peptides N- terminus C- terminus

25. Ch 20 | 25 of 59 Protein Structure A polypeptide containing 50 or more amino acids is called a protein There are different ways to describe the structure of a protein: –Primary Structure –Secondary Structure –Tertiary Structure –Quaternary Structure

26. Ch 20 | 26 of 59 Three-dimensional arrangement of amino acids with the polypeptide chain in a corkscrew shape Held by H bonds between the H of –N-H group and the – O of C=O of the fourth amino acid along the chain Looks like a coiled “telephone cord” Secondary Structure: Alpha Helices

27. Ch 20 | 27 of 59 Specific overall shape of a protein Results from cross-links between R groups of amino acids in chain disulfide –S–S– + ionic –COO – H 3 N– H bonds C=O HO– hydrophobic –CH 3 H 3 C– Tertiary Structure

28. Ch 20 | 28 of 59 Levels of Protein Structure

29. Ch 20 | 29 of 59 A telephone cord has three levels of structure. Levels of Protein Structure

30. Ch 20 | 30 of 59 Primary Structure Human Myoglobin

31. Ch 20 | 31 of 59 Secondary Structure Geometrical orientation of polypeptide chains Two main kinds of secondary structure: –Alpha helices –Beta pleated sheets

32. Ch 20 | 32 of 59 The hydrogen bonding between the carbonyl oxygen atom of one peptide linkage and the amide hydrogen atom of another peptide linkage. Secondary Structure

33. Ch 20 | 33 of 59 Two pleated sheet protein structure. Secondary Structure

34. Ch 20 | 34 of 59 Four representations of the helix secondary structure. Secondary Structure

35. Ch 20 | 35 of 59 The secondary structure of a single protein. Secondary Structure

36. Ch 20 | 36 of 59 Four types of interactions between amino acid R groups produce the tertiary structure of a protein. Tertiary Structure

37. Ch 20 | 37 of 59 The tertiary structure of the single-chain protein myoglobin. Tertiary Structure

38. Ch 20 | 38 of 59 Disulfide bonds involving cysteine residues can form in two different ways. Disulfide Bonding

39. Ch 20 | 39 of 59 Human insulin, a small two-chain protein, has both intrachain and interchain disulfide linkages as part of its tertiary structure. Human Insulin

40. Ch 20 | 40 of 59 Substitutions in Insulin

41. Ch 20 | 41 of 59 Disulfides and Hair

42. Ch 20 | 42 of 59 A schematic diagram showing the tertiary structure of the single-chain protein myoglobin.

43. Ch 20 | 43 of 59 Proteins with two or more chains –Quaternary structure is the relative organization of multiple chains to each other Example is hemoglobin Carries oxygen in blood Four polypeptide chains Each chain has a heme group to bind oxygen A conjugated protein (has a prosthetic group) Quaternary Structure

44. Ch 20 | 44 of 59 Tertiary and quaternary structure of the oxygen- carrying protein hemoglobin. Quaternary Structure

45. Ch 20 | 45 of 59 Globular proteins Fibrous proteins “spherical” shapelong, thin fibers Water solubleNot water soluble Multiple Types of 2 o structure1 Type of 2 o Structure Transport, Metabolism, etc.Strength, Protection More numerousFew in the body InsulinHair HemoglobinWool Enzymes Skin AntibodiesNails Globular and Fibrous Proteins

46. Ch 20 | 46 of 59 The tail feathers of a peacock. Fibrous Protein is α-keratin Fibrous Proteins PhotoDisc

47. Ch 20 | 47 of 59 The coiled-coil structure of the fibrous protein alpha keratin. Fibrous Proteins

48. Ch 20 | 48 of 59 Fibrous Proteins

49. Ch 20 | 49 of 59 Three helical peptide chains. Collagen

50. Ch 20 | 50 of 59 →Electron Micrograph Collagen fibers Collagen Prof. P.M. Motta & E. Vizza / Photo Researchers

51. Ch 20 | 51 of 59 Protein denaturation process. Protein Denaturation

52. Ch 20 | 52 of 59 Heat denatures the protein in egg white. Heat Denaturation E.R. Degginger

53. Ch 20 | 53 of 59 Hard boiling an egg Wiping the skin with alcohol swab for injection Cooking food to destroy E. coli. Heat used to cauterize blood vessels Autoclave sterilizes instruments Milk is heated to make yogurt Applications of Denaturation

54. Ch 20 | 54 of 59 Denaturation

55. Ch 20 | 55 of 59 Disulfides and Hair

56. Ch 20 | 56 of 59 Structure of immunoglobulin. Immunoglobulins

57. Ch 20 | 57 of 59 Immunoglobulin- antigen complex Immunoglobulins

58. Ch 20 | 58 of 59 Break down of peptide bonds Requires acid or base, water and heat Gives smaller peptides and amino acids Similar to digestion of proteins using enzymes Occurs in cells to provide amino acids to synthesize other proteins and tissues Protein Hydrolysis

59. Ch 20 | 59 of 59 Hydrolysis of a Dipeptide