1. The Three-Dimensional Structure of Proteins
Chapter 4
The Three-Dimensional Structure of Proteins

2. 4.1 Overview of Protein Structure

3. Protein Conformation Conformation
Spatial arrangement of atoms in a protein
Tendency to have the lowest Gibbs free energy (highest stability)
Noncovalent interactions determining protein conformation
Maximum hydrogen bonding within the protein
DH for H bonds in protein ≈ DH for H bonds with water
DS > 0 by H bonding in protein caused by decrease in solvation shell of structured water
Hydrophobic interaction
Hydrophobic residues are buried in the protein interior
Ionic interactions (salt bridge)
Disulfide bonds
Native proteins
Proteins in any of their functional, folded conformation

4. The Peptide Bond is Rigid and Planar
Double bond character of peptide bond
Resonance between the carbonyl oxygen and the amide nitrogen
6 atoms of the peptide group lie in a single plane
No free rotation of peptide C-N bond (trans)
Rotation of peptide chain
f : rotation angle of N-Ca
y : rotation angle of Ca-C
f, y = 180 (or -180)

5. Ramachandran Plot Ramachandran Plot
Rotation of peptide chain
-180 < f &y < 180
f, y = 0
Reference point for describing the angels of rotation
Two peptide bonds are in the same plane
Restricted by steric overlap
Ramachandran Plot
Plotting of the allowed values of f vs. y

6. 4.2 Protein Secondary Structure
Local conformation of polypeptide
 helix,  sheet : 60% of the polypeptide chain
Random coils and - turn

7.  Helix Hydrogen bond between carbonyl O (n) and amid H (n+4)
Right-handed helix
One turn: 5.4 Å along the axis, 3.6 amino acids
y = -45 to -50 f = -60
Side chains point outward

8. Amino Acid Sequence Affects a Helix Stability
Amino acids destabilizing a helix
Electrostatic repulsion
Glu, Lys, Arg
Bulkiness & shape of adjacent R groups
Asn, Ser, Thr, Cys
Restricted rotation
Pro
No N-Ca (f)rotation  kink
No H in N for hydrogen bonding
Flexible rotation
Gly
Tendency to form coil structure different from a helix

9. Amino Acid Sequence Affects a Helix Stability
Interaction between amino acid residues at the ends of the helical segment and the electric dipole of a helix
(+) charged a.a near C-terminus
(-) charged a.a near N-terminus

10. Constraints for the stability of a-helix
Intrinsic propensity of a.a to form a-helix
Interactions between side chains
Bulkiness of adjacent side chains
Occurrence of Pro and Gly residues
Interactions between a. a at the ends of the helical segment and the electric dipole inherent to the a-helix

11. b Conformation b stand Zigzag polypeptide backbone
b sheet, b-pleated sheet
Hydrogen bonding between adjacent b strands
Parallel
Antiparallel
Amino acids for specific b sheet structure
Stacking of b sheet
b-keratins (silk fibroin, spider web)
Rich in small amino acids: Gly, Ala

12. b Turns Connecting elements 1/3 of amino acids in a globular protein
Turns and loops
b turns
Connecting the ends of two adjacent segments of antiparallel b sheet
180o turns involving 4 amino acids and hydrogen bonding
Gly : small and flexible
Pro : cis configuration amenable to a tight turn

13. Bond Angles of Amino Acid Content of Secondary Structure
Relatively restricted range of y and f depending on the types of secondary structure
Different distribution of amino acids in different secondary structures

14. Circular dichroism

15. 4.3 Protein Tertiary and
Quaternary Structure

16. Higher Protein Structure
Tertiary structure
Overall 3D arrangement of all atoms in a protein
Quaternary structure
Arrangement of protein subunits
Classification by higher structure
Fibrous proteins
Single type of secondary structure
Provide support, shape, and external protection
Globular proteins
Several types of secondary structure
Enzymes and regulatory proteins

17. Characteristics of fibrous proteins Strength and flexibility
Water insoluble
High concentration of hydrophobic amino acids

18. a keratin
Structural protein for hair, wool, feathers, nails, hooves, horns
Providing strength
Coiled coil (left handed twist) of a-helix with hydrophobic amino acids (A, I, V, M, F)
Forming fibers by hydrophobic interactions

19. Disulfide bonds The more S-S bonds the harder the structure
Permanent wave
Reducing of disulfide bond  Generation of new disulfide bond

20. Collagen Providing strength in connective tissue
Tendon, cartilage, organic matrix of bone, cornea
Structure
Left-handed helix with 3 a.a./turn : a chain
Right-handed supertwist of 3 a chains
Amino acid composition
Repeating tripeptide unit, Gly-X, Y
X; Pro, Y; 4-Hyp
35% Gly, 11% Ala, 21% Pro and 4-Hyp
Gly is essential for the structure
Mutation  genetic disease
Very low nutritional value
Very close packing
Collagen fibrils
Crosslinking of collagen molecules
by involving lysine, hydroxylysine, histidine

21. Silk Fibroin Produced by insects and spiders b conformation
Rich in Ala and Gly
Close packing of b-sheets and interlocking alignment of R groups
Stabilization by hydrogen bonding and van der Waals interactions
Flexible
Strand of fibroin emerging from the spinnerets of a spider

22. Globular Proteins Globular proteins Compact
Structural diversity to carry out diverse functions
Myoglobin
Structure determined by x-ray diffraction studies (John Kendrew, 1950’s)
Oxygen carrier in muscle : containing heme group
153 a.a

23. Diverse Tertiary Structure of Globular Proteins
Shared properties w/ myoglobin
Compact folding
Hydrophobic side chains in the interior
Hydrophilic sided chains on the surface
Stabilization by non-covalent interactions

24. Common Structural Patterns
Motifs (folds or supersecondary structures); folding pattern
Stable arrangements of several elements of secondary structure
Domains
Stable, globular units; distinct functions

25. Rules of common protein folding patterns
Hydrophobic interaction
Burial of hydrophobic R groups
Layers of 2nd structures; b-a-b loop, a-a corner
In general, a helices and b sheets are in different structural layers
Stacking of the adjacent polypeptide segments
No crossover connection
b conformation is most stable with slight right-handed twist

26. Constructing Large Motifs form Smaller Ones

27. Classification of Protein Structures
Structural classification of proteins (SCOP) database
Classification
All a
All b
a/b : a and b segments are interspersed or alternate
a + b : a and b regions are segregated
< 1,000 different folds or motifs
Protein family
Proteins with similarities in
Primary sequence
(and/or) Structure
Function
Superfamily
Families with little primary sequence similarity but with similarities in motifs and function
Tracing structural motifs using protein database
Useful to identify evolutionary relationships
(protein 3rd structure is more conserved than A. a. sequence)

28. Structural classification from SCOP database

29. Structural classification from SCOP database

30. Structural classification from SCOP database

31. Quaternary Structure Hemoglobin
Tetramer : two a chains and two b chains
Dimer of ab protomer
Symmetric patterns of multimeric proteins with identical subunits
Rotational symmetry
Cyclic symmetry
Single axis for rotation : Cn , n fold rotation axis
Dihedral symmetry
Intersecting twofold rotational axis and n fold axis at right angles : Dn, 2n protomers
Icosahedral symmetry
12-cornered polyhedron with 20 equilateral triangular faces
Virus coats and capsids
Helical symmetry
Capsid of tobacco mosaic virus
Actin filaments

32. Symmetric patterns of multimeric proteins
Helical symmetry

33. 4.4 Protein Denaturation and Folding

34. Protein Denaturation Denaturation
A loss of three-dimensional structure sufficient to cause loss of function
Not necessarily means complete unfolding or random conformations
Abrupt unfolding over a narrow temperature range
Cooperative unfolding process
Denaturing agents
Heat
Affect weak interactions (H bonds) pH
Alternation of the protein net charge
Electrostatic repulsion, disruption of H bonds
Organic solvents (alcohol, acetone), urea, guanidine HCl, detergents
Disruption of hydrophobic interactions

35. Amino Acid Sequenc Determines Tertiary Structure
Renaturation
Reversal of denaturation
Amino acid sequence contains all the information required to protein folding
First experimental evidence by Christian Anfinsen (1950s)
Denaturation of ribonuclease with urea and reducing agent
Spontaneous refolding to an active form upon removal of the denaturing reagents

36. “Levinthal’s Paradox”
Protein Folding
Protein folding in living cells
Not a random, trial-and-error process
E. coli : make 100 a.a. protein in 5 sec
10 possible conformations/ a.a.  conformations
10-13 sec for each conformation  1077 years to test all the conformations
“Levinthal’s Paradox”

37. Models for Protein Folding
Hierarchical folding
From local folding (a helix, b sheets) to entire protein folding
Molten globule state model (hydrophobic collapse)
Initiation of folding by spontaneous collapse by hydrophobic interactions

38. Thermodynamics of Protein Folding
Free-energy funnel
Unfolded states
High entropy and high free energy
Folding process
Decrease in the number of conformational species (entropy) and free energy
Semistable folding intermediates

39. Molecular Chaperones Molecular chaperones
Proteins facilitating protein folding by interacting with partially or improperly folded proteins
Classes of molecular chaperones
Hsp70
Induced in stressed cells (heat shock protein)
Binding to hydrophobic regions of unfolded proteins, preventing aggregation
Cyclic binding and release of proteins by ATP hydrolysis and cooperation with co-chaperones (Hsp40 etc.)
E. coli: DnaK (Hsp70), DnaJ (Hsp40)
Chaperonin
Protein complex providing microenvironments for protein folding
E. coli : 10~15% protein require GroES (lid) and GroEL
Isomerases in protein folding
Protein disulfide isomerase (PDI)
Shuffling disulfide bonds
Peptide prolyl cis-trans isomerase (PPI)
Interconversion of the cis and trans isomers of Pro peptide bonds

40. Protein Folding by DnaK and DnaJ

41. Chaperonin in Protein Folding

42. Protein Folding and Diseases
Cystic fibrosis
Misfolding of cystic fibrosis transmembrane conductance regulator (CFTR; Cl- channel)
Neurodegenerative diseases
Alzheimer’s, Parkinson’s, Huntinton’s desease, ALS
Prion diseases
Mad cow disease (bovine spongiform encephalopathy, BSE)
Kuru, Creutsfeldt-Jakob disease in human
Scrapie in sheep
Prion : proteinaceous infectious only protein
PrPSc (scrapie) prion form converts PrPC to PrPSc

43. Neurodegenerative disorders
The amyloid formation is the common phenomenon observed in
various neurodegenerative disorders, including Parkinson’s disease,
Alzheimer’s disease, Huntington’s chorea, Amyotrophic lateral
sclerosis, Prion disease, etc.
Parkinson’s disease
Alzheimer’s disease
Prion disease [mad cow disease]

44. Misfolded protein Folded state
degradation
Misfolded
protein
Folded
state
Amino acids
refolding
Accumulation
Amyloid formation
Degenerative disorders

45. Amyloid-b peptide in Alzheimer’s disease

46. Creutzfeldt-Jakob disease [Spongiform encephalopathies]