The Three-Dimensional Structure of Proteins Part 1 Chapter 4
Proteins: Structure, Function, Folding –Structure and properties of the peptide bond –Structural hierarchy in proteins –Structure and function of fibrous proteins –Structure analysis of globular proteins –Protein folding and denaturation Learning goals: to Know:
Structure of Proteins Unlike most organic polymers, protein molecules adopt a specific three- dimensional conformation. This structure is able to fulfill a specific biological function This structure is called the native fold The native fold has a large number of favorable interactions within the protein There is a cost in conformational entropy of folding the protein into one specific native fold
Favorable Interactions in Proteins Hydrophobic effect –Release of water molecules from the structured solvation layer around the molecule as protein folds increases the net entropy Hydrogen bonds –Interaction of N-H and C=O of the peptide bond leads to local regular structures such as -helices and -sheets London dispersion –Medium-range weak attraction between all atoms contributes significantly to the stability in the interior of the protein Electrostatic interactions –Long-range strong interactions between permanently charged groups –Salt-bridges, esp. buried in the hydrophobic environment strongly stabilize the protein
Folding Final Structure: Chymotrypsin and Glycine 75 Daltons 21,000 Daltons, 3 polypeptides
Protein Conformation Stabilized by weak bonds: ΔG separating folded and unfolded is small Bond: H bonds, hydrophobic interatction, ionic interaction and –S-S-. Proteins possess a “solvation layer” The extent of which depends on surface amino acid R groups Overall structural patterns: Hydrophobic areas buried in protein interior Number of H-bonds is maximized
The Peptide Bond
Only non-planar Bonds Rotate Each α-Carbon has a Φ and Ψ
Getting the Angles
Many Angles are Prohibited due to Steric Overlap
Ramachandran Plot
Pauling and Corey and the Alpha Helix
How To Determine Protein Structure The Classic Method – X-ray Crystallography Methods to form Crystals take Proteins to their Solubility Minimum
Proteins Crystals in Electron Microscopy
X-ray Diffraction
X-ray Diffraction Pattern of Myoglobin and DNA Fourier Transform to convert X-ray pattern to Electron Density Map
X ray Diffraction Patterns from Different Proteins
Fitting Electron Density Map to Structure
Fitting Electron Density Map to Primary Structure
X-ray Crystallography at Fine Resolution
Proton Nuclear Magnetic Resonance of a Protein
2 Dimensional NMR
NMR Structure of Myoglobin NMR is limited to small proteins
TROSY NMR Transverse Relaxation Optimized Spectroscopy increases time overwhich NMR signals from neighboring methyl groups can be detected. The trick is to deuterate the protein then protonate methyls…. A look into a Proteasome cavity. This protein is 670 kD! (20S) Red groups = methyls that are mobile Yellow groups = active site…protein degradation. C+E News Feb 5, 2007
Here Is How It Worked Nature 445:618 Feb 8, 2007
Proteasome Function Core Proteasome Ubiquitin Binding Sites top and bottom
4 th Edition: See pages , Fig th Edition: See pages , Fig 27-47, 48 Ubiquitin Targeting a Cytoplasmic Protein Protein AminoTerminal-aaHalf-life stabilizing M, G, A, S, T, V>20 hrs destabilizing I, N, Y, D, P, L, F, K, R 30 – 2 min
What’s New: Free-Electron Lasers X-ray pulses, in series of femtoseconds on drops containing microcrystals. Free-electron X ray source at Stanford only one ($300 million), Resolution 2Å. Schichting, I. May, 2012 Max-Plank Gesellschaft
Alpha Helix Stabilized by H-bonding to every 4 th Amino Acid
Alpha Helix Stabilized by Dipole Moments and Hydrogen Bonds Can be Right or Left Handed
Alpha Helix H-bonding - Stability H-bonds to every 4 th amino acid So, amino acid-8 in a 15 aa α-helix is H-bonded to aa-11 and aa-5. What about amino acids at the N- and C-terminal ends? Instability is brought about by: 1. electrostatic repulsion or attraction – charged R groups. 2.adjacent bulky R groups. 3.interaction with R groups 3-4 aa’s up or down the helix. 4.occurrence of G. 5.interaction of aa’s at C-terminal and N-terminal ends with any near aa-R group.
table 4-1 A
How Long is an 80 amino acid alpha helix? FACTS to KNOW: One turn: 3.6 aa’s, 5.4 Å long NOW DO IT
How Long is an 80 amino acid alpha helix? FACTS to KNOW: One turn: 3.6 aa’s, 5.4 Å long 80 aa’s / (3.6 aa’s/turn) = 22.2 turns 22.2 turns x 5.4 Å/turn = 120 Å long
Sheets The planarity of the peptide bond and tetrahedral geometry of the -carbon create a pleated sheet- like structure Sheet-like arrangement of backbone is held together by hydrogen bonds between the backbone amides in different strands Side chains protrude from the sheet alternating in up and down direction
Beta (Pleated Sheet) Structure
Antiparallel Beta-turns
Antiparallel Beta-turns with Proline Normal = transIn Beta-turns, Proline is cis
Ramachandran Plot showing 2 o Structures
Ramachandran Plot of Pyruvate Kinase Excludes Glycines – they are too flexible
Frequency of Amino Acids in 2 o Structure
Circular Dichroism Spectra A Difference in right handed and left handed polarized light on the extinction coefficient.
Tertiary structure refers to the overall spatial arrangement of atoms in a protein Stabilized by numerous weak interactions between amino acid side chains. Largely hydrophobic and polar interactions Can be stabilized by disulfide bonds Interacting amino acids are not necessarily next to each other in the primary sequence. Two major classes – Fibrous and globular (water or lipid soluble) Protein Tertiary Structure
Fibrous Proteins: From Structure to Function
Alpha Keratin Structure – Almost All Alpha Helix
Biochemists at the Hairdressers Why a Permanent is not a Temporary!
Chicken Feather α-keratin Carbonizing (under O 2 free environment) makes the fiber into a graphite- like material = light weight, high strength, low cost polymer)
Silk Fibroin is almost all Beta Structure
Silk A
Spinnerets of a Spider – SEM, Artificially Colored
Things to Know and Do Before Class 1.The peptide bond and why it is planar. 2.Rotation around the alpha carbon, Ramachandran Plot. 3.Basic idea of X-ray crystallography and how it is used to get 3-D structure. 4.Alpha helix and B-structure. 5.Circular Dichroism spectra: what they demonstrate. 6.Fibrous proteins that are essentially all alpha helix or beta structure. 7.EOC problems 1-4. We will do some in class and a case study with music.