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Download Basics of protein structure Me Introduction to protein structure Four
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Transcript
10/28/10 Me Basics of protein structure Basics of protein structure (Chapter 2) Also check appendix A: “Bonds and energetics of macromolecules” [email protected] Tel 018-4714177, 070-5988391 Nucleic acid structure (Chapter 3) contains parts beyond this course Translation (Chapter 8) Membrane proteins (Chapter 10) Four structure levels Introduction to protein structure 1 10/28/10 Why do we need to know structure to understand macromolecules? Proteins consist of L amino acids pKa ≈8 pKa ≈3 2 10/28/10 Table 2.1 Salt bridges - interactions between charged side chains Side chains that can participate in hydrogen bonds Primary structure Direction: N-terminus => C-terminus 3 10/28/10 The polypeptide chain α-carbon R1 H H 2N Cα C O N-terminus R3 H O H N C-terminus carbonyl group side chain Cα H peptide bond R2 C The polypeptide conformation N H O Cα C O amide nitrogen OH H 2N Cα H C OH R4 peptide bond formed by elimination of H2O Allowed backbone torsion angles: exercize Ramachandran diagram Ala Gly psi Ramachandran diagram: sterically allowed torsion angles phi 4 10/28/10 Side chain conformations • Ile and Thr have chiral Cβ. α-helix (3.613 helix) Right-handed 3.6 residues per turn 13 atoms in the ring formed by H-bond • Preferred torsion angles in side chains (rotamers) based on staggered conformations. 9 Aspartic acid rotamers Properties of the α helix Helix dipole • All side chains point in the same direction C-terminus N-terminus 5 10/28/10 Other types of right-handed helices 310 helix H-bonding to N+3 Antiparallel β-sheet π helix (4.116) H-bonding to N+5 Table 2.3!! Parallel β-sheet Mixed β-sheet Parallel Anti-parallel Thioredoxin 6 10/28/10 Topology - the way the secondary structure elements are connected Other types of secondary structure β-strand β-bulges Polyproline helices (collagen) α-helix Turns (several kinds) Tertiary structure – create a complex surface topography that can interact with other (small or large) molecules Anti-parallel beta sheets N Beta C hairpin open 4-stranded up-and-down sheet Closed cylinder 7-bladed propeller 7 10/28/10 Parallel beta sheets Greek key 3 2 1 4 Jelly roll beta helix 5 4 7 2 1 8 3 6 The βαβ unit The βαβ unit C 6 5 4 1 2 3 N Rossmann fold TIM barrel (Triose phosphate isomerase) Active site at C-terminal end of beta strands. 8 10/28/10 Alpha domains – helices pack with certain angles Myohemerythrin Let’s find out which are the preferred packing angles 25° 45° Myoglobin Helix packing 20° N C Four-helix bundle 50° Globin fold 9 10/28/10 Classification of domains Alpha domains Beta domains Cross‐linked domains Transducin-α: domains can be inserted Alpha/beta domains Alpha + beta domains Domain swapping Mosaic proteins 10 10/28/10 Protein folding • Proteins are only marginally stable ΔG=ΔH‐TΔS Protein folding landscape 1 105 dG dH TdS Energy (cal/mol) 5 104 0 -5 104 -1 105 150 200 250 300 350 400 450 T (K) Hydration shell Hydrophobic core small caviAes allow flexibility 11 10/28/10 Metal ions in proteins Further stabilisation by disulfide bonds, metal ions and cofactors DaAT: pyridoxal phosphate myoglobin: heme 12
