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Bioinformatica I

Bioinformatica I. The amino acids. Things to do today. Proteins (high speed sneak preview) Primary structure Secondary structure Tertiary structure The amino acids One amino acid Our first protein A closer look at the amino acids Secondary structure preferences.

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Bioinformatica I

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  1. Bioinformatica I The amino acids

  2. Things to do today • Proteins (high speed sneak preview) • Primary structure • Secondary structure • Tertiary structure • The amino acids • One amino acid • Our first protein • A closer look at the amino acids • Secondary structure preferences

  3. Our goal for today:a different view on proteins

  4. Protein? Protein!

  5. Proteins • Primary structure • A.K.A. “the sequence” • Secondary structure • Short stretches form distinct ‘substructures’ • Helices • Strands • Turns & Loops • Tertiary structure • The arrangement of secondary structure elements with respect to each other

  6. Primary structure The amino acid sequence (alsocalledprimarystructure) of a protein is the order of the aminoacids in the proteinchain. The sequence is alwaysreadfrom the N-terminusto the C-terminus of the protein. For example: +H3N-Lys-Val-Phe-Ala-Met-Cys-Leu-Leu-Arg-Val-COO- Or (in one-lettercode): KVFAMCLLRV

  7. Proteins • Primary structure • A.K.A. “the sequence” • Secondary structure • Short stretches form distinct ‘substructures’ • Helices • Strands • Turns & Loops • Tertiary structure • The arrangement of secondary structure elements with respect to each other

  8. Secondary structure - helix

  9. Secondary structure - strands

  10. Secondary structure - turn

  11. Proteins • Primary structure • A.K.A. “the sequence” • Secondary structure • Short stretches form distinct ‘substructures’ • Helices • Strands • Turns & Loops • Tertiary structure • The arrangement of secondary structure elements with respect to each other

  12. From sequence to structure?

  13. “When you understand the amino acids, you understand everything”

  14. The amino acids A short introduction

  15. One amino acid • Cα is at the heart of the amino acid • Cα, C N and O are called backbone atoms • R can be any of the 20 side chains

  16. Our first protein

  17. Our first protein • We now have an oligomer • Proteins are made upfrom 20 different amino acids • String of amino acids is called“primary structure”

  18. The 20 amino acids A Ala Alanine C Cys Cysteine D Asp Aspartic acid (Aspartate) E Glu Glutamic acid (Glutamate) F Phe Phenylalanine G Gly Glycine H His Histidine I Ile Isoleucine K Lys Lysine L Leu Leucine M Met Methionine N Asn Asparagine P Pro Proline Q Gln Glutamine R Arg Arginine S Ser Serine T Thr Threonine V Val Valine W Trp Tryptophan Y Tyr Tyrosine

  19. The 20 amino acids The side chains, R, determine the differences in the structural and chemical properties of the 20 ‘natural’ amino acids. The 20 amino acids can, for example, be classified as follows: Hydrophobic Aliphatic Ala, Leu, Ile, Val Aromatic Phe, Tyr, Trp, (His) Hydrophilic Polar Asn, Gln Alcoholic Ser, Thr, (Tyr) Charged Arg, Lys, Asp, Glu, (His) Inbetween: Sulfur-containing Met, Cys Special Gly (no R), Pro (cyclic) Several amino acids belong in more than one category.

  20. There are many ways to characterize the properties of amino acids. The ones most useful and most commonly used are: • Hydrophobicity • Size • Charge • Secondary structure preference • Alcoholicity • Aromaticity • And on top of that there are some special characteristics like bridge forming by cysteines, rigidity of prolines, titrating at physiological pH of histidine, flexibility of glycines, etc.

  21. Hydrophobic

  22. Aromatic

  23. Hydrophilic - neutral

  24. Hydrophilic - charged

  25. Sulfur - containing

  26. Really special

  27. Cysteines are extra special

  28. Key points about the character of amino acid side chains • amino acids don’t fall neatly into classes--they are different combinations of small/large, charged/uncharged, polar/nonpolar properties • the properties of a residue type can also vary with conditions/environment

  29. Obviously, there are relations between the physico-chemical characteristics of the amino acids and their secondary structure preference.

  30. Secondary structure preferences

  31. Secondary structure - helix

  32. Secondary structure - helix • Helices pack because of the hydrogen bonds and because of the hydrophobic packing of side chains along the length of the helix. • Certain residues do this hydrophobic packing better than others, and those residues are thus good for a helix.Remember: AMELK

  33. Secondary structure - strands

  34. Secondary structure - strands • Also strands pack because hydrophobic packing of side chains along the length of the strand. • Certain residues do this hydrophobic packing better than others, and those residues are thus good for a strands. b-branched residues (Ile, Thr, Val) are very good for strands, and so are the large hydrophobic residues. • Remember: VITWYF

  35. Secondary structure - turn

  36. Secondary structure - turns • To create a turn the backbone needs to be bent pretty sharply, and some residues are really good at that. • Glycine is special because it is so flexible, so it can easily make the sharp turns and bends needed in a b-turn. Proline is special because it is so rigid; you could say that it is pre-bent for the turn. Aspartic acid, asparagine, and serine have in common that they have short side chains that can form hydrogen bonds with the own backbone. These hydrogen bonds compensate the energy loss caused by bending the chain into a • Remember: PSDNG

  37. A common theme • Most secondary structure elements are located at the surface of the protein • For helices and strands that means that there is a part facing the ‘outside’ and a part that’s facing the ‘inside’

  38. What goes where?

  39. Hydrophobicity Hydrophobicity is the most important characteristic of amino acids. It is the hydrophobic effect that drives proteins towards folding. Actually, it is all done by water. Water does not like hydrophobic surfaces. When a protein folds, exposed hydrophobic side chains get buried, and release water of its sad duty to sit against the hydrophobic surfaces of these side chains. Water is very happy in bulk water because there it has on average 3.6 H-bonds and about six degrees of freedom. So, whenever we discuss protein structure, folding, and stability, it is all the entropy of water, and that is called the hydrophobic effect.

  40. When hydrophobic objects come together in water, the number of unhappy waters go down, and that is good for stability. Free waters are happy waters.

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