1 / 168

Computational Molecular Biology

Computational Molecular Biology. Protein Structure: Introduction and Prediction. Protein Folding. One of the most important problem in molecular biology Given the one-dimensional amino-acid sequence that specifies the protein, what is the protein’s fold in three dimensions?. Overview.

latoyan
Download Presentation

Computational Molecular Biology

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Computational Molecular Biology Protein Structure: Introduction and Prediction

  2. Protein Folding • One of the most important problem in molecular biology • Given the one-dimensional amino-acid sequence that specifies the protein, what is the protein’s fold in three dimensions? My T. Thai mythai@cise.ufl.edu

  3. Overview • Understand protein structures • Primary, secondary, tertiary • Why study protein folding: • Structure can reveal functional information which we cannot find from the sequence • Misfolding proteins can cause diseases: mad cow disease • Use in drug designs My T. Thai mythai@cise.ufl.edu

  4. Overview of Protein Structure • Proteins make up about 50% of the mass of the average human • Play a vital role in keeping our bodies functioning properly • Biopolymers made up of amino acids • The order of the amino acids in a protein and the properties of their side chains determine the three dimensional structure and function of the protein My T. Thai mythai@cise.ufl.edu

  5. R O H N C C OH H H Amino Acid • Building blocks of proteins • Consist of: • An amino group (-NH2) • Carboxyl group (-COOH) • Hydrogen (-H) • A side chain group (-R) attached to the central α-carbon • There are 20 amino acids • Primary protein structure is a sequence of a chain of amino acids Side chain Aminogroup Carboxylgroup My T. Thai mythai@cise.ufl.edu

  6. Side chains (Amino Acids) • 20 amino acids have side chains that vary in structure, size, hydrogen bonding ability, and charge. • R gives the amino acid its identity • R can be simple as hydrogen (glycine) or more complex such as an aromatic ring (tryptophan) My T. Thai mythai@cise.ufl.edu

  7. Chemical Structure of Amino Acids

  8. How Amino Acids Become Proteins Peptide bonds My T. Thai mythai@cise.ufl.edu

  9. Polypeptide • More than fifty amino acids in a chain are called a polypeptide. • A protein is usually composed of 50 to 400+ amino acids. • We call the units of a protein amino acid residues. amidenitrogen carbonylcarbon My T. Thai mythai@cise.ufl.edu

  10. Side chain properties • Carbon does not make hydrogen bonds with water easily – hydrophobic. • These ‘water fearing’ side chains tend to sequester themselves in the interior of the protein • O and N are generally more likely than C to h-bond to water – hydrophilic • Ten to turn outward to the exterior of the protein My T. Thai mythai@cise.ufl.edu

  11. My T. Thai mythai@cise.ufl.edu

  12. Primary Structure Primary structure: Linear String of Amino Acids Side-chain Backbone ... ALA PHE LEU ILE LEU ARG ... Each amino acid within a protein is referred to as residues Each different protein has a unique sequence of amino acid residues, this is its primary structure My T. Thai mythai@cise.ufl.edu

  13. Secondary Structure • Refers to the spatial arrangement of contiguous amino acid residues • Regularly repeating local structures stabilized by hydrogen bonds • A hydrogen atom attached to a relatively electronegative atom • Examples of secondary structure are the α–helix and β–pleated-sheet My T. Thai mythai@cise.ufl.edu

  14. Alpha-Helix • Amino acids adopt the form of a right handed spiral • The polypeptide backbone forms the inner part of the spiral • The side chains project outward • every backbone N-H group donates a hydrogen bond to the backbone C = O group My T. Thai mythai@cise.ufl.edu

  15. Beta-Pleated-Sheet • Consists of long polypeptide chains called beta-strands, aligned adjacent to each other in parallel or anti-parallel orientation • Hydrogen bonding between the strands keeps them together, forming the sheet • Hydrogen bonding occurs between amino and carboxyl groups of different strands My T. Thai mythai@cise.ufl.edu

  16. Parallel Beta Sheets My T. Thai mythai@cise.ufl.edu

  17. Anti-Parallel Beta Sheets My T. Thai mythai@cise.ufl.edu

  18. Mixed Beta Sheets My T. Thai mythai@cise.ufl.edu

  19. Tertiary Structure • The full dimensional structure, describing the overall shape of a protein • Also known as its fold My T. Thai mythai@cise.ufl.edu

  20. Quaternary Structure • Proteins are made up of multiple polypeptide chains, each called a subunit • The spatial arrangement of these subunits is referred to as the quaternary structure • Sometimes distinct proteins must combine together in order to form the correct 3-dimensional structure for a particular protein to function properly. • Example: the protein hemoglobin, which carries oxygen in blood. Hemoglobin is made of four similar proteins that combine to form its quaternary structure. My T. Thai mythai@cise.ufl.edu

  21. Other Units of Structure • Motifs (super-secondary structure): • Frequently occurring combinations of secondary structure units • A pattern of alpha-helices and beta-strands • Domains: A protein chain often consists of different regions, or domains • Domains within a protein often perform different functions • Can have completely different structures and folds • Typically a 100 to 400 residues long My T. Thai mythai@cise.ufl.edu

  22. What Determines Structure • What causes a protein to fold in a particular way? • At a fundamental level, chemical interactions between all the amino acids in the sequence contribute to a protein’s final conformation • There are four fundamental chemical forces: • Hydrogen bonds • Hydrophobic effect • Van der Waal Forces • Electrostatic forces My T. Thai mythai@cise.ufl.edu

  23. Hydrogen Bonds • Occurs when a pair of nucliophilic atoms such as oxygen and nitrogen share a hydrogen between them • Pattern of hydrogen bounding is essential in stabilizing basic secondary structures My T. Thai mythai@cise.ufl.edu

  24. Van der Waal Forces • Interactions between immediately adjacent atoms • Result from the attraction between an atom’s nucleus and it neighbor’s electrons My T. Thai mythai@cise.ufl.edu

  25. Electrostatic Forces • Oppositely charged side chains con form salt-bridges, which pulls chains together My T. Thai mythai@cise.ufl.edu

  26. Experimental Determination • Centralized database (to deposit protein structures) called the protein Databank (PDB), accessible at http://www.rcsb.org/pdb/index.html • Two main techniques are used to determine/verify the structure of a given protein: • X-ray crystallography • Nuclear Magnetic Resonance (NMR) • Both are slow, labor intensive, expensive (sometimes longer than a year!) My T. Thai mythai@cise.ufl.edu

  27. X-ray Crystallography • A technique that can reveal the precise three dimensional positions of most of the atoms in a protein molecule • The protein is first isolatedto yield a high concentration solution of the protein • This solution is then used to grow crystals • The resulting crystal is then exposed to an X-ray beam My T. Thai mythai@cise.ufl.edu

  28. Disadvantages • Not all proteins can be crystallized • Crystalline structure of a protein may be different from its structure • Multiple maps may be needed to get a consensus My T. Thai mythai@cise.ufl.edu

  29. NMR • The spinning of certain atomic nuclei generates a magnetic moment • NMR measures the energy levels of such magnetic nuclei (radio frequency) • These levels are sensitive to the environment of the atom: • What they are bonded to, which atoms they are close to spatially, what distances are between different atoms… • Thus by carefully measurement, the structure of the protein can be constructed My T. Thai mythai@cise.ufl.edu

  30. Disadvantages • Constraint of the size of the protein – an upper bound is 200 residues • Protein structure is very sensitive to pH. My T. Thai mythai@cise.ufl.edu

  31. Computational Methods • Given a long and painful experimental methods, need computational approaches to predict the structure from its sequence. My T. Thai mythai@cise.ufl.edu

  32. Functional Region Prediction My T. Thai mythai@cise.ufl.edu

  33. Protein Secondary Structure My T. Thai mythai@cise.ufl.edu

  34. Tertiary Structure Prediction My T. Thai mythai@cise.ufl.edu

  35. More Details on X-ray Crystallography My T. Thai mythai@cise.ufl.edu

  36. Overview My T. Thai mythai@cise.ufl.edu

  37. Overview My T. Thai mythai@cise.ufl.edu

  38. Crystal • A crystal can be defined as an arrangement of building blocks which is periodic in three dimensions My T. Thai mythai@cise.ufl.edu

  39. Crystallize a Protein • Have to find the right combination of all the different influences to get the protein to crystallize • This can take a couple hundred or even thousand experiments • Most popular way to conduct these experiments • Hanging-drop method My T. Thai mythai@cise.ufl.edu

  40. Hanging drop method • The reservoir contains a precipitant concentration twice as high as the protein solution • The protein solutions is made up of 50% of stock protein solution and 50% of reservoir solution • Overtime, water will diffuse from the protein drop into the reservoir • Both the protein concentration and precipitant concentration will increase • Crystals will appear after days, weeks, months My T. Thai mythai@cise.ufl.edu

  41. Properties of protein crystal • Very soft • Mechanically fragile • Large solvent areas (30-70%) My T. Thai mythai@cise.ufl.edu

  42. A Schematic Diffraction Experiment My T. Thai mythai@cise.ufl.edu

  43. Why do we need Crystals • A single molecule could never be oriented and handled properly for a diffraction experiment • In a crystal, we have about 1015 molecules in the same orientation so that we get a tremendous amplification of the diffraction • Crystals produce much simpler diffraction patterns than single molecules My T. Thai mythai@cise.ufl.edu

  44. Why do we need X-rays • X-rays are electromagnetic waves with a wavelength close to the distance of atoms in the protein molecules • To get information about where the atoms are, we need to resolve them -> thus we need radiation My T. Thai mythai@cise.ufl.edu

  45. A Diffraction Pattern My T. Thai mythai@cise.ufl.edu

  46. My T. Thai mythai@cise.ufl.edu

  47. Resolution • The primary measure of crystal order/quality of the model • Ranges of resolution: • Low resolution (>3-5 Ao) is difficult to see the side chains only the overall structural fold • Medium resolution (2.5-3 Ao) • High resolution (2.0 Ao) My T. Thai mythai@cise.ufl.edu

  48. Some Crystallographic Terms • h,k,l: Miller indices (like a name of the reflection) • I(h,k,l): intensity • 2θ: angle between the x-ray incident beam and reflect beam My T. Thai mythai@cise.ufl.edu

  49. Diffraction by a Molecule in a Crystal • The electric vector of the X-ray wave forces the electrons in our sample to oscillate with the same wavelength as the incoming wave My T. Thai mythai@cise.ufl.edu

  50. Description of Waves My T. Thai mythai@cise.ufl.edu

More Related