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Structural Bioinformatics

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Structure allows the detailed understanding of function ... Databases: PDB, SCOP, CATH, FSSP. Lecture 10 CS566 Fall 2006. 8. Structural representation ... – PowerPoint PPT presentation

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Title: Structural Bioinformatics


1
Structural Bioinformatics
  • Motivation
  • Concepts
  • Structure Solving
  • Structure Comparison
  • Structure Prediction
  • Modeling Structural Interaction

2
Motivation
  • Holy Grail Mapping between sequence and
    structure. Structure F(Sequence)
  • Structure allows the detailed understanding of
    function
  • Science-Fiction Simulate life as a movie of
    molecular interactions

3
Concepts
  • Protein and DNA structure of maximum interest,
    though growing interest in carbohydrates
  • Central Dogma
  • Primary structure gt Secondary structure,
    Tertiary structure gt Function
  • Primary structure
  • The actual permutation, i.e., the sequence per se
  • 20L possibilities, but only about 103-4 families
    (equivalence classes)
  • High spatial locality
  • Secondary structure
  • Helix, Sheet, Loop, Coil
  • Intermediate spatial locality Local organization
  • Tertiary structure
  • Only so many folds
  • Evolutionary bias?
  • Only so many stable structures?
  • Low spatial locality The actual 3D structure

4
Structural Bioinformatics
  • Macromolecular complex gt
  • Protein gt (No. of species 104)
  • Fold gt (103)
  • Domain gt (103-4)
  • Module gt
  • Motif gt
  • Residue gt
  • Atom

Level of abstraction
5
Primary structure
  • Determined
  • Experimentally
  • Sequencing
  • Computationally
  • Proteome prediction from genome
  • Finite number of real-world families based on
    sequence similarity
  • Significance Sine qua none
  • Databases Swiss-Prot, PIR, Genpept

6
Secondary structure
  • Determined
  • Experimentally
  • Circular dichroism, NMR, Raman spectroscopy
  • Computationally (Next semester!)
  • Sliding window context analysis
  • Periodicity analysis
  • Significance
  • Higher order building block
  • Mechanistic significance in protein folding

7
Tertiary structure
  • Determined
  • Experimentally
  • X-ray crystallography, NMR
  • Computationally
  • Based on similarity to known structures (Homology
    modeling)
  • a priori
  • Significance
  • Level of abstraction highly indicative of
    function
  • Databases PDB, SCOP, CATH, FSSP

8
Structural representation
  • Cartesian coordinates (x,y,z) for each atom in
    structure One vector for each atom
  • Internal coordinate representation (edges,
    angles) Set of inter-atom vectors
  • Visualized in graphical programs as
  • Surface representation
  • All atoms or just backbone (N-C-C) atoms
  • Cartoons Helix, Sheet, Loop shorthand

9
Structure Solving X-ray crystallography(With
apologies to crystallographers)
  • Given primary structure, find the tertiary
    structure experimentally
  • X-ray crystallography
  • Based on property of electrons to scatter X-rays
  • Make big beautiful protein crystal (Like sugar
    crystals Slow desiccation of protein soup)
  • Shoot X-rays through crystal and record
    diffraction pattern (Ripples from different
    sources forming interference pattern Light waves
    too gross for measurement of small interatomic
    distances)
  • Provided phase known, structure can be
    reconstructed using Fourier transforms

10
Structure Solving X-ray crystallography(With
apologies to crystallographers)
  • Phase information deduced by
  • Incorporation of heavy metals into proteins
    (Crystals from immersion of protein in heavy
    metal soup)
  • Use of known structures of similar sequences
    homology based structure solving
  • Iterative structure refinement based on matching
    simulated data from model and experimental
    diffraction pattern obtained
  • Limitation
  • No crystals, no structure!
  • Structure is an average over prolonged period of
    time

11
Structure Solving Nuclear Magnetic Resonance
Spectroscopy(With apologies to NMR
spectroscopists)
  • Basis
  • Based on magnetic properties of spinning protons
    and neutrons
  • Different atoms in different (structural)
    contexts react differently to magnetic fields
  • Key elements
  • Specially prepared (different forms of N and C)
    protein (soup) solution subjected to strong
    electromagnetic field to obtain spectroscopic
    data
  • Spectroscopic data interpreted as constraints on
    distances between atoms
  • Simulated annealing used to find best match
    between constraints and model

12
Structure Solving Nuclear Magnetic Resonance
Spectroscopy(With apologies to NMR
spectroscopists)
  • Limitations
  • Set of structures (not unique single solution)
    determined
  • On average, higher error than crystallography
  • Solves smaller structures than crystallography
  • Bright side of structure-solving
  • Algorithms and software well developed
  • More powerful sources of X-rays (can work with
    smaller crystals and in smaller time periods) and
    electromagnets becoming available
  • Optimized centers exist that can do a structure a
    week!
  • Challenges Higher resolution (The elusive but
    all-powerful hydrogen bond), Structures of
    complexes (Life is molecular interaction.
    Period)
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