Post on 30-Dec-2015
PROTEINSPROTEINS
PROTEINSPROTEINS
Wood, brick, nails, glass Materials Amino acids, cofactors
Temperature, earthquakes Environmental Factors Temperature, solubility
How many people? Population Factors # partner proteins, # reactants
How many doors and windows? Portals Passages for substrates and reactants
Spanish, Victorian, Motifs/Styles Conserved domains or protein folds
1950's blocky science building
Julia Morgan Architect Evolution
Traditional Architecture Molecular ArchitectureFormfits
function
Levels of Protein Structure
Primary structure = order of amino acids in the protein chain
Charged and polar R-groups tend to map to protein surfaces
Non-polar R-groups tend to be buried in the cores of proteins
MyoglobinBlue = non-polarR-group
Red = Heme
Amino Acids Are Joined By Peptide Bonds In Peptides
- -carboxyl of one amino acid is joined to -amino of a second amino acid (with removal of water)
- only -carboxyl and -amino groups are used, not R-group carboxyl or amino groups
Chemistry of peptide bond formation
The peptide bond is planar
This resonance restricts the number of conformations in proteins -- main chain rotations are restricted to and
Primary sequence reveals important clues about a protein
DnaG E. coli ...EPNRLLVVEGYMDVVAL...DnaG S. typ ...EPQRLLVVEGYMDVVAL...DnaG B. subt ...KQERAVLFEGFADVYTA...gp4 T3 ...GGKKIVVTEGEIDMLTV...gp4 T7 ...GGKKIVVTEGEIDALTV...
: *: :: * * : :
small hydrophobiclarge hydrophobicpolarpositive chargenegative charge
• Evolution conserves amino acids that are important to protein structure and function across species. Sequence comparison of multiple “homologs” of a particular protein reveals highly conserved regions that are important for function.
• Clusters of conserved residues are called “motifs” -- motifs carry out a particular function or form a particular structure that is important for the conserved protein.
motif
Secondary structure = local folding of residues into regular patterns
The -helix• In the -helix, the carbonyl oxygen of residue “i” forms a hydrogen bond with the amide of residue “i+4”.
• Although each hydrogen bond is relatively weak in isolation, the sum of the hydrogen bonds in a helix makes it quite stable.
• The propensity of a peptide for forming an -helix also depends on its sequence.
The -sheet • In a -sheet, carbonyl oxygens and amides form hydrogen bonds.
• These secondary structures can be either antiparallel (as shown) or parallel and need not be planar (as shown) but can be twisted.
• The propensity of a peptide for forming -sheet also depends on its sequence.
Why do Secondary Structures form
Tertiary structure = global folding of a protein chain
Tertiary structures are quite varied
Quaternary structure = Higher-order assembly of proteins
Examples of other quaternary structures
Tetramer Hexamer Filament
SSB DNA helicase Recombinase Allows coordinated Allows coordinated DNA binding Allows complete DNA binding and ATP hydrolysis coverage of an
extended molecule
Quaternary Structures
Classes of proteinsFunctional definition:Enzymes: Accelerate biochemical reactions
Structural: Form biological structures
Transport: Carry biochemically important substances
Defense: Protect the body from foreign invaders
Structural definition:Globular: Complex folds, irregularly shaped tertiary structures
Fibrous: Extended, simple folds -- generally structural proteins
Cellular localization definition:Membrane: In direct physical contact with a membrane; generally
water insoluble.
Soluble: Water soluble; can be anywhere in the cell.
Protein Overview
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from sequence to structure
Function
to dynamics
Need to understand physical principles underlie the passage
LEVINTHAL PARADOXLEVINTHAL PARADOX
100 a.a in general
If there are 10 states/a.a 10100 conformations
Three Folding Problems
• Computational:Computational: Protein structure prediction from an amino acid sequence.
• .Folding speed: “Levinthal paradox” the kinetic question how can a protein fold so fasts
• The folding code: The folding code: The ”thermodynamic” question of how a native structure results from interatomic forces acting on an amino acid sequence
What if proteins misfold?• Diseases such as Alzheimer's disease, cystic fibrosis,
BSE (Mad Cow disease), and even many cancers are believed to result from protein misfolding.
• When proteins misfold, they can clump together ("aggregate"). These clumps can often gather in the brain, where they are believed to cause the symptoms of Mad Cow or Alzheimer's disease.
Experimental Structure PredictionExperimental Structure Prediction
• Electron Microscopy:Structural information for large macromolecules at low resolution
• NMR (Nuclear Magnetic Resonance) Spectroscopy: A solution of protein is placed in a magnetic field and the effects of different radio frequencies on the resonance of different atoms in proteins.
• X-ray crystallography: The beam of x-rays are passed through a crystal of protein. Atoms in the protein crystal scatter the x-rays, which produce a diffraction pattern on a photographic film.
Pros and ConsPros and Cons
• None of them is high throughput technology• NMR
– Size of protein limited (about 200 residues)– Protein must be soluble– can provide the structure in near physiological condition– can provide informations about dynamics
• X-ray Crystallography– Must be able to crystallize protein– Accurate
X-ray crystallographyX-ray crystallography
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NMRNMR
QuickTime™ and aTIFF (LZW) decompressor
are needed to see this picture.
Why Predict Protein Structures?
High Resolution Structures better than 3Å
To eliminate protein structure determination
To speed up drug discovery
Sequence --------------> StructureSequence --------------> Structure
FunctionFunction
‘Protein folding problem’
Bioinformatics. Sequence
alignments
A fundamental paradigm of protein science: The amino acid sequence encodes the structure; the structure determines
the function
Mod
ellin
g an
d
sim
ulat
ions
Dill & Chan
From a computational point of view:
What is a molecular dynamics simulation?
• Simulation that shows how the atoms in the system move with time
• Typically on the nanosecond timescale
• Atoms are treated like hard balls, and their motions are described by Newton’s laws.
Molecular Dynamics Theory
MD as a tool for minimizationEnergy
positionEnergy minimizationstops at local minima
Molecular dynamicsuses thermal energyto explore the energysurface
State A
State B
Folding Energy Landscape
The Folding @ Home initiative(Vijay Pande, Stanford University)
http://folding.stanford.edu/
The Folding @ Home initiative