Presentation is loading. Please wait.

Presentation is loading. Please wait.

Database extraction of residue-specific empirical potentials

Published byΛαυρέντιος Λούλης Modified over 5 years ago

Similar presentations

Presentation on theme: "Database extraction of residue-specific empirical potentials"— Presentation transcript:

1 Database extraction of residue-specific empirical potentials
building a complete set of energy parameters including distance and angle dependence of inter-residue interactions estimation of secondary structure propensities of amino acids utility in fold recognition, homology modeling and/or threading 11/11/2018

2 Underlying principle: Inverse Boltzmann law
Energies --> Probabilities (Boltzmann) Probabilities --> Energies (inverse Boltzmann) Boltzmann law: Pi ~ exp (-Ei/RT) Inverse Boltzmann: Ei = -RTlnPi + ct

3 Two types of interaction: Long-range Short-range
(close in space, not in sequence) Short-range (sequential neighbors) Long-range are the most important dominant interactions in folding

4 Residue-specific interactions
Interactions of hydrophobic residues Interactions between charged/polar residues

5 Residue-Residue Interactions (from Protein Structures)
Effective solvent-mediated contact potential = exy + e00 – ex0 – eyo

6 Residue-specific distributions of # of neighbors
0.0 0.1 0.2 0.3 Tot Gly Ala Leu Glu Pro Frequencies 15 10 5 # Neighbors

7 Short-range (bonded) interactions
Coupling between consecutive dihedral angles in the virtual bond model

8 Abscissa values from helix-coil transition [O'Neil and deGrado (1990)]
Comparison of predicted and experimental helical propensities 0.2 0.4 0.6 0.8 -0.2 A M ) (kcal/mol) L Q Y I F - F , V S + C ( N W A-GLY T - E G -  G (kcal/mol) Abscissa values from helix-coil transition [O'Neil and deGrado (1990)] For more info... Bahar, Kaplan and Jernigan, Proteins 1998

9 Experimental (abscissa) values from [Kim and Berg (1993)]
Comparison of predicted and experimental b-strand propensities 1 1.5 2 2.5 0.3 0.35 0.4 0.45 0.5 0.55 0.6 E X ( + , - ) =  G R= 0.90 I V C F )/RT Y L - , M W + K T D ( H A Q - E R N E S A -  G (kcal/mol) Experimental (abscissa) values from [Kim and Berg (1993)]

10

11 Multi-body geometry-dependent interactions?
Long distance effects can be taken care by ‘whole sentence exponential model”. Spatial, not sequential, correlations are important in controlling folding, misfolding, interactions. Can we select features/attributes that characterize the 3-d topology of contacts? Multi-body geometry-dependent interactions? Keskin, O. , Bahar, I. , Badredtinov, A., Ptitsyn, O. B., & Jernigan, R. L. Protein Science 7, , 1998.

Download ppt "Database extraction of residue-specific empirical potentials"

Similar presentations

Protein NMR terminology COSY-Correlation spectroscopy Gives experimental details of interaction between hydrogens connected via a covalent bond NOESY-Nuclear.

Protein NMR terminology COSY-Correlation spectroscopy Gives experimental details of interaction between hydrogens connected via a covalent bond NOESY-Nuclear.
François Fages MPRI Bio-info 2007 Formal Biology of the Cell Protein structure prediction with constraint logic programming François Fages, Constraint.

François Fages MPRI Bio-info 2007 Formal Biology of the Cell Protein structure prediction with constraint logic programming François Fages, Constraint.
Secondary structure prediction from amino acid sequence.

Secondary structure prediction from amino acid sequence.
1 Resonance assignment strategies. 2 Amino acid sequence + The assignment problem.

1 Resonance assignment strategies. 2 Amino acid sequence + The assignment problem.
PhyCMAP: Predicting protein contact map using evolutionary and physical constraints by integer programming Zhiyong Wang and Jinbo Xu Toyota Technological.

PhyCMAP: Predicting protein contact map using evolutionary and physical constraints by integer programming Zhiyong Wang and Jinbo Xu Toyota Technological.
Secondary structure assignment

Secondary structure assignment
Protein Structure Prediction using ROSETTA

Protein Structure Prediction using ROSETTA
Protein Threading Zhanggroup 2003 10 22. Overview Background protein structure protein folding and designability Protein threading Current limitations.

Protein Threading Zhanggroup Overview Background protein structure protein folding and designability Protein threading Current limitations.
Structure Prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography, NMR) [2]

Structure Prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography, NMR) [2]
Protein Secondary Structures

Protein Secondary Structures
Chapter 9 Structure Prediction. Motivation Given a protein, can you predict molecular structure Want to avoid repeated x-ray crystallography, but want.

Chapter 9 Structure Prediction. Motivation Given a protein, can you predict molecular structure Want to avoid repeated x-ray crystallography, but want.
Protein-a chemical view A chain of amino acids folded in 3D Picture from on-line biology bookon-line biology book Peptide Protein backbone N / C terminal.

Protein-a chemical view A chain of amino acids folded in 3D Picture from on-line biology bookon-line biology book Peptide Protein backbone N / C terminal.
Garnier-Osguthorpe-Robson

Garnier-Osguthorpe-Robson
Structure Prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography, NMR) [2]

Structure Prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography, NMR) [2]
Determination of alpha-helix propensities within the context of a folded protein Blaber et al. J. Mol. Biol 1994.

Determination of alpha-helix propensities within the context of a folded protein Blaber et al. J. Mol. Biol 1994.
Protein structure determination & prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray.

Protein structure determination & prediction. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray.
Protein Structural Prediction. Protein Structure is Hierarchical.

Protein Structural Prediction. Protein Structure is Hierarchical.
Protein Structure Prediction Dr. G.P.S. Raghava Protein Sequence + Structure.

Protein Structure Prediction Dr. G.P.S. Raghava Protein Sequence + Structure.
What are proteins? Proteins are important; e.g. for catalyzing and regulating biochemical reactions, transporting molecules, … Linear polymer chain composed.

What are proteins? Proteins are important; e.g. for catalyzing and regulating biochemical reactions, transporting molecules, … Linear polymer chain composed.
Lecture 10: Protein structure

Lecture 10: Protein structure

Similar presentations

Ads by Google