Presentation is loading. Please wait.

Presentation is loading. Please wait.

Computer-Assisted Drug Design (1) i)Random Screening ii)Lead Development and Optimization using Multivariate Statistical Analyses. iii)Lead Generation.

Published byCarmel Hamilton Modified over 9 years ago

Similar presentations

Presentation on theme: "Computer-Assisted Drug Design (1) i)Random Screening ii)Lead Development and Optimization using Multivariate Statistical Analyses. iii)Lead Generation."— Presentation transcript:

1 Computer-Assisted Drug Design (1) i)Random Screening ii)Lead Development and Optimization using Multivariate Statistical Analyses. iii)Lead Generation – Structure Based Drug Design using Computer Graphics and Computer Chemistry.

2 Computer-Assisted Drug Design (2) Structure Based Drug Design i)Computer Graphics ii)Docking Study using Molecular Mechanics iii)Lead Generation i)Generate Novel Compounds that Fit to the Pharmacophore Features ii)Optimize their Chemical Structures using Molecular Mechanics and Molecular Dynamics.

3 Procedure of Structure Based Drug Design (Lead Generation) i)Determine 3D structure of a target protein using X-ray crystallography and NMR (Nuclear Magnetic Resonance) ii)Generate chemical structure that fits to the pharmacophore of the protein Using Computer Graphics, etc. iii)Compute the interaction energy between the compound and the protein. iv)Optimize the chemical structure in order to maximize the interaction energy

4

5 Experimental Methods for Determining 3D Structures of Proteins 1) X-ray crystallography ・ more accurate than NMR ・ crystal has to be grown to a sufficient size and volume 2) NMR ・ information about flexibility ・ no need for crystals ・ easy to change conditions (pH, temperature, etc.) ・ size limit

6 A Computational Method for Determining 3D Structures of Proteins Homology Modeling using Sequence Homology 1.Identify homologous proteins and determine the extent of their sequence similarity with one another and the unknown 2.Align the sequences 3. Identify structurally conserved and structurally variable regions 4. Generate coordinates for core (structurally conserved) residues of the unknown structure from those of the known structure(s) 5.Generate conformations for the loops (structurally variable) in the unknown structure 6.Build the side-chain conformations 7.Refine and evaluate the unknown structure. http://cl.sdsc.edu/hm.html

7 Determination of Molecular Structure Using Moolecular Mechanics E total = E stretch + E bend + E torsion + E vdW + E dipole E stretch E bend E torsion E vdW minimize

8 Molecular Dynamics Calculation 1)Determine the initial positions and the initial velocities of the atoms 2)Compute Forces using the equation, 3)According to the equation of motion, F=ma, Compute the next position of the atoms

9 Molecular Dynamics Calculation

10

Download ppt "Computer-Assisted Drug Design (1) i)Random Screening ii)Lead Development and Optimization using Multivariate Statistical Analyses. iii)Lead Generation."

Similar presentations

Crystallography, Birkbeck MOLECULAR SIMULATIONS ALL YOU (N)EVER WANTED TO KNOW Julia M. Goodfellow Dynamic Processes: Lecture 1 Lecture Notes.

Crystallography, Birkbeck MOLECULAR SIMULATIONS ALL YOU (N)EVER WANTED TO KNOW Julia M. Goodfellow Dynamic Processes: Lecture 1 Lecture Notes.
3D Molecular Structures C371 Fall 2004. Morgan Algorithm (Leach & Gillet, p. 8)

3D Molecular Structures C371 Fall Morgan Algorithm (Leach & Gillet, p. 8)
Computational Chemistry

Computational Chemistry
Tutorial Homology Modelling. A Brief Introduction to Homology Modeling.

Tutorial Homology Modelling. A Brief Introduction to Homology Modeling.
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.
Computing Protein Structures from Electron Density Maps: The Missing Loop Problem I. Lotan, H. van den Bedem, A. Beacon and J.C. Latombe.

Computing Protein Structures from Electron Density Maps: The Missing Loop Problem I. Lotan, H. van den Bedem, A. Beacon and J.C. Latombe.
1 Protein Structure, Structure Classification and Prediction Bioinformatics X3 January 2005 P. Johansson, D. Madsen Dept.of Cell & Molecular Biology, Uppsala.

1 Protein Structure, Structure Classification and Prediction Bioinformatics X3 January 2005 P. Johansson, D. Madsen Dept.of Cell & Molecular Biology, Uppsala.
Lecture 3 – 4. October 2010 Molecular force field 1.

Lecture 3 – 4. October 2010 Molecular force field 1.
Structural bioinformatics

Structural bioinformatics
Molecular Simulation. Molecular Simluation Introduction: Introduction: Prerequisition: Prerequisition: A powerful computer, fast graphics card, A powerful.

Molecular Simulation. Molecular Simluation Introduction: Introduction: Prerequisition: Prerequisition: A powerful computer, fast graphics card, A powerful.
Protein structure determination. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography,

Protein structure determination. Tertiary protein structure: protein folding Three main approaches: [1] experimental determination (X-ray crystallography,
CISC667, F05, Lec21, Liao1 CISC 467/667 Intro to Bioinformatics (Fall 2005) Protein Structure Prediction 3-Dimensional Structure.

CISC667, F05, Lec21, Liao1 CISC 467/667 Intro to Bioinformatics (Fall 2005) Protein Structure Prediction 3-Dimensional Structure.
The 7 steps of Homology modeling. 1: Template recognition and initial alignment.

The 7 steps of Homology modeling. 1: Template recognition and initial alignment.
. Protein Structure Prediction [Based on Structural Bioinformatics, section VII]

. Protein Structure Prediction [Based on Structural Bioinformatics, section VII]
1 Protein Structure Prediction Reporter: Chia-Chang Wang Date: April 1, 2005.

1 Protein Structure Prediction Reporter: Chia-Chang Wang Date: April 1, 2005.
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.
IV. Protein Structure Prediction and Determination Methods of protein structure determination Critical assessment of structure prediction Homology modelling.

IV. Protein Structure Prediction and Determination Methods of protein structure determination Critical assessment of structure prediction Homology modelling.
Physics of Protein Folding. Why is the protein folding problem important? Understanding the function Drug design Types of experiments: X-ray crystallography.

Physics of Protein Folding. Why is the protein folding problem important? Understanding the function Drug design Types of experiments: X-ray crystallography.
Using Structure to Elucidate Function/Mechanism An experimental strategy for – determining the arrangement of atoms/molecules in space to obtain structural.

Using Structure to Elucidate Function/Mechanism An experimental strategy for – determining the arrangement of atoms/molecules in space to obtain structural.
Genetic Threading By J.Yadgari and A.Amir Published: special issue on Bioinformatics in Journal of Constraints, June 2001 Alexandre Tchourbanov University.

Genetic Threading By J.Yadgari and A.Amir Published: special issue on Bioinformatics in Journal of Constraints, June 2001 Alexandre Tchourbanov University.

Similar presentations

Ads by Google