Difference between revisions of "2012 DOCK tutorial with Streptavidin"

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DOCK 6.X uses an incremental construction algorithm called ''anchor and grow''. It is described by a three-step process:
 
DOCK 6.X uses an incremental construction algorithm called ''anchor and grow''. It is described by a three-step process:
  
1) Rigid portion of ligand (anchor) is docked by geometric methods.
+
*1) Rigid portion of ligand (anchor) is docked by geometric methods.
2) Non-rigid segments added in layers; energy minimized.
+
*2) Non-rigid segments added in layers; energy minimized.
3) The resulting configurations are 'pruned' and energy re-minimized, yielding the docked configurations.
+
*3) The resulting configurations are 'pruned' and energy re-minimized, yielding the docked configurations.
  
 
===Streptavidin & Biotin===
 
===Streptavidin & Biotin===

Revision as of 11:43, 24 February 2012

For additional Rizzo Lab tutorials see DOCK Tutorials.

I. Introduction

DOCK

DOCK is a molecular docking program used in drug discovery. It was developed by Irwin D. Kuntz, Jr. and colleagues at UCSF (see UCSF DOCK). This program, given a protein binding site and a small molecule, tries to predict the correct binding mode of the small molecule in the binding site, and the associated binding energy. Small molecules with highly favorable binding energies could be new drug leads. This makes DOCK a valuable drug discovery tool. DOCK is typically used to screen massive libraries of millions of compounds against a protein to isolate potential drug leads. These leads are then further studied, and could eventually result in a new, marketable drug. DOCK is works well as a screening procedure for generating leads, but not nearly as well for optimization of those leads.

DOCK 6.X uses an incremental construction algorithm called anchor and grow. It is described by a three-step process:

  • 1) Rigid portion of ligand (anchor) is docked by geometric methods.
  • 2) Non-rigid segments added in layers; energy minimized.
  • 3) The resulting configurations are 'pruned' and energy re-minimized, yielding the docked configurations.

Streptavidin & Biotin

Streptavidin is a tetrameric prokaryoke protein that binds the co-enzyme biotin with an extremely high affinity. The streptavidin monomer is composed of eight antiparallel beta-strands which folds to give a beta barrel tertiary structure. A biotin binding-site is located at one end of each β-barrel, which has a high affinity as well as a high avidity for biotin. Four identical streptavidin monomers associate to give streptavidin’s tetrameric quaternary structure. The biotin binding-site in each barrel consists of residues from the interior of the barrel, together with a conserved Trp120 from neighbouring subunit. In this way, each subunit contributes to the binding site on the neighboring subunit, and so the tetramer can also be considered a dimer of functional dimers.

Biotin is a water soluble B-vitamin complex which is composed of an ureido (tetrahydroimidizalone) ring fused with a tetrahydrothiophene ring. It is a co-enzyme that is required in the metabolism of fatty acids and leucine. It is also involved in gluconeogenisis.


Organizing Directories

While performing docking, it is convenient to adopt a standard naming scheme / directory structure so that files are easy to identify and find. For this tutorial, we will use something similar to the following:

~username/AMS536/DOCK-Tutorial/00-original-files/
                              /01-dockprep/
                              /02-surface-spheres/
                              /03-box-grid/
                              /04-dock/
                              /05-virtual-screen/

The following sections will refer back to files within these directories.

II. Preparing the Receptor and Ligand

Downloading the PDB Structure

Preparing for DOCK with Chimera

III. Generating Receptor Surface and Spheres

Receptor Surface

Spheres

IV. Generating Box and Grid

Box

Grid

V. Docking a Single Molecule for Pose Reproduction

Docking

Results

VI. Virtual Screening

Virtual Screening Protocol

Virtual Screening Results

VII. Running DOCK in Serial and in Parallel on Seawulf

Use PBS Queue as a reference.

Serial Calculation for Pose Reproduction

Parallel Virtual Screen

VIII. Frequently Encountered Problems