Dr. Jayarama Reddy Foundation| Drug Designing| AutoDock Vina PyRx| Molecular Docking| Bioinformatics скачать в хорошем качестве

Dr. Jayarama Reddy Foundation| Drug Designing| AutoDock Vina PyRx| Molecular Docking| Bioinformatics

Subscribe to    / @drjayaramareddyfoundation:   You are welcome to join Dr. Jayarama Reddy Online University in a way that suits you. Visit: www.drjayaramareddy.com Protocol for Molecular Docking Using AutoDock Vina (PyRx): Introduction Molecular docking is a key technique in computer-aided drug design (CADD) used to predict the binding orientation, interaction, and affinity between a small-molecule ligand and a biological macromolecule (usually a protein). AutoDock Vina is a widely used open-source docking engine known for its speed and improved scoring function, while PyRx is a user-friendly graphical interface that integrates AutoDock Vina with ligand preparation and virtual screening tools. ________________________________________ Requirements for Docking Using PyRx–AutoDock Vina • Protein structure (PDB format) • Ligand structures (SDF/MOL/PDB format) • PyRx software (with AutoDock Vina) • Visualization tools (PyMOL, Discovery Studio) • Stable computing environment ________________________________________ Step-by-Step Protocol for Docking Using PyRx ________________________________________ Step 1: Target Protein Preparation 1. Download the 3D structure of the target protein from the Protein Data Bank (PDB). 2. Open the protein in PyMOL or Discovery Studio. 3. Perform protein cleaning: o Remove water molecules o Remove co-crystallized ligands (if required) o Delete unwanted ions 4. Save the cleaned protein in PDB format. Purpose: Ensures accurate docking by eliminating unnecessary molecules. ________________________________________ Step 2: Ligand Preparation 1. Download ligands from databases such as: o PubChem o ZINC o DrugBank 2. Import ligand files (SDF/MOL) into PyRx. 3. Perform: o Energy minimization o Geometry optimization 4. Convert ligands to PDBQT format using Open Babel (integrated in PyRx). Purpose: Generates energetically stable ligand conformations. ________________________________________ Step 3: Importing Files into PyRx 1. Launch PyRx. 2. Import the prepared protein and ligand files. 3. Convert the protein to macromolecule (PDBQT) format. 4. Ensure all ligands are listed in the ligand panel. ________________________________________ Step 4: Defining the Grid Box 1. Open the Vina Wizard in PyRx. 2. Set the grid box around: o Known active site or o Entire protein (blind docking) 3. Adjust grid parameters: o X, Y, Z center coordinates o Grid box dimensions Purpose: Defines the search space for ligand binding. ________________________________________ Step 5: Docking Using AutoDock Vina 1. Select AutoDock Vina as the docking engine. 2. Set docking parameters: o Exhaustiveness (controls search thoroughness) o Number of binding modes 3. Start the docking process. 4. Vina predicts: o Binding poses o Binding affinity (kcal/mol) ________________________________________ Step 6: Docking Output and Results • PyRx displays: o Binding energy values o Ranked docking poses • Lower (more negative) binding energy indicates stronger binding affinity. • Save docking results for further analysis. ________________________________________ Step 7: Visualization of Docked Complex 1. Export docked complexes to PyMOL or Discovery Studio. 2. Analyze protein–ligand interactions: o Hydrogen bonds o Hydrophobic interactions o π–π interactions 3. Capture images for reports or publications. ________________________________________ Step 8: Post-Docking Analysis • Compare docking scores of multiple ligands • Identify lead compounds • Correlate docking results with biological activity • Perform ADMET analysis (SwissADME, pkCSM) Applications of AutoDock Vina–PyRx Protocol 1. Virtual Screening of Drug Libraries 2. Lead Identification and Optimization 3. Structure-Based Drug Design 4. Drug Repurposing Studies 5. Understanding Molecular Interactions 6. Academic and Industrial Research 7. Teaching and Training in CADD 8. Pre-clinical Drug Discovery ________________________________________ Advantages of Using PyRx with AutoDock Vina • Free and open source • User-friendly graphical interface • High-throughput virtual screening • Faster and accurate scoring • Supports large ligand libraries ________________________________________ Limitations • Rigid receptor assumption (limited protein flexibility) • Docking results require experimental validation • Accuracy depends on quality of input structures ________________________________________ Conclusion AutoDock Vina integrated with PyRx provides a powerful and accessible platform for molecular docking and virtual screening in CADD. Its streamlined protocol, combined with reliable scoring and visualization