Structure-based drug discovery is a collection of methods that exploits the ability to determine and analyse the three dimensional structure of biological molecules. These methods have been adopted and enhanced to improve the speed and quality of discovery of new drug candidates. After an introductory overview of the principles and application of structure-based methods in drug discovery, this book then describes the essential features of the various methods. Chapters on X-ray crystallography, NMR spectroscopy, and computational chemistry and molecular modelling describe how these particular techniques have been enhanced to support rational drug discovery, with discussions on developments such as high throughput structure determination, probing protein-ligand interactions by NMR spectroscopy, virtual screening and fragment-based drug discovery. The concluding chapters complement the overview of methods by presenting case histories to demonstrate the major impact that structure-based methods have had on discovering drug molecules. Written by international experts from industry and academia, this comprehensive introduction to the methods and practice of structure-based drug discovery not only illustrates leading-edge science but also provides the scientific background for the non-expert reader. The book provides a balanced appraisal of what structure-based methods can and cannot contribute to drug discovery. It will appeal to industrial and academic researchers in pharmaceutical sciences, medicinal chemistry and chemical biology, as well as providing an insight into the field for recent graduates in the biomolecular sciences.
Tabla de materias
Chapter 1: 3D Structure and the Drug Discovery Process; 1: Introduction; 2: The Drug Discovery Process; 3: What is Structure-based Drug Discovery?; 4: The Evolution of the Ideas of Structure-based Drug Discovery; 5: What isn’t in this Book; 6: Concluding Remarks; References; Chapter 2: Structure Detemination – Crystallography for Structure-based Drug Design; 1: What is X-ray Crystallography?; 2: What is required to Produce a Crystal Structure?; 3: Crystallisability of Proteins; 4: How Does the X-ray Data Relate to the Electron Density? The Phase Problem; 5: Electron Density Map Interpretation and Atomic Model of the Protein; 6: Useful Crystallographic Therminology when Utilising Crystal Structures; 7: The Structure Determination Process; 8: Recent technological Advances; 9: The Role of Crystal Structures in the Discovery Process; 10: The Optimal SBDD System; 11: The Impact of Structural Genomics; 12: Producing a Biologically Relevant Structure; 13: Phosphorylation; 14: Balancing Solubility with Crystallisability; 15: Engineering Solubility; 16: Specific Crystal Packing Engineering; 17: Engineering Stability; 18: Use of Surrogate Proteins; References; Chapter 3: Molecular Modelling; 1: Introduction; 2: Methods; 3: Applications; 4: Conclusion; References; Chapter 4: Applications of NMR in Structure-based Drug Design; 1: Introduction; 2: Studying Ligand/Receptor Interactions by NMR; 3: NMR in Structure-based Lead Optimization; 4: Other Applications of NMR in SBDD; 5: Conclusion and Outlook; References; Chapter 5: Fragment Screening – An Introduction; 1: Introduction; 2: The Concept of Drug Likeness; 3: The Evolution of Lead-likeness and Fragment Screening; 4: Finding Fragments by Screening; 5: The Design of Fragment Screening Sets; 6: Turning Fragment Hits into Leads; 7:Summary; References; Chapter 6: Iterative Structure-based Screening of Virtual Chemical Libraries and Factor Xa: Finding the Orally Available Antithrombotic Candadate LY517717; 1: Introduction; 2: Morphology of the Factor Xa Active Site; 3: Structure-based Library Design; 4: Design Strategy for Factor Xa; 5: Introducing Oral Availability; 6: Non-basic S1 Series; 7: Oral Antithrombotic Activity; 8: Conclusion; References; Chapter 7: Anti-influenza Drugs from Sialidase Inhibitors; 1: Introduction; 2: Influenza Viruses; 3: Early Attempts to Discover Neuraminidase Inhibitors; 4: Neuraminidase Structure; 5: Structure-based Discovery of Inhibitors; 6: Retrospective Analyses of Inhibitor-binding; 7: Laboratory Studies of Inhibitor Resistant Variants; 8: Clinical Studies of Drug Resistance; 9: Drug Profiles; Conclusions; References; Chapter 8: Isoform Specificity: The Design of Estrogen Receptor- Selective Compounds; 1: Introduction; 2: Structure-based Design Methodology; 3: The Design of Aryl Diphenolic Azoles as ER? Selective Agonists; 4: Learning From and Moving Beyond the Genistein Scaffold; 5: Evaluation of ER? Selective Compounds in Biological Assays; Conclusions; Acknowledgements; References