Logo UAB
2022/2023

Structure and Function of Proteins and Drug Design

Code: 42398 ECTS Credits: 12
Degree Type Year Semester
4313473 Bioinformatics OT 0 1

Contact

Name:
Xavier Daura Ribera
Email:
xavier.daura@uab.cat

Use of Languages

Principal working language:
english (eng)

Teachers

Ester Boix Borras
Leonardo Pardo Carrasco
Josep Vendrell Roca
Jean-Didier Pierre Marechal
Angel Gonzalez Wong
Marc Gómez Autet
Nil Casajuana Martín
Laura Masgrau Fontanet
Alex Peralvarez Marin
Oscar Conchillo Solé
José Emilio Sanchez Aparicio
Xavier Daura Ribera

Prerequisites

To take this module it is necessary to have  previously passed both compulsory modules I and II (Programming in Bioinformatics and Core Bioinformatics). Basic notions of Chemistry and/or Biochemistry are also needed.

It is recommended to have the B2 Level in English or equivalent.

Objectives and Contextualisation

Proteins are the subject of intensive research in many different areas, from being the target of drug design projects to the design of new enzymes to be used as biocatalysts in new industrial processes of interest and/or in a more  environmentally-friendly way.

Molecular modelling is a very powerful tool in all these areas, in which it has become an essential part of the conducted research, both in academia and in companies.

In this module, students will be provided with the fundamental and practical knowledge to become skilled scientists in the field.

Thus, the objective of this module is to provide students with theoretical and practical knowledge on:

- the physical grounds that sustain the different molecular modelling techniques 

- the basic and state-of-the-art methods applied in the field

- an overview of main areas of application, with special emphasis in drug design

Competences

  • Analyse and interpret data deriving from omic technology using biocomputing methods .
  • Communicate research results clearly and effectively in English.
  • Design and apply scientific methodology in resolving problems.
  • Identify the biocomputing needs of research centres and companies in the biotechnology and biomedicine sectors.
  • Possess and understand knowledge that provides a basis or opportunity for originality in the development and/or application of ideas, often in a research context.
  • Propose biocomputing solutions for problems deriving from omic research.
  • Propose innovative and creative solutions in the field of study
  • Understand the molecular bases and most common standard experimental techniques in omic research (genomics, transcriptomics, proteomics, metabolomics, interactomics, etc.)
  • Use and manage bibliographical information and computer resources in the area of study
  • Use operating systems, programs and tools in common use in biocomputing and be able to manage high performance computing platforms, programming languages and biocomputing analysis.

Learning Outcomes

  1. Carry out searches ( virtual screening) in chemical structures bookshops.
  2. Communicate research results clearly and effectively in English.
  3. Create models of pharmacophores using the structures of ligand sets.
  4. Describe and apply modelling techniques for homology in the three-dimensional protein structure.
  5. Describe and characterise computing techniques for molecular dynamics in studying the structure and function of proteins.
  6. Describe and classify techniques for predicting the secondary structure using amino acid sequence.
  7. Describe the operation, characteristics and limitations of techniques for analysing and visualising protein structures.
  8. Design and apply scientific methodology in resolving problems.
  9. Establish the corresponding relationships between aminoacidic sequence, three-dimensional structure and proteic function using sources of biological data and the foundations of biocomputing analysis.
  10. Identify and apply techniques for CAD, computer assisted drug design
  11. Possess and understand knowledge that provides a basis or opportunity for originality in the development and/or application of ideas, often in a research context.
  12. Propose innovative and creative solutions in the field of study
  13. Recognise and apply different prediction methods of the functions and three-dimensional structure of proteins.
  14. Recognise the strategic importance of the protein model in the area of human health, especially in personalised medicine applications and pharmacogenomics.
  15. Simulate the union of the ligand and the receptor using ?docking? techniques and molecular dynamics
  16. Understand X-ray crystallography and NMR techniques to obtain protein structures
  17. Understand the biomolecular and pharmacological techniques used in functional protein assays.
  18. Use and manage bibliographical information and computer resources in the area of study
  19. Use programs for calculating structure-activity relationships.
  20. Use programs for calculating structure.
  21. Use programs for visualising structure.

Content

MODULE 4: Structure and Function of Proteins and Drug Design           

Part I  MOLECULAR MODELING. Basic concepts.

            Basic concepts

                Introduction

                Energy calculation (PES, QM, Force fields, Hybrid QM/MM)

                Conformational Exploration (other than MD: MC, GA, NMA)

Part II   STRUCTURE CHARACTERIZATION AND MODELLING

           Methods for Determining Protein Structure

              X-ray crystallography               

              NMR

              Cryo-electron microscopy

           Homology modeling

                      

Part III MOLECULAR DYNAMICS (MD)   

           Molecular dynamics, an essential technique

                Basics

                MD in water

                MD in the membrane environment

                Coarse grain

                Scripting & Analysis

                Enhanced sampling methods (e.g. US, metadynamics…)

                Free energy: TI, FEP, MM/PBSA

           

Part IV DRUG DESIGN

            Basics in pharmacology

            Hot targets and currently marketed drugs: Kinases, Nuclear receptors, G protein-coupled receptors, Membrane transport proteins

            Molecular descriptors

            ADME-Tox

            Ligand-based and structure-based pharmacophore modelling

            Docking

                Ligand-protein docking

                Protein-protein docking

            Virtual screening

            MD applications in drug design.

 

Methodology

The methodology will combine theoretical classes, solving problems in class, practices in the computers lab, seminars and independent study and delivarable tasks. The virtual platform of the UAB will be used.

 

 

Annotation: Within the schedule set by the centre or degree programme, 15 minutes of one class will be reserved for students to evaluate their lecturers and their courses or modules through questionnaires.

Activities

Title Hours ECTS Learning Outcomes
Type: Directed      
Seminars 4 0.16 2
Solving problems in class and work in the computing lab 45 1.8 2, 3, 7, 4, 5, 6, 1, 8, 9, 10, 12, 13, 15, 11, 20, 19, 21, 18
Theoretical classes 23 0.92 17, 16, 2, 7, 4, 5, 6, 8, 9, 10, 12, 13, 14, 11, 18
Type: Autonomous      
Regular study 224 8.96 17, 16, 3, 7, 4, 5, 6, 1, 8, 9, 10, 12, 13, 14, 15, 11, 20, 19, 21, 18

Assessment

The evaluation system is organized in two main activities. There will be, in addition, a retake exam. The details of the activities are:

Main evaluation activities

  • Student's portfolio (60%): works done and presented by the student all along the course. None of the individual assessment activities will account for more than 50% of the final mark.
  • Individual theoretical and practical test (40%): a final exam will take place at the end of this module. 

Retake exam

To be eligible for the retake process, the student should have been previously evaluated in a set of activities equaling at least two thirds of the final score of the module. The teacher will inform the procedure and deadlines for the retake process.

Not valuable

The student will be graded as "Not Valuable" if the weight of the evaluation is less than 67% of the final score.

 

Assessment Activities

Title Weighting Hours ECTS Learning Outcomes
Individual theoretical and practical tests 40% 4 0.16 17, 16, 2, 3, 7, 4, 5, 6, 1, 8, 9, 10, 12, 13, 14, 15, 11, 20, 19, 21, 18
Works done and presented by the student (student's portfolio) 60% 0 0 17, 16, 2, 3, 7, 4, 5, 6, 1, 8, 9, 10, 12, 13, 14, 15, 11, 20, 19, 21, 18

Bibliography

Molecular Modeling principles and applications, A. Leach, Ed. Pearson (i.e. second edition ISBN-13: 978-0582382107) (physical document available at the UAB library services)

Essential of Computational Chemistry, C. J. Cramer, (i.e. second Edition, ISBN-13: 978-0470091821)  (physical and electronic documents available at the UAB library services)

Introduction to Computational Chemistry. Frank Jensen. JohnWiley § Sons Ltd. (ISBN: 0470011874, 2007)  (electronic document available at the UAB library services)

Python, how to think like a computer scientist [http://www.greenteapress.com/thinkpython/]  (electronic document available at the UAB library services)

Computational and Visualization techniques for structural bioinformatics using chimera, Forbes J. Burkowski, CRC press (electronic document available at the UAB library services)

Software

On Linux:

UCSF Chimera

UCSF ChimeraX

PyMol

Gaussian

Gaussview

VMD

AMBER

Ambertools

Modeller

Gromacs

LigandScout

Datawarrior

Conda

grace

Jupyter Notebook

Matplotlib

Python

Rasmol

ssh

xxdiff