Advanced Protein Science 2 – Protein Structure Determination
This course in integrative structural biology will introduce the student to a range of methods that can be used, often together, to study protein structures at various levels of resolution. A key thread through the course is the integration of computational and experimental methods. On the experimental side, the greatest focus is on X-ray crystallography, NMR spectroscopy and cryo-electron microscopy, but these can be supplemented by other biophysical techniques (small-angle X-ray and neutron scattering, fluorescence methods and electron paramagnetic resonance) and molecular simulations and modelling. The course will provide a broad background to how NMR, cryo-EM and X-ray crystallography can be used to derive the three-dimensional structures of proteins. Further examples, will include how other biophysical methods, sometimes integrated with computational tools, can be used to study structures when other methods fail or when the systems are highly dynamic. The students will also learn how to analyse and evaluate experimentally derived protein structures. Finally, the course will contain an overview of how computational methods in structural biology, e.g. molecular dynamics simulations, can be used to study the structure and dynamics of proteins, including of intrinsically disordered proteins. We will also discuss how homology modelling and deep-learning-based structure prediction methods can be used to predict the structures of proteins and be used together with experiments. The format for the course is a mixture of lectures, group discussions and journal clubs discussing examples of the how the different methods can be used. A substantial part of the reading material is primary research articles and review articles.
MSc Programme in Biochemistry
MSc Programme in Physics
- Understand the fundamental principles in integrative structural biology
- Understand how protein structures can be determined via X-ray crystallography
- Understand how protein structures can be determined via NMR spectroscopy
- Understand the key spectroscopic observables available in NMR
- Understand how other biophysical techniques can be used to obtain lower resolution structural information
- To understand the basic principles of simulation techniques and how they can be used together with experimental methods
- Have an overview of methods for protein structure prediction and homology modelling
- To have working knowledge on examples of how protein dynamics
can affect protein function
- Have the ability to read and critically evaluate publications containing macromolecular X-ray crystallography or NMR structures/data
- Be able to, at a rudimentary level, design strategies for structural studies of proteins
- To compare the strengths, limitations and complementary potential of structural data obtained using techniques based on completely different physical phenomena
- To be able to use simple methods for protein structure determination
- To be able to visualize results from molecular simulations
The central competency is to be able to view and understand a broad range of biophysical methods, including those in computers, and to envisage how these methods can be integrated in structural studies of proteins.
Two weekly three-hour sessions for seven weeks.
Lectures, student presentations of research papers, group discussions and computer exercises.
A bachelor degree either in Biochemistry, Chemistry or Nano-technology is required. Other applicants may be admitted on the basis of an evaluation of their individual qualifications. Basic knowledge of protein science, as obtained for example in dedicated protein science courses, is a requirement, as is a previous basic introduction to biophysical techniques.
- 7,5 ECTS
- Type of assessment
Oral examination, 20 minutes (20 minutes preparation time)
- Without aids
- Marking scale
- 7-point grading scale
- Censorship form
- No external censorship
One internal examiner
Criteria for exam assessment
In order to achieve the grade 12 the
student should be able to demonstrate a substantial amount of
the knowledge, skills and competencies described under
The student should also have participated actively in the lectures, contributed actively in the student presentations, in both cases as outlined above.
Single subject courses (day)
- Theory exercises
- Course number
- 7,5 ECTS
- Programme level
- Full Degree Master
- Block 4
The number of seats may be reduced in the late registration period
- Study Board for the Biological Area
- Department of Biology
- Faculty of Science
- Kresten Lindorff-Larsen (8-716e736974776b6b45676e7433707a336970)
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Courseinformation of students