Biophysics of Proteins, DNA and Membranes – University of Copenhagen

Forward this page to a friend Resize Print Bookmark and Share

Membrane Biophysics group > Teaching and Courses > Biophysics of Proteins...

Biophysics of Proteins, DNA and Membranes

Bachelor Course. Block 2, 2016 / 2017, Skema A

schedule: Tuesday 9-12, Thursday 9-12 / Excercises: Thursday 13-15
place: Aud. D, Blegdamsvej 17
first class: Tuesday, Nov 22, 9:00, Aud. D
Christmas: No teaching from Dec. 26, 2016 - Dec. 30, 2016
exam: Tuesday or Thursday, week 4 2017 (to be discussed)
Link to KU kurser page Link to Time and Place Current handout and other material
ABSTRACT: This course is the second introductory biophysics course and focuses on the thermodynamics of biological systems. These are in particular biological macromolecules (proteins and nucleic acids), membranes, and the interactions between them. This includes a brief introduction into concepts of thermodynamics and statistical thermodynamics. Topics are (amongst others) protein binding, protein and DNA folding, cooperative transitions (helix coil transitions, denaturation, allosteric reactions), cold denaturation, etc. The second major topic is biological membranes, which are those components of a biological cell that separate the functional units and form the spacial boundaries of the organelles. The major building block is the lipid bilayer into which proteins are embedded. Membranes maintain the chemical potentials of the cell components, and regulate transport. The membrane proteins have many catalytic and transport properties. The membranes themselves display all kinds of interesting physical properties: They can melt and they are characterized by elastic constants, which are important for membrane fusion and structural changes and depend on the melting. Furthermore, membranes may be permeable to certain molecules and they form lateral domains of their components, which are highly discussed in the context of cell signaling. We will introduce into the thermodynamics of membranes, their electrostatics, the hydrophobic effect, elastic theory and lipid-protein interactions.