Physics of Genes

- DNA & RNA thermodynamics

- RNA secondary structure

- DNA biopolymer physics

- Polyelectrolyte properties

- DNA topology

- Replication

- Transcription

- Translation

- Gene regulation

- Searching for binding sites

- Stochastic gene expression

- Sequencing

- Information storage

- Origins

After successful completion of the module, students are able to:

• formulate the essential biophysical properties of nucleic acids, apply them to specific problems and understand their use in biotechnology, genetic engineering and nanotechnology 
• understand physical aspects of gene expression and thus to gain a better understanding of genetic processes and also of modern genetic engineering techniques
• follow presentations dealing with biophysical properties of nucleic acids or gene expression and participate in the corresponding scientific discussions
• independently educate themselves through literature research, based on the foundations laid in the lecture
• carry out simple calculations on DNA structure and thermodynamics, also with the help of computer programs

No preconditions in addition to the requirements for the Master’s program in Physics.

A basic knowledge of biophysics and biochemistry are desirable to follow the course more easily.

The module consists of a lecture and exercise classes. In the thematically structured lecture the learning content will be presented.
The students will be involved in scientific discussions and ecouraged to apply their knowledge to specific problems. In the exercises, the learning content is deepened and practiced by discussing specific problems of nucleic
acid biophysics and corresponding example calculations. Moreover, in the exercises special literature will be
read and discussed in detail.

The lecture will be held via Powerpoint presentation, on occasion supported by blackboard. A script for the lecture will be provided via moodle. Tasks and technical literature are given out for the exercises.

• A. Vologodskii: Biophysics of DNA, Cambridge University Press, (2015)
• V.A. Bloomfield, D.M. Crothers, I. Tinoco J.E. Hearst, D.E. Wemmer, P.A. Killman, D.H. Turner: Nucleic Acids: Structures, Properties, and Functions, University Science Books, (2000)
• A.D. Bates & A. Maxwell: DNA Topology, Oxford University Press, (2005)
• R. Phillips, J. Kondev, J. Theriot, H. Garcia: Physical Biology of the Cell, Taylor & Francis, (2012)

Further specific literature (publications) will be provided and discussed in the lecture and in the accompanying exercises

There will be an oral exam of 25 minutes duration. Therein the achievement of the competencies given in section learning outcome is tested exemplarily at least to the given cognition level using comprehension questions and sample calculations.

For example an assignment in the exam might be:

• Describe quantitatively the mechanical properties of single- and double-stranded DNA
• Which quantities are used to describe the topology of DNA molecules?
• Determine the secondary structure of a given (short) nucleic acid sequence
• How do you calculate the melting point of a given DNA sequence?

In the exam no learning aids are permitted.