Wednesday, 10 December, 2014
NIM scientist Hendrik Dietz receives Gottfried Wilhelm Leibniz Prize
Germany’s most prestigious research award
The NIM member Prof. Hendrik Dietz (TUM) has been awarded the Gottfried Wilhelm Leibniz Prize of the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation). The 36-year-old biophysicist is thus the recipient of Germany’s most prestigious research award, which is endowed with 2.5 million euros. Hendrik Dietz is being honored for his internationally-renowned work in the field of bionanotechnology. His research into the mechanical and structural properties of proteins has opened up completely new horizons for the development of DNA-based “nanomachines”. A particularly outstanding aspect of Professor Dietz’s research is its interdisciplinarity (biomolecular physics, biochemistry, molecular medicine).
Dietz has been professor of physics at the TUM since 2009 and also a Hans Fischer Fellow of the TUM Institute for Advanced Study (IAS). He has already been awarded one of the European Union’s highly coveted ERC Starting Grants and the Arnold Sommerfeld Prize of the Bavarian Academy of Sciences and Humanities.
The human cell mostly consists of large complex molecules like DNA and proteins, which are self-organizing. The associated information is contained in their sequence – for example, in the base sequence – and in their three-dimensional structure. In his research, Dietz focuses on the question as to how nature’s principle of programmable structure formation can be exploited for technological purposes.
Dietz and his team use DNA as a building material, which is folded in a special way using a kind of “DNA origami” and thereby converted into three-dimensional structures. They have developed methods that enable the very fast and accurate implementation of this process. The development of a synthetic channel for lipid membranes is one example which illustrates the potential offered by this research. This channel could enable the programmed perforation of cells or bacteria and be further developed for the targeted localization of biologically active molecules in the cell interior.
Source (based on): Press release TU München