Direkt zum Inhalt springen

Technische Universität München

Headerimage

Zeichnung

Headerfoto

Slogan TUM for english language
You are not logged in. login.gif Login    |

Spacer Portlet

 
Sitemap Media Press releases Nanoscale origami from DNA
up   Back to  News Board    previous   Browse in News  next    

Researchers develop a new toolbox for nano-engineering:

Nanoscale origami from DNA

DNA molecules as ideal building blocks for nano structures

06.08.2009, Press releases

Scientists at the Technische Universitaet Muenchen (TUM) and Harvard University have thrown the lid off a new toolbox for building nanoscale structures out of DNA, with complex twisting and curving shapes. In the August 7 issue of the journal Science, they report a series of experiments in which they folded DNA, origami-like, into three-dimensional objects including a beach ball-shaped wireframe capsule just 50 nanometers in diameter.

"Our goal was to find out whether we could program DNA to assemble into shapes that exhibit custom curvature or twist, with features just a few nanometers wide," says biophysicist Hendrik Dietz, a professor at the Technische Universitaet Muenchen. Dietz's collaborators in these experiments were Professor William Shih and Dr. Shawn Douglas of Harvard University. "It worked," he says, "and we can now build a diversity of three-dimensional nanoscale machine parts, such as round gears or curved tubes or capsules. Assembling those parts into bigger, more complex and functional devices should be possible."

As a medium for nanoscale engineering, DNA has the dual advantages of being a smart material – not only tough and flexible but also programmable – and being very well characterized by decades of study. Basic tools that Dietz, Douglas, and Shih employ are programmable self-assembly – directing DNA strands to form custom-shaped bundles of cross-linked double helices – and targeted insertions or deletions of base pairs that can give such bundles a desired twist or curve. Right-handed or left-handed twisting can be specified. They report achieving precise, quantitative control of these shapes, with a radius of curvature as tight as 6 nanometers.

The toolbox they have developed includes a graphical software program that helps to translate specific design concepts into the DNA programming required to realize them. Three-dimensional shapes are produced by "tuning" the number, arrangement, and lengths of helices.

In their current paper, the researchers present a wide variety of nanoscale structures and describe in detail how they designed, formed, and verified them. "Many advanced macroscopic machines require curiously shaped parts in order to function," Dietz says, "and we have the tools to make them. But we currently cannot build something intricate such as an ant's leg or, much smaller, a ten-nanometer-small chemical plant such as a protein enzyme. We expect many benefits if only we could build super-miniaturized devices on the nanoscale using materials that work robustly in the cells of our bodies – biomolecules such as DNA."

Original paper:

Folding DNA into Twisted and Curved Nanoscale Shapes
Hendrik Dietz, Shawn M. Douglas, and William M. Shih,
Science 7 August 2009: Vol. 325. no. 5941, pp. 725 - 730 - DOI: 10.1126/science.1174251

Contact:

Prof. Hendrik Dietz
Department of Physics
Technische Universitaet Muenchen
James-Franck-Str. 1, 85748 Garching, Germany
Tel. +49 89 289 12539
Fax: +49 89 289 12523
E-mail - Internet

Kontakt: presse@tum.de

Rechte Seite

Corporate Communications Center

Media Relations Team
Arcisstr. 19
80333 München

Tel.: +49.89.289.22778
Fax: +49.89.289.23388

 presse@tum.de

Contact