DNA enables nanoscale control of the structure of matter

Nadrian C. Seeman

doi:10.1017/S0033583505004087

Abstract

1. Introduction 363

2. Motif and sequence design 364

3. Structural and topological constructions 366

4. Nanomechanical devices 367

5. Conclusions, applications and challenges 370

6. Acknowledgments 371

7. References 371

Structural DNA nanotechnology consists of constructing objects, lattices and devices from branched DNA molecules. Branched DNA molecules open the way for the construction of a variety of N-connected motifs. These motifs can be joined by cohesive interactions to produce larger constructs in a bottom-up approach to nanoconstruction. The first objects produced by this approach were stick polyhedra and topological targets, such as knots and Borromean rings. These were followed by periodic arrays with programmable patterns. It is possible to exploit DNA structural transitions and sequence-specific binding to produce a variety of DNA nanomechanical devices, which include a bipedal walker and a machine that emulates the translational capabilities of the ribosome. Much of the promise of this methodology involves the use of DNA to scaffold other materials, such as biological macromolecules, nanoelectronic components, and polymers. These systems are designed to lead to improvements in crystallography, computation and the production of diverse and exotic materials.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Niemeyer, Christof M. 2007. Functional devices from DNA and proteins. Nano Today, Vol. 2, Issue. 2, p. 42.

Svahn, Mathias G. Hasan, Maroof Sigot, Valeria Valle-Delgado, Juan José Rutland, Mark W. Lundin, Karin E. and Smith, C.I. Edvard 2007. Self-Assembling Supramolecular Complexes by Single-Stranded Extension from Plasmid DNA. Oligonucleotides, Vol. 17, Issue. 1, p. 80.

Chworos, Arkadiusz and Jaeger, Luc 2007. Foldamers. p. 291.

Worrall, J.A.R. Górna, M. Pei, X.Y. Spring, D.R. Nicholson, R.L. and Luisi, B.F. 2007. Design and chance in the self-assembly of macromolecules. Biochemical Society Transactions, Vol. 35, Issue. 3, p. 502.

Dietz, Hendrik Bornschlögl, Thomas Heym, Roland König, Frauke and Rief, Matthias 2007. Programming protein self assembly with coiled coils. New Journal of Physics, Vol. 9, Issue. 11, p. 424.

Cohen, Justin D. Sadowski, John P. and Dervan, Peter B. 2008. Programming Multiple Protein Patterns on a Single DNA Nanostructure. Journal of the American Chemical Society, Vol. 130, Issue. 2, p. 402.

Mayer, Günter Ackermann, Damian Kuhn, Nicole and Famulok, Michael 2008. Aufbau von DNA‐Architekturen mit RNA‐Haarnadelschleifen. Angewandte Chemie, Vol. 120, Issue. 5, p. 985.

He, Yu Ye, Tao Su, Min Zhang, Chuan Ribbe, Alexander E. Jiang, Wen and Mao, Chengde 2008. Hierarchical self-assembly of DNA into symmetric supramolecular polyhedra. Nature, Vol. 452, Issue. 7184, p. 198.

Bernhardt, Harold S. and Tate, Warren P. 2008. Self-assembling transfer RNA has potential for nanoparticle arrays. Current Applied Physics, Vol. 8, Issue. 3-4, p. 380.

Kuznetsov, Alexander M. and Ulstrup, Jens 2008. Bioinorganic Electrochemistry. p. 161.

Andersen, Felicie F. Knudsen, Bjarne Oliveira, Cristiano Luis Pinto Frøhlich, Rikke F. Krüger, Dinna Bungert, Jörg Agbandje-McKenna, Mavis McKenna, Robert Juul, Sissel Veigaard, Christopher Koch, Jørn Rubinstein, John L. Guldbrandtsen, Bernt Hede, Marianne S. Karlsson, Göran Andersen, Anni H. Pedersen, Jan Skov and Knudsen, Birgitta R. 2008. Assembly and structural analysis of a covalently closed nano-scale DNA cage. Nucleic Acids Research, Vol. 36, Issue. 4, p. 1113.

Mayer, Günter Ackermann, Damian Kuhn, Nicole and Famulok, Michael 2008. Construction of DNA Architectures with RNA Hairpins. Angewandte Chemie International Edition, Vol. 47, Issue. 5, p. 971.

Falconi, Mattia Oteri, Francesco Chillemi, Giovanni Andersen, Felicie F. Tordrup, David Oliveira, Cristiano L. P. Pedersen, Jan S. Knudsen, Birgitta R. and Desideri, Alessandro 2009. Deciphering the Structural Properties That Confer Stability to a DNA Nanocage. ACS Nano, Vol. 3, Issue. 7, p. 1813.

Wang, Sixue S. L. Johnson, John J. X. Hughes, Bradley S. T. Karabay, Dundar A. O. Bader, Karson D. W. Austin, Alan Habib, Aisha Hatef, Husnia Joshi, Megha Nguyen, Lawrence and Mills, Allen P. 2009. Production of random DNA oligomers for scalable DNA computing. Biotechnology Journal, Vol. 4, Issue. 1, p. 119.

Lundin, Karin E. Simonson, Oscar E. Moreno, Pedro M. D. Zaghloul, Eman M. Oprea, Iulian I. Svahn, Mathias G. and Smith, C. I. Edvard 2009. Nanotechnology approaches for gene transfer. Genetica, Vol. 137, Issue. 1, p. 47.

Peters, Justin P. and Maher, L. James 2010. DNA curvature and flexibilityin vitroandin vivo. Quarterly Reviews of Biophysics, Vol. 43, Issue. 1, p. 23.

Bhalerao, Kaustubh and Nistala, Goutam 2010. Encyclopedia of Agricultural, Food, and Biological Engineering, Second Edition. p. 1117.

Severcan, Isil Geary, Cody Chworos, Arkadiusz Voss, Neil Jacovetty, Erica and Jaeger, Luc 2010. A polyhedron made of tRNAs. Nature Chemistry, Vol. 2, Issue. 9, p. 772.

2012. Nanostructures and Nanoconstructions based on DNA. Vol. 20125034, Issue. , p. 41.

Rawlings, Andrea E. Bramble, Jonathan P. and Staniland, Sarah S. 2012. Innovation through imitation: biomimetic, bioinspired and biokleptic research. Soft Matter, Vol. 8, Issue. 25, p. 6675.

Download full list

Article contents

DNA enables nanoscale control of the structure of matter

Abstract

Access options

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

DNA enables nanoscale control of the structure of matter

Abstract

Access options

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests