Dr Jon Bath

Programmable one-pot multistep organic synthesis using DNA junctions.

J Am Chem Soc 134:3 (2012) 1446-1449

Authors:

Mireya L McKee, Phillip J Milnes, Jonathan Bath, Eugen Stulz, Rachel K O'Reilly, Andrew J Turberfield

Abstract:

A system for multistep DNA-templated synthesis is controlled by the sequential formation of DNA junctions. Reactants are attached to DNA adapters which are brought together by hybridization to DNA template strands. This process can be repeated to allow sequence-controlled oligomer synthesis while maintaining a constant reaction environment, independent of oligomer length, at each reaction step. Synthesis can take place in a single pot containing all required reactive monomers. Different oligomers can be synthesized in parallel in the same vessel, and the products of parallel synthesis can be ligated, reducing the number of reaction steps required to produce an oligomer of a given length.

A DNA-based molecular motor that can navigate a network of tracks.

Nat Nanotechnol 7:3 (2012) 169-173

Authors:

Shelley FJ Wickham, Jonathan Bath, Yousuke Katsuda, Masayuki Endo, Kumi Hidaka, Hiroshi Sugiyama, Andrew J Turberfield

Abstract:

Synthetic molecular motors can be fuelled by the hydrolysis or hybridization of DNA. Such motors can move autonomously and programmably, and long-range transport has been observed on linear tracks. It has also been shown that DNA systems can compute. Here, we report a synthetic DNA-based system that integrates long-range transport and information processing. We show that the path of a motor through a network of tracks containing four possible routes can be programmed using instructions that are added externally or carried by the motor itself. When external control is used we find that 87% of the motors follow the correct path, and when internal control is used 71% of the motors follow the correct path. Programmable motion will allow the development of computing networks, molecular systems that can sort and process cargoes according to instructions that they carry, and assembly lines that can be reconfigured dynamically in response to changing demands.

Macromolecule synthesis by DNA templated chemistry

ABSTRACTS OF PAPERS OF THE AMERICAN CHEMICAL SOCIETY 243 (2012)

Authors:

Phillip J Milnes, Mireya L Mckee, Jonathan Bath, Eugen Stulz, Andrew J Turberfield, Rachel K O'Reilly

Reversible logic circuits made of DNA.

J Am Chem Soc 133:50 (2011) 20080-20083

Authors:

Anthony J Genot, Jonathan Bath, Andrew J Turberfield

Abstract:

We report reversible logic circuits made of DNA. The circuits are based on an AND gate that is designed to be thermodynamically and kinetically reversible and to respond nonlinearly to the concentrations of its input molecules. The circuits continuously recompute their outputs, allowing them to respond to changing inputs. They are robust to imperfections in their inputs.

A programmable molecular robot.

Nano Lett 11:3 (2011) 982-987

Authors:

Richard A Muscat, Jonathan Bath, Andrew J Turberfield

Abstract:

We have developed a programmable and auton-omous molecular robot whose motion is fueled by DNA hybridization. Instructions determining the path to be followed are programmed into the fuel molecules, allowing precise control of cargo motion on a branched track.