Dr Jon Bath

Modelling DNA origami self-assembly at the domain level

Journal of Chemical Physics American Institute of Physics 143:16 (2015) 165102

Authors:

Frits Dannenberg, Katherine E Dunn, Jonathan Bath, Marta Kwiatkowska, Andrew Turberfield, Thomas E Ouldridge

Abstract:

We present a modelling framework, and basic model parameterization, for the study of DNA origami folding at the level of DNA domains. Our approach is explicitly kinetic and does not assume a specific folding pathway. The binding of each staple is associated with a free-energy change that depends on staple sequence, the possibility of coaxial stacking with neighbouring domains, and the entropic cost of constraining the scaffold by inserting staple crossovers. A rigorous thermodynamic model is difficult to implement as a result of the complex, multiply connected geometry of the scaffold: we present a solution to this problem for planar origami. Coaxial stacking of helices and entropic terms, particularly when loop closure exponents are taken to be larger than those for ideal chains, introduce interactions between staples. These cooperative interactions lead to the prediction of sharp assembly transitions with notable hysteresis that are consistent with experimental observations. We show that the model reproduces the experimentally observed consequences of reducing staple concentration, accelerated cooling, and absent staples. We also present a simpler methodology that gives consistent results and can be used to study a wider range of systems including non-planar origami.

Modelling DNA Origami Self-Assembly at the Domain Level

(2015)

Authors:

Frits Dannenberg, Katherine E Dunn, Jonathan Bath, Marta Kwiatkowska, Andrew J Turberfield, Thomas E Ouldridge

Folding pathways: DNA origami as a model system

EUROPEAN BIOPHYSICS JOURNAL WITH BIOPHYSICS LETTERS 44 (2015) S67-S67

Authors:

KE Dunn, F Dannenberg, TE Ouldridge, M Kwiatkowska, J Bath, AJ Turberfield

Programmable energy landscapes for kinetic control of DNA strand displacement.

Nature communications 5 (2014) 5324-5324

Authors:

Robert RF Machinek, Thomas E Ouldridge, Natalie EC Haley, Jonathan Bath, Andrew J Turberfield

Abstract:

DNA is used to construct synthetic systems that sense, actuate, move and compute. The operation of many dynamic DNA devices depends on toehold-mediated strand displacement, by which one DNA strand displaces another from a duplex. Kinetic control of strand displacement is particularly important in autonomous molecular machinery and molecular computation, in which non-equilibrium systems are controlled through rates of competing processes. Here, we introduce a new method based on the creation of mismatched base pairs as kinetic barriers to strand displacement. Reaction rate constants can be tuned across three orders of magnitude by altering the position of such a defect without significantly changing the stabilities of reactants or products. By modelling reaction free-energy landscapes, we explore the mechanistic basis of this control mechanism. We also demonstrate that oxDNA, a coarse-grained model of DNA, is capable of accurately predicting and explaining the impact of mismatches on displacement kinetics.

"Giant surfactants" created by the fast and efficient functionalization of a DNA tetrahedron with a temperature-responsive polymer.

ACS Nano 7:10 (2013) 8561-8572

Authors:

Thomas R Wilks, Jonathan Bath, Jan Willem de Vries, Jeffery E Raymond, Andreas Herrmann, Andrew J Turberfield, Rachel K O'Reilly

Abstract:

Copper catalyzed azide-alkyne cycloaddition (CuAAC) was employed to synthesize DNA block copolymers (DBCs) with a range of polymer blocks including temperature-responsive poly(N-isoproylacrylamide) (poly(NIPAM)) and highly hydrophobic poly(styrene). Exceptionally high yields were achieved at low DNA concentrations, in organic solvents, and in the absence of any solid support. The DNA segment of the DBC remained capable of sequence-specific hybridization: it was used to assemble a precisely defined nanostructure, a DNA tetrahedron, with pendant poly(NIPAM) segments. In the presence of an excess of poly(NIPAM) homopolymer, the tetrahedron-poly(NIPAM) conjugate nucleated the formation of large, well-defined nanoparticles at 40 °C, a temperature at which the homopolymer precipitated from solution. These composite nanoparticles were observed by dynamic light scattering and cryoTEM, and their hybrid nature was confirmed by AFM imaging. As a result of the large effective surface area of the tetrahedron, only very low concentrations of the conjugate were required in order for this surfactant-like behavior to be observed.