(498c) Anisotropic Shrinkage of DNA Origami After a Wet-to-Dry Transition On Mica Surface | AIChE

(498c) Anisotropic Shrinkage of DNA Origami After a Wet-to-Dry Transition On Mica Surface

Authors 

Verma, A. - Presenter, Indian Institute of Technology Kanpur
Schulman, R., Johns Hopkins University



DNA nanotechnology is a fast
emerging area with many potential applications such as nanofabrication,
targeted drug delivery and self-assembly. DNA origami, for example, can serve
as a scaffold for the assembly of functional materials. While most studies on
DNA origami are done in aqueous solution, their application as templates for
functional structures will inevitably occur in the dry state. Therefore, it is
important to study the wet-to-dry transition of DNA origami and how this
transition is affected by intrinsic factors such as origami design and external
variables such as interfacial forces, buffer and drying conditions. Here we
present a comparative study of the wet-to-dry transition in two different types
of rectangular DNA origami on mica surface. The first type of origami is the
tall rectangle (TR) with 10.67 bp/turn designed by Rothemund (2006).1 This structure is distorted
from its designed flat structure because of the deviation from a relaxed double
stranded DNA configuration (i.e. 10.5 bp/turn).2
We also considered a flatter tall rectangle (TRF) with 10.44 bp/turn designed by Woo and Rothemund
(2011) in which twist in
the direction perpendicular to helix stacking was reduced by introducing an
irregular crossover pattern and leaving out parts of the scaffold unused in origami
design.2 While both structures shrink about 8-15%
in transition from wet to dry state, TRF shrinks more anisotropically
as compared to TR. Anisotropic shrinkage in TRF may be attributed to a more
relaxed design where the inter-helix gap can be reduced more freely. Further,
the unused parts of the DNA scaffold provide a cushion that facilitates
shrinkage between two helices.2These
differences in the wet-dry transition may be due to the unidirectional
curvature of TRF, which allows preferential shrinkage along the length. In
contrast, twist in both the directions perhaps puts more constraints in TR and
the shrinkage is nearly isotropic. In the presence of weaker helical
interaction, origami may be more likely to reduce interhelical
spacing during drying.

The results suggest that
it is important to consider the shrinkage during drying of origami while
designing and assembling precision circuits as a change of few nanometers may
compromise the functionality of the device.

References

1.    Rothemund, P. W. K. Folding DNA to create nanoscale shapes and patterns. Nature
440, 297?302 (2006).

2.    Woo, S. and Rothemund,
P. W. K. Programmable molecular recognition based on the geometry of DNA
nanostructures. Nat. Chem. 3, 620-627 (2011).