posted on 2017-08-15, 00:00authored byAurora Fabry-Wood, Madalyn E. Fetrow, Carl W. Brown, Nicholas A. Baker, Nadiezda Fernandez Oropeza, Andrew P. Shreve, Gabriel A. Montaño, Darko Stefanovic, Matthew R. Lakin, Steven W. Graves
We
report a versatile microsphere-supported lipid bilayer system that
can serve as a general-purpose platform for implementing DNA nanotechnologies
on a fluid surface. To demonstrate our platform, we implemented both
toehold-mediated strand displacement (TMSD) and DNAzyme reactions,
which are typically performed in solution and which are the cornerstone
of DNA-based molecular logic and dynamic DNA nanotechnology, on the
surface. We functionalized microspheres bearing supported lipid bilayers
(μSLBs) with membrane-bound nucleic acid components. Using functionalized μSLBs,
we developed TMSD and DNAzyme reactions by optimizing reaction conditions
to reduce nonspecific interactions between DNA and phospholipids and
to enhance bilayer stability. Additionally, the physical and optical
properties of the bilayer were tuned via lipid composition and addition
of fluorescently tagged lipids to create stable and multiplexable
μSLBs that are easily read out by flow cytometry. Multiplexed
TMSD reactions on μSLBs enabled the successful operation of
a Dengue serotyping assay that correctly identified all 16 patterns
of target sequences to demonstrate detection of DNA strands derived
from the sequences of all four Dengue serotypes. The limit of detection
for this assay was 3 nM. Furthermore, we demonstrated DNAzyme reactions
on a fluid lipid surface, which benefit from free diffusion on the
surface. This work provides the basis for expansion of both TMSD and
DNAzyme based molecular reactions on supported lipid bilayers for
use in molecular logic and DNA nanotechnology. As our system is multiplexable
and results in fluid surfaces, it may be of use in compartmentalization
and improved kinetics of molecular logic reactions and as a useful
building block in a variety of DNA nanotechnology systems.