Prediction and simulation on DNA strand displacement for the analysis of DNA nanotechnology

As a strategy for regulating entropy, thermal annealing is a commonly adopted approach for controlling dynamic pathways in colloid assembly. By coupling DNA strand-displacement circuits with DNA-functionalized colloid assembly, we developed an enthalpy-mediated strategy for achieving the same goal while working at a constant temperature. Using this tractable approach allows colloidal bonding to be programmed for synchronization with colloid assembly, thereby realizing the optimal programmability of DNA-functionalized colloids. We applied this strategy to conditionally activate colloid assembly and dynamically switch colloid identities by reconfiguring DNA molecular architectures, thereby achieving orderly structural transformations; leveraging the advantage of room-temperature assembly, we used this method to prepare a lattice of temperature-sensitive proteins and gold nanoparticles. This approach bridges two subfields: dynamic DNA nanotechnology and DNA-functionalized colloid programming.

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A domain-level DNA strand displacement reaction enumerator allowing arbitrary non-pseudoknotted secondary structures

Journal of The Royal Society Interface ◽

10.1098/rsif.2019.0866 ◽

2020 ◽

Vol 17 (167) ◽

pp. 20190866 ◽

Cited By ~ 3

Author(s):

Stefan Badelt ◽

Casey Grun ◽

Karthik V. Sarma ◽

Brian Wolfe ◽

Seung Woo Shin ◽

...

Keyword(s):

Dna Nanotechnology ◽

Biophysical Model ◽

Kinetic Properties ◽

Strand Displacement ◽

Natural Connection ◽

Dna Strand Displacement ◽

Wide Range ◽

Dna Strand ◽

High Level ◽

Domain Level

Information technologies enable programmers and engineers to design and synthesize systems of startling complexity that nonetheless behave as intended. This mastery of complexity is made possible by a hierarchy of formal abstractions that span from high-level programming languages down to low-level implementation specifications, with rigorous connections between the levels. DNA nanotechnology presents us with a new molecular information technology whose potential has not yet been fully unlocked in this way. Developing an effective hierarchy of abstractions may be critical for increasing the complexity of programmable DNA systems. Here, we build on prior practice to provide a new formalization of ‘domain-level’ representations of DNA strand displacement systems that has a natural connection to nucleic acid biophysics while still being suitable for formal analysis. Enumeration of unimolecular and bimolecular reactions provides a semantics for programmable molecular interactions, with kinetics given by an approximate biophysical model. Reaction condensation provides a tractable simplification of the detailed reactions that respects overall kinetic properties. The applicability and accuracy of the model is evaluated across a wide range of engineered DNA strand displacement systems. Thus, our work can serve as an interface between lower-level DNA models that operate at the nucleotide sequence level, and high-level chemical reaction network models that operate at the level of interactions between abstract species.

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Cross-Inhibitor: a time-sensitive molecular circuit based on DNA strand displacement

Nucleic Acids Research ◽

10.1093/nar/gkaa835 ◽

2020 ◽

Vol 48 (19) ◽

pp. 10691-10701

Author(s):

Chanjuan Liu ◽

Yuan Liu ◽

Enqiang Zhu ◽

Qiang Zhang ◽

Xiaopeng Wei ◽

...

Keyword(s):

Input Signal ◽

Dna Nanotechnology ◽

Strand Displacement ◽

Important Goal ◽

Molecular Systems ◽

Molecular Programming ◽

Dna Strand Displacement ◽

Input Signals ◽

Biochemical Systems ◽

Dna Strand

Abstract Designing biochemical systems that can be effectively used in diverse fields, including diagnostics, molecular computing and nanomachines, has long been recognized as an important goal of molecular programming and DNA nanotechnology. A key issue in the development of such practical devices on the nanoscale lies in the development of biochemical components with information-processing capacity. In this article, we propose a molecular device that utilizes DNA strand displacement networks and allows interactive inhibition between two input signals; thus, it is termed a cross-inhibitor. More specifically, the device supplies each input signal with a processor such that the processing of one input signal will interdict the signal of the other. Biochemical experiments are conducted to analyze the interdiction performance with regard to effectiveness, stability and controllability. To illustrate its feasibility, a biochemical framework grounded in this mechanism is presented to determine the winner of a tic-tac-toe game. Our results highlight the potential for DNA strand displacement cascades to act as signal controllers and event triggers to endow molecular systems with the capability of controlling and detecting events and signals.

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Programming Cell-Free Biosensors with DNA Strand Displacement Circuits

10.1101/2021.03.16.435693 ◽

2021 ◽

Author(s):

Jaeyoung K. Jung ◽

Khalid K. Alam ◽

Julius B. Lucks

Keyword(s):

Response Times ◽

Dna Nanotechnology ◽

Fine Tuning ◽

Digital Converter ◽

Strand Displacement ◽

Design Rules ◽

Analog To Digital ◽

Dna Strand Displacement ◽

Dna Strand ◽

Molecular Computations

ABSTRACTCell-free biosensors are emerging as powerful platforms for monitoring human and environmental health. Here, we expand the capabilities of biosensors by interfacing their outputs with toehold-mediated strand displacement circuits, a dynamic DNA nanotechnology that enables molecular computation through programmable interactions between nucleic acid strands. We develop design rules for interfacing biosensors with strand displacement circuits, show that these circuits allow fine-tuning of reaction kinetics and faster response times, and demonstrate a circuit that acts like an analog-to-digital converter to create a series of binary outputs that encode the concentration range of the target molecule being detected. We believe this work establishes a pathway to create “smart” diagnostics that use molecular computations to enhance the speed, robustness and utility of biosensors.

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DNA breathing initiated strand displacement circuits for mimicking ant foraging with nanopore readout

10.21203/rs.3.rs-810240/v1 ◽

2021 ◽

Author(s):

Jinbo Zhu ◽

Jinglin Kong ◽

Ulrich Keyser ◽

Erkang Wang

Keyword(s):

Single Molecule ◽

Dna Nanotechnology ◽

Path Selection ◽

Strand Displacement ◽

Initiation Mechanism ◽

Single Molecule Level ◽

Sensing Platform ◽

Dna Strand Displacement ◽

Dna Strand Exchange ◽

Dna Strand

Abstract DNA strand displacement reaction is essential for the development of molecular computing based on DNA nanotechnology. Additional DNA strand exchange strategies with high selectivity for input will enable novel complex systems including biosensing applications. Most approaches use bulk readout methods based on fluorescent probes that complicate the monitoring of parallel computations. Herein we propose an autocatalytic strand displacement (ACSD) circuit, which is initiated by DNA breathing and accelerated by seesaw catalytic reaction. The special initiation mechanism of the ACSD circuit enables detection of single base mutations at multiple sites in the input strand with much higher sensitivity than classic toehold-mediated strand displacement. A swarm intelligence model is constructed using the ACSD circuit to mimic foraging behaviour of ants. We introduce a multiplexed nanopore sensing platform to report the output results of a parallel path selection system on the single-molecule level. The ACSD strategy and nanopore multiplexed readout method enhance the toolbox for the future development of DNA computing.

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