Design and analysis of linear cascade DNA hybridization chain reactions using DNA hairpins

Bui, Hieu; Garg, Sudhanshu; Miao, Vincent N.; Song, Tianqi; Mokhtar, Reem; Reif, John H.

doi:10.1088/1367-2630/aa53d0

Cited by 12 publications

(10 citation statements)

References 74 publications

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“…The loop consists of two clamp domains (C i–1 and C i+1 ), a linker domain (L), and a sequestered domain (S i+1 ). The two clamp domains were used to prevent a hairpin from reclosing via a localized blunt-end displacement once it has been opened near both ends of the hairpin’s stem. , The purposes of the loop are (i) to encode the sequestered domain for the cascade reaction and (ii) to fasten the cargo (S i+1 ) from floating away to solution. Each hairpin has two toehold domains (S i and S i+1 ): S i is an external toehold domain and readily available for hybridization and S i+1 is an internal toehold domain and unavailable for hybridization.…”

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confidence: 99%

Localized DNA Hybridization Chain Reactions on DNA Origami

et al. 2018

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The field of DNA nanoscience has demonstrated many exquisite DNA nanostructures and intricate DNA nanodevices. However, the operation of each step of prior demonstrated DNA nanodevices requires the diffusion of DNA strands, and the speed of these devices is limited by diffusion kinetics. Here we demonstrate chains of localized DNA hybridization reactions on the surface of a self-assembled DNA origami rectangle. The localization design for our DNA nanodevices does not rely on the diffusion of DNA strands for each step, thus providing faster reaction kinetics. The locality also provides considerable increased scalability, since localized components of the devices can be reused in other locations. A variety of techniques, including atomic force microscopy, total internal reflection fluorescence, and ensemble fluorescence spectroscopy, are used to confirm the occurrence of localized DNA hybridization reactions on the surface of DNA origami. There are many potential biological applications for our localized DNA nanodevices, and the localization design is extensible to applications involving DNA nanodevices operating on other molecular surfaces, such as those of the cell.

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confidence: 99%

Localized DNA Hybridization Chain Reactions on DNA Origami

et al. 2018

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“…Recent advances in DNA‐based computation have been proposed and experimented with DNA motifs that are localized on a surface. Recently our work has already produced empirical results that show computation on a DNA substrate using the DNA hairpin motif . It is conceivable that our time‐responsive design could also be localized on a substrate.…”

Section: Discussionmentioning

confidence: 99%

Renewable Time‐Responsive DNA Circuits

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Bui

et al. 2018

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DNA devices have been shown to be capable of evaluating Boolean logic. Several robust designs for DNA circuits have been demonstrated. Some prior DNA-based circuits are use-once circuits since the gate motifs of the DNA circuits get permanently destroyed as a side effect of the computation, and hence cannot respond correctly to subsequent changes in inputs. Other DNA-based circuits use a large reservoir of buffered gates to replace the working gates of the circuit and can be used to drive a finite number of computation cycles. In many applications of DNA circuits, the inputs are inherently asynchronous, and this necessitates that the DNA circuits be asynchronous: the output must always be correct regardless of differences in the arrival time of inputs. This paper demonstrates: 1) renewable DNA circuits, which can be manually reverted to their original state by addition of DNA strands, and 2) time-responsive DNA circuits, where if the inputs change over time, the DNA circuit can recompute the output correctly based on the new inputs, that are manually added after the system has been reset. The properties of renewable, asynchronous, and time-responsiveness appear to be central to molecular-scale systems; for example, self-regulation in cellular organisms.

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“…For instance, a double-stranded DNA duplex with an overhang at the 5 /3 end is used as the basis. Multiple individual bases are then programmed in a cascade reaction for achieving linear forward motions [118]. In general, the field of dynamic DNA nanotechnology aims to design systems that are often inspired by the behavior of molecular protein motors.…”

Section: Dynamic Dna Systemsmentioning

confidence: 99%

“…Furthermore, scalability is another current issue in the field, since it is necessary to implement practical functionalities in order to make the structures more advantageous [125]. Likewise, reliable sequence design and oligonucleotide synthesis are fundamental for the development of functional DNA structures [114,118].…”

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confidence: 99%

DNA Microsystems for Biodiagnosis

2020

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Researchers are continuously making progress towards diagnosis and treatment of numerous diseases. However, there are still major issues that are presenting many challenges for current medical diagnosis. On the other hand, DNA nanotechnology has evolved significantly over the last three decades and is highly interdisciplinary. With many potential technologies derived from the field, it is natural to begin exploring and incorporating its knowledge to develop DNA microsystems for biodiagnosis in order to help address current obstacles, such as disease detection and drug resistance. Here, current challenges in disease detection are presented along with standard methods for diagnosis. Then, a brief overview of DNA nanotechnology is introduced along with its main attractive features for constructing biodiagnostic microsystems. Lastly, suggested DNA-based microsystems are discussed through proof-of-concept demonstrations with improvement strategies for standard diagnostic approaches.

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Design and analysis of linear cascade DNA hybridization chain reactions using DNA hairpins

Cited by 12 publications

References 74 publications

Localized DNA Hybridization Chain Reactions on DNA Origami

Localized DNA Hybridization Chain Reactions on DNA Origami

Renewable Time‐Responsive DNA Circuits

DNA Microsystems for Biodiagnosis

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