Concept and Development of Framework Nucleic Acids

Ge, Zhilei; Gu, Hongzhou; Li, Qian; Chen, Fan

doi:10.1021/jacs.8b10529

Cited by 207 publications

(167 citation statements)

References 152 publications

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“…[1,2] DNA structures have gained much interest as a promising drug carriers, as a wide range of nanomaterials possess unique physical properties that can facilitate drug deliver system safer and more effective. [3][4][5][6] Several experiments proved that self-assembled DNA Herein, the dynamic transmembrane process of TDNs is tracked by force tracing technique based on atomic force microscopy (AFM), the force and duration of the transmembrane transport process of single nanoparticles/molecules could be detected down to pico-newton and milliseconds, respectively. [13,14] Combining experiment and simulation, the TDNs size effect on the transmembrane dynamics and protein-mediated mechanism was explored at single particle level under near physiological condition.…”

Section: Introductionmentioning

confidence: 99%

Size‐Independent Transmembrane Transporting of Single Tetrahedral DNA Nanostructures

Chen

Tian

et al. 2019

Global Challenges

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DNA nanostructures have attracted considerable attention as drug delivery carriers. However, the transmembrane kinetics of DNA nanostructures remains less explored. Herein, the dynamic process of transporting single tetrahedral DNA nanostructures (TDNs) is monitored in real time using a force‐tracing technique based on atomic force microscopy. The results show that transporting single TDNs into living HeLa cells need ≈53 pN force and ≈25 ms duration with the average speed of ≈0.6 µm s−1. Interestingly, the dynamic parameters are irrelevant to the size of TDNs, while the larger TDNs rotated slightly during the transporting process. Meanwhile, both the results from single‐molecule force tracing and ensemble fluorescence imaging demonstrate that the different size TDNs transmembrane transporting depends on caveolin‐mediated endocytosis.

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Section: Introductionmentioning

confidence: 99%

Size‐Independent Transmembrane Transporting of Single Tetrahedral DNA Nanostructures

Chen

Tian

et al. 2019

Global Challenges

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“…To transport these therapeutic molecules into target cells and tissues, scientists have devised a number of nanocarriers, such as nanoparticles and DNA nanostructures . Framework nucleic acids (FNAs), a wide variety of robust DNA nanoframes (for example, tetrahedrons, pyramids, and cubes), display unique biophysical and biochemical properties, and have proven ideal nanocarriers for intracellular transport of molecular payloads, including proteins, anticancer drugs, siRNAs, and ASOs . However, the activation of the FNA nanocarriers in vivo for controllable cargo release once they enter cells remains a challenge.…”

Section: Introductionmentioning

confidence: 99%

Environment‐Recognizing DNA‐Computation Circuits for the Intracellular Transport of Molecular Payloads for mRNA Imaging

et al. 2020

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Programming intelligent DNA nanocarriers for the targeted transport of molecular payloads in living cells has attracted extensive attention. In vivo activation of these nanocarriers usually relies on external light irradiation. An interest is emerging in the automatic recognition of intracellular surroundings by nanocarriers and their in situ activation under the control of programmed DNA‐computation circuits. Herein, we report the integration of DNA circuits with framework nucleic acid (FNA) nanocarriers that consist of a truncated square pyramid (TSP) cage and a built‐in duplex cargo containing an antisense strand of the target mRNA. An i‐motif and ATP aptamer embedded in the TSP are employed as logic‐controlling units to respond to H+ and ATP inside cellular compartments, triggering the release of the sensing element for fluorescent mRNA imaging. Logic‐controlled FNA devices could be used to target drug delivery, enabling precise disease treatment.

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“…At early stage, DNA machines were mainly based on small DNA‐assembled structures that could switch between different states . The fast development of DNA origami technology in the past decade makes it possible to create various nanostructures with desired shapes, facilitating the construction of more complex DNA nanomachines . These DNA origami‐based structures exhibit enhanced rigidity over small DNA strands, allowing for the design of nanomachines that mimic the motion behavior of macroscopic machines.…”

Section: Introductionmentioning

confidence: 99%

Programming Motions of DNA Origami Nanomachines

Wang

Zhang

Liu

et al. 2019

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DNA nanotechnology enables the precise fabrication of DNA‐based machines with nanoscale dimensions. A wide range of DNA nanomachines are designed, which can be activated by specific inputs to perform various movement and functions. The excellent rigidity and unprecedented addressability of DNA origami have made it an excellent platform for manipulating and investigating the motion behaviors of DNA machines at single‐molecule level. In this Concept, power supply, machine actuation, and motion behavior of DNA machines on origami platforms are summarized and classified. The strategies utilized for programming motion behavior of DNA machines on DNA origami are also discussed with representative examples. The challenges and outlook for future development of manipulating DNA nanomachines at the single molecule level are presented and discussed.

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Concept and Development of Framework Nucleic Acids

Cited by 207 publications

References 152 publications

Size‐Independent Transmembrane Transporting of Single Tetrahedral DNA Nanostructures

Size‐Independent Transmembrane Transporting of Single Tetrahedral DNA Nanostructures

Environment‐Recognizing DNA‐Computation Circuits for the Intracellular Transport of Molecular Payloads for mRNA Imaging

Programming Motions of DNA Origami Nanomachines

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