Real-time magnetic actuation of DNA nanodevices via modular integration with stiff micro-levers

Structural deoxyribonucleic acid (DNA) nanotechnology offers a robust platform for diverse nanoscale shapes that can be used in various applications. Among a wide variety of DNA assembly strategies, DNA origami is the most robust one in constructing custom nanoshapes and exquisite patterns. In this account, the static structural and functional patterns assembled on DNA origami are reviewed, as well as the reconfigurable assembled architectures regulated through dynamic DNA nanotechnology. The fast progress of dynamic DNA origami nanotechnology facilitates the construction of reconfigurable patterns, which can further be used in many applications such as optical/plasmonic sensors, nanophotonic devices, and nanorobotics for numerous different tasks.

Section: The Development Of Dna Nanotechnologymentioning

confidence: 99%

Section: The Development Of Dna Nanotechnologymentioning

confidence: 99%

Create Nanoscale Patterns with DNA Origami

Fan

Wang

Kenaan

et al. 2019

“…Recently developed DNA nanomachines are mainly powered by the addition and removal of designed single DNA strands, to induce the hybridization and dehybridization between two complementary strands as the driving force . In addition, enzymatic reactions and external applied fields could also provide energy to initiate and maintain the machine motion.…”

Section: Power Supply For Dna Nanomachinesmentioning

confidence: 99%

“…By introducing molecules responsive to external applied fields to DNA machines, externally applied fields such as electric field, magnetic field and light irradiation can provide energy to power the mechanical motion of DNA nanomachines. Taking advantages of the naturally negatively charged property of DNA molecules, the motion of DNA machine can be actuated and programmed with computer‐controlled switching of the applied electric fields (Figure d) .…”

Section: Power Supply For Dna Nanomachinesmentioning

confidence: 99%

Programming Motions of DNA Origami Nanomachines

Wang

Zhang

Liu

et al. 2019

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.

“…The stimuli and energy sources for the operation of such devices can be quite diverse, for instance, DNA strand displacement processes, binding of biomolecules through aptamers, environmental changes (e.g., changes in salt concentrations or physical stimuli such as temperature), or electric and magnetic fields . In many cases, “switchability” has been introduced by appropriate chemical modifications of the devices.…”

Section: Introductionmentioning

confidence: 99%

Periodic Operation of a Dynamic DNA Origami Structure Utilizing the Hydrophilic–Hydrophobic Phase‐Transition of Stimulus‐Sensitive Polypeptides

Goetzfried

Vogele

Mückl

et al. 2019

Dynamic DNA nanodevices are designed to perform structure‐encoded motion actuated by a variety of different physicochemical stimuli. In this context, hybrid devices utilizing other components than DNA have the potential to considerably expand the library of functionalities. Here, the reversible reconfiguration of a DNA origami structure using the stimulus sensitivity of elastin‐like polypeptides is reported. To this end, a rectangular sheet made using the DNA origami technique is functionalized with these peptides and by applying changes in salt concentration the hydrophilic–hydrophobic phase transition of these peptides actuate the folding of the structure. The on‐demand and reversible switching of the rectangle is driven by externally imposed temperature oscillations and appears at specific transition temperatures. Using transmission electron microscopy, it is shown that the structure exhibits distinct conformational states with different occupation probabilities, which are dependent on structure‐intrinsic parameters such as the local number and the arrangement of the peptides on the rectangle. It is also shown through ensemble fluorescence resonance energy transfer spectroscopy that the transition temperature and thus the thermodynamics of the rectangle‐peptide system depends on the stimuli salt concentration and temperature, as well as on the intrinsic parameters.