DNA Bipedal Motor Achieves a Large Number of Steps Due to Operation Using Microfluidics-Based Interface

Tomov, Toma E.; Tsukanov, Roman; Glick, Yaïr; Berger, Yaron; Liber, Miran; Avrahami, Dorit; Gerber, Doron; Nir, Eyal

doi:10.1021/acsnano.7b00547

Cited by 72 publications

(66 citation statements)

References 35 publications

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“…Alternatively, Nir et al. sacrificed autonomy of bipedal DNA walkers to gain processivity, increasing the number of steps from 7 to 32 (44 % percent of the walkers) . Increasing the number of DNA legs to create polyvalent DNA motors can also boost processivity at the cost of diminished speed.…”

Section: Introductionmentioning

confidence: 99%

“…DNA origami has been instrumental in the field of dynamic DNA nanotechnology. In fact, the vast majority of DNA motors use DNA origami as their track . Patterning the location of fuel footholds on an origami scaffold is also a common strategy to guide motor trajectory .…”

Section: Introductionmentioning

confidence: 99%

“…In fact, the vast majority of DNA motors use DNA origami as their track . Patterning the location of fuel footholds on an origami scaffold is also a common strategy to guide motor trajectory . Herein, we aimed to test the hypothesis that DNA origami structures can be engineered as the body for a polyvalent DNA motor.…”

Section: Introductionmentioning

confidence: 99%

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Tunable DNA Origami Motors Translocate Ballistically Over μm Distances at nm/s Speeds

Bazrafshan

Meyer

et al. 2020

Angew Chem Int Ed

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Inspired by biological motor proteins, that efficiently convert chemical fuel to unidirectional motion, there has been considerable interest in developing synthetic analogues. Among the synthetic motors created thus far, DNA motors that undertake discrete steps on RNA tracks have shown the greatest promise. Nonetheless, DNA nanomotors lack intrinsic directionality, are low speed and take a limited number of steps prior to stalling or dissociation. Herein, we report the first example of a highly tunable DNA origami motor that moves linearly over micron distances at an average speed of 40 nm/ min. Importantly, nanomotors move unidirectionally without intervention through an external force field or a patterned track. Because DNA origami enables precise testing of nanoscale structure-function relationships, we were able to experimentally study the role of motor shape, chassis flexibility, leg distribution, and total number of legs in tuning performance. An anisotropic rigid chassis coupled with a high density of legs maximizes nanomotor speed and endurance.Supporting information and the ORCID identification number(s) for the author(s) of this article can be found under https://doi.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Tunable DNA Origami Motors Translocate Ballistically Over μm Distances at nm/s Speeds

Bazrafshan

Meyer

et al. 2020

Angew Chem Int Ed

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“…Numerous current works regarding the machine-assisted production and analysis of small-molecule compounds, [70] DNAm olecules, [71] colloidal nanoparticles, [72] and technical platforms for handling and analysis of DNA nanostructures [73] and DNAs urfaces [23,74] indicate that the development of integrated systems involves lab-on-a-chip devices and robotics along with in-line analytics and data acquisition. Numerous current works regarding the machine-assisted production and analysis of small-molecule compounds, [70] DNAm olecules, [71] colloidal nanoparticles, [72] and technical platforms for handling and analysis of DNA nanostructures [73] and DNAs urfaces [23,74] indicate that the development of integrated systems involves lab-on-a-chip devices and robotics along with in-line analytics and data acquisition.…”

Section: Discussionmentioning

confidence: 99%

DNA Surface Technology: From Gene Sensors to Integrated Systems for Life and Materials Sciences

Schneider

Niemeyer

2018

Angewandte Chemie

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The evolution of DNA microarray technology has led to sophisticated DNA chips that are being used as routine tools for fundamental and applied genome research such as genotyping and expression profiling. Owing to their capability for highly parallel, site‐directed immobilization of complementary nucleic acids through canonical Watson–Crick base‐pairing, however, DNA‐modified surfaces can also be used for the assembly of complex surface architectures comprised of non‐nucleic acid compounds, such as proteins or colloidal materials. Furthermore, implementation of functional DNA devices and structural DNA nanotechnology can unlock the full potential of DNA surfaces. Based on case studies from diagnostics, sensing, proteome research, cell adhesion, and cell signaling, we show how classical gene sensors have developed into modern integrated systems and platforms for various applications in life sciences and materials research.

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“…[48] By developing am icrofluidics-based user interfacet of acilitate the handling of multiple DNA inputs and the removal of redundant strands, Nir and co-workersa chieved al arge number of consecutive movements teps of aD NA bipedal walker. [49] They also conducted an experimental and theoretical study to investigate the influence of step size on the walking efficiency and stepping kinetics of the DNA bipedal motor. [50] Beyondw alking alongp rescribed tracks, Qian and co-workers built aD NA nanorobot capable of random walkinga nd smart cargo sorting on at wo-dimensional DNA origami land.…”

Section: Category 2: Toehold-mediated Strandd Isplacementmentioning

confidence: 99%

Stimuli‐Responsive DNA Self‐Assembly: From Principles to Applications

Jin

et al. 2019

Chemistry A European J

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Stimuli‐responsive DNA self‐assembly shares the advantages of both designed stimuli‐responsiveness and the molecular programmability of DNA structures, offering great opportunities for basic and applied research in dynamic DNA nanotechnology. In this minireview, we summarize the most recent progress in this rapidly developing field. The trigger mechanisms of the responsive DNA systems are first divided into six categories, which are then explained with illustrative examples following this classification. Subsequently, proof‐of‐concept applications in terms of biosensing, in vivo pH‐mapping, drug delivery, and therapy are discussed. Finally, we provide some remarks on the challenges and opportunities of this highly promising research direction in DNA nanotechnology.

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DNA Bipedal Motor Achieves a Large Number of Steps Due to Operation Using Microfluidics-Based Interface

Cited by 72 publications

References 35 publications

Tunable DNA Origami Motors Translocate Ballistically Over μm Distances at nm/s Speeds

Tunable DNA Origami Motors Translocate Ballistically Over μm Distances at nm/s Speeds

DNA Surface Technology: From Gene Sensors to Integrated Systems for Life and Materials Sciences

Stimuli‐Responsive DNA Self‐Assembly: From Principles to Applications

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