Dynamics of DNA Origami Lattices

Julin, Sofia; Keller, Adrian; Linko, Veikko

doi:10.1021/acs.bioconjchem.2c00359

Cited by 10 publications

(22 citation statements)

References 100 publications

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“…Based on wide literature, , increasing the surface mobility (μ) of the DNA origami should lead to improved lattice formation on a substrate and thus favor larger lattices. For the deposition, we used commonly utilized 1× TAE + 12.5 mM MgCl 2 (Mg 2+ ) buffer with varied concentrations ( C Na ) of NaCl (Na + ).…”

Section: Resultsmentioning

confidence: 99%

“…Assembling large DNA origami lattices on surfaces creates new ways to craft metamaterial surfaces for nano-optics applications. , Especially, the recently introduced DNA-assisted lithography (DALI) enables direct transformation of the DNA origami shapes into metallic structures on different substrates. , This could offer a straightforward way to create plasmonic metasurfaces such as the fishnet-type metallic lattice, which has unique properties like a negative refractive index . One example of a self-assembled fishnet-type lattice has been achieved using the cross-shaped Seeman tile (ST) DNA origami.…”

Section: Introductionmentioning

confidence: 99%

“…3 One example of a self-assembled fishnet-type lattice has been achieved using the cross-shaped Seeman tile (ST) DNA origami. However, this has been realized only on a mica surface via direct formation of the lattice on the surface, 17 i.e., surfaceassisted assembly, 12,13 or with lattices formed within bulk solution and then deposited on mica. 16 To fully employ DALI or any other pattern transfer method 27 to obtain metasurfaces, the formation of the lattice needs to be extended to a silicon substrate, a feat that so far has not been fully realized.…”

Section: ■ Introductionmentioning

confidence: 99%

“…A particularly interesting method to fabricate hierarchical supramolecular structures is DNA origami since it allows folding of arbitrarily shaped nanostructures that can be further designed to organize into larger entities via different interactions like DNA hybridization or blunt end stacking under certain user-defined conditions. , In the past, different kinds of DNA origami, like rectangles, , cross-shapes, the so-called Seeman tiles, , and triangles, − have been arranged into two-dimensional (2D) lattices. Also, 3D lattices , or assemblies like tubes and gears , have been realized, either in solution or on a surface.…”

Section: Introductionmentioning

confidence: 99%

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Large-Scale Formation of DNA Origami Lattices on Silicon

et al. 2023

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In recent years, hierarchical nanostructures have found applications in fields like diagnostics, medicine, nano-optics, and nanoelectronics, especially in challenging applications like the creation of metasurfaces with unique optical properties. One of the promising materials to fabricate such nanostructures has been DNA due to its robust self-assembly properties and plethora of different functionalization schemes. Here, we demonstrate the assembly of a two-dimensional fishnet-type lattice on a silicon substrate using cross-shaped DNA origami as the building block, i.e., tile. The effects of different environmental and structural factors are investigated under liquid atomic force microscopy (AFM) to optimize the lattice assembly. Furthermore, the arm-to-arm binding affinity of the tiles is analyzed, revealing preferential orientations. From the liquid AFM results, we develop a methodology to produce closely-spaced DNA origami lattices on silicon substrate, which allows further nanofabrication process steps, such as metallization. This formed polycrystalline lattice has high surface coverage and is extendable to the wafer scale with an average domain size of about a micrometer. Further studies are needed to increase the domain size toward a single-crystalline large-scale lattice.

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Large-Scale Formation of DNA Origami Lattices on Silicon

et al. 2023

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“…Nevertheless, the library of already demonstrated small dynamic DNA-based devices 31,32 suggests the DNA origami method could also be harnessed in building larger dynamic lattices and other highly ordered assemblies. 33 In this work, we created a dynamic 2D DNA origami lattice that changes its configuration in response to the pH of the surrounding solution. For that, we designed a pliers-like DNA origami unit that serves as the basic building block of the lattice and that can be readily switched between an open "+"-shaped and a closed "X"-shaped state upon a pH change.…”

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confidence: 99%

Reconfigurable pH-Responsive DNA Origami Lattices

Julin

Linko

Kostiainen

2023

Preprint

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DNA nanotechnology enables straightforward fabrication of user-defined and nano-meter-precise templates for a cornucopia of different uses. To date, most of these DNA assemblies have been static, but dynamic structures are increasingly coming into view. The programmability of DNA not only allows encoding of the DNA object shape, but it may be equally used in defining the mechanism of action and the type of stimuli- responsiveness of the dynamic structures. However, these "robotic" features of DNA nanostructures are usually demonstrated for only small, discrete and device-like objects rather than for collectively behaving higher-order systems. Here, we show how a large- scale, two-dimensional (2D) and pH-responsive DNA origami -based lattice can be assembled on a mica substrate and further reversibly switched between two distinct states upon the pH change of the surrounding solution. The control over these two configurations is achieved by equipping the arms of the lattice-forming DNA origami units with "pH-latches" that form Hoogsteen-type triplexes at low pH. In a nutshell, we demonstrate how the electrostatic control over the adhesion and mobility of the DNA origami units on the surface can be used both in the large lattice formation (with the help of directed polymerization) and in the conformational switching of the whole lattice on the substrate. To further emphasize the feasibility of the method, we also demonstrate the formation of reconfigurable 2D gold nanoparticle lattices. We believe this work serves as an important milestone in bridging the nanometer-precise DNA origami templates and higher-order large-scale systems with the stimuli-induced dynamicity.

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Life at the interface: Engineering bio‐nanomaterials through interfacial molecular self‐assembly

Miller,

Medina

2024

WIREs Nanomed Nanobiotechnol

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Interfacial self‐assembly describes the directed organization of molecules and colloids at phase boundaries. Believed to be fundamental to the inception of primordial life, interfacial assembly is exploited by a myriad of eukaryotic and prokaryotic organisms to execute physiologic activities and maintain homeostasis. Inspired by these natural systems, chemists, engineers, and materials scientists have sought to harness the thermodynamic equilibria at phase boundaries to create multi‐dimensional, highly ordered, and functional nanomaterials. Recent advances in our understanding of the biophysical principles guiding molecular assembly at gas–solid, gas–liquid, solid–liquid, and liquid–liquid interphases have enhanced the rational design of functional bio‐nanomaterials, particularly in the fields of biosensing, bioimaging and biotherapy. Continued development of non‐canonical building blocks, paired with deeper mechanistic insights into interphase self‐assembly, holds promise to yield next generation interfacial bio‐nanomaterials with unique, and perhaps yet unrealized, properties.This article is categorized under: Nanotechnology Approaches to Biology > Nanoscale Systems in Biology Therapeutic Approaches and Drug Discovery > Emerging Technologies

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Dynamics of DNA Origami Lattices

Cited by 10 publications

References 100 publications

Large-Scale Formation of DNA Origami Lattices on Silicon

Large-Scale Formation of DNA Origami Lattices on Silicon

Reconfigurable pH-Responsive DNA Origami Lattices

Life at the interface: Engineering bio‐nanomaterials through interfacial molecular self‐assembly

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