Structural DNA Nanotechnology: Artificial Nanostructures for Biomedical Research

2018 ◽  
Vol 20 (1) ◽  
pp. 375-401 ◽  
Author(s):  
Yonggang Ke ◽  
Carlos Castro ◽  
Jong Hyun Choi
Keyword(s):  
Biomedical Research ◽  
Self Assembly ◽  
Biomedical Applications ◽  
Dna Nanotechnology ◽  
Dna Nanostructures ◽  
Considerable Effort ◽  
Artificial Nanostructures ◽  
Active Pursuit ◽  
External Stimuli ◽  
Structural Dna Nanotechnology

Structural DNA nanotechnology utilizes synthetic or biologic DNA as designer molecules for the self-assembly of artificial nanostructures. The field is founded upon the specific interactions between DNA molecules, known as Watson–Crick base pairing. After decades of active pursuit, DNA has demonstrated unprecedented versatility in constructing artificial nanostructures with significant complexity and programmability. The nanostructures could be either static, with well-controlled physicochemical properties, or dynamic, with the ability to reconfigure upon external stimuli. Researchers have devoted considerable effort to exploring the usability of DNA nanostructures in biomedical research. We review the basic design methods for fabricating both static and dynamic DNA nanostructures, along with their biomedical applications in fields such as biosensing, bioimaging, and drug delivery.

ARTIFICIALLY DESIGNED DNA NANOSTRUCTURES

NANO ◽  
2009 ◽  
Vol 04 (03) ◽  
pp. 119-139 ◽  
Author(s):  
RASHID AMIN ◽  
SOYEON KIM ◽  
SUNG HA PARK ◽  
THOMAS HENRY LABEAN
Keyword(s):  
Dna Sequences ◽  
Self Assembly ◽  
Dna Nanotechnology ◽  
Medical Applications ◽  
Dna Nanostructures ◽  
Base Pairing ◽  
Assembly Instructions ◽  
Artificial Dna ◽  
Structural Dna Nanotechnology ◽  
Complex Nanostructures

In the field of structural DNA nanotechnology, researchers create artificial DNA sequences to self-assemble into target molecular superstructures and nanostructures. The well-understood Watson–Crick base-pairing rules are used to encode assembly instructions directly into the DNA molecules. A wide variety of complex nanostructures has been created using this method. DNA directed self-assembly is now being adapted for use in the nanofabrication of functional structures for use in electronics, photonics, and medical applications.

scholarly journals Generating DNA Origami Nanostructures through Shape Annealing

2021 ◽  
Vol 11 (7) ◽  
pp. 2950
Author(s):  
Bolutito Babatunde ◽  
D. Sebastian Arias ◽  
Jonathan Cagan ◽  
Rebecca E. Taylor
Keyword(s):  
Self Assembly ◽  
Design Space ◽  
Simulated Annealing Algorithm ◽  
Dna Nanotechnology ◽  
Dna Origami ◽  
Design Tools ◽  
Dna Nanostructures ◽  
Formal Approach ◽  
Annealing Algorithm ◽  
Structural Dna Nanotechnology

Structural DNA nanotechnology involves the design and self-assembly of DNA-based nanostructures. As a field, it has progressed at an exponential rate over recent years. The demand for unique DNA origami nanostructures has driven the development of design tools, but current CAD tools for structural DNA nanotechnology are limited by requiring users to fully conceptualize a design for implementation. This article introduces a novel formal approach for routing the single-stranded scaffold DNA that defines the shape of DNA origami nanostructures. This approach for automated scaffold routing broadens the design space and generates complex multilayer DNA origami designs in an optimally driven way, based on a set of constraints and desired features. This technique computes unique designs of DNA origami assemblies by utilizing shape annealing, which is an integration of shape grammars and the simulated annealing algorithm. The results presented in this article illustrate the potential of the technique to code desired features into DNA nanostructures.

scholarly journals Strategies to Build Hybrid Protein–DNA Nanostructures

Nanomaterials ◽  
2021 ◽  
Vol 11 (5) ◽  
pp. 1332
Author(s):  
Armando Hernandez-Garcia
Keyword(s):  
Dynamic Systems ◽  
Dna Nanotechnology ◽  
Chemical Properties ◽  
Hybrid Nanostructures ◽  
Advanced Materials ◽  
Dna Nanostructures ◽  
Hybrid Protein ◽  
Structural Protein ◽  
The Individual ◽  
Structural Dna Nanotechnology

Proteins and DNA exhibit key physical chemical properties that make them advantageous for building nanostructures with outstanding features. Both DNA and protein nanotechnology have growth notably and proved to be fertile disciplines. The combination of both types of nanotechnologies is helpful to overcome the individual weaknesses and limitations of each one, paving the way for the continuing diversification of structural nanotechnologies. Recent studies have implemented a synergistic combination of both biomolecules to assemble unique and sophisticate protein–DNA nanostructures. These hybrid nanostructures are highly programmable and display remarkable features that create new opportunities to build on the nanoscale. This review focuses on the strategies deployed to create hybrid protein–DNA nanostructures. Here, we discuss strategies such as polymerization, spatial directing and organizing, coating, and rigidizing or folding DNA into particular shapes or moving parts. The enrichment of structural DNA nanotechnology by incorporating protein nanotechnology has been clearly demonstrated and still shows a large potential to create useful and advanced materials with cell-like properties or dynamic systems. It can be expected that structural protein–DNA nanotechnology will open new avenues in the fabrication of nanoassemblies with unique functional applications and enrich the toolbox of bionanotechnology.

scholarly journals Hybrid Nanoassemblies from Viruses and DNA Nanostructures

Nanomaterials ◽  
2021 ◽  
Vol 11 (6) ◽  
pp. 1413
Author(s):  
Sofia Ojasalo ◽  
Petteri Piskunen ◽  
Boxuan Shen ◽  
Mauri A. Kostiainen ◽  
Veikko Linko
Keyword(s):  
Cell Activation ◽  
Immune Cell ◽  
Dna Nanotechnology ◽  
Biological Properties ◽  
Dna Nanostructures ◽  
Dna Structures ◽  
Nanoscale Structures ◽  
Immune Cell Activation ◽  
Wide Range ◽  
Structural Dna Nanotechnology

Viruses are among the most intriguing nanostructures found in nature. Their atomically precise shapes and unique biological properties, especially in protecting and transferring genetic information, have enabled a plethora of biomedical applications. On the other hand, structural DNA nanotechnology has recently emerged as a highly useful tool to create programmable nanoscale structures. They can be extended to user defined devices to exhibit a wide range of static, as well as dynamic functions. In this review, we feature the recent development of virus-DNA hybrid materials. Such structures exhibit the best features of both worlds by combining the biological properties of viruses with the highly controlled assembly properties of DNA. We present how the DNA shapes can act as “structured” genomic material and direct the formation of virus capsid proteins or be encapsulated inside symmetrical capsids. Tobacco mosaic virus-DNA hybrids are discussed as the examples of dynamic systems and directed formation of conjugates. Finally, we highlight virus-mimicking approaches based on lipid- and protein-coated DNA structures that may elicit enhanced stability, immunocompatibility and delivery properties. This development also paves the way for DNA-based vaccines as the programmable nano-objects can be used for controlling immune cell activation.

scholarly journals Constructing Large 2D Lattices Out of DNA-Tiles

Molecules ◽  
2021 ◽  
Vol 26 (6) ◽  
pp. 1502
Author(s):  
Johannes M. Parikka ◽  
Karolina Sokołowska ◽  
Nemanja Markešević ◽  
J. Jussi Toppari
Keyword(s):  
Self Assembly ◽  
Dna Nanotechnology ◽  
Building Blocks ◽  
High Yield ◽  
Dna Nanostructures ◽  
Liquid Interfaces ◽  
Basic Principles ◽  
Dna Tiles ◽  
One Step ◽  
Solid Liquid

The predictable nature of deoxyribonucleic acid (DNA) interactions enables assembly of DNA into almost any arbitrary shape with programmable features of nanometer precision. The recent progress of DNA nanotechnology has allowed production of an even wider gamut of possible shapes with high-yield and error-free assembly processes. Most of these structures are, however, limited in size to a nanometer scale. To overcome this limitation, a plethora of studies has been carried out to form larger structures using DNA assemblies as building blocks or tiles. Therefore, DNA tiles have become one of the most widely used building blocks for engineering large, intricate structures with nanometer precision. To create even larger assemblies with highly organized patterns, scientists have developed a variety of structural design principles and assembly methods. This review first summarizes currently available DNA tile toolboxes and the basic principles of lattice formation and hierarchical self-assembly using DNA tiles. Special emphasis is given to the forces involved in the assembly process in liquid-liquid and at solid-liquid interfaces, and how to master them to reach the optimum balance between the involved interactions for successful self-assembly. In addition, we focus on the recent approaches that have shown great potential for the controlled immobilization and positioning of DNA nanostructures on different surfaces. The ability to position DNA objects in a controllable manner on technologically relevant surfaces is one step forward towards the integration of DNA-based materials into nanoelectronic and sensor devices.

Self-Assembly-Based Structural DNA Nanotechnology

2011 ◽  
Vol 15 (4) ◽  
pp. 534-547 ◽  
Author(s):  
Zhao Zhang ◽  
Yanming Fu ◽  
Baojie Li ◽  
Guoyin Feng ◽  
Can Li ◽  
...  
Keyword(s):  
Self Assembly ◽  
Dna Nanotechnology ◽  
Structural Dna Nanotechnology

scholarly journals Self-assembly of large RNA structures: learning from DNA nanotechnology

2016 ◽  
Vol 2 (1) ◽  
Author(s):  
Jaimie Marie Stewart ◽  
Elisa Franco
Keyword(s):  
Self Assembly ◽  
De Novo ◽  
Dna Nanotechnology ◽  
De Novo Design ◽  
Dna Nanostructures ◽  
Rna Structures ◽  
Functional Nanostructures ◽  
Rna And Dna ◽  
Unique Chemical

AbstractNucleic acid nanotechnology offers many methods to build self-assembled structures using RNA and DNA. These scaffolds are valuable in multiple applications, such as sensing, drug delivery and nanofabrication. Although RNA and DNA are similar molecules, they also have unique chemical and structural properties. RNA is generally less stable than DNA, but it folds into a variety of tertiary motifs that can be used to produce complex and functional nanostructures. Another advantage of using RNA over DNA is its ability to be encoded into genes and to be expressed in vivo. Here we review existing approaches for the self-assembly of RNA and DNA nanostructures and specifically methods to assemble large RNA structures. We describe de novo design approaches used in DNA nanotechnology that can be ported to RNA. Lastly, we discuss some of the challenges yet to be solved to build micron-scale, multi stranded RNA scaffolds.

scholarly journals Review of the Electrical Characterization of Metallic Nanowires on DNA Templates

2018 ◽  
Vol 19 (10) ◽  
pp. 3019 ◽  
Author(s):  
Türkan Bayrak ◽  
Nagesh Jagtap ◽  
Artur Erbe
Keyword(s):  
Electronic Properties ◽  
Self Assembly ◽  
Dna Nanotechnology ◽  
Electrical Characterization ◽  
Dna Nanostructures ◽  
Metallic Nanowires ◽  
Electronic Circuits ◽  
Electrically Conducting ◽  
Dna Strands

The use of self-assembly techniques may open new possibilities in scaling down electronic circuits to their ultimate limits. Deoxyribonucleic acid (DNA) nanotechnology has already demonstrated that it can provide valuable tools for the creation of nanostructures of arbitrary shape, therefore presenting an ideal platform for the development of nanoelectronic circuits. So far, however, the electronic properties of DNA nanostructures are mostly insulating, thus limiting the use of the nanostructures in electronic circuits. Therefore, methods have been investigated that use the DNA nanostructures as templates for the deposition of electrically conducting materials along the DNA strands. The most simple such structure is given by metallic nanowires formed by deposition of metals along the DNA nanostructures. Here, we review the fabrication and the characterization of the electronic properties of nanowires, which were created using these methods.

scholarly journals 3D DNA Nanostructures: The Nanoscale Architect

2021 ◽  
Vol 11 (6) ◽  
pp. 2624
Author(s):  
Daniel Fu ◽  
John Reif
Keyword(s):  
Single Molecule ◽  
Mechanical Design ◽  
Dna Nanotechnology ◽  
Dna Nanostructures ◽  
Biophysical Studies ◽  
Significant Research ◽  
Core Concepts ◽  
Potential Applications ◽  
The Stability ◽  
Structural Dna Nanotechnology

Structural DNA nanotechnology is a pioneering biotechnology that presents the opportunity to engineer DNA-based hardware that will mediate a profound interface to the nanoscale. To date, an enormous library of shaped 3D DNA nanostructures have been designed and assembled. Moreover, recent research has demonstrated DNA nanostructures that are not only static but can exhibit specific dynamic motion. DNA nanostructures have thus garnered significant research interest as a template for pursuing shape and motion-dependent nanoscale phenomena. Potential applications have been explored in many interdisciplinary areas spanning medicine, biosensing, nanofabrication, plasmonics, single-molecule chemistry, and facilitating biophysical studies. In this review, we begin with a brief overview of general and versatile design techniques for 3D DNA nanostructures as well as some techniques and studies that have focused on improving the stability of DNA nanostructures in diverse environments, which is pivotal for its reliable utilization in downstream applications. Our main focus will be to compile a wide body of existing research on applications of 3D DNA nanostructures that demonstrably rely on the versatility of their mechanical design. Furthermore, we frame reviewed applications into three primary categories, namely encapsulation, surface templating, and nanomechanics, that we propose to be archetypal shape- or motion-related functions of DNA nanostructures found in nanoscience applications. Our intent is to identify core concepts that may define and motivate specific directions of progress in this field as we conclude the review with some perspectives on the future.

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