DNA Origami: Recent Progress and Applications.

This chapter explores the basic concept of DNA origami and its various types. By showing the progress made in structural DNA nanotechnology during the last 15 years, the chapter draws attention to the capability of DNA origami to construct complex structures in both 2D and 3D level. As well as looking at a few examples of dynamic DNA nanostructures, the chapter also explores the possible applications of DNA origami in different fields, such as biological computing, nanorobotics, and DNA walkers.

DNA hydrogels as selective biomaterials for specifically capturing DNA, protein and bacteria.

The ability to selectively capture biomacromolecules and other components from solution has many important applications in biotechnology. However, capturing targets from solution while minimizing interference with the sample solution is still challenging. Here, we describe the design and assembly of a group of DNA hydrogels consisting of long single-stranded DNA produced by rolling amplification reaction (RCA) and crosslinked by DNA duplexes. The developed DNA hydrogels can selectively capture and separate oligonucleotides, proteins and bacteria from solution in situ without complex separation processes. Since such DNA hydrogels can capture their targets in the solution independently, multiple DNA hydrogels that target different compounds can be employed to separate different compounds in the solution at the same time. The work not only expands the application of DNA hydrogels, but also paves the way for developing novel selective biomaterials. STATEMENT OF SIGNIFICANCE: Biomaterials capable of selectively capturing various components have great potential in the field of biotechnology. Here, we proposed a new class of hydrogel composed of crosslinked long DNA strands for selectively capturing DNA, protein and bacteria. Unlike traditional polymeric hydrogels that have small meshes and limit macromolecule diffusion owing to the short distance between two adjacent crosslinks, the described DNA hydrogel has a much larger distance between its crosslinks because of the sequence designability of DNA, which allows easy diffusion of biomacromolecules through its networks and greatly expand its specific surface area. Moreover, the developed DNA hydrogel can also easily combine different aptamers to target different components via the Watson-Crick base pairing without making significant changes in its original design.

Interlocked DNA Nanojoints for Reversible Thermal Sensing.

The ability to precisely measure and monitor temperature at high resolution at the nanoscale is an important task for better understanding the thermodynamic properties of functional entities at the nanoscale in complex systems, or at the level of a single cell. However, the development of high-resolution and robust thermal nanosensors is challenging. The design, assembly, and characterization of a group of thermal-responsive deoxyribonucleic acid (DNA) joints, consisting of two interlocked double-stranded DNA (dsDNA) rings, is described. The DNA nanojoints reversibly switch between the static and mobile state at different temperatures without a special annealing process. The temperature response range of the DNA nanojoint can be easily tuned by changing the length or the sequence of the hybridized region in its structure, and because of its interlocked structure the temperature response range of the DNA nanojoint is largely unaffected by its own concentration; this contrasts with systems that consist of separated components.

Design, assembly, characterization, and operation of double-stranded interlocked DNA nanostructures.

Mechanically interlocked DNA nanostructures are useful as flexible entities for operating DNA-based nanomachines. Interlocked structures made of double-stranded (ds) DNA components can be constructed by irreversibly threading them through one another to mechanically link them. The interlocked components thus remain bound to one another while still permitting large-amplitude motion about the mechanical bond. The construction of interlocked dsDNA architectures is challenging because it usually involves the synthesis and modification of small dsDNA nanocircles of various sizes, dependent on intrinsically curved DNA. Here we describe the design, generation, purification, and characterization of interlocked dsDNA structures such as catenanes, rotaxanes, and daisy-chain rotaxanes (DCRs). Their construction requires precise control of threading and hybridization of the interlocking components at each step during the assembly process. The protocol details the characterization of these nanostructures with gel electrophoresis and atomic force microscopy (AFM), including acquisition of high-resolution AFM images obtained in intermittent contact mode in liquid. Additional functionality can be conferred on the DNA architectures by incorporating proteins, molecular switches such as photo-switchable azobenzene derivatives, or fluorophores for studying their mechanical behavior by fluorescence quenching or fluorescent resonance energy transfer experiments. These modified interlocked DNA architectures provide access to more complex mechanical devices and nanomachines that can perform a variety of desired functions and operations. The assembly of catenanes can be completed in 2 d, and that of rotaxanes in 3 d. Addition of azobenzene functionality, fluorophores, anchor groups, or the site-specific linkage of proteins to the nanostructure can extend the time line.

Growing Embossed Nanostructures of Polymer Brushes on Wet-Etched Silicon Templated via Block Copolymers.

Block copolymer nanolithography has attracted enormous interest in chip technologies, such as integrated silicon chips and biochips, due to its large-scale and mass production of uniform patterns. We further modified this technology to grow embossed nanodots, nanorods, and nanofingerprints of polymer brushes on silicon from their corresponding wet-etched nanostructures covered with pendent SiHx (X = 1-3) species. Atomic force microscopy (AFM) was used to image the topomorphologies, and multiple transmission-reflection infrared spectroscopy (MTR-IR) was used to monitor the surface molecular films in each step for the sequential stepwise reactions. In addition, two layers of polymethacrylic acid (PMAA) brush nanodots were observed, which were attributed to the circumferential convergence growth and the diffusion-limited growth of the polymer brushes. The pH response of PMAA nanodots in the same region was investigated by AFM from pH 3.0 to 9.0.

Small circular DNA molecules act as rigid motifs to build DNA nanotubes.

Small circular DNA molecules with designed lengths, for example 64 and 96 nucleotides (nt), after hybridization with a few 32-nt staple strands respectively, can act as rigid motifs for the construction of DNA nanotubes with excellent uniformity in ring diameter. Unlike most native DNA nanotubes, which consist of longitudinal double helices, nanotubes assembled from circular DNAs are constructed from lateral double helices. Of the five types of DNA nanotubes designed here, four are built by alternating two different rings of the same ring size, while one is composed of all the same 96-nt rings. Nanotubes constructed from the same 96-nt rings are 10-100 times shorter than those constructed from two different 96-nt rings, because there are fewer hinge joints on the rings.

Periodical assembly of repetitive RNA sequences synthesized by rolling circle transcription with short DNA staple strands to RNA-DNA hybrid nanowires.

The long single-stranded RNAs produced from Rolling Circle Transcription (RCT) were used as scaffolds to be folded with a few short DNA staples into RNA-DNA hybrid nanowires.

Rolling circle amplification-based DNA origami nanostructrures for intracellular delivery of immunostimulatory drugs.

Several single-stranded scaffold DNA, obtained from rolling circle amplification (RCA), are folded by different staples to form DNA nanoribbons. These DNA nanoribbons are rigid, simple to design, and cost-effective drug carriers, which are readily internalized by mammalian cells and show enhanced immunostimulatory activity.

RCA strands as scaffolds to create nanoscale shapes by a few staple strands.

Thousands of nucleotide(nt)-long single strand DNAs, generated from rolling-circle-amplification (RCA), were used as scaffolds to create DNA nanoscale wires and plates with a few short staple strands by following the origami design principle with a crossover at 1.5 turns. The core sequence of the circle template, for producing tens and hundreds of tandemly repeated copies of it by RCA, was designed according to Seeman's sequence design principle for nucleic acid structural engineering (Seeman, N. C. J. Biomol. Struct. Dyn. 1990, 8, 573). The significance for folding the RCA products into nanoscale shapes lies in the design flexibility of both staple and scaffold strand codes, simplicity of a few short staple strands to fold the periodic sequence of RCA products, and lower cost.

Microwave irradiated click reactions on silicon surfaces via derivertization of covalently grafted poly(PEGMA) brushes.

Two surface chemistry approaches were realized to complete click reactions at covalently grafted polymer brushes of poly(poly(ethylene glycol) monomethacrylate) on a planar silicon surface (Si-g-P(PEGMAOH)). On one hand, the hydroxyls from Si-g-P(PEGMA-OH) brushes can be replaced by chlorines of thionyl chloride and then chlorines can be substituted with azides of sodium azide to achieve azide-terminated (Si-g-P(PEGMA-N(3))) brushes. On the other hand, the terminal acetylene (Si-g-P(PEGMA-CH(2)C[triple bond]CH)) brushes can be prepared easily by reaction between Si-g-P(PEGMA-OH) and propargyl bromide. Model compounds of acetylene-terminated propargylamine, propiolic acid, and 10-undecynoic acid as well as azide-terminal benzyl azide were chosen to investigate the surface click reactions catalyzed with Cu(II)/sodium L-ascorbate by microwave irradiation under very mild conditions at 30°C for 1h. The stepwise modifications were characterized by two surface-sensitive techniques, Multiple Transmission-Reflection Infrared Spectroscopy (MTR-IR) and X-ray Photoelectron Spectroscopy (XPS), and their spectra were analyzed in detail. The triazole ring v(H-C=) stretching at 3139 cm(-1) and the XPS high-resolution scan of N 1s directly confirm the click reactions. By quantifying their infrared spectra before and after click reactions, we conclude that the click reactions on silicon surfaces by microwave irradiation possess high yield and efficiency. Hence, the microwave irradiated click reaction approaches might open convenient avenues to fabricate functional and hybrid organic/silicon devices.