Surface‐Assisted Large‐Scale Ordering of DNA Origami Tiles

The arrangement of DNA‐based nanostructures into extended higher order assemblies is an important step towards their utilization as functional molecular materials. We herein demonstrate that by electrostatically controlling the adhesion and mobility of DNA origami structures on mica surfaces by the simple addition of monovalent cations, large ordered 2D arrays of origami tiles can be generated. The lattices can be formed either by close‐packing of symmetric, non‐interacting DNA origami structures, or by utilizing blunt‐end stacking interactions between the origami units. The resulting crystalline lattices can be readily utilized as templates for the ordered arrangement of proteins.     

Assembly and Purification of Enzyme‐Functionalized DNA Origami Structures

The positioning of enzymes on DNA nanostructures for the study of spatial effects in interacting biomolecular assemblies requires chemically mild immobilization procedures as well as efficient means for separating unbound proteins from the assembled constructs. We herein report the exploitation of free‐flow electrophoresis (FFE) for the purification of DNA origami structures decorated with biotechnologically relevant recombinant enzymes: the S‐selective NADP⁺/NADPH‐dependent oxidoreductase Gre2 from S. Cerevisiae and the reductase domain of the monooxygenase P450 BM3 from B. megaterium. The enzymes were fused with orthogonal tags to facilitate site‐selective immobilization. FFE purification yielded enzyme–origami constructs whose specific activity was quantitatively analyzed. All origami‐tethered enzymes were significantly more active than the free enzymes, thereby suggesting a protective influence of the large, highly charged DNA nanostructure on the stability of the proteins.     

Self‐assembly of DNA Origami Using Rolling Circle Amplification Based DNA Nanoribbons

During the development of structural DNA nanotechnology, the emerging of scaffolded DNA origami is marvelous. It utilizes DNA double helix inherent specificity of Watson‐Crick base pairing and structural features to create self‐assembling structures at the nanometer scale exhibiting the addressable character. However, the assembly of DNA origami is disorderly and unpredictable. Herein, we present a novel strategy to assemble the DNA origami using rolling circle amplification based DNA nanoribbons as the linkers. Firstly, long single‐stranded DNA from Rolling Circle Amplification is annealed with several staples to form kinds of DNA nanoribbons with overhangs. Subsequently, the rectangle origami is formed with overhanged staple strands at any edge that would hybridize with the DNA nanoribbons. By mixing them up, we illustrate the one‐dimensional even two‐dimensional assembly of DNA origami with good orientation.     

Polyrotaxane‐Mediated Self‐Assembly of Gold Nanospheres into Fully Reversible Supercrystals

The use of a thiol‐functionalized nonionic surfactant to stabilize spherical gold nanoparticles in water induces the spontaneous formation of polyrotaxanes at the nanoparticle surface in the presence of the macrocycle α‐cyclodextrin. Whereas using an excess of surfactant an amorphous gold nanocomposite is obtained, under controlled drying conditions the self‐assembly between the surface supramolecules provides large and homogenous supercrystals with hexagonal close packing of nanoparticles. Once formed, the self‐assembled supercrystals can be fully redispersed in water. The reversibility of the crystallization process may offer an excellent reusable material to prepare gold nanoparticle inks and optical sensors with the potential to be recovered after use.     

Nanoparticle‐Assisted Alignment of Carbon Nanotubes on DNA Origami

Aligning carbon nanotubes (CNTs) is a key challenge for fabricating CNT‐based electronic devices. Herein, we report a spherical nucleic acid (SNA) mediated approach for the highly precise alignment of CNTs at prescribed sites on DNA origami. We find that the cooperative DNA hybridization occurring at the interface of SNA and DNA‐coated CNTs leads to an approximately five‐fold improvement of the positioning efficiency. By combining this with the intrinsic positioning addressability of DNA origami, CNTs can be aligned in parallel with an extremely small angular variation of within 10°. Moreover, we demonstrate that the parallel alignment of CNTs prevents incorrect logic functionality originating from stray conducting paths formed by misaligned CNTs. This SNA‐mediated method thus holds great potential for fabricating scalable CNT arrays for nanoelectronics.     

Ion‐Selective Formation of a Guanine Quadruplex on DNA Origami Structures

DNA origami nanostructures are a versatile tool that can be used to arrange functionalities with high local control to study molecular processes at a single‐molecule level. Here, we demonstrate that DNA origami substrates can be used to suppress the formation of specific guanine (G) quadruplex structures from telomeric DNA. The folding of telomeres into G‐quadruplex structures in the presence of monovalent cations (e.g. Na⁺ and K⁺) is currently used for the detection of K⁺ ions, however, with insufficient selectivity towards Na⁺. By means of FRET between two suitable dyes attached to the 3′‐ and 5′‐ends of telomeric DNA we demonstrate that the formation of G‐quadruplexes on DNA origami templates in the presence of sodium ions is suppressed due to steric hindrance. Hence, telomeric DNA attached to DNA origami structures represents a highly sensitive and selective detection tool for potassium ions even in the presence of high concentrations of sodium ions.     

Site‐Directed,On‐Surface Assembly of DNA Nanostructures

Two‐dimensional DNA lattices have been assembled from DNA double‐crossover (DX) motifs on DNA‐encoded surfaces in a site‐specific manner. The lattices contained two types of single‐stranded protruding arms pointing into opposite directions of the plane. One type of these protruding arms served to anchor the DNA lattice on the solid support through specific hybridization with surface‐bound, complementary capture oligomers. The other type of arms allowed for further attachment of DNA‐tethered probe molecules on the opposite side of the lattices exposed to the solution. Site‐specific lattice assembly and attachment of fluorophore‐labeled oligonucleotides and DNA–protein conjugates was demonstrated using DNA microarrays on flat, transparent mica substrates. Owing to their programmable orientation and addressability over a broad dynamic range from the nanometer to the millimeter length scale, such supramolecular architecture might be used for presenting biomolecules on surfaces, for instance, in biosensor applications.     

Reversible Reconfiguration of DNA Origami Nanochambers Monitored by Single‐Molecule FRET

Today, DNA nanotechnology is one of the methods of choice to achieve spatiotemporal control of matter at the nanoscale. By combining the peculiar spatial addressability of DNA origami structures with the switchable mechanical movement of small DNA motifs, we constructed reconfigurable DNA nanochambers as dynamic compartmentalization systems. The reversible extension and contraction of the inner cavity of the structures was used to control the distance‐dependent energy transfer between two preloaded fluorophores. Interestingly, single‐molecule FRET studies revealed that the kinetics of the process are strongly affected by the choice of the switchable motifs and/or actuator sequences, thus offering a valid method for fine‐tuning the dynamic properties of large DNA nanostructures. We envisage that the proposed DNA nanochambers may function as model structures for artificial biomimetic compartments and transport systems.     

Single‐Molecule Mechanochemical Sensing Using DNA Origami Nanostructures

While single‐molecule sensing offers the ultimate detection limit, its throughput is often restricted as sensing events are carried out one at a time in most cases. 2D and 3D DNA origami nanostructures are used as expanded single‐molecule platforms in a new mechanochemical sensing strategy. As a proof of concept, six sensing probes are incorporated in a 7‐tile DNA origami nanoassembly, wherein binding of a target molecule to any of these probes leads to mechanochemical rearrangement of the origami nanostructure, which is monitored in real time by optical tweezers. Using these platforms, 10 pM platelet‐derived growth factor (PDGF) are detected within 10 minutes, while demonstrating multiplex sensing of the PDGF and a target DNA in the same solution. By tapping into the rapid development of versatile DNA origami nanostructures, this mechanochemical platform is anticipated to offer a long sought solution for single‐molecule sensing with improved throughput.     

Programmed‐Assembly System Using DNA Jigsaw Pieces

A novel method for assembling multiple DNA origami structures has been developed by using designed 2D DNA origami rectangles, so‐called “DNA jigsaw pieces” that have sequence‐programmed connectors. Shape and sequence complementarity were introduced to the concavity and convex connectors in the DNA rectangles for selective connection with the help of nonselective π‐stacking interactions between the side edges of the DNA jigsaw piece structures. Single DNA jigsaw piece units were assembled into unidirectional nanostructures with the correct alignment and uniform orientation. Three and five different DNA jigsaw pieces were assembled into predesigned and ordered nanostructures in a programmed fashion. Finally, three‐, four‐, and five‐letter words have been displayed by using this programmed DNA jigsaw piece system.     

Synthesis and Characterization of Gold‐Nanoparticle‐Cored Dendrimers Stabilized by Metal–Carbon Bonds

Synthesis and characterization of gold‐nanoparticle‐cored dendrimers (NCDs), in which the dendrons are attached to the gold core through gold–carbon bonds, are described. Synthesis of these materials involved the simultaneous reduction of HAuCl₄ and a Fréchet‐type dendron with a diazonium group at the focal point, all in an organic solvent such as toluene. These materials possess a nanometer‐sized gold core surrounded by a shell of polyaryl ether dendrons, which are connected radially to the core. The NCDs were characterized by TEM, thermogravimetric analysis (TGA), and IR, UV, and NMR spectroscopic techniques. Average particle diameter of the NCDs ranged from 4.7 to 5.5 nm for the different generations. All NCDs exhibit the characteristic plasmon absorption of gold nanoparticles at 520 nm. Average numbers of dendrons per NCD in AuG_n were calculated using results from TGA and TEM studies. Multiple layering of the dendrons is proposed as a possible reason for the high dendron/NCD value.