We created nanometer-scale transmembrane channels in lipid bilayers using self-assembled DNA-based nanostructures. Scaffolded DNA origami was used to create a stem that penetrates and spans a lipid membrane, and a barrel-shaped cap that adheres to the membrane in part via 26 cholesterol moieties. In single-channel electrophysiological measurements, we find similarities to the response of natural ion channels, such as conductances on the order of 1 nS and channel gating. More pronounced gating was seen for mutations in which a single DNA strand of the stem protruded into the channel. In single-molecule translocation experiments, we highlight one of many potential applications of the synthetic channels, namely as single DNA molecule sensing devices.
We demonstrate that, at constant temperature, hundreds of DNA strands can cooperatively fold a long template DNA strand within minutes into complex nanoscale objects. Folding occurred out of equilibrium along nucleation-driven pathways at temperatures that could be influenced by the choice of sequences, strand lengths, and chain topology. Unfolding occurred in apparent equilibrium at higher temperatures than those for folding. Folding at optimized constant temperatures enabled the rapid production of three-dimensional DNA objects with yields that approached 100%. The results point to similarities with protein folding in spite of chemical and structural differences. The possibility for rapid and high-yield assembly will enable DNA nanotechnology for practical applications.
A key goal for nanotechnology is to design synthetic objects that may ultimately achieve functionalities known today only from natural macromolecular complexes. Molecular self-assembly with DNA has shown potential for creating user-defined 3D scaffolds, but the level of attainable positional accuracy has been unclear. Here we report the cryo-EM structure and a full pseudoatomic model of a discrete DNA object that is almost twice the size of a prokaryotic ribosome. The structure provides a variety of stable, previously undescribed DNA topologies for future use in nanotechnology and experimental evidence that discrete 3D DNA scaffolds allow the positioning of user-defined structural motifs with an accuracy that is similar to that observed in natural macromolecules. Thereby, our results indicate an attractive route to fabricate nanoscale devices that achieve complex functionalities by DNAtemplated design steered by structural feedback.N atural macromolecular machines have complex 3D shapes with subnanometer-precise structural features that enable executing tasks such as signal transduction, molecular transport, and enzymatic catalysis (1). A key goal for nanotechnology is to fabricate synthetic objects with similarly precise features to ultimately control tasks known today only from natural "nanomachines." Molecular self-assembly with DNA is considered a candidate route to achieve this goal (2-13). Densely packed 3D DNA-origami objects (14-18) seem particularly suited for use as rigid scaffolds to position reactive groups at target locations in space, and to implement features known from natural macromolecular complexes, such as shape complementarity and controlled domain movement. Designing such objects to meet precise structural specifications will benefit strongly from detailed 3D structural feedback. Here we present a cryo-EM map of an asymmetric, densely packed DNA object that comprises 15,238 nt in 164 chains. Combined with prior knowledge about the topology of chain connectivity, this map provided sufficient detail to construct a full pseudoatomic model for this particle. Thereby, our results provide structural feedback on DNA-templated design that will prove valuable for the design of complex functionalities.Results and Discussion DNA-Templated Design and Synthesis. Our DNA object was designed to be suitable for structure determination by cryo-EM singleparticle analysis, because the choice of a distinctly asymmetric shape facilitated the recognition of different particle orientations in electron micrographs (Fig. 1A). The object was designed to assemble as 82 parallel dsDNA helices of varying length in a square lattice (17) of 10 columns and 12 rows and comprising a total of 15,238 nt with a molecular mass of 4.8 MDa (Fig. S1). A total of 740 nt were distributed among flexible loops at the ends of the helices to prevent aggregation by blunt-end stacking (19). Synthesis of the object was based on templated molecular selfassembly (3) with a 7,249-nt-long "scaffold" DNA strand derived from M13 bacteriophage an...
DNA has become a prime material for assembling complex three-dimensional objects that promise utility in various areas of application. However, achieving user-defined goals with DNA objects has been hampered by the difficulty to prepare them at arbitrary concentrations and in user-defined solution conditions. Here, we describe a method that solves this problem. The method is based on poly(ethylene glycol)-induced depletion of species with high molecular weight. We demonstrate that our method is applicable to a wide spectrum of DNA shapes and that it achieves excellent recovery yields of target objects up to 97 %, while providing efficient separation from non-integrated DNA strands. DNA objects may be prepared at concentrations up to the limit of solubility, including the possibility for bringing DNA objects into a solid phase. Due to the fidelity and simplicity of our method we anticipate that it will help to catalyze the development of new types of applications that use self-assembled DNA objects.
DNA-based nanopores are synthetic biomolecular membrane pores, whose geometry and chemical functionality can be tuned using the tools of DNA nanotechnology, making them promising molecular devices for applications in single-molecule biosensing and synthetic biology. Here we introduce a large DNA membrane channel with an ≈4 nm diameter pore, which has stable electrical properties and spontaneously inserts into flat lipid bilayer membranes. Membrane incorporation is facilitated by a large number of hydrophobic functionalizations or, alternatively, streptavidin linkages between biotinylated channels and lipids. The channel displays an Ohmic conductance of ≈3 nS, consistent with its size, and allows electrically driven translocation of single-stranded and double-stranded DNA analytes. Using confocal microscopy and a dye influx assay, we demonstrate the spontaneous formation of membrane pores in giant unilamellar vesicles. Pores can be created both in an outside-in and an inside-out configuration.
DNA has it covered: DNA origami gatekeeper nanoplates convert nanopores in solid-state membranes into versatile devices for label-free macromolecular sensing applications. The custom apertures in the nanoplates can be chemically addressed for sequence-specific detection of DNA.
The fast kinetics of induction and relaxation of bacteriochlorophyll prompt and delayed fluorescence together with absorption changes of the reaction center (RC) dimer (P) were measured by combination of flashes from laser diodes in intact cells of wild type, carotenoidless (R-26) and cytochrome c 2 deficient (CYCA) mutants of photosynthetic bacteria Rhodobacter sphaeroides. The fluorescence induction under high intensity of continuous light splits into fast and slow rises both overlapped by the (carotenoid and/or bacteriochlorophyll) triplet quenching. The fast phase is purely photochemical as it depends strongly on the number of photons absorbed. The slow phase is the combination of thermal and photochemical reactions and reflects the multiple turnover of the system. Upon short flash, the fluorescence yield cannot reach the maximum due to partial reopening of the RCs by rapid donor and acceptor side reactions. Longer flashes are needed to close the RC completely. Contrary to higher plants, the kinetics of induction and relaxation of the fluorescence yield in bacteria are controlled principally by P þ . The reactions on the quinone side play minor role. The quantitative determination of the cyclic electron transfer rate can be based on calibration to the quantity of P þ . 2797-SympDesign and Engineering of a Light-Activated Potassium Channel
Molecular self-assembly with DNA offers a route for building user-defined nanoscale objects, but an apparent requirement for magnesium in solution has limited the range of conditions for which practical utility of such objects may be achieved. Here we report conditions for assembling templated multi-layer DNA objects in the presence of monovalent ions, showing that neither divalent cations in general or magnesium in particular are essential ingredients for the successful assembly of such objects. The percentage of DNA strands in an object that do not form thermally stable double-helical DNA domains (Tm>45 °C) with the template molecule correlated with the sodium requirements for obtaining folded objects. Minimizing the fraction of such weakly binding strands by rational design choices enhanced the yield of folding. The results support the view that DNA-based nanodevices may be designed and produced for a variety of target environments.
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