DNA is increasingly used to engineer dynamic nanoscale circuits, structures, and motors, many of which rely on DNA strand‐displacement reactions. The use of functional DNA sequences (e.g., aptamers, which bind to a wide range of ligands) in these reactions would potentially confer responsiveness on such devices, and integrate DNA computation with highly varied molecular stimuli. By using high‐throughput single‐molecule FRET methods, we compared the kinetics of a putative aptamer–ligand and aptamer–complement strand‐displacement reaction. We found that the ligands actively disrupted the DNA duplex in the presence of a DNA toehold in a similar manner to complementary DNA, with kinetic details specific to the aptamer structure, thus suggesting that the DNA strand‐displacement concept can be extended to functional DNA–ligand systems. 相似文献
Toehold‐mediated DNA strand displacement endows DNA nanostructures with dynamic response capability. However, the complexity of sequence design dramatically increases as the size of the DNA network increases. We attribute this problem to the mechanism of toehold‐mediated strand displacement, termed exact strand displacement (ESD), in which one input strand corresponds to one specific substrate. In this work, we propose an alternative to toehold‐mediated DNA strand displacement, termed fuzzy strand displacement (FSD), in which one‐to‐many and many‐to‐one relationships are established between the input strand and the substrate, to reduce the complexity. We have constructed four modules, termed converter, reporter, fuzzy detector, and fuzzy trigger, and demonstrated that a sequence pattern recognition network composed of these modules requires less complex sequence design than an equivalent network based on toehold‐mediated DNA strand displacement. 相似文献
Toehold-mediated strand displacement has proven extremely powerful in programming enzyme-free DNA circuits and DNA nanomachines. To achieve multistep, autonomous, and complex behaviors, toeholds must be initially inactivated by hybridizing to inhibitor strands or domains and then relieved from inactivation in a programmed, timed manner. Although powerful and reasonably robust, this strategy has several drawbacks that limit the architecture of DNA circuits. For example, the combination between toeholds and branch migration (BM) domains is 'hard wired' during DNA synthesis thus cannot be created or changed during the execution of DNA circuits. To solve this problem, I propose a strategy called 'associative toehold activation', where the toeholds and BM domains are connected via hybridization of auxiliary domains during the execution of DNA circuits. Bulged thymidines that stabilize DNA three-way junctions substantially accelerate strand displacement reactions in this scheme, allowing fast strand displacement initiated by reversible toehold binding. To demonstrate the versatility of the scheme, I show (1) run-time combination of toeholds and BM domains, (2) run-time recombination of toeholds and BM domains, which results in a novel operation 'toehold switching', and (3) design of a simple conformational self-replicator. 相似文献
A photofunctionalized square bipyramidal DNA nanocapsule (NC) was designed and prepared for the creation of a nanomaterial carrier. Photocontrollable open/close system and toehold system were introduced into the NC for the inclusion and release of a gold nanoparticle (AuNP) by photoirradiation and strand displacement. The reversible open and closed states were examined by gel electrophoresis and atomic force microscopy (AFM), and the open behavior was directly observed by high‐speed AFM. The encapsulation of the DNA‐modified AuNP within the NC was carried out by hybridization of a specific DNA strand (capture strand), and the release of the AuNP was examined by addition of toehold‐containing complementary DNA strand (release strand). The release of the AuNP from the NC was achieved by the opening of the NC and subsequent strand displacement. 相似文献
Flexible spacer chains are utilized to enhance the hybridization of terminally anchored oligonucleotide probes of DNA microarrays. A polymer physics approach identifies an underlying mechanism and yields guidelines for the optimal spacer length in terms of the effect on the equilibrium state. For low grafting densities, the dominant effect arises because of the decimation in the number of accessible chain configurations due to the impenetrable surface. Opposing trends are found for long targets and for short targets. At higher grafting densities, different brush regimes introduce an extra hybridization penalty. A novel brush regime is obtained for long neutral spacers and short targets at intermediate ionic strength where the chain stretching is due to the electrostatic interactions between the probes. 相似文献
An electrochemical biosensor for determination of DNA is described that is based on the reaction of regulated DNA (reg-DNA) first with substrated DNA (subs-DNA) to form a reaction intermediate. The intermediate binds target DNA (T) by hybridization and initiates a branch migration leading to the production of complex of substrated DNA and target DNA (TC). Once TC is produced, it reacts with assisted DNA (ass-DNA) through a toehold exchange mechanism, yielding the product complex of substrated DNA and assisted DNA (CS). The target is then released back into the solution and and catalyzes the next cycle of toehold-exchange with the reaction intermediate of substrated DNA and regulated DNA (CPR). Unlike in a conventional DNA toehold that is hardwired with the branch migration domain, the allosteric DNA toehold is designed into a reg-DNA which is independent of the branch migration domain. Under the optimal experimental conditions and at a working potential as low as 0.18 V, response to DNA is linear in the 1 fM to 1000 pM concentration range, and the detection limit is 0.83 fM. The assay is highly specific and can discriminate target DNA even from a single-base mismatch. It was applied to the analysis of DNA spiked plasma samples.
Graphical abstract Schematic illustration of the electrochemical strategy for target DNA detection based on regulation of DNA strand displacement using an allosteric DNA toehold strategy. It can be used to analyze DNA-spiked plasma samples and has a low detection limit of 0.83 fM.
Introduction of artificial metal–ligand base pairs can enrich the structural diversity and functional controllability of nucleic acids. In this work, we revealed a novel approach by placing a ligand-type nucleoside as an independent toehold to control DNA strand-displacement reactions based on metal–ligand complexation. This metal-mediated artificial base pair could initiate strand invasion similar to the natural toehold DNA, but exhibited flexible controllability to manipulate the dynamics of strand displacement that was only governed by its intrinsic coordination properties. External factors that influence the intrinsic properties of metal–ligand complexation, including metal species, metal concentrations and pH conditions, could be utilized to regulate the strand dynamics. Reversible control of DNA strand-displacement reactions was also achieved through combination of the metal-mediated artificial base pair with the conventional toehold-mediated strand exchange by cyclical treatments of the metal ion and the chelating reagent. Unlike previous studies of embedded metal-mediated base pairs within natural base pairs, this metal–ligand complexation is not integrated into the nucleic acid structure, but functions as an independent toehold to regulate strand displacement, which would open a new door for the development of versatile dynamic DNA nanotechnologies.This metal-mediated artificial base pair can function as an independent toehold based on metal–ligand coordination and exhibit flexible and reversible controllability to manipulate the dynamics of strand displacement.相似文献
Oligonucleotide‐based molecular circuits offer the exciting possibility to introduce autonomous signal processing in biomedicine, synthetic biology, and molecular diagnostics. Here we introduce bivalent peptide–DNA conjugates as generic, noncovalent, and easily applicable molecular locks that allow the control of antibody activity using toehold‐mediated strand displacement reactions. Employing yeast as a cellular model system, reversible control of antibody targeting is demonstrated with low nM concentrations of peptide–DNA locks and oligonucleotide displacer strands. Introduction of two different toehold strands on the peptide–DNA lock allowed signal integration of two different inputs, yielding logic OR‐ and AND‐gates. The range of molecular inputs could be further extended to protein‐based triggers by using protein‐binding aptamers. 相似文献
DNA strand displacement is a technique to exchange one strand of a double stranded DNA by another strand (invader). It is an isothermal, enzyme free method driven by single stranded overhangs (toeholds) and is employed in DNA amplification, mismatch detection and nanotechnology. We discovered that anomeric (α/β) DNA can be used for heterochiral strand displacement. Homochiral DNA in β-D configuration was transformed to heterochiral DNA in α-D/β-D configuration and further to homochiral DNA with both strands in α-D configuration. Single stranded α-D DNA acts as invader. Herein, new anomeric displacement systems with and without toeholds were designed. Due to their resistance against enzymatic degradation, the systems are applicable to living cells. The light-up intercalator ethidium bromide is used as fluorescence sensor to follow the progress of displacement. Anomeric DNA displacement shows benefits over canonical DNA in view of toehold free displacement and simple detection by ethidium bromide. 相似文献
A simple, versatile, and label‐free DNA computing strategy was designed by using toehold‐mediated strand displacement and stem‐loop probes. A full set of logic gates (YES, NOT, OR, NAND, AND, INHIBIT, NOR, XOR, XNOR) and a two‐layer logic cascade were constructed. The probes contain a G‐quadruplex domain, which was blocked or unfolded through inputs initiating strand displacement and the obviously distinguishable light‐up fluorescent signal of G‐quadruplex/NMM complex was used as the output readout. The inputs are the disease‐specific nucleotide sequences with potential for clinic diagnosis. The developed versatile computing system based on our label‐free and modular strategy might be adapted in multi‐target diagnosis through DNA hybridization and aptamer‐target interaction. 相似文献
We demonstrate a method of heterogeneous vesicle binding using membrane-anchored, single-stranded DNA that can be used over several orders of magnitude in vesicle size, as demonstrated for large 100 nm vesicles and giant vesicles several microns in diameter. The aggregation behavior is studied for a range of DNA surface concentrations and solution ionic strengths. Three analogous states of aggregation are observed on both vesicle size scales. We explain the existence of these three regimes by a combination of DNA binding favorability, vesicle collision kinetics, and lateral diffusion of the DNA within the fluid membrane. The reversibility of the DNA hybridization allows dissociation of the structures formed and can be achieved either thermally or by a reduction in the ionic strength of the external aqueous environment. Difficulty is found in fully unbinding giant vesicles by thermal dehybridization, possibly frustrated by the attractive van der Waals minimum in the intermembrane potential when brought into close contact by DNA binding. This obstacle can be overcome by the isothermal reduction of the ionic strength of the solution: this reduces the Debye screening length, coupling the effects of DNA dehybridization and intermembrane repulsion due to the increased electrostatic repulsion between the highly charged DNA backbones. 相似文献
We report a generalizable strategy for biosensing that takes advantage of the resistance of DNA aptamers against nuclease digestion when bound with their targets, coupled with toehold mediated strand displacement (TMSD) and rolling circle amplification (RCA). A DNA aptamer containing a toehold extension at its 5′-end protects it from 3′-exonuclease digestion by phi29 DNA polymerase (phi29 DP) in a concentration-dependent manner. The protected aptamer can participate in RCA in the presence of a circular template that is designed to free the aptamer from its target via TMSD. The absence of the target leads to aptamer digestion, and thus no RCA product is produced, resulting in a turn-on sensor. Using two different DNA aptamers, we demonstrate rapid and quantitative real-time fluorescence detection of two human proteins: platelet-derived growth factor (PDGF) and thrombin. Sensitive detection of PDGF was also achieved in human serum and human plasma, demonstrating the selectivity of the assay. 相似文献
Catalyzed hairpin assembly (CHA) is a robust enzyme-free signal-amplification reaction that has a wide range of potential applications, especially in biosensing. Although most studies of the analytical applications of CHA have focused on the measurement of concentrations of biomolecules, we show here that CHA can also be used to probe the spatial organization of biomolecules such as single-stranded DNA. The basis of such detection is the fact that a DNA structure that brings a toehold and a branch-migration domain into close proximity can catalyze the CHA reaction. We quantitatively studied this phenomenon and applied it to the detection of domain reorganization that occurs during DNA self-assembly processes such as the hybridization chain reaction (HCR). We also show that CHA circuits can be designed to detect certain types of hybridization defects. This principle allowed us to develop a "signal on" assay that can simultaneously respond to multiple types of mutations in a DNA strand in one simple reaction, which is of great interest in genotyping and molecular diagnostics. These findings highlight the potential impacts of DNA circuitry on DNA nanotechnology and provide new tools for further development of these fields. 相似文献
We report an experimental study in which we compare the self-assembly of 1 mum colloids bridged through hybridization of complementary single-stranded DNA (ssDNA) strands (12 bp) attached to variable-length double-stranded DNA spacers that are grafted to the colloids. We considered three different spacer lengths: long spacers (48 500 bp), intermediate length spacers (7500 bp), and no spacers (in which case the ssDNA strands were directly grafted to the colloids). In all three cases, the same ssDNA pairs were used. However, confocal microscopy revealed that the aggregation behavior is very different. Upon cooling, the colloids coated with short and intermediate length DNAs undergo a phase transition to a dense amorphous phase that undergoes structural arrest shortly after percolation. In contrast, the colloids coated with the longest DNA systematically form finite-sized clusters. We speculate that the difference is due to the fact that very long DNA can easily be stretched by the amount needed to make only intracluster bonds, and in contrast, colloids coated with shorter DNA always contain free binding sites on the outside of a cluster. The grafting density of the DNA decreases strongly with increasing spacer length. This is reflected in a difference in the temperature dependence of the aggregates: for the two systems coated with long DNA, the resulting aggregates were stable against heating, whereas the colloids coated with ssDNA alone would dissociate upon heating. 相似文献
DNA three‐way junctions (DNA 3WJ) have been widely used as important building blocks for the construction of DNA architectures and dynamic assemblies. Herein, we describe for the first time a catalytic hairpin assembly‐programmed DNA three‐way junction (CHA‐3WJ) strategy for the enzyme‐free and amplified electrochemical detection of target DNA. It takes full advantage of the target‐catalyzed hairpin assembly‐induced proximity effect of toehold and branch‐migration domains for the ingenious execution of the strand displacement reaction to form the DNA 3WJ on the electrode surface. A low detection limit of 0.5 pM with an excellent selectivity was achieved for target DNA detection. The developed CHA‐3WJ strategy also offers distinct advantages of simplicity in probe design and biosensor fabrication, as well as enzyme‐free operation. Thus, it opens a promising avenue for applications in bioanalysis, design of DNA‐responsive devices, and dynamic DNA assemblies. 相似文献
We investigate how probe density influences hybridization for unlabeled target oligonucleotides that contain mismatched sequences or targets that access different binding locations on the immobilized probe. We find strong probe density effects influencing not only the efficiency of hybridization but also the kinetics of capture. Probe surfaces are used repeatedly, and the potentially large contributions of sample-to-sample variations in surface heterogeneity and nonspecific adsorption are addressed. Results of kinetic, equilibrium, and temperature-dependent studies, obtained using in-situ surface plasmon resonance (SPR) spectroscopy, show that hybridization for surface immobilized DNA is quite different from the well-studied solution-phase reaction. Surface hybridization depends strongly on the target sequence and probe density. Much of the data can be explained by the presence of steric crowding at high probe density; however, the behavior of mismatched sequences cannot be understood using standard models of hybridization even at the lowest density studied. In addition to unusual capture kinetics observed for the mismatched targets, we find that the binding isotherms can be fit only if a heterogeneous model is used. For mismatched targets, the Sips model adequately describes probe-target binding isotherms; for perfectly matched targets, the Langmuir model can be used. 相似文献
Morpholino (MO) is a neutral analogue of DNA, which shows promise in the development of DNA biosensors and diagnostic devices. The present study explores the hybridization process of a surface‐attached MO 22‐mer with 10‐mer and 20‐mer DNA targets on a gold electrode. The melting process of the MO‐DNA duplex at the electrode/buffer interface is recorded using cyclic voltammetry. These results show that the length of target DNA, the binding location of the target DNA on the surface‐immobilized MO chain, and electrostatic forces from neighbouring duplexes all modulate the stability and hybridization kinetics of the DNA targets with the MO probes. Melting temperatures for immobilized MO‐DNA duplexes are found to be insensitive to ionic strength, provided the duplexes do not have a linker. Although the melting temperature does not shift appreciably with ionic strength, the maximum hybridization yield does. This somewhat surprising observation is considered to originate from an electrostatic limit on the extent of attainable hybridization. It is also reported that hybridization tends to initiate at the upper half of MO probes. 相似文献
Spatial confinement, within cells or micro‐ and nanofabricated devices, impacts the conformation and binding kinetics of biomolecules. Understanding the role of spatial confinement on molecular behavior is important for comprehending diverse biological phenomena, as well as for designing biosensors. Specifically, the behavior of molecular binding under an applied electric field is of importance in the development of electrokinetic biosensors. Here, we investigate whether confinement of DNA oligomers in capillary electrophoresis impacts the binding kinetics of the DNA. To infer the role of confinement on hybridization dynamics, we perform capillary electrophoresis measurements on DNA oligomers within micro‐ and nanochannels, then apply first‐order reaction dynamics theory to extract kinetic parameters from electropherogram data. We find that the apparent dissociation constants at the nanoscale (i.e., within a 100 nm channel) are lower than at the microscale (i.e., within a 1 μm channel), indicating stronger binding with increased confinement. This confirms, for the first time, that confinement‐based enhancement of DNA hybridization persists under application of an electric field. 相似文献
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