Cloning DNA typically involves the joining of target DNAs with vector constructs by enzymatic ligation. A commonly used enzyme for this reaction is bacteriophage T4 DNA ligase, which requires ATP as the energy source to catalyze the otherwise unfavorable formation of a phosphodiester bond. Using in vitro selection, we have isolated a DNA sequence that catalyzes the ligation of DNA in the absence of protein enzymes. We have used the action of two catalytic DNAs, an ATP-dependent self-adenylating deoxyribozyme (AppDNA) and a self-ligating deoxyribozyme, to create a ligation system that covalently joins oligonucleotides via the formation of a 3',5'-phosphodiester linkage. The two-step process is conducted in separate reaction vessels wherein the products of deoxyribozyme adenylation are purified before their use as substrates for deoxyribozyme ligation. The final ligation step of the deoxyribozyme-catalyzed sequence of reactions mimics the final step of the T4 DNA ligase reaction. The initial rate constant (k(obs)) of the optimized deoxyribozyme ligase was found to be 1 x 10(-)(4) min(-)(1). Under these conditions, the ligase deoxyribozyme promotes DNA ligation at least 10(5)-fold faster than that generated by a simple DNA template. The self-ligating deoxyribozyme has also been reconfigured to generate a trans-acting construct that joins separate DNA oligonucleotides of defined sequence. However, the sequence requirements of the AppDNA and that of the 3' terminus of the deoxyribozyme ligase limit the range of sequences that can be ligated. 相似文献
We report the new method for detection of DNA hybridization using enzymatic cleavage. The strategy is based on that S1 nuclease is able to specifically cleave only single strand DNA, but not double strand DNA. The capture probe DNA, thiolated single strand DNA labeled with electroactive ferrocene group, was immobilized on a gold electrode. After hybridization of target DNA of complementary and noncomplementary sequences, nonhybridized single strand DNA was cleaved using S1 nuclease. The difference of enzymatic cleavage on the modified gold electrode was characterized by cyclic voltammetry and differential pulse voltammetry. We successfully applied this method to the sequence‐selective discrimination between perfectly matched and mismatched target DNA including a single‐base mismatched target DNA. Our method does not require either hybridization indicators or other exogenous signaling molecules which most of the electrochemical hybridization detection systems require. 相似文献
DNA hydrogels are of great interest for a variety of biomedical applications owing to their biocompatibility and biodegradability but the advantages of DNA hydrogels have not been exploited yet because of their limited availability. Thus far, DNA hydrogels have been prepared from synthetically derived building blocks, and their production on large scale would be far too expensive. As an alternative, here the generation of DNA hydrogels from plasmid DNA is reported. Plasmid DNA can be prepared on large scale at reasonable costs by a fermentation process. The desired linear DNA building blocks are then obtained from the plasmid DNA by enzymatic digestion. Gel formation is carried out by covalent bond formation between individual building blocks via enzymatic ligation. The generation of pristine DNA hydrogels from plasmid DNA is thus presented for the first time. The viscoelastic properties of the hydrogels were studied by rheology, which confirmed that the gels have storage moduli G′ of >100 Pa. 相似文献
DNA is currently explored as a new material for functional, molecular nano-architectures. In this respect, one major question is to transform DNA into a conducting material which has the potential for self-assembly into electronically active networks. The article covers recent insight into how DNA transports positive (holes) and negative (excess electrons) charges. It was found that holes move through DNA over significant distances using a G- and to a lesser extent also A-based hopping mechanism. EPR studies and recent investigations with model systems show that excess electrons can also hop through the duplex. The second part of the article describes how DNA is currently modified, particularly coated with metals, in order to increase the conductivity. 相似文献
Abstract Recently there has been an increasing demand to produce systems for the detection of specific DNA sequences that are amenable to non-specialised laboratories. This demand has led to many innovative and novel approaches to DNA analysis which may collectively be termed ′new DNA technology′. Here, we review these advances in relation to their applicability for the production of a DNA biosensor. The present state of the art is described and future possibilities are considered. 相似文献
Alternative DNA conformations are of particular interest as potential signals to mark important sites on the genome. The structural variability of CA microsatellites is particularly pronounced; these are repetitive poly(CA) · poly(TG) DNA sequences spread in all eukaryotic genomes as tracts of up to 60 base pairs long. Many in vitro studies have shown that the structure of poly(CA) · poly(TG) can vary markedly from the classical right handed DNA double helix and adopt diverse alternative conformations. Here we have studied the mechanism of formation and the structure of an alternative DNA structure, named Form X, which was observed previously by polyacrylamide gel electrophoresis of DNA fragments containing a tract of the CA microsatellite poly(CA) · poly(TG) but had not yet been characterized. 相似文献
The distinct base pairing property of DNA is an advantageous phenomenon that has been exploited in the usage of DNA as scaffold for directed self-organization to form nanometer-sized objects in a desirable fashion. Herein we report the construction of three-dimensional DNA-based networks that can be generated and amplified by the DNA polymerase chain reaction (PCR). The approach is flexible allowing tuning of the meshes of the network by variation of the size of the template. Additionally, further diversification can be introduced by employment of chemically modified nucleotides in PCR allowing the introduction of functionalities and reporter moieties. 相似文献
Determination of the sequence of DNA is one of the most important aspects of modern molecular biology. New sequencing methods currently being developed enable DNA sequence to be determined increasingly faster and more efficiently. One of the major advances in sequencing technology is the development of automated DNA sequencers. These utilize fluorescent rather than radioactive labels. A laser beam excites the fluorescent dyes, the emitted fluorescence is collected by detectors, and the information analyzed by computer. Robotic work stations are being developed to perform template preparation and purification, and the sequencing reactions themselves. Research is currently in progress to develop the technology of mass spectrometry for DNA sequencing. Success in this endeavor would mean that the gel electrophoresis step in DNA sequencing could be eliminated. A major innovation has been the application of polymerase chain reaction (PCR) technology to DNA sequence determination, which has led to the development of linear amplification sequencing (cycle sequencing). This very powerful yet technically simple method of sequencing has many advantages over conventional techniques, and may be used in manual or automated methods. Other recent innovations proposed recently to increase speed and efficiency include multiplex sequencing. This consists of pooling a number of samples and processing them as pools. After electrophoresis, the DNA is transferred to a membrane, and sequence images of the individual samples are obtained by sequential hybridizations with specific labeled oligonucleotides. Multiplex DNA sequencing has been used in conjunction with direct blotting electrophoresis to facilitate transfer of the DNA to a membrane. Chemiluminescent detection can also be used in conjunction with multiplex DNA sequencing to visualize the image on the membrane. 相似文献
Electrochemical DNA biosensors, based either on carbon paste electrode (CPE) or hanging mercury drop electrode (HMDE) were prepared. These biosensors were used in the study of interaction between double stranded DNA (dsDNA) and single stranded DNA (ssDNA) and acridine orange, a well known DNA intercalator. The different electrochemical behaviors were compared in the article. 相似文献
3'-S-Phosphorothiolate (3'-SP) linkages have been incorporated into the DNA strand of both a DNA.RNA duplex and a DNA.DNA duplex. Thermal melting (T(m)) studies established that this modification significantly stabilises the DNA.RNA duplex with an average increase in T(m) of about 1.4 degrees C per modification. For two or three modifications, the increase in T(m) was larger for an alternating, as compared to the contiguous, arrangement. For more than three modifications their arrangement had no effect on T(m). In contrast to the DNA.RNA duplex, the 3'-S-phosphorothiolate linkage destabilised the DNA.DNA duplex, irrespective of the arrangement of the 3'-SP linkages. The effect of ionic strength on duplex stability was similar for both the phosphorothiolate-substituted and the unmodified RNA.DNA duplexes. The results are discussed in terms of the influence that the sulfur atom has on the conformation of the furanose ring and comparisons are also drawn between the current study and those previously conducted with other modifications that have a similar conformational effect. 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.
A novel electrochemical assay for DNA ligase activity is described. The assay exploits the properties of DNA hairpins tethered at one terminus to a gold electrode and labelled at the other with a ferrocene group for rapid characterisation of DNA status by cyclic voltammetry. Successful ligation of 'nicked' DNA hairpins is indicated by retention of the ferrocene couple when exposure to DNA ligase is followed by conditions that denature the hairpin. The results demonstrate the simplicity of integrating electrochemical detection with hairpin based biosensors and illustrate a new approach to the assay of DNA ligases, of which the NAD(+)-dependent enzymes represent a potential broad spectrum antibacterial drug target. 相似文献
The advent of DNA origami technology greatly simplified the design and construction of nanometer-sized DNA objects. The self-assembly of a DNA-origami structure is a straightforward process in which a long single-stranded scaffold (often from the phage M13mp18) is folded into basically any desired shape with the help of a multitude of short helper strands. This approach enables the ready generation of objects with an addressable surface area of a few thousand nm(2) and with a single "pixel" resolution of about 6 nm. The process is rapid, puts low demands on experimental conditions, and delivers target products in high yields. These features make DNA origami the method of choice in structural DNA nanotechnology when two- and three-dimensional objects are desired. This Minireview summarizes recent advances in the design of DNA origami nanostructures, which open the door to numerous exciting applications. 相似文献
A new technique is proposed for detecting interactions between DNA and DNA autoimmune antibodies using a potentiometric sensor based on a glassy-carbon electrode modified with polyaniline and native DNA from chicken erythrocytes. It is shown that the DNA-antibody interaction changes the rate of polyaniline doping in transferring the DNA sensor from an alkaline (pH 7.5) solution, which is optimum for the immunochemical reaction, to an acidic (pH 3.0) solution. The dynamics of the variation of the DNA sensor potential depends on the titer of antibodies and their origin. The dependence of the DNA sensor signal on the dilution of the blood sera from systemic lupus erythematosus and autoimmune thyroiditis patients shows that DNA antibodies can be diagnosed by the characteristic maximum in the dilution curve found in the range of serum dilutions from 1: 20 to 1: 50. 相似文献
A novel and sensitive electrochemical DNA biosensor based on multi-walled carbon nanotubes functionalized with a carboxylic acid group (MWNTs-COOH) for covalent DNA immobilization and enhanced hybridization detection is described. The MWNTs-COOH-modified glassy carbon electrode (GCE) was fabricated and oligonucleotides with the 5'-amino group were covalently bonded to the carboxyl group of carbon nanotubes. The hybridization reaction on the electrode was monitored by differential pulse voltammetry (DPV) analysis using an electroactive intercalator daunomycin as an indicator. Compared with previous DNA sensors with oligonucleotides directly incorporated on carbon electrodes, this carbon nanotube-based assay with its large surface area and good charge-transport characteristics dramatically increased DNA attachment quantity and complementary DNA detection sensitivity. This is the first application of carbon nanotubes to the fabrication of an electrochemical DNA biosensor with a favorable performance for the rapid detection of specific hybridization. 相似文献
