Quantitative detection of single DNA molecules on DNA tetrahedron decorated substrates

A single DNA molecule detection method on DNA tetrahedron decorated substrates has been developed. DNA tetrahedra were introduced onto substrates for both preventing nonspecific adsorption and sensitive recognition of single DNA molecules.     

Compaction dynamics of single DNA molecules under tension

Using transverse magnetic tweezers, we studied the dynamics of DNA compaction induced by hexaammine cobalt chloride under constant forces. Discontinuous DNA compaction events were found for forces ranging from 0.5 to 1.7 pN, with approximately 270 nm DNA adsorbed in each compaction event. Forces larger than 6 pN were found able to unravel the toroid in a similar intermittent stepwise manner. The observations indicate that the folding/unfolding events are transitions between two metastable structural states which are separated by a tension-dependent energy barrier. Analysis of the waiting time revealed that the degree of the package ordering of DNA in a toroid depends on the compaction kinetics.     

Nanofluidic system for the studies of single DNA molecules

Here, we describe a simple and low-cost lithographic technique to fabricate size-controllable nanopillar arrays inside the microfluidic channels for the studies of single DNA molecules. In this approach, nanosphere lithography has been employed to grow a single layer of well-ordered close-packed colloidal crystals inside the microfluidic channels. The size of the polymeric colloidal nanoparticles could be trimmed by oxygen plasma treatment. These size-trimmed colloidal nanoparticles were then used as the etching mask in a deep etching process. As a result, well-ordered size-controllable nanopillar arrays could be fabricated inside the microfluidic channels. The gap distance between the nanopillars could be tuned between 20 and 80 nm allowing the formation of nanofluidic system where the behavior of a single lambda-phage DNA molecule has been investigated. It was found that the lambda-phage DNA molecule could be fully stretched in the nanofluidic system formed by nanopillars with 50 nm gap distance at a field of 50 V/cm.     

Electrophoretic manipulation of single DNA molecules in nanofabricated capillaries

We demonstrate the use of nanofabricated capillaries, integrated as part of a microfluidic structure, to study the electrophoretic behaviour of single, fluorescently-labelled, molecules of DNA as a function of capillary size. The nanocapillaries, fabricated using a focused ion beam, have cross-sections down to 150 x 180 nm. Control of single-molecule direction and velocity was achieved using voltage manipulation. DNA mobility was found to increase with decreasing cross-section, which we interpret in terms of reduced electro-osmotic counter-flow. Such nanofabricated capillaries as part of larger fluidic structures have great potential for biotechnology, particularly single molecule manipulation and analysis.     

Label-free "digital detection" of single-molecule DNA hybridization with a single electron transistor

Here we present a novel assay that eliminates fluorescent labels and enables "digital detection" of single-molecule DNA hybridization in complex matrixes with greatly simplified protocols. Electronic coupling of the binding state of a single oligonucleotide to the quantum dot (QD) of a single electron transistor (SET) affords direct observation of binding events in real-time via "molecular gating". The change of electrostatic charge associated with the molecular capture is used in lieu of a gate electrode to modulate the SET conductivity. Target oligos containing base mismatches do not elicit SET response under 0.1X SSC at room temperature nor do changes in ionic strength or pH. Furthermore, hybridization is detected even in optically inaccessible matrixes such as serum or quanidinium thiocyanate lysis buffer.     

An ultra-sensitive DNA assay based on single-molecule detection coupled with hybridization accumulation and its application

An ultra-sensitive assay for quantification of DNA based on single-molecule detection coupled with hybridization accumulation was developed. In this assay, target DNA (tDNA) in solution was accumulated on a silanized substrate blocked with ethanolamine and bovine serum albumin (BSA) through a hybridization reaction between tDNA and capture DNA immobilized on the substrate. The tDNA on the substrate was labeled with quantum dots which had been modified with detection DNA and blocked with BSA. The fluorescence image of single QD-labeled tDNA molecules on the substrate was acquired using total internal reflection fluorescence microscopy. The tDNA was quantified by counting the bright dots on the image from the QDs. The limit of detection of the DNA assay was as low as 6.4 × 10(-18) mol L(-1). Due to the ultra-high sensitivity, the DNA assay was applied to measure the beta-2-microglobulin messenger RNA level in single human breast cancer cells without a need for PCR amplification.     

Trajectory analysis of single molecules exhibiting non-brownian motion

Four techniques for analyzing single molecule tracking data--confinement level analysis, time series analysis and statistical analysis of lateral diffusion, multistate kinetics, and a newly developed method, radius of gyration evolution analysis--are compared using a set of sample fluorophore trajectories obtained from the lipophilic carbocyanine dye 1,1'-dioctadecyl-3,3,3'3'-tetramethylindocarbocyanine, DiIC(18), partitioned into surface tethered poly(n-isopropylacrylamide). The purpose here is two-fold: first to test that these techniques can be applied to single molecules trajectories, which typically contain a smaller total number of frames than those obtained from other particles, e.g. quantum dots or gold nanoparticles; and second to critically compare the information obtained from each method against the others. A set of five SMT trajectories, ranging in length from 41 to 273 steps with a 30 ms frame transfer exposure, were all successfully analyzed by all four techniques, provided two important criteria were met: enough steps to define the motion were acquired in the trajectory, generally on the order of 50 steps, and the fast and slow diffusion coefficients differ by at least a factor of 5. Beyond that the four trajectory analysis methods studied provide partially confirmatory and partially complementary information. SMT data resulting from more complex physical behavior may well benefit from using these techniques in succession to identify and sort populations.     

Analytical assays based on detecting conformational changes of single molecules.

One common strategy for the detection of biomolecules is labeling either the target itself or an antibody that binds to it. Herein, a different approach, based on detecting the conformational change of a probe molecule induced by binding of the target is discussed. That is, what is being detected is not the presence of the target or the probe, but the conformational change of the probe. Recently, a single-molecule sensor has been developed that exploits this mechanism to detect hybridization of a single DNA oligomer to a DNA probe, as well as specific binding of a single protein to a DNA probe. Biomolecular recognition often involves large conformational changes of the molecules involved, and therefore this strategy may be applicable to other assays.     

Motion of single long DNA molecules through arrays of magnetic columns

We present a videomicroscopy study of T4 DNA (169 kbp) in microfluidic arrays of posts formed by the self-assembly of magnetic beads. We observe DNA moving through an area of 10 000 microm(2), typically containing 100-600 posts. We determine the distribution of the contact times with the posts and the distribution of passage times across the field of view for hundreds of DNA per experiment. The contact time is well approximated by a Poisson process, scaling like the inverse of the field strength, independent of the density of the array. The distribution of passage times allows us to estimate the mean velocity and dispersivity of the DNA during its motion over distances long compared to our field of view. We compare these values with those computed from a lattice Monte Carlo model and geometration theory. We find reasonable quantitative agreement between the lattice Monte Carlo model and experiment, with the error increasing with increasing post density. The deviation between theory and experiment is attributed to the high mobility of DNA after disengaging from the posts, which leads to a difference between the contact time and the total time lost by colliding. Classical geometration theory furnishes surprisingly good agreement for the dispersivity, while geometration theory with a mean free path significantly overestimates the dispersivity.     

Electrochemical single-molecule conductivity of duplex and quadruplex DNA

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Adsorption of single DNA molecules at the water/fused-silica interface

We applied total internal reflection fluorescence microscopy (TIRFM) to study intermolecular interactions at the water/fused-silica interface at the single-molecule level. Real-time molecular motion at the interface was recorded to reveal adsorption behavior and conformational dynamics of three DNAs with sticky ends of different numbers of unpaired bases. Features of DNA motion at the interface, such as evanescent-field residence time, linear velocity and frequency of adsorption/desorption events were measured to assess the relative affinities of the oligonucleotides for the surface. The general trend of stronger interaction with the surface for longer sticky ends confirmed hydrophobic interaction and hydrogen bonding as the driving forces of DNA adsorption to fused-silica at pH 5. For DNAs of different sizes, different conformational dynamics and the accessibility of sticky ends give rise to a nonlinear relationship with respect to affinity. Such information may prove valuable for chromatography studies as well as for the design of DNA microarrays and drug delivery systems.     

Sequence-specific single-molecule analysis of 8-oxo-7,8-dihydroguanine lesions in DNA based on unzipping kinetics of complementary probes in ion channel recordings

Translocation measurements of intact DNA strands with the ion channel α-hemolysin (α-HL) are limited to single-stranded DNA (ssDNA) experiments as the dimensions of the channel prevent double-stranded DNA (dsDNA) translocation; however, if a short oligodeoxynucleotide is used to interrogate a longer ssDNA strand, it is possible to unzip the duplex region when it is captured in the α-HL vestibule, allowing the longer strand to translocate through the α-HL channel. This unzipping process has a characteristic duration based on the stability of the duplex. Here, ion channel recordings are used to detect the presence and relative location of the oxidized damage site 8-oxo-7,8-dihydroguanine (OG) in a sequence-specific manner. OG engages in base pairing to C or A with unique stabilities relative to native base Watson-Crick pairings, and this phenomenon is used here to engineer probe sequences (10-15mers) that, when base-paired with a 65mer sequence of interest, containing either G or OG at a single site, produce characteristic unzipping times that correspond well with the duplex melting temperature (T(m)). Unzipping times also depend on the direction from which the duplex enters the vestibule if the stabilities of leading base pairs at the ends of the duplex are significantly different. It is shown here that the presence of a single DNA lesion can be distinguished from an undamaged sequence and that the relative location of the damage site can be determined based on the duration of duplex unzipping.     

An integrated system for enzymatic cleavage and electrostretching of freely-suspended single DNA molecules

A novel polyacrylamide gel-based femtolitre microchamber system for performing single-molecule restriction enzyme assay on freely-suspended DNA molecules and subsequent DNA electrostretching by applying an alternating electric field has been developed. We attempted the integration by firstly initiating restriction enzyme reaction on a fluorescent-stained lambdaDNA molecule, encapsulated in a microchamber, using magnesium as an external trigger. Upon complete digestion, the cleaved DNA fragments were electrostretched to analyze the DNA lengths optically. The critical parameters for electrostretching of encapsulated DNA were investigated and optimum stretching was achieved by using 1.5 kHz pulses with electric field strength in the order of 10(3) V cm(-1) in 7% linear polyacrylamide (LPA) solution. LPA was adopted to minimize the adverse effects of ionic thermal agitation on molecular dielectrophoretic elongation in the microchamber. In our experiments, as the fragments were not immobilized throughout the entire protocol, it was found from repeated tests that digestion always occurred, producing the expected number of cleaved fragments. This versatile microchamber approach realized direct observation of these biological reactions on real-time basis at a single-molecule level. Furthermore, with the employment of porous polyacrylamide gel, the effective manipulation of DNA assays and the ability to combine conventionally independent bioanalytical processes have been demonstrated.     

Processive replication of single DNA molecules in a nanopore catalyzed by phi29 DNA polymerase

Coupling nucleic acid processing enzymes to nanoscale pores allows controlled movement of individual DNA or RNA strands that is reported as an ionic current/time series. Hundreds of individual enzyme complexes can be examined in single-file order at high bandwidth and spatial resolution. The bacteriophage phi29 DNA polymerase (phi29 DNAP) is an attractive candidate for this technology, due to its remarkable processivity and high affinity for DNA substrates. Here we show that phi29 DNAP-DNA complexes are stable when captured in an electric field across the α-hemolysin nanopore. DNA substrates were activated for replication at the nanopore orifice by exploiting the 3'-5' exonuclease activity of wild-type phi29 DNAP to excise a 3'-H terminal residue, yielding a primer strand 3'-OH. In the presence of deoxynucleoside triphosphates, DNA synthesis was initiated, allowing real-time detection of numerous sequential nucleotide additions that was limited only by DNA template length. Translocation of phi29 DNAP along DNA substrates was observed in real time at ?ngstrom-scale precision as the template strand was drawn through the nanopore lumen during replication.     

Photobleaching of asymmetric cyanines used for fluorescence imaging of single DNA molecules

The photobleaching of the cyanine dyes YO and YOYO has been investigated for both free and DNA-bound dyes, using absorption and fluorescence spectroscopy coupled with fluorescence microscopy. For the free dyes, the nature of the reactive species involved in the photodegradation process is different for the monomer and the dimer, as shown by scavenger studies. For DNA-bound dyes, photoinduced fading of the visible absorption band occurs by different pathways depending on the drug binding mode and can be attenuated by appropriate scavengers. However, none of these scavengers were found to have any significant effect on the photobleaching of dye fluorescence. It appears that the reduction of fluorescence intensity comes from a quenching of the dye fluorescence by modified DNA bases, possibly 8-oxo-7,8-dihydro-2'-deoxyguanosine.     

Stretching of single DNA molecules complexed with restriction endonuclease by Langmuir-Blodgett method

We have proposed a new technique for stretching single double-stranded DNA molecules on solid substrates by the Langmuir–Blodgett (LB) method. The polyion complex monolayer of a cationic amphiphile and DNA molecules formed at the air–water interface was transferred on a clean glass substrate. Vertical lifting up of the glass substrate provided the transferred monolayer consisting the stretched individual DNA molecules aligned parallel to the lifting direction on the glass. The DNA molecules complexed with the restriction endonuclease (EcoRI) were employed for stretching by using this method. Fluorescence images of the transferred monolayer showed that the EcoRI-binding DNA molecules could be stretched and immobilized on the glass substrate. A specific sequence of DNA recognized by EcoRI was detected as spatial positions of the stretched DNA molecules.