Hybridization of single-stranded DNA targets to immobilized complementary DNA probes: comparison of hairpin versus linear capture probes

A microtiter-based assay system is described in which DNA hairpin probes with dangling ends and single-stranded, linear DNA probes were immobilized and compared based on their ability to capture single-strand target DNA. Hairpin probes consisted of a 16 bp duplex stem, linked by a T₂-biotin·dT-T₂ loop. The third base was a biotinylated uracil (U_B) necessary for coupling to avidin coated microtiter wells. The capture region of the hairpin was a 3′ dangling end composed of either 16 or 32 bases. Fundamental parameters of the system, such as probe density and avidin adsorption capacity of the plates were characterized. The target DNA consisted of 65 bases whose 3′ end was complementary to the dangling end of the hairpin or to the linear probe sequence. The assay system was employed to measure the time dependence and thermodynamic stability of target hybridization with hairpin and linear probes. Target molecules were labeled with either a 5′-FITC, or radiolabeled with [γ-³³P]ATP and captured by either linear or hairpin probes affixed to the solid support. Over the range of target concentrations from 10 to 640 pmol hybridization rates increased with increasing target concentration, but varied for the different probes examined. Hairpin probes displayed higher rates of hybridization and larger equilibrium amounts of captured targets than linear probes. At 25 and 45°C, rates of hybridization were better than twice as great for the hairpin compared with the linear capture probes. Hairpin–target complexes were also more thermodynamically stable. Binding free energies were evaluated from the observed equilibrium constants for complex formation. Results showed the order of stability of the probes to be: hairpins with 32 base dangling ends > hairpin probes with l6 base dangling ends > 16 base linear probes > 32 base linear probes. The physical characteristics of hairpins could offer substantial advantages as nucleic acid capture moieties in solid support based hybridization systems.     

Hybridization of DNA targets to glass-tethered oligonucleotide probes

Hybridization of nucleic acids to surface-tethered oligonucleotide probes has numerous potential applications in genome mapping and DNA sequence analysis. In this article, we describe a simple standard protocol for routine preparation of terminal amine-derivatized 9-mer oligonucleotide arrays on ordinary microscope slides and hybridization conditions with DNA target strands of up to several hundred bases in length with good discrimination against mismatches. Additional linker arms separating the glass surface from the probe sequence are not necessary. The technique described here offers a powerful tool for the detection of specific genetic mutations.     

Peptide nucleic acid (PNA) facilitates multistranded hybrid formation between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded DNA probes

RecA protein-coated single-stranded DNA probes, known as RecA nucleoprotein filaments, bind specifically to homologous DNA sequences within double-stranded DNA targets, forming multistranded probe-target DNA hybrids. This DNA hybridization reaction can be used for sequence-specific gene capture, gene modification, and gene regulation. Thus, factors that enhance the efficiency of the hybridization reaction are of significant practical importance. We show here that the hybridization of a peptide nucleic acid (PNA) within or adjacent to the probe-target homology region significantly enhances the yield of hybrid DNA formed in the reaction between linear double-stranded DNA targets and RecA protein-coated complementary single-stranded (css)DNA probes. The possible mechanisms and the advantages of using RecA nucleoprotein filaments in combination with PNA for genomic DNA cloning and mutagenesis are presented.     

An alternate method for synthesis of double-stranded DNA segments

Recent progress in the chemical synthesis of DNA has now made it possible to rapidly synthesize single-stranded DNAs over 40 bases in length. We have taken advantage of these longer DNAs in assembling and cloning a 132-base pair gene segment coding for amino acids 126 through the stop codon of human leukocyte interferon alpha 2. The method used involves DNA polymerase I-mediated repair synthesis of synthetic oligonucleotide substrates having short stretches of complementary sequence at their 3' termini. In the presence of DNA polymerase I and the four deoxyribonucleoside triphosphates, those primer-templates are converted to full length double-stranded DNAs. The economy in chemical synthesis using this approach is substantial with a greater than 40% reduction in the amount of chemical synthesis required as compared with the conventional approach. We describe in detail this methodology for the biochemical assembly of long gene segments from synthetic oligodeoxyribonucleotides.     

The biophysics of DNA hybridization with immobilized oligonucleotide probes.

A mathematical model based on receptor-ligand interactions at a cell surface has been modified and further developed to represent heterogeneous DNA-DNA hybridization on a solid surface. The immobilized DNA molecules with known sequences are called probes, and the DNA molecules in solution with unknown sequences are called targets in this model. Capture of the perfectly complementary target is modeled as a combined reaction-diffusion limited irreversible reaction. In the model, there are two different mechanisms by which targets can hybridize with the complementary probes: direct hybridization from the solution and hybridization by molecules that adsorb nonspecifically and then surface diffuse to the probe. The results indicate that nonspecific adsorption of single-stranded DNA on the surface and subsequent two-dimensional diffusion can significantly enhance the overall reaction rate. Heterogeneous hybridization depends strongly on the rate constants for DNA adsorption/desorption in the non-probe-covered regions of the surface, the two-dimensional (2D) diffusion coefficient, and the size of probes and targets. The model shows that the overall kinetics of DNA hybridization to DNA on a solid support may be an extremely efficient process for physically realistic 2D diffusion coefficients, target concentrations, and surface probe densities. The implication for design and operation of a DNA hybridization surface is that there is an optimal surface probe density when 2D diffusion occurs; values above that optimum do not increase the capture rate. Our model predicts capture rates in agreement with those from recent experimental literature. The results of our analysis predict that several things can be done to improve heterogeneous hybridization: 1) the solution phase target molecules should be about 100 bases or less in size to speed solution-phase and surface diffusion; 2) conditions should be created such that reversible adsorption and two-dimensional diffusion occur in the surface regions between DNA probe molecules; 3) provided that 2) is satisfied, one can achieve results with a sparse probe coverage that are equal to or better than those obtained with a surface totally covered with DNA probes.     

Simple and effective method for generating single-stranded DNA targets and probes

A simple and efficient PCR method was developed for generating dye- or radiolabeled single-stranded DNA targets or probes used for hybridization studies. The method involved the use of a pair of long primers with high annealing temperatures and a short, labeled primer with a low annealing temperature in a PCR consisting of two cycles at different temperatures. We used this method to generate dye Cy 5-labeled and [32P]-radiolabeled single-stranded DNA targets and probes. These labeled probes were used successfully for the microarray identification of point mutations in Mycobacterium tuberculosis genes and for the Northern blot detection of expression changes of the GATA-2 gene in Pneumocystis carinii-infected rat lungs.     

Tuning G-quadruplex vs double-stranded DNA recognition in regioisomeric lysyl-peptidyl-anthraquinone conjugates

Anthraquinone is a versatile scaffold to provide effective DNA binders. This planar system can be easily conjugated to protonable side chains: the nature of the lateral groups and their positions around the tricyclic moiety largely affect the DNA recognition process in terms of binding affinity and mode, as well as sequence and structure of the target nucleic acid. Starting from an anthracenedione system symmetrically functionalized with N-terminal lysyl residues, we incremented the length of side chains by introducing a Gly, Ala, or Phe spacer, characterized by different flexibility, lipophilicity, and bulkiness. Moreover, 2,6, 2,7, 1,8, and 1,5 regioisomers were examined to yield a small bis(lysyl-peptidyl) anthracenedione library. By merging spectroscopic, enzymatic, and cellular results, we showed that the proper combination of a basic aminoacid (Lys) with a more hydrophobic residue (Phe) can provide selective G-quadruplex recognition, in particular when side chains are located at positions 2,6 or 2,7. In fact, while these derivatives effectively bind G-quadruplex structures, they behave at the same time as rather poor double-stranded DNA intercalators. As a result, the Lys-Phe substituted anthraquinones are poorly cytotoxic but still able to promote a senescence mechanism in cancer cells. This combination of chemical and biological properties foresees potentially valuable applications in anticancer medicinal chemistry.     

DNA microarrays with unimolecular hairpin double-stranded DNA probes: fabrication and exploration of sequence-specific DNA/protein interactions

We have fabricated double-stranded DNA (dsDNA) microarrays containing unimolecular hairpin dsDNA probes immobilized on glass slides. The unimolecular hairpin dsDNA microarrays were manufactured by four steps: Firstly, synthesizing single-stranded DNA (ssDNA) oligonucleotides with two reverse-complementary sequences at 3' hydroxyl end and an overhang sequence at 5' amino end. Secondly, microspotting ssDNA on glutaraldehyde-derived glass slide to form ssDNA microarrays. Thirdly, annealing two reverse-complementary sequences to form hairpin primer at 3' end of immobilized ssDNA and thus to create partial-dsDNA microarray. Fourthly, enzymatically extending hairpin primer to convert partial-dsDNA microarrays into complete-dsDNA microarray. The excellent efficiency and high accuracy of the enzymatic synthesis were demonstrated by incorporation of fluorescently labeled dUTPs in Klenow extension and digestion of dsDNA microarrays with restriction endonuclease. The accessibility and specificity of the DNA-binding proteins binding to dsDNA microarrays were verified by binding Cy3-labeled NF-kappaB to dsDNA microarrays. The dsDNA microarrays have great potential to provide a high-throughput platform for investigation of sequence-specific DNA/protein interactions involved in gene expression regulation, restriction and so on.     

Mechanical properties of double-stranded DNA biolayers immobilized on microcantilever under axial compression

In label-free biodetections based on microcantilever technology, double-stranded DNA (dsDNA) structures form through the linkage between probe single-stranded DNA (ssDNA) molecules immobilized on solid substrates and target ssDNA molecules in solutions. Mechanical/electrical properties of these biolayers are important factors for nanomechanical deflections of microcantilevers. In this paper, the biolayer immobilized on microcantilever is treated as a bar with a macroscopic elastic modulus on the basis of continuum mechanics viewpoints. In consideration of hydration force, screened electrostatic repulsion and conformational fluctuation in biolayers, load-deformation curves of dsDNA biolayers under axial compression are depicted with the help of the energy conservation law and a mesoscopic free energy presented by Strey et al. (1997, 1999) [Strey, H.H., Parsegian, V.A., Podgornik, R., 1997. Equation of state for DNA liquid crystals: fluctuation enhanced electrostatic double layer repulsion. Physical Review Letters 78, 895–898; Strey, H.H., Parsegian, V.A., Podgornik, R., 1999. Equation of state for polymer liquid crystals: theory and experiment. Physical Review E 59, 999–1008] from a liquid crystal theory. And the analytical relation between macroscopic Young's modulus of biolayers and nanoscopic geometrical properties of dsDNA, packing density, buffer salt solution concentration, etc. is also formulated.     

Quantization of chloroplast DNA using dot blot filter hybridization with double-stranded probes

Summary Hybridization characteristics of purified chloroplast DNA, immobilized in dot blots on nitrocellulose filters using radiolabeled chloroplast DNA restriction fragments or recombinant DNA probes were investigated. Conditions are described which provide a near linear relationship between amounts of hybridization and amounts of immobilized DNA. A standard curve constructed using such data provided a simple means for quantizing specific chloroplast DNA sequences in partially purified total DNA from protoplast extracts. Using this technique, DNA sequences corresponding to about 0.01 % of the total immobilized DNA could be detected.     

Enzymatic collapse of artificial polymer composite material containing double-stranded DNA

Large amounts of DNA-enriched biomaterials, such as salmon milts and shellfish gonads, are discarded as industrial waste around the world. Therefore, the utilizations of DNA with the specific function are important for the biomaterial science and the curce technology. We could convert the discarded DNA to an enzymatic collapsible material by the addition of DNA to the artificial polymer material, such as nylon. Although these DNA-artificial polymer composite materials were stable in water, these materials indicated the collapsibility at the DNA-hydrolyzed enzyme, such as Micrococcal nuclease, condition. Additionally, these collapsibilities under enzyme condition were controlled by the number of imino groups in the components of the artificial polymer. Furthermore, these composite materials could create the fiber form with a highly ordered molecular orientation by the reaction at the liquid/liquid interface. The DNA-artificial polymer composite materials may have the potential utility as a novel bio-, medical-, and environmental materials with the enzymatic collapsibility and degradability.     

Transient kinetics measured with force steps discriminate between double-stranded DNA elongation and melting and define the reaction energetics

Under a tension of ∼65 pN, double-stranded DNA undergoes an overstretching transition from its basic (B-form) conformation to a 1.7 times longer conformation whose nature is only recently starting to be understood. Here we provide a structural and thermodynamic characterization of the transition by recording the length transient following force steps imposed on the λ-phage DNA with different melting degrees and temperatures (10–25°C). The shortening transient following a 20–35 pN force drop from the overstretching force shows a sequence of fast shortenings of double-stranded extended (S-form) segments and pauses owing to reannealing of melted segments. The lengthening transients following a 2–35 pN stretch to the overstretching force show the kinetics of a two-state reaction and indicate that the whole 70% extension is a B-S transition that precedes and is independent of melting. The temperature dependence of the lengthening transient shows that the entropic contribution to the B-S transition is one-third of the entropy change of thermal melting, reinforcing the evidence for a double-stranded S-form that maintains a significant fraction of the interstrand bonds. The cooperativity of the unitary elongation (22 bp) is independent of temperature, suggesting that structural factors, such as the nucleic acid sequence, control the transition.     

Hybridization of polyuridylic acid to human DNA immobilized onto nitrocellulose filters.

The level of deoxyadenylate (da) regions in human DNA was estimated from formation of poly(U)-poly(da) triplexes on nitrocellulose filters that were RNAase resistant. The (dA) rich sequences were determined following mild ribonuclease treatment of the poly(U)-DNA hybrids (5 mug/ml at 25 degreesC for 30 min), where as exhaustive ribonuclease treatment (5 mug/ml at 25 degrees C for 6 hr) estimated the more (dA) pure sequences. The level of (dA) rich regions was 0.39% of the DNA and for the more (dA) pure regions it was 0.07%. The (dA) regions were widely distributed throughout human DNA regardless of base composition or sequence repetition. However, a concentration of (dA) regions into main band CsC1 gradient fractions of DNA and into repeated DNA was observed.     

Hybridization of 2'-O-methyl and 2'-deoxy molecular beacons to RNA and DNA targets

Molecular beacons are stem–loop hairpin oligonucleotide probes labeled with a fluorescent dye at one end and a fluorescence quencher at the other end; they can differentiate between bound and unbound probes in homogeneous hybridization assays with a high signal-to-background ratio and enhanced specificity compared with linear oligonucleotide probes. However, in performing cellular imaging and quantification of gene expression, degradation of unmodified molecular beacons by endogenous nucleases can significantly limit the detection sensitivity, and results in fluorescence signals unrelated to probe/target hybridization. To substantially reduce nuclease degradation of molecular beacons, it is possible to protect the probe by substituting 2′-O-methyl RNA for DNA. Here we report the analysis of the thermodynamic and kinetic properties of 2′-O-methyl and 2′-deoxy molecular beacons in the presence of RNA and DNA targets. We found that in terms of molecular beacon/target duplex stability, 2′-O-methyl/RNA > 2′-deoxy/RNA > 2′-deoxy/DNA > 2′-O-methyl/DNA. The improved stability of the 2′-O-methyl/RNA duplex was accompanied by a slightly reduced specificity compared with the duplex of 2′-deoxy molecular beacons and RNA targets. However, the 2′-O-methyl molecular beacons hybridized to RNA more quickly than 2′-deoxy molecular beacons. For the pairs tested, the 2′-deoxy-beacon/DNA-target duplex showed the fastest hybridization kinetics. These findings have significant implications for the design and application of molecular beacons.     

Hybridization of 2'-O-methyl and 2'-deoxy molecular beacons to RNA and DNA targets

Molecular beacons are stem-loop hairpin oligonucleotide probes labeled with a fluorescent dye at one end and a fluorescence quencher at the other end; they can differentiate between bound and unbound probes in homogeneous hybridization assays with a high signal-to-background ratio and enhanced specificity compared with linear oligonucleotide probes. However, in performing cellular imaging and quantification of gene expression, degradation of unmodified molecular beacons by endogenous nucleases can significantly limit the detection sensitivity, and results in fluorescence signals unrelated to probe/target hybridization. To substantially reduce nuclease degradation of molecular beacons, it is possible to protect the probe by substituting 2'-O-methyl RNA for DNA. Here we report the analysis of the thermodynamic and kinetic properties of 2'-O-methyl and 2'-deoxy molecular beacons in the presence of RNA and DNA targets. We found that in terms of molecular beacon/target duplex stability, 2'-O-methyl/RNA > 2'-deoxy/RNA > 2'-deoxy/DNA > 2'-O-methyl/DNA. The improved stability of the 2'-O-methyl/RNA duplex was accompanied by a slightly reduced specificity compared with the duplex of 2'-deoxy molecular beacons and RNA targets. However, the 2'-O-methyl molecular beacons hybridized to RNA more quickly than 2'-deoxy molecular beacons. For the pairs tested, the 2'-deoxy-beacon/DNA-target duplex showed the fastest hybridization kinetics. These findings have significant implications for the design and application of molecular beacons.