PNA openers as a tool for direct quantification of specific targets in duplex DNA

Strand invasion of conventional PNA to arbitrary sequence in DNA assisted by single-stranded DNA binding protein

In the presence of single-stranded DNA binding protein (SSB), conventional peptide nucleic acid (PNA) without chemical modifications efficiently invades into arbitrary sequences in DNA.

Stem-loop oligonucleotides as tools for labelling double-stranded DNA

We report on a sequence-specific double-stranded DNA labelling strategy in which a stem-loop triplex forming oligonucleotide (TFO) is able to encircle its DNA target. Ligation of this TFO to either a short hairpin oligonucleotide or a long double-stranded DNA fragment leads to the formation of a topological complex. This process requires the hybridization of both extremities of the TFO to each other on a few base pairs. The effects of different factors on the formation of these complexes have been investigated. Efficient complex formation was observed using both GT or TC TFOs. The stem-loop structure enhances the specificity of the complex. The topologically linked TFO remains associated with its target even under conditions that do not favour triple-helix formation. This approach is sufficiently sensitive for detection of a 20-bp target sequence at the subfemtomolar level. This study provides new insights into the mechanics and properties of stem-loop TFOs and their complexes with double-stranded DNA targets. It emphasizes the interest of such molecules in the development of new tools for the specific labelling of short DNA sequences.

End invasion of peptide nucleic acids (PNAs) with mixed-base composition into linear DNA duplexes

Peptide nucleic acid (PNA) is a synthetic DNA mimic with valuable properties and a rapidly growing scope of applications. With the exception of recently introduced pseudocomplementary PNAs, binding of common PNA oligomers to target sites located inside linear double-stranded DNAs (dsDNAs) is essentially restricted to homopurine-homopyrimidine sequence motifs, which significantly hampers some of the PNA applications. Here, we suggest an approach to bypass this limitation of common PNAs. We demonstrate that PNA with mixed composition of ordinary nucleobases is capable of sequence-specific targeting of complementary dsDNA sites if they are located at the very termini of DNA duplex. We then show that such targeting makes it possible to perform capturing of designated dsDNA fragments via the DNA-bound biotinylated PNA as well as to signal the presence of a specific dsDNA sequence, in the case a PNA beacon is employed. We also examine the PNA-DNA conjugate and prove that it can initiate the primer-extension reaction starting from the duplex DNA termini when a DNA polymerase with the strand-displacement ability is used. We thus conclude that recognition of duplex DNA by mixed-base PNAs via the end invasion has a promising potential for site-specific and sequence-unrestricted DNA manipulation and detection.

Current two-dimensional electrophoresis technology for proteomics

Two-dimensional gel electrophoresis (2-DE) with immobilized pH gradients (IPGs) combined with protein identification by mass spectrometry (MS) is currently the workhorse for proteomics. In spite of promising alternative or complementary technologies (e.g. multidimensional protein identification technology, stable isotope labelling, protein or antibody arrays) that have emerged recently, 2-DE is currently the only technique that can be routinely applied for parallel quantitative expression profiling of large sets of complex protein mixtures such as whole cell lysates. 2-DE enables the separation of complex mixtures of proteins according to isoelectric point (pI), molecular mass (Mr), solubility, and relative abundance. Furthermore, it delivers a map of intact proteins, which reflects changes in protein expression level, isoforms or post-translational modifications. This is in contrast to liquid chromatography-tandem mass spectrometry based methods, which perform analysis on peptides, where Mr and pI information is lost, and where stable isotope labelling is required for quantitative analysis. Today's 2-DE technology with IPGs (Görg et al., Electrophoresis 2000, 21, 1037-1053), has overcome the former limitations of carrier ampholyte based 2-DE (O'Farrell, J. Biol. Chem. 1975, 250, 4007-4021) with respect to reproducibility, handling, resolution, and separation of very acidic and/or basic proteins. The development of IPGs between pH 2.5-12 has enabled the analysis of very alkaline proteins and the construction of the corresponding databases. Narrow-overlapping IPGs provide increased resolution (delta pI = 0.001) and, in combination with prefractionation methods, the detection of low abundance proteins. Depending on the gel size and pH gradient used, 2-DE can resolve more than 5000 proteins simultaneously (approximately 2000 proteins routinely), and detect and quantify < 1 ng of protein per spot. In this article we describe the current 2-DE/MS workflow including the following topics: sample preparation, protein solubilization, and prefractionation; protein separation by 2-DE with IPGs; protein detection and quantitation; computer assisted analysis of 2-DE patterns; protein identification and characterization by MS; two-dimensional protein databases.

Sequence-specific DNA strand cleavage by 111In-labeled peptide nucleic acids

Peptide nucleic acids (PNAs) bind tightly and sequence-specifically to single- and double-stranded nucleic acids, and are hence of interest in the design of gene-targeted radiotherapeutics that could deliver the radiodamage to designated DNA and/or RNA sites. As a first step towards this goal, we developed a procedure for incorporation of Auger electron-emitting radionuclide (indium-111) into PNA oligomers and studied the efficiency of PNA-directed cleavage of single-stranded DNA targets. Accordingly, diethylene triamine penta-acetic acid (DTPA) was conjugated to the lysine-appended mixed-base PNAs and sequence-homologous DNA oligomer with a proper linker for comparative studies. By chelation of PNA-DTPA and DNA-DTPA conjugates with (111)In(3+) in acidic aqueous solutions, (111)In-labeled PNA and DNA oligomers were obtained. Targeting of single-stranded DNA with PNA-DTPA-[(111)In] conjugates yielded highly localized DNA strand cleavage; the distribution of breaks along the target DNA strand has two maxima corresponding to both termini of PNA oligomer. After 10-14 days, the overall yield of breaks thus generated within the PNA-targeted DNA by (111)In decay was 5-7% versus < or =2% in the case of control oligonucleotide DNA-DTPA-[(111)In]. The estimated yield of DNA strand breaks per nuclear decay is ~0.1 for the PNA-directed delivery of (111)In, which is three times more than for the DNA-directed delivery of this radionuclide. This in vitro study shows that (111)In-labeled PNAs are much more effective than radiolabeled DNA oligonucleotides for site-specific damaging of DNA targets. Accordingly, we believe that PNA oligomers are promising radionuclide delivery tools for future antisense/antigene radiotherapy trials.

P-loop catalytically assisting the enzymatic cleavage of single-stranded DNA

We demonstrated that a P-loop, a looped complex formed inside duplex DNA by adding peptide nucleic acids (PNA), acts catalytically as a template for enzymatic cleavage of single-stranded probe oligodeoxynucleotides (ODN). A PD-loop complex formed from P-loop and probe ODN was digested efficiently by a restriction enzyme, and the truncated probe ODN was released. The P-loop nicked by the enzyme can form PD-loop again with another probe ODN, and then assisted the enzymatic cleavage of an excess of probe ODN. In addition, by using dumbbell-formed ODN as a probe ODN, the efficiency of the P-loop-assisted ODN cleavage was enhanced considerably as compared with that of linear ODN. Thus, the method utilizing P-loop will make it possible to amplify the sequence information of duplex DNA via a catalytic cleavage of probe ODNs.

Superior duplex DNA strand invasion by acridine conjugated peptide nucleic acids

DNA helix invasion by P-loop forming peptide nucleic acids (PNAs) is extremely sensitive to increased ionic strength as this stabilizes the DNA duplex. To address this, the DNA intercalator 9-aminoacridine was conjugated to helix invading PNAs, and the duplex DNA binding efficiency of such constructs was measured at different ionic strength conditions by electrophoretic mobility shift analysis. Remarkably, at physiogically relevant ionic strength (140 mM K+/10 mM Na+, 2 mM Mg2+), acridine conjugated PNAs showed 20-150-fold superior binding to a cognate sequence target as compared to the conventional PNAs. This enhancement occurred without compromising the sequence specificity of binding. Thus, simply conjugating the DNA intercalator 9-aminoacridine to PNA represents a major step toward the development of helix invading constructs for in vivo applications such as gene targeting.

Artificial site-specific DNA-nicking system based on common restriction enzyme assisted by PNA openers

We report on the peptide nucleic acid (PNA)-directed design of a DNA-nicking system that enables selective and quantitative cleavage of one strand of duplex DNA at a designated site, thus mimicking natural nickases and significantly extending their potential. This system exploits the ability of pyrimidine PNAs to serve as openers for specific DNA sites by invading the DNA duplex and exposing one DNA strand for oligonucleotide hybridization. The resultant secondary duplex can act as a substrate for a restriction enzyme, which ultimately creates a nick in the parent DNA. We demonstrate that several restriction enzymes of different types could be successfully used in the PNA-assisted system we developed. Importantly, the enzyme cleavage efficiency is basically not impaired on such artificially generated substrates, compared with the efficiency on regular DNA duplexes. Our design originates a vast class of semisynthetic rare-cleaving DNA nickases, which are essentially absent at present. In addition, we show that the site-specific PNA-assisted nicking of duplex DNA can be engaged in a rolling-circle DNA amplification (RCA) reaction. This new RCA format demonstrates the practical potential of the novel biomolecular tool we propose for DNA technology and DNA diagnostics.

Pausing of DNA polymerases on duplex DNA templates due to ligand binding in vitro

Using the recently developed peptide nucleic acid (PNA)-assisted assay, which makes it possible to extend a primer on duplex DNA, we study the sequence-specific inhibition of the DNA polymerase movement along double-stranded DNA templates imposed by DNA-binding ligands. To this end, a plasmid vector has been prepared featuring the polylinker with two flanking priming sites to bi-directionally initiate the primer-extension reactions towards each other. Within this plasmid, we have cloned a set of random DNA sequences and analyzed the products of these reactions with several phage and bacterial DNA polymerases capable of strand-displacement synthesis. Two of them, ø29 and modified T7 (Sequenase 2.0) enzymes, were found to be most potent for primer extension in the presence of DNA-binding ligands. We used these enzymes for a detailed study of ligand-induced pausing effects with four ligands differing in modes of binding to the DNA double-helix. GC-specific intercalator actinomycin D and three minor groove-binders, chromomycin A(3) (GC-specific), distamycin A and netropsin (both AT-specific), have been chosen. In the presence of each ligand both selected DNA polymerases experienced multiple clear-cut pauses. Each ligand yielded its own characteristic pausing pattern for a particular DNA sequence. The majority of pausing sites could be located with a single-nucleotide resolution and corresponded to the preferred binding sites known from the literature for the ligands under study. Besides, DNA polymerases stalled exactly at the positions occupied by PNA oligomers that were employed to initiate the primer extension. These findings provide an important insight into the DNA polymerase performance. In addition, the high-resolution ligand-induced pausing patterns we obtained for the first time for DNA polymerase elongation on duplex DNA may become a valuable addition to the existing arsenal of methods used to monitor duplex DNA interactions with various DNA-binding ligands, including drugs.

Monitoring of single nicks in duplex DNA by gel electrophoretic mobility-shift assay

We demonstrate that the gel electrophoretic mobility-shift assay (EMSA) can be used for site-selective and quantitative monitoring of nicks in linear double-stranded DNA (dsDNA) thus allowing to expediently follow the nicking activity of enzymes or other agents targeted to a designated dsDNA site. At elevated temperature and/or in the presence of urea, DNA fragments carrying a single nick produced by the nicking enzyme N.BstNBI exhibit a well-detectable gel retardation effect. On the basis of permutation analysis, the decreased electrophoretic mobility of nicked dsDNA fragments is attributed to a bend (or hinge) in the DNA double helix sequence-specifically generated by a nick. Since nick-induced DNA bending depends on interaction between base pairs adjacent to a nick, the change in mobility is different for nicked DNA sites with different sequences. Therefore, EMSA monitoring of differential mobility change caused by nicks within various DNA sequences could be useful for studying the differential base stacking and nearest-neighbor energetics.

Hybridization of DNA and PNA molecular beacons to single-stranded and double-stranded DNA targets

Molecular beacons are sensitive fluorescent probes hybridizing selectively to designated DNA and RNA targets. They have recently become practical tools for quantitative real-time monitoring of single-stranded nucleic acids. Here, we comparatively study the performance of a variety of such probes, stemless and stem-containing DNA and PNA (peptide nucleic acid) beacons, in Tris-buffer solutions containing various concentrations of NaCl and MgCl(2). We demonstrate that different molecular beacons respond differently to the change of salt concentration, which could be attributed to the differences in their backbones and constructions. We have found that the stemless PNA beacon hybridizes rapidly to the complementary oligodeoxynucleotide and is less sensitive than the DNA beacons to the change of salt thus allowing effective detection of nucleic acid targets under various conditions. Though we found stemless DNA beacons improper for diagnostic purposes due to high background fluorescence, we believe that use of these DNA and similar RNA constructs in molecular-biophysical studies may be helpful for analysis of conformational flexibility of single-stranded nucleic acids. With the aid of PNA "openers", molecular beacons were employed for the detection of a chosen target sequence directly in double-stranded DNA (dsDNA). Conditions are found where the stemless PNA beacon strongly discriminates the complementary versus mismatched dsDNA targets. Together with the insensitivity of PNA beacons to the presence of salt and DNA-binding/processing proteins, the latter results demonstrate the potential of these probes as robust tools for recognition of specific sequences within dsDNA without denaturation and deproteinization of duplex DNA.

PD-loop technology: PNA openers at work

A concise survey of the emerging PD-loop technology is presented, which outlines several exemplary methods with robust DNA diagnostic potential: duplex DNA capture, topological DNA labeling, nondenaturing DNA sequencing and hybridization of molecular beacons to double-stranded DNA. Advantages of these new PNA-based assays over existing techniques for sequence-specific detection and manipulation of DNA duplexes are discussed. Future prospects for the further development of PD-loop technology are highlighted.

PNA beacons for duplex DNA

We report here on the hybridization of peptide nucleic acid (PNA)-based molecular beacons (MB) directly to duplex DNA sites locally exposed by PNA openers. Two stemless PNA beacons were tested, both featuring the same recognition sequence and fluorophore-quencher pair (Fluorescein and DABCYL, respectively) but differing in arrangement of these groups and net electrostatic charge. It was found that one PNA beacon rapidly hybridized, with the aid of openers, to its complementary target within duplex DNA at ambient conditions via formation of a PD-like loop. In contrast, the other PNA beacon bound more slowly to preopened duplex DNA target and only at elevated temperatures, although it readily hybridized to single-stranded (ss) DNA target. Besides a higher selectivity of hybridization provided by site-specific PNA openers, we expect this approach to be very useful in those MB applications when denaturation of the duplex DNA analytes is unfavorable or undesirable. Furthermore, we show that PNA beacons are advantageous over DNA beacons for analyzing unpurified/nondeproteinized DNA samples. This feature of PNA beacons and our innovative hybridization strategy may find applications in emerging fluorescent DNA diagnostics.

An artificial primosome: design, function, and applications

Double-stranded (ds) DNA is capable of the sequence-specific accommodation of an additional oligodeoxyribonucleotide strand by the peptide nucleic acid(PNA)-assisted formation of a so-called PD-loop. We demonstrate here that the PD-loop may function as an artificial primosome within linear, nonsupercoiled DNA duplexes. DNA polymerase with its strand displacement activity uses this construct to initiate the primer extension reaction at a designated dsDNA site. The primer is extended by several hundred nucleotides. The efficiency of dsDNA priming by the artificial primosome assembly is comparable to the single-stranded DNA priming used in various assays. The ability of the PD-loop structure to perform like an artificial primosome on linear dsDNA may find applications in biochemistry, molecular biology, and molecular biotechnology, as well as for DNA diagnostics. In particular, multiple labels can be incorporated into a chosen dsDNA site resulting in ultrasensitive direct quantification of specific sequences. Furthermore, nondenaturing dsDNA sequencing proceeds from the PD-loop. This approach opens the way to direct isothermal reading of the DNA sequence against a background of unrelated DNA, thereby eliminating the need for purification of the target DNA.

Sequence-specific targeting of duplex DNA by peptide nucleic acids via triplex strand invasion

Because of a set of exceptional chemical, physical, and biological properties, polyamide or peptide nucleic acids (PNAs) hold a distinctive position among various synthetic ligands designed for DNA-targeting purposes. Cationic pyrimidine PNAs (cpyPNAs) represent a special group of PNAs, which effectively form strand invasion triplexes with double-stranded DNA (dsDNA) also known as P-loops. Extraordinary stability of the invasion triplexes and high sequence specificity of their formation combined with local opening of the DNA double helix within the P-loops make these complexes very attractive for sequence-specific manipulation with dsDNA. Important for applications is the fact that the discrimination between correct and mismatched binding sites in dsDNA by cpyPNAs is a nonequilibrium, kinetically controlled process. Therefore, a careful choice of experimental conditions that are optimal for the kinetic discrimination of correct versus mismatched cpyPNA binding is crucial for sequence-specific recognition of dsDNA by cpyPNAs. The experimental and theoretical data presented make it possible to select those solution parameters and cpyPNA constructions that are most favorable for sequence specificity without compromising the affinity of dsDNA targeting.

Peptide nucleic acid-assisted topological labeling of duplex dna

Peptide nucleic acids (PNAs) are a family of synthetic polyamide mimics of nucleic acids that offer a variety of applications. Pyrimidine bis-PNAs can be used for rational design of novel interlocked DNA nanostructures, earring labels, representing locked pseudorotaxanes or locked catenanes. These structures are created through DNA ligase-mediated catenation of duplex DNA with a circularized oligonucleotide tag at a designated DNA site. The assembly is performed via formation of the PD-loop consisting of a pair of bis-PNA openers and the probe oligonucleotide. The openers locally expose one of the two strands of duplex DNA for hybridizing the probe, whose termini are complementary to the displaced DNA strand. After hybridization, they are in juxtaposition and can subsequently be linked by DNA ligase. As a result, a true topological link forms at a precise position on the DNA double helix yielding locked, earring-like label. DNA topological labeling can be done both in solution and, for longer templates, within the agarose gel plug. Accordingly, highly localized DNA detection with rolling circle amplification of hybridization signal and effective micromanipulations with DNA duplexes become possible through precise spatial positioning of various ligands on the DNA scaffold.

Peptide nucleic acid: a versatile tool in genetic diagnostics and molecular biology

During the past ten years, the DNA mimic peptide nucleic acid has inspired the development of a variety of hybridisation-based methods for detection, quantification, purification and characterisation of nucleic acids. Most of these methods have taken advantage of the very favourable DNA and RNA hybridisation properties of peptide nucleic acids combined with the unique properties and opportunities offered by peptide chemistry. Within the past year, significant progress in in situ hybridisation technology has been achieved, which has resulted, in particular, in reliable and sensitive methods for detection of bacteria in clinical samples, as well as in environmental samples. Furthermore, applications of the polymerase chain reaction clamping method have been expanded, and novel ways of exploiting complexes of peptide nucleic acids with double-stranded DNA, such as double duplex invasion complexes and PD loops, have been developed.