Hybridization and Melting Behavior of Peptide Nucleic Acid (PNA) Oligonucleotide Chimeras Conjugated to Gold Nanoparticles

Peptide nucleic acids (PNA) and PNA–DNA chimeras carrying thiol groups were used for surface functionalization of Au nanoparticles. Conjugation of PNA to citrate‐stabilized Au nanoparticles destabilized the nanoparticles causing them to precipitate. Addition of a tail of glutamic acid to the PNA prevented destabilization of the nanoparticles but resulted in loss of interaction with complementary sequences. Importantly, PNA–DNA chimeras gave stable conjugates with Au nanoparticles. The hybridization and melting properties of complexes formed from chimera–nanoparticle conjugates and oligonucleotide–nanoparticle conjugates are described for the first time. Similar to oligonucleotide–nanoparticle conjugates, conjugates with PNA–DNA chimeras gave sharper and more‐defined melting profiles than those obtained with unmodified oligonucleotides. In addition, mismatch discrimination was found to be more efficient than with unmodified oligonucleotides.     

New synthesis of a spin-labeled peptide nucleic acid and its interactions with nucleic acids

A new combined solid-liquid phase synthesis method for a spin labeled peptide nucleic acid (PNA) is developed. The methodology involved initial preparation of a protected PNA on solid phase, followed by efficient solution phase coupling to a spin label containing a reactive carboxylic group. This strategy allows to maintain the integrity of the nitroxide moiety during the various steps of chemical synthesis assuring in the same time the fidelity of the hybridization assay. This compound can be used as a reporter molecule to investigate the binding of peptide nucleic acids to oligonucleotide sequences (DNA or RNA) by EPR spectroscopy.     

PNA探针与DNA探针的系统比较

肽核酸（Peptide Nucleic Acid,PNA）是近十几年发展起来的以中性酰胺键为骨架的脱氧核糖核酸（Deoxyribonucleic Acid,DNA）类似物,其结构介于多肽和DNA之间。由于PNA能够与DNA和RNA特异性地结合,可以制备PNA探针。与DNA探针相比,其杂交的稳定性和特异性增加且能在低盐浓度下进行杂交。本文从DNA和PNA的分子结构和性质、DNA探针和PNA探针的设计制备、杂交亲和性、杂交动力学以及在生物传感器上的应用等方面进行了系统比较。     

Sequence Specific Electrochemical DNA Detection Based on Solution‐Phase Competitive Hybridization

We report a novel electrochemical method for detecting sequence‐specific DNA based on competitive hybridization that occurs in a homogeneous solution phase instead of on a solution‐electrode interface as in previously reported competition‐based electrochemical DNA detection schemes. The method utilizes the competition between the target DNA (t‐DNA) and a ferrocene‐labeled peptide nucleic acid probe (Fc‐PNA) to hybridize with a probe DNA (p‐DNA) in solution. The neutral PNA backbone and the electrostatic repulsion between the negatively‐charged DNA backbone and the negatively‐charged electrode surface are then exploited to determine the result of the competition through measurement of the electrochemical signal of Fc. Upon the introduction of the t‐DNA, the stronger hybridization affinity between the t‐DNA and p‐DNA releases the Fc‐PNA from the Fc‐PNA/p‐DNA hybrid, allowing it to freely diffuse to the negatively charged electrode to produce a significantly enhanced electrochemical signal of Fc. Therefore, the presence of the t‐DNA is indicated by the appearance or enhancement of the electrochemical signal, rendering a signal‐on DNA detection, which is less susceptible to false positive and can produce more reliable results than signal‐off detection methods. All the competitive hybridizations occur in a homogeneous solution phase, resulting in very high hybridization efficiency and therefore extremely short assay time. This simple and fast signal‐on solution‐competition‐based electrochemical DNA detection strategy has promising potential to find application in fields such as nucleic acid‐based point‐of‐care testing.     

Oligonucleotide fingerprinting with (CAC)5: nonradioactive in-gel hybridization and isolation of individual hypervariable loci

The first topic to be treated in this paper is the nonradioactive DNA fingerprinting by means of in-gel hybridization with digoxigenated (CAC)5. Besides the fact that time-consuming Southern blotting can be avoided, the dried agarose is an excellent matrix to produce background-free nonradioactive DNA fingerprints. There is no tendency of either the oligonucleotide probe or the antibody towards unspecific binding to the dried agarose. Prehybridization and blocking steps are therefore superfluous. Furthermore, we will discuss what effect the degree of crosslinking of the antibody-enzyme conjugates has. The second topic concerns the isolation and characterization of locus-specific probes from a human (CAC)5 fingerprint. The isolation and characterization of one variable probe, by screening complete genomic libraries, is described and discussed. This probe is compared to a hypervariable single-copy probe, isolated from a size-enriched genomic library. The sequence of the repeat flanking locus-specific probe is presented and a semi-specific, adaptor-mediated polymerase chain reaction was designed to amplify (CAC)n/(GTG)n flanking sequences.     

Kinetic discrimination in recognition of DNA quadruplex targets by guanine-rich heteroquadruplex-forming PNA probes

Guanine-rich peptide nucleic acid probes hybridize to DNA G quadruplex targets with high affinity, forming PNA-DNA heteroquadruplexes. We report a surprising degree of kinetic discrimination for PNA heteroquadruplex formation with a series of DNA targets. The fastest hybridization is observed for targets folded into parallel morphologies.     

Paramagnetic Particles and PNA Probe for Automated Separation and Electrochemical Detection of Influenza

Considerable efforts have been devoted to the development of rapid and sensitive methods allowing the detection of viral nucleic acid. We herein describe an assay for identification of a specific influenza sequence. The suggested method was based on isolation using paramagnetic particles coupled with electrochemical detection of isolated product. Peptide nucleic acid (PNA) was used as a probe for hybridization and identification of the influenza-derived specific sequence. The use of PNA can show numerous benefits: PNA probe is not degradable by enzymes and the duplex of PNA with RNA/DNA is more thermostable and more resistant to pH changes than DNA/DNA or RNA/RNA duplexes. This PNA probe assay can be applied as a magnetically guidable tool for detection of DNA/RNA samples under different conditions.     

Rapid Synthesis of Propargyl-γ-Modified Peptide Nucleic Acid Monomers for Late-Stage Functionalization of Oligomers

The exceptional hybridization properties of peptide nucleic acids (PNAs) coupled with the ease of their synthesis has made this artificial nucleic acid mimetic a desirable platform for diagnostics, therapeutics and supramolecular engineering. PNA backbone modifications have been extensively explored to finetune physicochemical properties and for conjugation of functional molecules. Here, we detail the synthesis of a universal γ-propargyl-PNA backbone from serine, and its acylation with the four DNA canonical nucleobases. The availability of serine as d or l enantiomer provide simple accesses to PNA oligomers for hybridization with natural oligonucleotides or for orthogonal hybridization circuitry. We show that late-stage conjugation enables optimization of the physicochemical properties. This approach is appealing due to its orthogonality to Fmoc-SPPS, its flexibility and ease for introducing diversity by on-resin copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC). We exemplified the utility of these novel monomers with PNA based hybridization chain reactions (HCRs).     

Nucleic acid-based fluorescent probes and their analytical potential

It is well known that nucleic acids play an essential role in living organisms because they store and transmit genetic information and use that information to direct the synthesis of proteins. However, less is known about the ability of nucleic acids to bind specific ligands and the application of oligonucleotides as molecular probes or biosensors. Oligonucleotide probes are single-stranded nucleic acid fragments that can be tailored to have high specificity and affinity for different targets including nucleic acids, proteins, small molecules, and ions. One can divide oligonucleotide-based probes into two main categories: hybridization probes that are based on the formation of complementary base-pairs, and aptamer probes that exploit selective recognition of nonnucleic acid analytes and may be compared with immunosensors. Design and construction of hybridization and aptamer probes are similar. Typically, oligonucleotide (DNA, RNA) with predefined base sequence and length is modified by covalent attachment of reporter groups (one or more fluorophores in fluorescence-based probes). The fluorescent labels act as transducers that transform biorecognition (hybridization, ligand binding) into a fluorescence signal. Fluorescent labels have several advantages, for example high sensitivity and multiple transduction approaches (fluorescence quenching or enhancement, fluorescence anisotropy, fluorescence lifetime, fluorescence resonance energy transfer (FRET), and excimer-monomer light switching). These multiple signaling options combined with the design flexibility of the recognition element (DNA, RNA, PNA, LNA) and various labeling strategies contribute to development of numerous selective and sensitive bioassays. This review covers fundamentals of the design and engineering of oligonucleotide probes, describes typical construction approaches, and discusses examples of probes used both in hybridization studies and in aptamer-based assays.     

Hybridization of PNA to structured DNA targets: quadruplex invasion and the overhang effect

Peptide nucleic acid (PNA) probes have been synthesized and targeted to quadruplex DNA. UV-vis and CD spectroscopy reveal that the quadruplex structure of the thrombin binding aptamer (TBA) is disrupted at 37 degrees C by a short PNA probe. The corresponding DNA probe fails to bind to the stable secondary structure at this temperature. Thermal denaturation experiments indicate surprisingly high thermal and thermodynamic stabilities for the PNA-TBA hybrid. Our results point to the nonbonded nucleobase overhangs on the DNA as being responsible for this stability. This "overhang effect" is found for two different PNA-DNA sequences and a variety of different overhang lengths and sequences. The stabilization offered by the overhangs assists the PNA in overcoming the stable secondary structure of the DNA target, an effect which may be significant in the targeting of biological nucleic acids, which will always be much longer than the PNA probe. The ability of PNA to invade a structured DNA target expands its potential utility as an antigene agent or hybridization probe.     

Paramagnetic Particles and PNA Probe for Automated Separation and Electrochemical Detection of Influenza

Considerable efforts have been devoted to the development of rapid and sensitive methods allowing the detection of viral nucleic acid. We herein describe an assay for identification of a specific influenza sequence. The suggested method was based on isolation using paramagnetic particles coupled with electrochemical detection of isolated product. Peptide nucleic acid (PNA) was used as a probe for hybridization and identification of the influenza-derived specific sequence. The use of PNA can show numerous benefits: PNA probe is not degradable by enzymes and the duplex of PNA with RNA/DNA is more thermostable and more resistant to pH changes than DNA/DNA or RNA/RNA duplexes. This PNA probe assay can be applied as a magnetically guidable tool for detection of DNA/RNA samples under different conditions.

     

Use of peptide nucleic acid probes for detecting DNA single-base mutations by capillary electrophoresis

Peptide nucleic acid (PNA) oligomers can be used as probes in pre-gel hybridization experiments, as an alternative to Southern hybridization. In this technique, the PNA probe is hybridized to a cyanine-5 labeled DNA sample denatured at low ionic strength, and the mixture is directly injected for size separation into a capillary electrophoresis (CE) system equipped with laser-induced fluorescence (LIF) detector. The neutral backbone of PNA allows hybridization to occur at low ionic strength and assures an efficient CE separation of the PNA/DNA hybrids from both double-stranded and single-stranded DNA. We have used as a model system the cystic fibrosis R553X and R1162X single-base mutations and we have assessed the influence of various factors, such as temperature and denaturants concentration on DNA/PNA hybrid stability in order to achieve the high specificity required for a single base pair discrimination.     

Synthesis of a PNA-encoded cysteine protease inhibitor library

Peptide nucleic acids (PNAs) have been used to encode a combinatorial library whereby each compound is labeled with a PNA tag which reflects its synthetic history and localizes the compound upon hybridization to an oligonucleotide array. We report herein the full synthetic details for a 4000 member PNA-encoded library targeted towards cysteine protease.     

Label‐Free Bioelectronic Detection of Point Mutation by Using Peptide Nucleic Acid Probes

An electrochemical hybridization biosensor based on peptide nucleic acid (PNA) probes with a label‐free protocol is described. The detection of PNA‐DNA and DNA‐DNA hybridizations were accomplished based on the oxidation signal of guanine by using differential pulse voltammetry (DPV) at carbon paste electrode (CPE). It was observed that the oxidation signals of guanine obtained from the PNA and DNA probe modified CPEs were higher than those obtained from the PNA‐DNA and DNA‐DNA hybrid modified CPEs due to the accessible unbound guanine bases. The detection of hybridization between PNA probe and point mutation containing DNA target sequences was clearly observed due to the difference of the oxidation signals of guanine bases, because the point mutation was guanine nearly at the middle of the sequence. The effect of the DNA target concentration on the hybridization signal was also observed. The PNA probe was also challenged with excessive and equal amount of noncomplementary DNA and also mixtures of point mutation and target DNA.     

Single-nucleotide-specific PNA-peptide ligation on synthetic and PCR DNA templates

DNA-directed chemical synthesis has matured into a useful tool with applications such as fabrication of defined (nano)molecular architectures, evolution of amplifiable small-molecule libraries, and nucleic acid detection. Most commonly, chemical methods were used to join oligonucleotides under the control of a DNA or RNA template. The full potential of chemical ligation reactions can be uncovered when nonnatural oligonucleotide analogues that can provide new opportunities such as increased stability, DNA affinity, hybridization selectivity, and/or ease and accuracy of detection are employed. It is shown that peptide nucleic acid (PNA) conjugates, nonionic biostable DNA analogues, allowed the fashioning of highly chemoselective and sequence-selective peptide ligation methods. In particular, PNA-mediated native chemical ligations proceed with sequence selectivities and ligation rates that reach those of ligase-catalyzed oligodeoxynucleotide reactions. Usually, sequence-specific ligations can only be achieved by employing short-length probes, which show DNA affinities that are too low to allow stable binding to target segments in large, double-stranded DNA. It is demonstrated that the PNA-based ligation chemistry allowed the development of a homogeneous system in which rapid single-base mutation analyses can be performed even on double-stranded PCR DNA templates.     

Polyaniline based nucleic acid sensor

Twenty-bases long NH2-modified DNA and PNA probes specific to a pathogen (Mycobacterium tuberculosis) were covalently immobilized onto a polyaniline (PANI)/Au electrode to detect nucleic acid hybridization with complementary, one-base mismatch and noncomplementary targets within 30 s using Methylene Blue. The PNA-PANI/Au electrode exhibits improved specificity (1000 times) and detection limit (0.125 x 10(-18) M) as compared to that of the DNA-PANI/Au electrode (2.5 x 10(-18) M). These PNA-PANI/Au electrodes can be utilized for detection of hybridization with the complementary sequence in 5 min sonicated M. tuberculosis genomic DNA within 1 min of hybridization time. These DNA-PANI/Au and PNA-PANI/Au electrodes can be used 6-7 and 13-15 times, respectively.     

Microfluidic chip for fast nucleic acid hybridization

The design and experimental verification of a fast nucleic acid hybridization microchip using the fluidic velocity and strain rate effects was conducted. This hybridization chip was able to increase the hybridization signal 6-fold, reduce non-specific target-probe binding and background noise within 30 min, as compared to conventional hybridization methods, which may take from 4 h to overnight. Excellent correlation between experimental results and simulation analysis was obtained in this study. A detailed study of a newly designed microfluidic chip for enhancing hybridization was conducted. Three different designs of devices were fabricated and tested. Two different lengths of targets, 25-mer oligonucleotide and 1.4 kb ssDNA, were tested in this study. The hybridization efficiency can be improved by introducing velocity and extensional strain rate to the sample. This study demonstrates that the signal in the proposed method exhibits intensities 6-fold higher than those in static conditions. The necessary time for the hybridization process can be reduced from overnight to 30 min using the methods developed in this study. Experimental results also show that the strain rate provides stronger effect on hybridization than that of velocity. Combining hybridization with microfluidic concepts of velocity and strain rate effects may provide additional specificity and efficiency in nucleic acid detection and genomic study. This microfluidic hybridization chip can provide potential application in genomic study.     

A Peptide Nucleic Acid (PNA)‐DNA Ferrocenyl Intercalator for Electrochemical Sensing

A ferrocenyl intercalator was investigated to develop an electrochemical DNA biosensor employing a peptide nucleic acid (PNA) sequence as capture probe. After hybridization with single strand DNA sequence, a naphthalene diimide intercalator bearing ferrocene moieties (FND) was introduced to bind with the PNA‐DNA duplex and the electrochemical signal of the ferrocene molecules was used to monitor the DNA recognition. Electrochemical impedance spectroscopy was used to characterize the different modification steps. Differential pulse voltammetry was employed to evaluate the electrochemical signal of the FND intercalator related to its interaction with the complementary PNA‐DNA hybrid. The ferrocene oxidation peaks were utilised for the target DNA quantification. The developed biosensor demonstrated a good linear dependence of FND oxidation peak on DNA concentration in the range 1 fM to 100 nM of target DNA, with a low detection limit of 11.68 fM. Selectivity tests were also investigated with a non‐complementary DNA sequence, indicating that the FND intercalator exhibits a selective response to the target PNA‐DNA duplex.     

DNA-templated three-branched nanostructures for nanoelectronic devices

Three-branched DNA molecules have been designed and assembled from oligonucleotide components. These nucleic acid constructs contain double- and single-stranded regions that control the hybridization behavior of the assembly. Specific localization of a single streptavidin molecule at the center of the DNA complex has been investigated as a model system for the directed placement of nanostructures. Highly selective silver and copper metallization of the DNA template has also been characterized. Specific hybridization of these DNA complexes to oligonucleotide-coupled nanostructures followed by metallization should provide a bottom-up self-assembly route for the fabrication and characterization of discrete three-terminal nanodevices.     

Synthesis and photo activity of phenylazonaphthalene peptide nucleic acid monomers

Phenylazonaphthalene peptide nucleic acid （PNA） monomers were successfully synthesized, and their photoisomerization was examined. The new PNA monomers showed reversible trans-cis isomerization with UVand visible light irradiation, which might be the foundation of photo-regulating the hybridization between PNA containing phenylazonaphthalene unit and DNA. Simultaneously, the fluorescence of the new PNA monomers might make them especially useful as structural probes.