Filter-based PNA in situ hybridization for rapid detection, identification and enumeration of specific micro-organisms

AIMS: A method for rapid and simultaneous detection, identification and enumeration of specific micro-organisms using Peptide Nucleic Acid (PNA) probes is presented. METHODS AND RESULTS: The method is based on a membrane filtration technique. The membrane filter was incubated for a short period of time. The microcolonies were analysed by in situ hybridization, using peroxidase-labelled PNA probes targeting a species-specific rRNA sequence, and visualized by a chemiluminescent reaction. Microcolonies were observed as small spots of light on film, thereby providing simultaneous detection, identification and enumeration. The method showed 95-100% correlation to standard plate counts along with definitive identification due to the specificity of the probe. CONCLUSION: Using the same protocol, results were generated approximately three times faster than culture methods for Gram-positive and -negative bacterial species and yeast species. SIGNIFICANCE AND IMPACT OF THE STUDY: The method is an improvement on the current membrane filtration technique, providing rapid determination of the level of specific pathogens, spoilage or indicator micro-organisms.     

A review of bioluminescent ATP techniques in rapid microbiology

Use of firefly luciferase to assay adenosine triphosphate (ATP) extracted from microorganisms provides an easy means to enumerate microbes within minutes. The small amount of light produced is proportional to ATP and thus microbial number. The average bacterium contains around 10^?15 g ATP per cell. Present reagents permit detection of 10³ cells per tube. Luminometers currently on the market detect about 10^?12 g ATP. Proper extraction of ATP from the microbes is an essential part of any protocol, as is the removal of non-microbial ATP from, for example, somatic cells also present in samples. The technique may be applied to a wide range of samples, for example food and beverages and clinical samples such as urine. The ATP assay gives a global measure of microbial numbers, i.e. it is not species specific unless a species separation step is included in the protocol.     

Inducing the replacement of PNA in DNA.PNA duplexes by DNA

The uncharged DNA-analogue peptide nucleic acid (PNA) can invade into dsDNA by displacing the non-complementary DNA strand. The formed strand displacement complexes can create a sterical hindrance to block access of enzymes such as nucleases and polymerases. Due to the high stability of DNA.PNA duplexes it is usually not possible to displace the PNA strand by ssDNA or ssRNA. We herein report that the polycationic, comb-type copolymer alphaPLL-g-Dex can induce such a replacement of PNA in DNA.PNA duplexes by ssDNA. The influence of the copolymer on strand exchange highly depends on the nature of the oligonucleotides. Acceleration has only been observed when both the starting duplex and the single-stranded exchanger strand were negatively charged. The presented approach should allow the withdrawal of PNA induced sterical hindrance of DNA by rehybridisation with ssDNA.     

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.     

Unique properties of purine/pyrimidine asymmetric PNA.DNA duplexes: differential stabilization of PNA.DNA duplexes by purines in the PNA strand

PNA.DNA duplexes are significantly stabilized by purine nucleobases in the PNA strand. To elucidate and understand the effect of switching the backbone in a nucleic acid duplex, we now report a thermodynamics study along with a solution conformations study of two purine/pyrimidine strand asymmetric duplexes and a strand symmetrical control by comparing the behavior of all four possible PNA/DNA combinations. In essence, we are comparing an identical basepair stack connected by either an aminoethyl glycine PNA or a deoxyribose DNA backbone. We show that the PNA.DNA duplexes containing purine-rich PNA strands are stabilized with regard to the thermal melting temperature and free energy as well as enthalpy (and concomitantly relatively less entropically disfavored). Based on our data, we find it unlikely that differences in counterion binding (identical ionic-strength dependence was observed), hydration (identical and insignificant water release was observed), or single-strand conformation can be responsible for the difference in duplex stability. The only consistent difference observed between the purine-rich PNA versus the pyrimidine-rich PNA in isosequential PNA.DNA duplexes is the significant increase in both binding enthalpy and entropy for the PNA.DNA duplexes containing pyrimidine-rich PNA in organic solvent, which would indicate that these duplexes are relatively enthalpically disfavored in water. Although our results so far do not allow us to identify the origin of the different stabilities of homopurine/homopyrimidine PNA.DNA duplexes, the evidence does point to a significant structural component, which involves enthalpic contributions both within the duplex structure and also from bound water molecules.     

PNA technology

Peptide nucleic acids (PNA) are deoxyribonucleic acid (DNA) mimics with a pseudopeptide backbone. PNA is an extremely good structural mimic of DNA (or of ribonucleic acid [RNA]), and PNA oligomers are able to form very stable duplex structures with Watson-Crick complementary DNA and RNA (or PNA) oligomers, and they can also bind to targets in duplex DNA by helix invasion. Therefore, these molecules are of interest in many areas of chemistry, biology, and medicine, including drug discovery, genetic diagnostics, molecular recognition, and the origin of life. Recent progress in studies of PNA properties and applications is reviewed.     

Combination of ATP-bioluminescence and PNA probes allows rapid total counts and identification of specific microorganisms in mixed populations.

We have combined ATP-dependent bioluminescence with a novel chemiluminescent in situ hybridization (CISH) method using peroxidase-labeled peptide nucleic acid (PNA) probes targeting species-specific rRNA sequences to provide total counts and subsequent identification of specific microorganisms. Both methods are applied to the same membrane filter following a short incubation time and both methods provide results in the form of spots of light that are captured by the MicroStar detection system. Each spot of light represents individual micro-colonies detected by either ATP bioluminescence or PNA CISH. This new concept is particularly intended for in process and quality control of non-sterile products to rapidly provide total counts as well as presence/absence of specific indicators and/or pathogens in non-sterile, filterable samples.     

Nucleobase‐caged peptide nucleic acids: PNA/PNA duplex destabilization and light‐triggered PNA/PNA recognition

The 2‐(o‐nitrophenyl)‐propyl (NPP) group is used as caging group to mask the nucleobases adenine and cytosine in N‐(2‐aminoethyl)glycine peptide nucleic acids (aeg‐PNA). The adeninyl and cytosinyl nucleo amino acid building blocks Fmoc‐a^NPP‐aeg‐OH and Fmoc‐c^NPP‐aeg‐OH were synthesized and incorporated into PNA sequences by Fmoc solid phase synthesis relying on high stability of the NPP nucleobase protecting group toward Fmoc‐cleavage, coupling, capping, and resin cleavage conditions. Removal of the nucleobase caging group was achieved by UV‐LED irradiation at 365 nm. The nucleobase caging groups provided sterical crowding effecting the Watson–Crick base pairing, and thereby, the PNA double strand stabilities. Duplex formation can completely be suppressed for complementary PNA containing caging groups in both strands. PNA/PNA recognition can be completely restored by UV light‐triggered release of the photolabile protecting group. Copyright © 2013 European Peptide Society and John Wiley & Sons, Ltd.     

A PNA microarray for tomato genotyping

The design and development of a PNA microarray designed for the simultaneous identification of several SNPs characteristic of seven different tomato varieties is described. Highly selective arginine-based monomer containing PNAs (Arg-PNAs) have been used in order to obtain very selective probes. Seven modified PNA probes were synthesised and their binding properties in solution were studied. PNA-microarrays based on these probes were prepared and applied to SNP discrimination in model experiments using oligonucleotide mixtures simulating the different sequences of the seven tomato varieties. The strength and the limitations of such a system for SNP recognition are thoroughly discussed.     

PNA biosensors for nucleic acid detection

Biosensor devices, based on the conversion of nucleic acid recognition reactions into useful electrical signals, offer considerable promise for DNA diagnostics. The unique hybridization properties of solution-phase PNA can be extrapolated onto transducer surfaces in connection with the design of remarkably specific DNA biosensors. This article reviews the development of PNA biosensors, and discusses common PNA-biosensing protocols along with their prospects in DNA biosensor technology.     

Thermodynamic studies on PNA and PNA/DNA dendrimer formation

In this work we report a kinetic and thermodynamic study relative to the formation of gel systems based on PNA and PNA/DNA dendrimers, useful for drug delivery or diagnostic applications. We realized two kinds of systems: a PNA-based monomolecular system formed by an autoassembling PNA tridendron (A) and a PNA/DNA bimolecular system based on a PNA tridendron with a mixed sequence and a DNA crosslinker (B). Both systems have the ability to form a three-dimensional network by means of specific W-C base pairing.