Constrained flexibility in PNA: DNA binding studies with bridged aminopropylglycyl PNA

Introduction of methylene bridges in aegPNA and apgPNA molecules give rise to cyclic five and six membered ring structures. Synthesis of a new six membered cyclic PNA monomer, aminopipecolyl PNA (pipPNA) is reported. Incorporation of pipPNA into PNA oligomers and comparative binding with target DNA sequences is studied.     

Structural Pre-organization of Peptide Nucleic Acids

Abstract

Introduction of constraint via chemical bridging in the aegPNA leads to the five or six membered cyclic structures that may contribute towards maintaining the balance between rigidity and flexibility of the PNA backbone. The significant promise of our approach to use the naturally occurring trans-4-hydroxy-L-proline to arrive at different chirally pure cyclic PNA analogs and their DNA binding properties will be presented.     

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.     

Structural Studies on Porphyrin–PNA Conjugates in Parallel PNA:PNA Duplexes: Effect of Stacking Interactions on Helicity

Parallel PNA:PNA duplexes were synthesized and conjugated with meso‐tris(pyridyl)phenylporphyrin carboxylic acid at the N‐terminus. The introduction of one porphyrin unit was shown to affect slightly the stability of the PNA:PNA parallel duplex, whereas the presence of two porphyrin units at the same end resulted in a dramatic increase of the melting temperature, accompanied by hysteresis between melting and cooling curves. The circular dichroism (CD) profile of the Soret band and fluorescence quenching strongly support the occurrence of a face‐to‐face interaction between the two porphyrin units. Introduction of a L‐lysine residue at the C‐terminal of one strand of the parallel duplex induced a left‐handed helical structure in the PNA:PNA duplex if the latter contains only one or no porphyrin moiety. The left‐handed helicity was revealed by nucleobase CD profile at 240–280 nm and by the induced‐CD observed in the presence of the DiSC₂(5) cyanine dye at ~500–550 nm. Surprisingly, the presence of two porphyrin units led to the disappearance of the nucleobase CD signal and the absence of CD exciton coupling within the Soret band region. In addition, a dramatic decrease of induced CD of DiSC₂(5) was observed. These results are in agreement with a model where the porphyrin–porphyrin interactions cause partial loss of chirality of the PNA:PNA parallel duplex, forcing it to adopt a ladder‐like conformation. Chirality 27:864–874, 2015. © 2015 Wiley Periodicals, Inc.     

ENGINEERING PREFERENCES OF HAIRPIN PNA BINDING TO COMPLEMENTARY DNA: EFFECT OF N7G IN aeg/aep PNA BACKBONE

AegPNA and aepPNA monomeric units bearing the N7-guanine nucleobase as a substitute for C⁺ have been demonstrated to bind to a GC base-pair of a duplex in a pH-independent manner when placed in the third strand. The aepPNA backbone exerts a preference for binding in the antiparallel Hoogsteen mode over the parallel Hoogsteen mode.     

PNA∗Synthesis and Diagnostic Application

Abstract

An optimized automated PNA synthesis protocol is reported. Under optimal conditions the product yield of a test 17-mer PNA is approximately 90 %. The average coupling yield is 99.4 %. The synthesis strategy is Boc/Z. The protocol is developed in a 5 pmole scale but is easily scaled up to 10–50 μmole scale syntheses on the automated synthesizer (ABI 433A). DNA capture experiments by PNA was used to develop a method for PNA-mediated purification of genomic Chlamydia DNA from urine. This purification removed efficiently substances that impeded DNA amplification.

     

Structural pre-organization of peptide nucleic acids

Introduction of constraint via chemical bridging in the aegPNA leads to the five or six membered cyclic structures that may contribute towards maintaining the balance between rigidity and flexibility of the PNA backbone. The significant promise of our approach to use the naturally occurring trans-4-hydroxy-L-proline to arrive at different chirally pure cyclic PNA analogs and their DNA binding properties will be presented.     

Conformationally Restrained Chiral PNA Conjugates: Synthesis and DNA Complementation Studies

Abstract

In recent times, PNA (I), a structural mimic of DNA in which the sugar-phosphate backbone is replaced by N-(2-aminoethyl)glycine (aeg) linkage has emerged as a potential antisense therapeutic agent.¹ A major limitation of PNAs from an application perspective is their poor solubility in aqueous medium and being achiral, they bind to cDNA in both parallel (N-PNA/5′-DNA) and antiparallel (N-PNA/3′-DNA) modes. In this connection, we have designed spermine conjugated and conformationally constrained PNA analogues to generate the 4-aminoprolyl backbone (II).² These were synthesised and evaluated for their DNA binding abilities by using UV and CD spectroscopic studies. It is seen that incorporation of one 4-aminoprolyl unit at the N-terminus of a PNA chain not only enhances the inherent binding of PNA to DNA, but also imparts significant bias in parallel and antiparallel binding with cDNA. Conjugation of spermine at C-terminus enhanced the PNA solubility.     

In Vitro Membrane Penetration of Modified Peptide Nucleic Acid (PNA)

Abstract

Efficient cellular uptake is crucial for the success of any drug directed towards targets inside cells. Peptide nucleic acid (PNA), a DNA analog with a promising potential as a gene-directed drug, has been shown to display slow membrane penetration in cell cultures. We here used liposomes as an in vitro model of cell membranes to investigate the effect on penetration of a PNA molecule colvalently modified with a lipophilic group, an adamantyl moiety. The adamantyl attachment was found to increase the membrane-penetration rate of PNA three-fold, as compared to corresponding unmodified PNA. From the penetration behaviour of a number of small and large molecules we could conclude that passive diffusion is the mechanism for liposome-membrane passage. Flow linear dichroism (LD) of the modified PNA in presence of rod-shaped micelles, together with octanol-water distribution experiments, showed that the adamantyl-modified PNA is amphiphilic; the driving force behind the observed increased membrane-penetration rate appears to be an accumulation of the PNA in the lipid double layer.     

A dual role for proline iminopeptidase in the regulation of bacterial motility and host immunity

During plant–pathogen interactions, pathogenic bacteria have evolved multiple strategies to cope with the sophisticated defence systems of host plants. Proline iminopeptidase (PIP) is essential to Xanthomonas campestris pv. campestris (Xcc) virulence, and is conserved in many plant‐associated bacteria, but its pathogenic mechanism remains unclear. In this study, we found that disruption of pip in Xcc enhanced its flagella‐mediated bacterial motility by decreasing intracellular bis‐(3′,5′)‐cyclic dimeric guanosine monophosphate (c‐di‐GMP) levels, whereas overexpression of pip in Xcc restricted its bacterial motility by elevating c‐di‐GMP levels. We also found that PIP is a type III secretion system‐dependent effector capable of eliciting a hypersensitive response in non‐host, but not host plants. When we transformed pip into the host plant Arabidopsis, higher bacterial titres were observed in pip‐overexpressing plants relative to wild‐type plants after Xcc inoculation. The repressive function of PIP on plant immunity was dependent on PIP's enzymatic activity and acted through interference with the salicylic acid (SA) biosynthetic and regulatory genes. Thus, PIP simultaneously regulates two distinct regulatory networks during plant–microbe interactions, i.e. it affects intracellular c‐di‐GMP levels to coordinate bacterial behaviour, such as motility, and functions as a type III effector translocated into plant cells to suppress plant immunity. Both processes provide bacteria with the regulatory potential to rapidly adapt to complex environments, to utilize limited resources for growth and survival in a cost‐efficient manner and to improve the chances of bacterial survival by helping pathogens to inhabit the internal tissues of host plants.     

Early diagnosis of blood culture isolates in patients with candidemia using PNA FISH

Candidemia is associated with high mortality, especially with neutropenic and intensive care unit patients. A delay in early, effective antifungal therapy has been associated with increased mortality and hospital costs. Peptide nucleic acid fluorescent in-situ hybridization (PNA FISH) can identify Candida species within 3 hours after a positive blood culture demonstrates yeast. A Candida albicans probe and a dual C. albicans/Candida glabrata probe are available in clinical practice, and multi-Candida species probes and flow cytometry are in development. Recent data suggest that the rapid identification of Candida species with PNA FISH can provide early targeted therapy to patients and thus reduce antifungal costs and improve patient care. This review evaluates the clinical and laboratory effects of the Candida probes and their limitations, and competing technologies. Candida PNA FISH probes offer clinicians the early knowledge of the species they are treating, allowing them to appropriately tailor therapy.     

Piperidinyl Peptide Nucleic Acids: Synthesis and DNA-Complementation Studies

Abstract

Synthesis of a new six membered PNA analogue by introducing a methylene bridge between β carbon atom of ethylene diamine and β′ carbon atom of linker to nucleobase.     

A practical approach to FRET-based PNA fluorescence in situ hybridization

Given the demand for improved methods for detecting and characterizing RNA variants in situ, we developed a quantitative method for detecting RNA alternative splicing variants that combines in situ hybridization of fluorescently labeled peptide nucleic acid (PNA) probes with confocal microscopy Förster resonance energy transfer (FRET). The use of PNA probes complementary to sequences flanking a given splice junction allows to specifically quantify, within the cell, the RNA isoform generating such splice junction as FRET efficiency measure. The FRET-based PNA fluorescence in situ hybridization (FP-FISH) method offers a conceptually new approach for characterizing at the subcellular level not only splice variant isoform structure, location, and dynamics but also potentially a wide variety of close range RNA–RNA interactions. In this paper, we explain the FP-FISH technique workflow for reliable and reproducible results.     

Long Range Electron Transfer in PNA/DNA Duplexes

Abstract

The conductive properties of PNA/DNA is examined. The electron donor is covalently linked to a fixed site in PNA which unambiguously places the acceptor in the hybrid duplex. The study shows that PNA/DNA acts like an insulator.     

MESSENGER RNA ISOLATION USING NOVEL PNA ANALOGUES

Homo-Thy hetero-oligomer probes composed of trans-4-hydroxy-L-proline based PNA-like (HypNA) monomers and phosphono PNA (pPNA) monom-ers demonstrated strong binding to complementary poly A⁺ RNA strands. We used a mixture of chimeric oligomers containing both “linear” and “clamping” PNA-analogues to develop an mRNA isolation procedure and demonstrate the improved recovery of RNA molecules with secondary structure at the 3′end as well as RNAs with short poly A tails.     

Composites of peptide nucleic acids with titanium dioxide nanoparticles. III. Kinetics of PNA dissociation from nanocomposites containing DNA/PNA duplexes

When delivering peptide nucleic acids (PNA) into cells in the TiO₂ · PL · DNA/PNA nanocomposites consisting of titanium dioxide nanoparticles coated with polylysine (PL) and immobilized DNA/PNA duplexes, it is important to control the rate of the release of PNA from the carrier due to dissociation of the immobilized DNA/PNA duplex, followed by the desorption of PNA to solution while the DNA remains on the carrier. It was found that the rate constant of dissociation of the DNA/PNA duplex in the TiO₂ · PL · DNA/PNA nanocomposites depended on the number of complementary bases in the duplex. The half-retention time values for PNA in the studied nanocomposites containing the duplexes with 10, 12, 14, and 16 overlapping complementary base pairs were 10, 14, 22, and 70 min, respectively. Thus, it was shown that the rate of the release of PNA from the proposed nanocomposites can be controlled by varying the number of overlapping complementary base pairs in the immobilized DNA/PNA duplex. The method of the PNA immobilization may be used for designing nanocomposites having the optimum time value of the PNA release. The proposed TiO₂ · PL · DNA/PNA nanocomposites can be used to efficiently deliver therapeutically significant PNA drugs for their selective effect on pathogenic nucleic acids in cells.     

Triplex Formation Between DNA and Mixed Purine-Pyrimidine PNA Analog with Lysines in Backbone

Abstract

Melting UV experiments and mixing curves indicated slow triplex formation between lysine comprising PNA and DNA complement in 100mM Na⁺ solution.     

APPLICATION OF MITSUNOBU REACTION TO SOLID-PHASE PEPTIDE NUCLEIC ACID (PNA) MONOMER SYNTHESIS

ABSTRACT

PNA type I monomer backbone with a reduced peptide bond was synthesized on a Merrifield resin in Mitsunobu reaction of Boc-amino ethanol with resin-bound o-nitrobenzenesulfonylglycine. The pseudo dipeptide secondary amine group was deprotected by thiolysis and acylated with thymin-1-ylacetic acid. The monomer was released as a methyl ester. The procedure seems to be of general applicability and allows various modifications of PNA structure by using diverse alcohols and amino acid esters.     

SYNTHESIS AND HYBRIDIZATION OF NOVEL CHIRAL PYRROLIDINE BASED PNA ANALOGUE

Four different PNA fragments containing units of either the R- or S- isomer of N-(2-pyrrolidine-methyl)-N-(thymine-1-acetyl)-glycine (Pmg) were synthesized on a solid support. UV thermal melting experiments with complementary RNAs were performed and it was found that R-Pmg containing PNAs bind better to RNA than those containing the S-Pmg units.     

Evidence for (PNA)2/DNA triplex structure upon binding of PNA to dsDNA by strand displacement

The binding of PNA (peptide nucleic acid) T₂CT₂CT₄-LysNH₂ to the double-stranded DNA target 5′ -A₂GA₂GA₄ was studied by KMnO₄ and dimethylsulfate (DMS) probing. It is found that upon sequence-specific strand displacement binding of the PNA to the dsDNA target concomitant protection of the N-7 of guanines within the target takes place. It is furthermore shown that the binding of this PNA is more efficient at pH 5.5 that at pH 6.5 and very inefficient at pH 7.5. These results clearly indicate that C⁺G Hoogsteen base pairing is present and important for binding and that the strand displacement complex therefore involves a PNA·DNA-PNA triplex.