Leishmania chagasi: homogenous metacyclic promastigotes isolated by buoyant density are highly virulent in a mouse model

Homogenous metacyclic promastigotes of Leishmania chagasi were isolated by buoyant density from in vitro heterogeneous cultures and used for biochemical characterization of isoforms of the major surface protease (MSP). Compared to stationary phase promastigotes, metacyclic cells had three times more MSP, produced 3-fold higher parasite loads in a mouse model in vivo, and were more resistant to complement-mediated lysis in vitro. These metacyclic L. chagasi expressed both the virulence-associated 59-kDa, and the constitutively expressed 63-kDa, isoforms of MSP.     

Insight into why pyrrolidinyl peptide nucleic acid binding to DNA is more stable than the DNA x DNA duplex

Molecular dynamics (MD) simulations and experimental measurements of the stability of a novel pyrrolidinyl PNA binding to DNA (PNA·DNA) in both parallel and antiparallel configurations were carried out. For comparison, simulations were also performed for the DNA·DNA duplex. The conformations of the three simulated systems were found to retain well-defined base pairing and base stacking as their starting B-like structure. A large gas-phase energy repulsion of the two negatively charged sugar-phosphate backbones of the DNA strands was found to reduce the stability of the DNA·DNA duplex significantly compared with that of the PNA·DNA complexes, especially in the antiparallel binding configuration. In addition, the antiparallel PNA·DNA was observed to be less solvated than that of the other two systems. The simulated binding free energies and the experimental melting temperatures for the three investigated systems are in good agreement, indicating that the antiparallel PNA·DNA is the most stable duplex.     

Peptide nucleic acids: Cellular delivery and recognition of DNA and RNA targets

Peptide nucleic acids (PNAs) can be conveniently delivered into cells in complex with DNA and cationic lipid. This advance enables researchers to test the hypothesis that PNAs offer advantages for recognition of DNA or RNA targets within cells. In this review, I describe the intracellular delivery of PNAs as DNA-PNA-cationic lipid complexes and discuss recognition of three classes of nucleic acid target: duplex DNA, single-stranded mRNA, and the ribonucleoprotein telomerase. These targets differ dramatically in their potential for base-paired structure, offering distinct challenges for hybridization by PNAs. It is apparent that PNAs can exert sequence-specific effects within cells, and their full potential has only begun to be explored.     

Thiolated pyrrolidinyl peptide nucleic acids for the detection of DNA hybridization using surface plasmon resonance

Thiolated pyrrolidinyl peptide nucleic acids (HS-PNAs) bearing d-prolyl-2-aminocyclopentanecarboxylic acid (ACPC) backbones with different lengths and types of thiol modifiers were synthesized and then characterized by MALDI–TOF mass spectrometry. These HS-PNAs were immobilized on gold-coated glass by self-assembled monolayer (SAM) formation via S atom linkage for the detection of DNA hybridization using surface plasmon resonance (SPR). The amount and the stability of the immobilized HS-PNAs, as well as the effects of spacer and blocking thiol on DNA hybridization efficiency, were determined. SPR results indicated that the hybridization efficiency was enhanced when the distance between the PNA portion and the thiol terminal was increased and/or when blocking thiol was used following the HS-PNA immobilization. The immobilized HS-PNA could discriminate between fully complementary DNA from one or two base mismatched DNA with a relatively high degree of mismatch discrimination (>45%) in PBS buffer at 25 °C. The lowest DNA concentration at which reliable discrimination between fully complementary and single mismatched DNA could still occur was at about 0.2 μM, which is equivalent to 10 pmol of DNA. This research demonstrates that using these novel thiolated PNAs in combination with the SPR technique offers a direct, rapid and non-label based method that could potentially be applied for the analysis of genomic or PCR-amplified DNA in the future.     

Development of a PNA probe for the detection of the toxic dinoflagellate Takayama pulchella

A peptide nucleic acid (PNA) probe was developed to detect the toxic dinoflagellate, Takayama pulchella TPXM, using fluorescent in situ hybridization (FISH) combined with epifluorescent microscopy and flow cytometry. The PNA probe was then used to analyze HAB samples from Xiamen Bay. The results indicated that the fluorescein phosphoramidite (FAM)-labeled probe (PNATP28S01) [Flu]-OO ATG CCA TCT CAA GA, entered the algal cells easily and bound to the target species specifically. High hybridization efficiency (nearly 100%) was observed. Detection by epifluorescence microscopy and flow cytometry gave comparable results. The fluorescence intensity of the PNA probe hybridized to T. pulchella cells was remarkably higher than that of two DNA probes used in this study and than the autofluorescence of the blank and negative control cells. In addition, the hybridization condition of the PNA probe was easier to control than DNA probes, and when applied to field-collected samples, the PNA probe showed higher binding efficiency to the target species than DNA probes. With the observed high specificity, binding efficiency, and detection signal intensity, the PNA probe will be useful for monitoring harmful algal blooms of T. pulchella.     

A convenient route for the preparation of peptide nucleic acid monomers carrying acid-labile groups for the protection of the amino function

A convenient route for the preparation of peptide nucleic acid (PNA) monomers is described. Two different base-labile protecting groups (2-cyanoethyl and 4-nitrophenylethyl) are described for the protection of the carboxylic function of the N-(2-aminoethyl)glycine backbone during the assembly of the monomers. These groups are selectively removed yielding the desired PNA monomers in high yields, the 2-cyanoethyl group being faster and cleaner than the 4-nitrophenylethyl group. The use of PNA monomers for the preparation of DNA–PNA chimeric molecules is also discussed.     

A biological transporter for the delivery of peptide nucleic acids (PNAs) to the nuclear compartment of living cells

To facilitate nuclear delivery of biomolecules we describe the synthesis of a modular transporter bearing a cellular membrane transport peptide (pAntp) and, as a cargo, a 16-mer peptide nucleic acid (PNA) covalently linked to a nuclear localisation signal (NLS[SV40-T]). Transport peptide and PNA are connected via N-terminal activated cysteine to form cleavable disulphide bonds. Internalization and subsequent delivery of PNA to the nucleus was verified in living and fixed cells by confocal laser scanning microscopy (CLSM) and fluorescence correlation spectroscopy (FCS). Double-labelling experiments indicate the cytoplasmic cleavage of the two modules and the effective nuclear import of the chromophore-tagged cargo. A non-degradable linker between transport module and cargo as well as a construct without NLS did not enable nuclear PNA import under the described experimental conditions. FCS-measurements revealed that most of the PNAs delivered into the cytoplasm by the modular transporter are anchored or encapsulated, indicating that intracellular transport of these compounds is not governed by molecular diffusion. Our results clearly demonstrate efficient compartment-directed transport using a synthetic, non-toxic modular transporter in living cells.     

Light-directed synthesis of peptide nucleic acids (PNAs) chips

We report herein the light-directed synthesis of peptide nucleic acids (PNAs) microarray using PNA monomers protected by photolabile protecting groups and a maskless technique that uses a digital micromirror array system to form virtual masks. An ultraviolet image from the virtual mask was cast onto the active surface of a glass substrate, which was mounted in a flow cell reaction chamber connected to a peptide synthesizer. Light exposure was followed by automatic chemical coupling cycles and these steps were repeated with different virtual masks to grow the desired PNA probes in a selected pattern. In a preliminary experiment, an array of PNA probes with dimensions of 4.11 mm × 4.11 mm was generated on each slide. Each synthesis region in the final array measured 210 μm × 210 μm for a total of 256 sites. The center-to-center space was 260 μm. It was observed from the hybridization pattern of the fluorescently labeled oligonucleotide targets that the fluorescence intensities of the matched, and mismatched sequences showed substantial difference, demonstrating specificity in the identification of complementary sequences. This opens the way to exploit processes from the microelectronics industry for the fabrication of PNA microarrays with high densities.