Duplex formation of the simplified nucleic acid GNA

Glycol nucleic acid (GNA) has an acyclic backbone of propylene glycol nucleosides that are connected by phosphodiester bonds. This paper characterizes the duplex-formation properties of this simplified nucleic acid. Although single and multiple GNA nucleotides are highly destabilizing if incorporated into DNA duplexes, the two enantiomeric oligomers (S)-GNA and (R)-GNA form antiparallel homoduplexes that are thermally and thermodynamically significantly more stable than analogous duplexes of DNA and RNA. The salt-dependence and Watson-Crick-pairing fidelity of GNA duplexes are similar to those of DNA duplexes, but, apparently, the 2'-deoxyribonucleotide and the propylene glycol backbones are not compatible with each other. This conclusion is further supported by cross-pairing experiments. Accordingly, both (S)- and (R)-GNA strands do not generally pair with DNA. However, (S)-GNA, but not (R)-GNA, forms stable heteroduplexes with RNA in sequences that are low in G:C content. Altogether, the high stability and fidelity of GNA duplex formation in combination with the economical accessibility of propylene glycol building blocks for oligonucleotide synthesis render GNA an attractive candidate for the design of self-assembling materials. They further suggest that GNA could be considered as a potential candidate for a predecessor of RNA during the evolution of life on Earth.     

Synthesis and properties of aminopropyl nucleic acids

Oligonucleotides that contain up to three aminopropyl nucleoside analogues have been synthesized. Dimers of aminopropyl adenine and thymidine were prepared and used as building blocks by applying phosphoramidite chemistry. Both R and S isomers of the aminopropyl nucleosides were used. This incorporation led to a reduction of thermal stability of double-stranded DNA. Furthermore, the (R)-adenine analogue, which yielded (S)-APNA, can be considered as a candidate for universal base pairing.     

Synthesis and degradation of nucleobases and nucleic acids by formamide in the presence of montmorillonites

We describe the role of formamide, a product of the hydrolysis of hydrogen cyanide, as precursor of several components of nucleic acids under prebiotic conditions. When formamide is heated in the presence of montmorillonites, the efficient one-pot synthesis of purine, adenine, cytosine, and uracil is obtained. Along with these nucleobases, several components of the inosine pathway are obtained: 5-aminoimidazole-4-carboxamide, 5-formamidoimidazole-4-carboxamide and hypoxanthine. This almost complete catalogue of nucleic acid precursors is accompanied by N(9)-formylpurine, which, containing a masked glycosidic bond in its formyl moiety, is a plausible precursor of purine acyclonucleosides. In addition, montmorillonites differentially affect the rate of degradation of nucleobases when embedded in 2'-deoxyoligonucleotides; namely, montmorillonites protect adenine and guanine from the degradative action of formamide, while thymine degradation is enhanced. The oligonucleotide backbone reactivity to formamide is also affected; this shows that the interaction with montmorillonites modifies the rate of abstraction of the Halpha and Hbeta protons on the sugar moieties.     

Synthesis of 5-(1,2,3-triazol-4-yl)-2'-deoxyuridines by a click chemistry approach: stacking of triazoles in the major groove gives increased nucleic acid duplex stability

A general protocol for converting alkyl and aryl halides into azides and for converting these in situ into 1,4-disubstituted triazoles was applied with 5-ethynyl-2'-deoxyuridine. This afforded three modified 2'-deoxyuridine analogues with either unsubstituted or 1-phenyl-/1-benzyl-substituted triazoles in their 5-positions. Modelling demonstrates coplanarity of the two heteroaromatic rings, and UV spectroscopy showed the uracil pK(a) values to be almost unchanged. The three nucleosides were introduced into nonamer oligonucleotides by phosphoramidite chemistry. The heteroaromatic triazoles became positioned in the major grooves of the short dsDNA and DNA-RNA duplexes. While single modifications led to decreased duplex stability, the stacking of four consecutive modifications led to enhanced duplex stability, especially for DNA-RNA duplexes. The duplex structures were studied by CD spectroscopy and molecular dynamics simulations, which supported the conjecture that the duplex stabilizing effect is due to efficient stacking of the heteroaromatic triazoles.     

The Inhibition Effect of Photo-Cross-Linking between Probes in Photo-Induced Double Duplex Invasion DNA

Double duplex invasion (DDI) DNA is a useful antigene method that inhibits expression of genomic DNA. We succeeded in performing photoinduced-DDI (pDDI) using ultrafast photo-cross-linking. 5-Cyanouracil (^CNU) has been used in pDDI to inhibit photo-cross-linking between probes, but its importance has not been clarified. Therefore, in this study, we evaluated the effect of spacer (S) and d-spacer (dS) that exhibit photo-cross-linking ability similar to that of ^CNU. ^CNU exhibited the highest pDDI efficiency, and S, dS, and T were not very different. The photo-cross-linking inhibitory effect was better with S and dS than with thymidine (T). Conversely, the thermal stability was significantly lower with S and dS than with T. The results suggest that the pDDI efficiency is determined by the balance between the photo-cross-linking inhibitory effect and the thermal stability, which is the introduction efficiency for double-stranded DNA. Therefore, ^CNU, which has a photo-cross-linking inhibitory effect and a high T_m value, showed the highest inhibitory efficiency.     

Identification of trinucleotide repeat ligands with a FRET melting assay

DNA hairpin structures formed within a repeated tract might be a causative factor for triplet expansion observed in several debilitating diseases. We have designed and used a fluorescence resonance energy transfer (FRET) melting assay to screen for ligands that bind specifically to the CNG triplet repeats. Using this assay, we screened a panel of 33 chemicals that were previously designed to bind DNA or RNA secondary structures. Remarkably, we found that macrocyclic compounds, such as acridine dimers and trimers, exhibit interesting affinities and specificities for this motif.     

A Single Molecular Beacon Probe Is Sufficient for the Analysis of Multiple Nucleic Acid Sequences

Molecular beacon (MB) probes are dual‐labeled hairpin‐shaped oligodeoxyribonucleotides that are extensively used for real‐time detection of specific RNA/DNA analytes. In the MB probe, the loop fragment is complementary to the analyte: therefore, a unique probe is required for the analysis of each new analyte sequence. The conjugation of an oligonucleotide with two dyes and subsequent purification procedures add to the cost of MB probes, thus reducing their application in multiplex formats. Here we demonstrate how one MB probe can be used for the analysis of an arbitrary nucleic acid. The approach takes advantage of two oligonucleotide adaptor strands, each of which contains a fragment complementary to the analyte and a fragment complementary to an MB probe. The presence of the analyte leads to association of MB probe and the two DNA strands in quadripartite complex. The MB probe fluorescently reports the formation of this complex. In this design, the MB does not bind the analyte directly; therefore, the MB sequence is independent of the analyte. In this study one universal MB probe was used to genotype three human polymorphic sites. This approach promises to reduce the cost of multiplex real‐time assays and improve the accuracy of single‐nucleotide polymorphism genotyping.     

Modulation of the biological activity of microRNA-210 with peptide nucleic acids (PNAs)

Herein we describe the activity of a peptide nucleic acid (PNA) that targets microRNA‐210 (miR‐210), which is associated with hypoxia and is modulated during erythroid differentiation. PNAs directed against miR‐210 were designed to bind with high affinity to the target RNA strand and to undergo efficient uptake in target cells. A polyarginine–PNA conjugate directed against miR‐210 (Rpep‐PNA‐a210) showed both very high affinity for RNA and efficient uptake into target cells without the need for transfection reagents. An unmodified PNA of the same sequence displayed the ability to bind RNA, but cellular uptake was very poor. Consistent with this, only Rpep‐PNA‐a210 strongly inhibited miR‐210 activity, as evaluated by assays on undifferentiated K562 cells and on cells treated with mithramycin, which was found to induce erythroid differentiation and miR‐210 overexpression. Targeting miR‐210 by Rpep‐PNA‐a210 resulted in: 1) a decrease in miR‐210 levels as measured by RT‐PCR, 2) up‐regulation of raptor mRNA, 3) a decrease in γ‐globin mRNA, and 4) decreased expression of differentiated functions (i.e., proportion of benzidine‐positive cells, content of embryo‐fetal hemoglobins). The efficient delivery of anti‐miR PNAs through a suitable peptide carrier (Rpep‐PNA‐a210) leads to the inhibition of miR‐210 activity, altering the expression of miR‐210‐regulated erythroid functions.     

Nanoparticle-functionalized nucleic acids: A strategy for amplified electrochemical detection of some single-base mismatches

In this study, nanoparticle-functionalized nucleic acids were employed to improve the sensitivity of electrochemical DNA biosensors that make capable them to detect different types of single-base mismatches (SBMs), including thermodynamically stable ones. The present biosensor was constructed by the immobilization of platinum nanoparticles (Pt-NPs) on the surface of a carbon paste electrode (CPE) via SH-functionalized DNA. A redox probe of 2-mercapto-1-methyl imidazole (MMI), which has different electrochemical behavior on Pt-NP and CPE, was used. This behavior helps to overcome the pinhole effect in DNA hybridization biosensors. Additionally, in the present biosensor, the positioning of the redox probe under the SBM in DNA, which decreases the sensitivity of most DNA biosensors, did not contribute to the observed electrochemical signal.     

Sensitive SNP dual-probe assays based on pyrene-functionalized 2'-amino-LNA: lessons to be learned

A homogenous fluorescence dual-probe assay containing 2'-N-(pyren-1-ylmethyl)-2'-amino-LNA (locked nucleic acid) building blocks has been developed for effective mismatch-sensitive nucleic acid detection. The pyrene units, which are connected to the rigid bicyclic furanose derivative of 2'-amino-LNA through a short linker, are positioned at the 3' and 5' ends of a dual-probe system. Whereas hybridization with complementary DNA/RNA results in very strong excimer signals, as the pyrene units are in close proximity to one another in the ternary complex, exposure to most singly mismatched DNA/RNA targets results in significantly lower excimer emission intensity. The mechanism that underlies this excellent optical discrimination of singly mismatched targets is clarified by comparison of the thermal-denaturation profiles and fluorescence properties of the dual probe and a covalently linked analogue. Optical discrimination of singly mismatched targets arises from a decrease in excimer emission intensity due to a failure to form a ternary complex (a decrease in thermal stability) and/or local mismatch-induced changes in the helix geometry, depending on the position of the mismatched base pair. The devised dual-probe assay constitutes a simple and sensitive system for the detection of single-nucleotide polymorphism and highlights that conformational restriction combined with the use of short probes conveys favorable properties to dual-probe constructs.     

Design and In Vitro Evaluation of Splice-Switching Oligonucleotides Bearing Locked Nucleic Acids,Amido-Bridged Nucleic Acids,and Guanidine-Bridged Nucleic Acids

Our group previously developed a series of bridged nucleic acids (BNAs), including locked nucleic acids (LNAs), amido-bridged nucleic acids (AmNAs), and guanidine-bridged nucleic acids (GuNAs), to impart specific characteristics to oligonucleotides such as high-affinity binding and enhanced enzymatic resistance. In this study, we designed a series of LNA-, AmNA-, and GuNA-modified splice-switching oligonucleotides (SSOs) with different lengths and content modifications. We measured the melting temperature (T_m) of each designed SSO to investigate its binding affinity for RNA strands. We also investigated whether the single-stranded SSOs formed secondary structures using UV melting analysis without complementary RNA. As a result, the AmNA-modified SSOs showed almost the same T_m values as the LNA-modified SSOs, with decreased secondary structure formation in the former. In contrast, the GuNA-modified SSOs showed slightly lower T_m values than the LNA-modified SSOs, with no inhibition of secondary structures. We also evaluated the exon skipping activities of the BNAs in vitro at both the mRNA and protein expression levels. We found that both AmNA-modified SSOs and GuNA-modified SSOs showed higher exon skipping activities than LNA-modified SSOs but each class must be appropriately designed in terms of length and modification content.     

Pyrene-modified unlocked nucleic acids: synthesis, thermodynamic studies, and fluorescent properties

Two pyrene-modified UNA monomers were synthesized and incorporated into 21-mer DNA oligonucleotides. Melting temperatures and thermodynamic properties of the modified duplexes were measured, and the fluorescence properties of single strands and duplexes containing one or more pyrene-UNA modifications were studied. It was found that incorporation of pyrene-UNA monomers increased duplex stability relative to UNA monomers, and thermodynamic studies revealed significant mismatch discriminative capabilities of the pyrene-UNA modified oligonucleotides. Furthermore, the steady-state fluorescence emission intensities of pyrene-UNA modified oligonucleotides were increased upon hybridization to DNA, which to the best of our knowledge is unprecedented for an acyclic pyrene modification in DNA. Interestingly, pyrene excimer emission was observed for single-stranded oligonucleotides containing three pyrene-UNA modifications, whereas this excimer emission disappeared after hybridization to DNA. In view of both the pyrene monomer and the excimer fluorescence emission, the triply modified oligonucleotides show intriguing properties relating to the development of new DNA/RNA detection tools.     

On the in vitro and in vivo properties of four locked nucleic acid nucleotides incorporated into an anti-H-Ras antisense oligonucleotide

Locked nucleic acid (beta-D-LNA) monomers are conformationally restricted nucleotides bearing a methylene 2'-O, 4'-C linkage that have an unprecedented high affinity for matching DNA or RNA. In this study, we compared the in vitro and in vivo properties of four different LNAs, beta-D-amino LNA (amino-LNA), beta-D-thio LNA (thio-LNA), beta-D-LNA (LNA), and its stereoisomer alpha-L-LNA in an antisense oligonucleotide (ODN). A well-known antisense ODN design against H-Ras was modified at the 5'- and 3'-ends with the different LNA analogues (LNA-DNA-LNA gapmer design). The resulting gapmers were tested in cancer-cell cultures and in a nude-mouse model bearing prostate tumor xenografts. The efficacy in target knockdown, the biodistribution, and the ability to inhibit tumor growth were measured. All anti H-Ras ODNs were very efficient in H-Ras mRNA knockdown in vitro, reaching maximum effect at concentrations below 5 nM. Moreover, the anti-H-Ras ODN containing alpha-L-LNA had clearly the highest efficacy in H-Ras knockdown. All LNA types displayed a great stability in serum. ODNs containing amino-LNA showed an increased uptake by heart, liver, and lungs as compared to the other LNA types. Both alpha-L-LNA and LNA gapmer ODNs had a high efficacy of tumor-growth inhibition and were nontoxic at the tested dosages. Remarkably, in vivo tumor-growth inhibition could be observed at dosages as low as 0.5 mg kg(-1) per day. These results indicate that alpha-L-LNA is a very promising member of the family of LNA analogues in antisense applications.     

Enzymatic Incorporation of Modified Purine Nucleotides in DNA

A series of nucleotide analogues, with a hypoxanthine base moiety (8‐aminohypoxanthine, 1‐methyl‐8‐aminohypoxanthine, and 8‐oxohypoxanthine), together with 5‐methylisocytosine were tested as potential pairing partners of N⁸‐glycosylated nucleotides with an 8‐azaguanine or 8‐aza‐9‐deazaguanine base moiety by using DNA polymerases (incorporation studies). The best results were obtained with the 5‐methylisocytosine nucleotide followed by the 1‐methyl‐8‐aminohypoxanthine nucleotide. The experiments demonstrated that small differences in the structure (8‐azaguanine versus 8‐aza‐9‐deazaguanine) might lead to significant differences in recognition efficiency and selectivity, base pairing by Hoogsteen recognition at the polymerase level is possible, 8‐aza‐9‐deazaguanine represents a self‐complementary base pair, and a correlation exists between in vitro incorporation studies and in vivo recognition by natural bases in Escherichia coli, but this recognition is not absolute (exceptions were observed).