Effects of halogenated WNA derivatives on sequence dependency for expansion of recognition sequences in non-natural-type triplexes

The Development of Non-natural Type Nucleoside to Stabilize Triplex DNA Formation against CG and TA Inversion Site

Based on the sequence-specific recognition of target duplex DNA by triplexforming oligonucleotides (TFOs) at the major groove side, the antigene strategy has been exploited as a gene-targeting tool with considerable attention. Triplex DNA is formed via the specific base triplets by the Hoogsteen or reverse Hoogsteen hydrogen bond interaction between TFOs and the homo-purine strand from the target duplex DNA, leading to the established sequence-specificity. However, the presence of inversion sites, which are known as non-natural nucleosides that can form satisfactory interactions with 2'- deoxythymidine (dT) and 2'-deoxycytidine (dC) in TA and CG base pairs in the target homo-purine DNA sequences, drastically restricts the formation of classically stable base triplets and even the triplex DNA. Therefore, the design of non-natural type nucleosides, which can effectively recognize CG or/and TA inversion sites with satisfactory selectivity, should be of great significance to expanding the triplex-forming sequence. Here, this review mainly provides a comprehensive review of the current development of novel nonnatural nucleosides to recognize CG or/and TA inversion sites in triplex DNA formation against double-strand DNA (dsDNA).

Inhibition of transcription and antiproliferative effects in a cancer cell line using antigene oligonucleotides containing artificial nucleoside analogues

Antigene methods are promising novel therapeutic approaches to suppress abnormal gene expression. One of these methods inhibits transcription by forming triplex DNA against duplex DNA. However, by using natural-type triplex-forming oligonucleotides (TFOs), stable triplex formation is limited to homopurine and homopyrimidine strands in targeted duplex DNA. We recently developed artificial nucleoside analogues with the ability to recognize CG and TA inversion sites. We successfully formed stable unnatural-type triplex DNA for duplex DNA containing a CG base pair and extended the target sequence using TFOs containing 2-amino-3-methylpyridinyl pseudo-dC (3MeAP-ΨdC). Therefore, this present study investigated triplex-forming regions and synthesized antigene TFOs containing 3MeAP-ΨdC. Some of the synthesized antigene TFOs reduced transcription products and inhibited cell proliferation in several types of cultured cancer cells. The antigene effects of antigene TFOs containing artificial nucleic acids were markedly stronger than those of natural-type TFOs, and these results clearly demonstrated the usefulness of incorporating artificial nucleic acids within TFOs.

Modification of the aminopyridine unit of 2'-deoxyaminopyridinyl-pseudocytidine allowing triplex formation at CG interruptions in homopurine sequences

The antigene strategy based on site-specific recognition of duplex DNA by triplex DNA formation has been exploited in a wide range of biological activities. However, specific triplex formation is mostly restricted to homo-purine strands within the target duplex DNA, due to the destabilizing effect of CG and TA inversion sites where there is an absence of natural nucleotides that can recognize the CG and TA base pairs. Hence, the design of artificial nucleosides, which can selectively recognize these inversion sites with high affinity, should be of great significance. Recently, we determined that 2-amino-3-methylpyridinyl pseudo-dC (^3MeAP-ΨdC) possessed significant affinity and selectivity toward a CG inversion site and showed effective inhibition of gene expression. We now describe the design and synthesis of new modified aminopyridine derivatives by focusing on small chemical modification of the aminopyridine unit to tune and enhance the selectivity and affinity toward CG inversion sites. Remarkably, we have newly found that 2-amino-4-methoxypyridinyl pseudo-dC (^4OMeAP-ΨdC) could selectively recognize the CG base pair in all four adjacent base pairs and form a stable triplex structure against the promoter sequence of the human gene including multiple CG inversion sites.

Development of Novel Functional Molecules Targeting DNA and RNA

Nucleic acid therapeutics such as antisense and small interfering RNA (siRNA) have attracted increasing attention as innovative medicines that interfere with and/or modify gene expression systems. We have developed new functional oligonucleotides that can target DNA and RNA with high efficiency and selectivity. This review summarizes our achievements, including (1) the formation of non-natural triplex DNA for sequence-specific inhibition of transcription; (2) artificial receptor molecules for 8-oxidized-guanosine nucleosides; and (3) reactive oligonucleotides with a cross-linking agent or a functionality-transfer nucleoside for RNA pinpoint modification.

Synthesis of 2'-deoxy-4-aminopyridinylpseudocytidine Derivatives for Incorporation Into Triplex Forming Oligonucleotides

This unit describes the detailed synthetic protocol for the preparation of the phosphoramidite units of the 2'-deoxy-4-aminopyridinylpseudocytidine derivatives. These C-nucleoside derivatives are useful units for the incorporation into triplex forming oligonucleotides (TFOs) to form the stable triplex DNA containing the CG interrupting sites. Commercially available 1-methyl-2'-deoxypseudouridine is prepared from thymidine and 5-iodo-uracil by a simple method, that is, coupling of glycal and 5-iodo-1-methyluracil by the Heck reaction, followed by desilylation and diastereoselective reduction. The carbonyl group at the 4 position of the pseudouridine derivative is activated by 3-nitorotriazole and treated with the corresponding aromatic amine compounds to produce the 2'-deoxy-4-aminopyridinylpseudocytidine derivatives. These derivatives are then successfully converted to the phosphoramidite units and incorporated into the oligodeoxynucleotides. © 2019 by John Wiley & Sons, Inc.

Modular synthesis of new C-aryl-nucleosides and their anti-CML activity

The C-aryl-ribosyles are of utmost interest for the development of antiviral and anticancer agents. Even if several synthetic pathways have been disclosed for the preparation of these nucleosides, a direct, few steps and modular approaches are still lacking. In line with our previous efforts, we report herein a one step - eco-friendly β-ribosylation of aryles and heteroaryles through a direct Friedel-Craft ribosylation mediated by bismuth triflate, Bi(OTf)₃. The resulting carbohydrates have been functionalized by cross-coupling reactions, leading to a series of new C-aryl-nucleosides (32 compounds). Among them, we observed that 5d exerts promising anti-proliferative effects against two human Chronic Myeloid Leukemia (CML) cell lines, both sensitive (K562-S) or resistant (K562-R) to imatinib, the "gold standard of care" used in this pathology. Moreover, we demonstrated that 5d kills CML cells by a non-conventional mechanism of cell death.

Enhancement of TFO Triplex Formation by Conjugation with Pyrene via Click Chemistry

This paper reports the preparation of 14-mer triplex-forming oligonucleotides (TFOs) containing a 2-O-methyl-1-β-phenyl-α-propargyl-ribose unit, which was conjugated with azide-modified molecules via a click reaction. Modification of these TFOs with pyrene assisted triplex formation, improving the stability of the triplex DNA and the anti-proliferative effects against A549 cells.

Synthesis of C-arylnucleoside analogues

Modified nucleoside analogues are of great biological importance as antiviral and antitumoral agents. There is special interest in the preparation of C-aryl nucleosides with an aromatic ring in different positions of the glycone for their biological activity. Different chemical synthesis strategies for these targets are described in this review.

N-(guanidinoethyl)-2'-deoxy-5-methylisocytidine exhibits selective recognition of a CG interrupting site for the formation of anti-parallel triplexes

The development of novel nucleoside analogues for the formation of triplex DNA containing pyrimidine-purine inversion sites has been a challenging field. In this paper, we describe the design and synthesis of non-natural nucleoside analogues, N-substituted-2'-deoxy-5-methylisocytidine derivatives, and their evaluation for triplex formation. It has been shown that N-(guanidinoethyl)-2'-deoxy-5-methylisocytidine exhibits selective recognition of a CG interrupting site and potentiates the formation of anti-parallel triplexes.

Properties of oligonucleotide with phenyl-substituted carbocyclic nucleoside analogs for the formation of duplex and triplex DNA

(1S,3S,4R)-1-Phenyl-1-thymidyl-3-hydroxy-4-hydroxymethylcyclopentane (10) and their analogs were synthesized, incorporated into the oligodeoxynucleotides, and their properties were evaluated for the formation of duplex and triplex DNA. The known chiral cyclopentanone derivative was converted into the corresponding ketimine sulfonamide derivative, which was subjected to a stereoselective PhLi addition. The formed sulfonamide was hydrolyzed to afford the primary amino group, on which the thymine moiety was built. The benzyl protecting groups were removed to form the nucleoside analog having a phenyl group and the thymine unit at the 1' position of a carbocyclic skeleton (10). In the estimation of the oligodeoxynucleotides incorporating 10 for duplex and triplex formation, the carbocyclic nucleoside analog 10 did not show the stabilizing effect for duplex formation; on the other hand, it stabilized the triplex. Therefore, the skeleton of the phenyl-substituted carbocyclic nucleoside analog 10 may be a platform for the formation of stable triplex DNA.

An efficient antigene activity and antiproliferative effect by targeting the Bcl-2 or survivin gene with triplex forming oligonucleotides containing a W-shaped nucleoside analogue (WNA-βT)

Triplex forming oligonucleotides (TFOs) are some of the most promising tools in the antigene strategy for the development of gene targeting therapeutics. However, the stable triplex formation is restricted to the homopurine sequences consisting of purine nucleosides, dG and dA. Therefore, the T or dC nucleoside in the homopurine strand inhibits the stable triplex formation. We have developed W-shaped nucleoside analogues (WNAs) for the formation of the unnatural type triplex DNA, with sequences containing the interrupting site in an antiparallel triplex formation. In the present study, we tested the antigene effect of TFOs having WNA-βT, which increased the stability of the triplex formation with a target sequence including the TA interrupting site. We designed the GU TFO (WNA) and GU TFO (natural) for targeting sequences of the Bcl-2 or survivin oncogene. The gel shift assay showed that the TFO (WNA) formed more stable triplexes than the natural TFO. Remarkably, the Bcl-2- or survivin-targeted TFO (WNA) inhibited the cell proliferation and induced a caspase-dependent apoptosis. It was confirmed that the survivin-targeted TFO (WNA) more effectively decreased the number of survivin products in the A549 cell than the natural TFOs.

Targeting duplex DNA with chimeric α,β-triplex-forming oligonucleotides

Triplex-directed DNA recognition is strictly limited by polypurine sequences. In an attempt to address this problem with synthetic biology tools, we designed a panel of short chimeric α,β-triplex-forming oligonucleotides (TFOs) and studied their interaction with fluorescently labelled duplex hairpins using various techniques. The hybridization of hairpin with an array of chimeric probes suggests that recognition of double-stranded DNA follows complicated rules combining reversed Hoogsteen and non-canonical homologous hydrogen bonding. In the presence of magnesium ions, chimeric TFOs are able to form highly stable α,β-triplexes, as indicated by native gel-electrophoresis, on-array thermal denaturation and fluorescence-quenching experiments. CD spectra of chimeric triplexes exhibited features typically observed for anti-parallel purine triplexes with a GA or GT third strand. The high potential of chimeric α,β-TFOs in targeting double-stranded DNA was demonstrated in the EcoRI endonuclease protection assay. In this paper, we report, for the first time, the recognition of base pair inversions in a duplex by chimeric TFOs containing α-thymidine and α-deoxyguanosine.

Efficient DNA strand displacement by a W-shaped nucleoside analogue (WNA-βT) containing an ortho-methyl-substituted phenyl ring

Molecules that can target duplex DNA with sequence selectivity have the potential to be useful tools in genomic research and also as therapeutic agents. Homopurine-homopyrimidine stretches in duplex DNA can be recognized by homopurine or homopyrimidine TFOs (triplex-forming oligonucleotides) through the formation of triplex DNA. We have previously developed bicyclic nucleoside analogues (WNAs) for the formation of stable triplexes in the formation of stable antiparallel triplexes containing a TA or a CG interrupting site. In this study, we investigated the effects on triplex DNA formation of ortho-, meta-, and para-methyl substituent groups on the aromatic ring of the WNA analogue. It was found that the homopurine TFO containing meta- and para-methyl-substituted WNA-βT (mMe-WNA-βT, pMe-WNA-βT) stabilized triplexes containing a TA interrupting site or a GC site, respectively. Interestingly, the ortho-methyl-substituted WNA-βT (oMe-WNA-βT) efficiently promoted DNA strand displacement to form the TFO/pyrimidine duplex. A detailed investigation showed that the duplex was in the antiparallel orientation and that its formation took place prior to triplex formation with the need for a magnesium cation. NOESY measurements indicated a significant difference in the rotation flexibilities of the phenyl rings of WNA-βTs: that is, the conformation of the ortho-methylated phenyl ring was stable in a temperature-independent manner. It was speculated that the initial formation of a ternary complex was followed by strand displacement and then the formation of the TFO/pyrimidine duplex together with the TFO(2)/pyrimidine triplex formation during the early stage, and that the equilibrium shifted to the triplex during the later stage. Although the detailed role is still uncertain, the fixed phenyl ring of oMe-WNA-βT might play a role in the displacement reaction.

Recognition of CG interrupting site by W-shaped nucleoside analogs (WNA) having the pyrazole ring in an anti-parallel triplex DNA

We have previously developed W-shaped nucleoside analogs (WNA) for recognition of TA and CG interrupting sites, which are the intrinsic limitation for the formation of a stable triplex DNA by the natural triplex-forming oligonucleotide (TFO). However, the stabilization effect of WNA is dependent on the neighboring nucleobases at both sides of the WNA analogs within the TFO. Considering that the base is located at the hindered site constructed of three bases of the target duplex and the TFO, it was expected that replacement of the pyrimidine base of the WNA analog with a smaller pyrazole ring might avoid steric repulsion to produce a greater stability for the triplex. In this study, the new WNA analogs bearing the pyrazole ring, 3-aminopyrazole (AP), and 4-methyl-3-pyrazole-5-on (MP) were synthesized, incorporated into the TFOs, then their stabilizing effects on the triplexes were evaluated. A remarkable success was illustrated by the fact that the TFO containing WNA-betaAP in the 3'G-WNA-G-5' sequence formed a stable triplex with selectivity to the CG interrupting site where the previous WNA-betaC did not induce the triplex formation.

Unnatural nucleosides with unusual base pairing properties

Synthetic modified nucleosides designed to pair in unusual ways with natural nucleobases have many potential applications in biology and biotechnology. This overview lays the foundation for future protocol units on synthesis and application of unnatural bases, with particular emphasis on unnatural base analogs that mimic natural bases in size, shape, and biochemical processing. Topics covered include base pairs with alternative H-bonding schemes, dimensionally expanded base pairs, hydrophobic base pairs, metal-ligated bases, degenerate bases, universal nucleosides, and triplex constituents.

Cross-linking to an interrupted polypurine sequence with a platinum-modified triplex-forming oligonucleotide

Triplex-forming oligonucleotides (TFOs) can bind specifically to polypurine sequences in double-stranded DNA. A single interruption of this polypurine tract can greatly destabilize triplex formation. The stability of triplexes can be significantly enhanced by covalently linking the TFO to its DNA target with reactive functional groups conjugated to the TFO. Covalently cross-linked TFOs are effective inhibitors of transcription of the target DNA sequence. We have designed a TFO with a platinum-modified base that can interact with and cross-link to a cytosine interruption in the polypurine tract of a target DNA duplex. The TFO contains an N(4)-(aminoalkyl)cytosine derivatized with cis-diamminediaquaplatinum(II) or trans-diamminediaquaplatinum(II). When bound to its target, the tethered platinum of the TFO can reach across the major groove and form an adduct with the guanine N7 of the interrupting C.G base pair. The optimal tether length is five methylene groups, and cross-linking is most efficient when the tether is modified with trans-diamminediaquaplatinum(II). Cross-linking requires that the TFO is bound to its designated DNA target. Addition of cyanide to the cross-linked TFO product reversed the cross-link, behavior that is consistent with the presence of a platinum-guanine adduct. The kinetics of the cross-linking reaction were studied and the half-life of the cross-linking reaction was approximately 3 h. Our results demonstrate that platinum-conjugated TFOs can be designed to cross-link with DNA targets that contain a single pyrimidine interruption. Modifications of this type may prove useful for expanding the DNA sequences that can be targeted by TFOs and increasing the stability of the resulting triplexes.

Interactions of platinum(II)-derivatized triplex-forming oligonucleotides with DNA

Polypyrimidine oligonucleotides can bind to tracts of contiguous purines in double-stranded DNA to form triple-stranded complexes. The stability of the triplex is reduced significantly if the target purine tract is interrupted by a single pyrimidine. Previous studies have shown that incorporation of an N4-aminoalkylcytosine into the triplex-forming oligonucleotide (TFO), opposite a single CG interruption, facilitates triplex formation. Examination of molecular models suggested that further modification of the amino group of the aminoalkyl arm might enable adduct formation with the N7 of the guanine of the CG interruption. To test this, we prepared 2′-deoxyribo-and 2′-O-methylribo-TFOs that contained cytosine (C), N4-(2-aminoethyl)cytosine (ae-C), or diethylenetriamineplatinum(II) (DPt-C) or cis-aquodiammineplatinum(II) (cPt-C) derivatives of N4-(2-aminoethyl)cytosine, positioned opposite a CG interruption of a polypurine tract found in the pol gene of HIV-1 proviral DNA. Although the C- and ae-C-derivatized deoxyribo-TFOs formed triplexes of modest stability and the DPt-C-modified TFO failed to form a triplex, the C- and ae-C-derivatized 2′-O-methylribo-TFOs formed remarkably stable triplexes (Tm = 57 °C). The DPt-C- and cPt-C-modified 2′-O-methylribo-TFOs also formed triplexes, although their stabilities were reduced (Tm = 33 °C), suggesting that the tethered platinum group may interfere sterically with TFO binding. Consistent with this hypothesis was the observation that triplex stability was restored (Tm = 57 °C) when the diethylenetriamineplatinum(II) group was tethered to the 5′-end of the 2′-O-methylribo-TFO via a 2-aminoethylcarbamate linkage. Taken together, these results suggest that 2′-O-methylribo-TFOs may be particularly useful in targeting purine tracts in DNA that have CG interruptions, and that further modification with platinum derivatives could lead to the design of TFOs that are capable of covalent binding to their target, thus increasing the effectiveness of the TFO.Key words: triplex-forming oligonucleotide, TFO, cisplatin, interrupted polypurine tract.