Facilitation of the cellular uptake of a triplex-forming oligonucleotide by novel polyamine analogues: structure-activity relationships.

The inefficient uptake of oligodeoxynucleotides, including that of TFO, through the cell membrane is a limiting factor in developing gene therapy approaches for cancer and other diseases. To develop a new strategy for oligonucleotide delivery into the nucleus, we synthesized a series of novel polyamine analogues and examined their effects on the uptake of a 37-mer [32P]-labeled TFO, targeted to the promoter region of c-myc oncogene. We used MCF-7 breast cancer cells to investigate the efficacy of polyamines on the internalization of the TFO. The uptake of TFO was enhanced by complexing it with several unsubstituted polyamine analogues at 0. 1-5 microM concentrations, with up to 6-fold increase in TFO uptake in the presence of a hexamine, 1,21-diamino-4,9,13, 18-tetraazahenicosane (H2N(CH2)(3)NH(CH2)(4)NH(CH2)(3)NH(CH2)(4)NH(CH2)(3)NH(2) or 3-4-3-4-3). TFO uptake increased with the cationicity of the polyamines; however, bis(ethyl) substitution and structural features of the methylene bridging region had significant effects on TFO uptake. The majority of labeled TFO was recovered from the nuclear fraction containing genomic DNA. Electrophoretic mobility shift assay revealed enhanced binding of TFO to a target duplex containing promoter region sequence of c-myc oncogene. Treatment of MCF-7 cells with the TFO complexed with 0.5 microM 3-4-3-4-3 suppressed c-myc mRNA level by 65%, as determined by Northern blot analysis. These data indicate a novel approach to deliver oligodeoxynucleotides to the cell nucleus, and suppress the expression of target genes, and provide new insights into the mechanism of oligonucleotide transport in living cells.     

133 Designed DNA crystals with a triple-helix veneer

DNA has been used as a tool for the self-assembly of nano-sized objects and arrays in two and three-dimensions. Triplex-forming oligonucleotides (TFOs) can be exploited to recognize and introduce functionality at precise duplex regions within these DNA nanostructures (Rusling et al., 2012). Here we have examined the feasibility of using TFOs to bind to specific locations within a 3-turn DNA tensegrity triangle motif. The tensegrity triangle is a rigid DNA motif with three-fold rotational symmetry, consisting of three helices directed along three linearly independent directions (Liu et al., 2004). The triangles form a three-dimensional crystalline lattice stabilized via sticky-end cohesion (Zheng et al., 2009). The TFO 5′-TTCTTTCTTCTCT was used to target the tensegrity motif containing an appropriately embedded oligopurine–oligopyrimidine binding site. Formation of DNA triplex in the motif was characterized by an electrophoretic mobility shift assay (EMSA), UV melting studies and FRET analysis. Non-denaturing gel analysis of annealed DNA motifs showed a band with slower mobility only in the presence of TFO and only when the DNA motif contained the triplex binding site. Experiments were undertaken at pH 5.0, since the formation of a triplex with cytidine-containing TFOs requires slightly acidic conditions (pH<?6.0). TFOs with modified C-analogs and T-analogs having a higher pK _a worked at a more neutral pH, also evidenced by EMSA. UV melting studies revealed that the melting point of the 3-turn triangle was 64?°C and the TFO binding increased the melting point to 80?°C. FRET analysis was done by labeling the triangle with fluorescein and the TFO with a cyanine dye (Cy5). The FRET melting curve revealed that a signal was observed only when the TFO was bound to the DNA motif and the results were consistent with UV melting studies. These results indicate that a TFO can be specifically targeted to the tensegrity triangle motif.     

Sulfur signaling: is the agent sulfide or sulfane?

Triplex-forming oligonucleotides (TFOs) are sequence-dependent DNA binders that may be useful for DNA targeting and detection. A sensitive and convenient method to monitor triplex formation by a TFO and its target DNA duplex is required for the application of TFO probes. Here we describe a novel design by which triplex formation can be monitored homogeneously without prelabeling the target duplex. The design uses a TFO probe tagged with a fluorophore that undergoes fluorescence resonance energy transfer with fluorescent dyes that intercalate into the target duplex. Through color compensation analysis, the specific emission of the TFO probe reveals the status of the triple helices. We used this method to show that triple helix formation with TFOs is magnesium dependent. We also demonstrated that the TFO probe can be used for detection of sequence variation in melting analysis and for DNA quantitation in real-time polymerase chain reaction.     

Sequence-specific gene cleavage in intact mammalian cells by 125I-labeled triplex-forming oligonucleotides conjugated with nuclear localization signal peptide

Triplex-forming oligonucleotides (TFO) are designed to bind sequence specifically to their DNA targets without a significant disturbance of the double helix. They have been proposed to deliver DNA-reactive agents to specific DNA sequences for gene targeting applications. We suggested the use of 125I-labeled TFO for delivery of the energy of radioiodine decay to specific genes. This approach is called antigene radiotherapy. Here we demonstrate the ability of 125I-labeled TFO to produce sequence-specific breaks within a target in the human mdrl gene in cultured cells. TFO and TFO conjugated with a nuclear localization signal peptide (NLS) were delivered into cells using cationic liposomes. This was done either alone or in the presence of an excess of a "ballast" oligonucleotide with an unrelated sequence. In all cases, nuclear localization of TFO and survival of the cells after treatment has been confirmed. Breaks in the gene target were analyzed by restriction enzyme digestion of the DNA recovered from the TFO-treated cells followed by Southern hybridization with DNA probes flanking the target sequence. We have found that TFO/NLS conjugates cleave the target in a concentration-dependent manner regardless of the presence of the "ballast" oligonucleotide. In contrast, TFO without NLS cleaved the target only in the presence of an excess of the "ballast." We hypothesize that TFO and TFO/NLS are delivered into the nucleus by different pathways. These results provide a new insight into the mechanism of intracellular transport of oligonucleotides and open new avenues for improvement of the efficacy of antigene therapies.     

Synthesis and evaluation of a triplex-forming oligonucleotide-pyrrolobenzodiazepine conjugate

In most cases, unmodified oligonucleotides designed as antigene molecules are incapable of binding to DNA with sufficient stability to prevent gene expression. To stabilize binding to a polypurine tract in the HER-2/neu promoter, a triplex forming oligonucleotide (TFO) was conjugated to a pyrrolo[1,4]benzodiazepine (PBD), desmethyltomaymycin, and site-specific DNA binding was evaluated. An activated ester of the PBD moiety was conjugated by an acylation reaction to a free primary amine on a 50-atom aliphatic linker at the 5' end of the TFO. This long aliphatic linker was designed to provide a bridge from the major groove binding site of the TFO to the minor groove binding site of the PBD. Triplex formation by the resulting TFO-PBD conjugate occurred more slowly and with a nearly 30-fold lower affinity compared to an unconjugated TFO. PBD binding to the triplex target was demonstrated by protection from restriction enzyme digestion, and covalent binding to the exocyclic amino group of guanine was inferred by substituting specific guanines with inosines. Although the binding of the TFO was less efficient, this report demonstrates that in principle, TFOs can be used to direct the binding of a PBD to specific location. Further optimization of TFO-PBD conjugate design, likely involving optimization of the linker and perhaps placing a PBD at both ends of the TFO, will be needed to make gene modification robust.     

Improved synthesis of daunomycin conjugates with triplex-forming oligonucleotides. The polypurine tract of HIV-1 as a target

Triple helix-forming oligonucleotides (TFOs) are promising agents for the control of gene expression, as they can selectively bind to a chosen oligopyrimidine.oligopurine region of a gene of interest thus interfering with its expression. The stability of the triplex formed by the TFO and the duplex is often too poor for successful applications of TFOs in vivo and the conjugation of a DNA intercalating moiety to the TFO is a common way to enhance the TFO affinity for its target. In a previous work, we investigated the properties of daunomycin conjugated TFO (dauno-TFO) and found that this class of compounds showed a higher degree of affinity than native oligonucleotides for an oligopyrimidine.oligopurine duplex target and that the presence of the amino sugar increases such stability. Here, we report a significantly improved synthetic procedure for the preparation of the conjugates, based on the protection of the daunosamine moiety by N-trifluoroacetylation. This protecting group is removed as a final step from the conjugation product by mild basic hydrolysis to give the desired dauno-TFO. Compared to the previous synthetic procedure, the improvement is important. The synthesis is now more reproducible and no side products are formed. Moreover, the thus protected daunomycin derivative is very stable, up to at least one year. Two dauno-TFOs, differing by the length of the oligonucleotide moiety, were prepared to target the polypurine tract (PPT) of HIV-1. Triplex formation by these compounds with model duplexes was studied by UV spectroscopy, thermal gradient gel electrophoresis (TGGE) and gel electrophoretic mobility shift. The experimental results demonstrate that dauno-TFOs bind to the PPT of HIV-1 more strongly than the unconjugated TFOs.     

Synthesis and triplex forming ability of conformationally locked oligonucleotides containing unnatural nucleobases: efficient recognition of a C.G interruption.

In order to develop a novel nucleoside analogue which recognizes C.G interruption in homopurine.homopyrimidine DNA, we designed and synthesized a conformationally locked nucleoside analogue, 1-(2-O,4-C-methylene-beta-D-ribofuranosyl)pyridin-2-one (4), and introduced it into a triplex-forming oligonucleotide (TFO). On melting temperature (Tm) measurements, the unprecedented C.G base recognition ability of 4 was observed.     

Promotion of triplex formation by a fixed N-form sugar puckering: thermodynamic and kinetic studies.

We analyzed the effect of a fixed N-form sugar puckering of TFO (triplex-forming oligonucleotide) on the pyrimidine motif triplex formation at neutral pH, a condition where pyrimidine motif triplexes are unstable. Both thermodynamic and kinetic analyses revealed that the binding constant of the pyrimidine motif triplex formation at pH 6.8 with modified TFO containing the fixed N-form sugar puckering was about 20-times larger than that observed with unmodified TFO. Kinetic data also demonstrated that the observed increase in the binding constant at neutral pH by the fixed N-form sugar puckering resulted from the considerable decrease in the dissociation rate constant. Our results certainly support the idea that the fixed N-form sugar puckering of TFO could be a key modification and may eventually lead to progress in therapeutic applications of the antigene strategy in vivo.     

Interrupted 2'-o,4'-C-aminomethylene bridged nucleic acid modification enhances pyrimidine motif triplex-forming ability and nuclease resistance under physiological condition

Due to instability of pyrimidine motif triplex DNA at physiological pH, triplex stabilization at physiological pH is crucial in improving its potential in various triplex formation-based strategies in vivo, such as regulation of gene expression, mapping of genomic DNA, and gene-targeted mutagenesis. To this end, we investigated the effect of our previously reported chemical modification, 2'-O,4'-C-aminomethylene bridged nucleic acid (2',4'- BNA(NC)) modification, introduced into interrupted and continuous positions of triplex-forming oligonucleotide (TFO) on pyrimidine motif triplex formation at physiological pH. The interrupted 2',4'-BNA(NC) modifications of TFO increased the binding constant of the triplex formation at physiological pH by more than 10-fold, and significantly increased the nuclease resistance of TFO. On the other hand, the continuous 2',4'-BNA(NC) modification of TFO showed lower ability to promote the triplex formation at physiological pH than the interrupted 2',4'-BNA(NC) modifications of TFO, and did not significantly change the nuclease resistance of TFO. Selection of the interruptedly 2',4'-BNA(NC)-modified positions in TFO was more favorable for achieving the higher binding affinity of the pyrimidine motif triplex formation at physiological pH and the higher nuclease resistance of TFO than that of the continuously 2',4'-BNA(NC)-modified positions in TFO. We conclude that the interrupted 2',4'-BNA(NC) modification of TFO could be a key chemical modification to enhance pyrimidine motif triplex-forming ability and nuclease resistance under physiological condition, and may eventually lead to progress in various triplex formation-based strategies in vivo.     

Triple helix formation: binding avidity of acridine-conjugated AG motif third strands containing natural, modified and surrogate bases opposed to pyrimidine interruptions in a polypurine target.

A critical issue for the general application of triple-helix-forming oligonucleotides (TFOs) as modulators of gene expression is the dramatically reduced binding of short TFOs to targets that contain one or two pyrimidines within an otherwise homopurine sequence. Such targets are often found in gene regulatory regions, which represent desirable sites for triple helix formation. Using intercalator-conjugated AG motif TFOs, we compared the efficacy and base selectivity of 13 different bases or base surrogates in opposition to pyrimidines and purines substituted into selected positions within a paradigm 15-base polypurine target sequence. We found that substitutions closer to the intercalator end of the TFO (positions 4-6) had a more deleterious effect on the dissociation constant (K d) than those farther away (position 11). Opposite T residues at position 11, 3-nitropyrrole or cytosine in the TFO provided adequate binding avidity for useful triplex formation (K ds of 55 and 110 nM, respectively). However, 3-nitropyrrole was more base selective than cytosine, binding to T >/=4 times better than to A, G or C. None of the TFOs tested showed avid binding when C residues were in position 11, although the 3-nitropyrrole-containing TFO bound with a K d of 200 nM, significantly better than the other designs. Molecular modeling showed that the 3-nitropyrrole.T:A triad is isomorphous with the A.A:T triad, and suggests novel parameters for evaluating new base triad designs.     

Targeted correction of an episomal gene in mammalian cells by a short DNA fragment tethered to a triplex-forming oligonucleotide

Triplex-forming oligonucleotides (TFOs) can bind to polypurine/polypyrimidine regions in DNA in a sequence-specific manner and provoke DNA repair. We have coupled a TFO to a short donor fragment of DNA that shares homology to a selected gene as a strategy to mediate gene targeting and correction. In this bifunctional oligonucleotide, the TFO domain is designed to bind the target gene and stimulate repair and recombination, with the donor domain positioned for recombination and information transfer. A series of these tethered donor-TFO (TD-TFO) molecules with donor domains of 40-44 nucleotides and TFO domains in both the purine and pyrimidine triplex motifs were tested for their ability to mediate either gene correction or mutation of a supF reporter gene contained in a SV40 shuttle vector in mammalian cells. In vitro binding assays revealed that the attachment of the donor domain via a flexible linker did not significantly alter the binding affinity of the TFO domain for the polypurine site in the supF target DNA, with equilibrium dissociation constants in the 10(-8) M range. Experiments in which the target vector and the linked TD-TFOs were pre-incubated in vitro and co-transfected into cells led to conversion frequencies approaching 1%, 4-fold greater than with the two domains unlinked. When cells that had been previously transfected with the SV40 vector were electroporated with the TD-TFOs, frequencies of base pair-specific gene correction were seen in the range of 0.04%, up to 50-fold over background and at least 3-fold over either domain alone or in unlinked combinations. Sequence conversion by the TD-TFOs was achieved using either single- or double-stranded donor domains and either triplex motif. Substitution of either domain in the TD-TFO with control sequences yielded reagents with diminished activity, as did mixtures of unlinked TFO and donor DNA segments. The boost in activity provided by the attached TFO domain was reduced in cells deficient in the nucleotide excision repair factor XPA but was restored in a subclone of these cells expressing XPA cDNA, suggesting a role for nucleotide excision repair in the pathway of triple helix-stimulated gene conversion. The ability to correct or mutate a specific target site in mammalian cells using the TD-TFO strategy may provide a useful tool for research and possibly for therapeutic applications.     

Presence of 2',5'-linkages in a homopyrimidine DNA oligonucleotide promotes stable triplex formation under physiological conditions

We prepared 15-mer homopyrimidine oligonucleotides containing three or four 2',5'-linked DNA units, and their ability as a triplex-forming oligonucleotide (TFO) was analyzed in detail UV melting experiments showed that replacement of a 3',5'-linkage by a 2',5'-linkage at every third or fourth residue in TFO significantly promoted stable triplex formation under physiological conditions.     

Intercalator conjugates of pyrimidine locked nucleic acid-modified triplex-forming oligonucleotides: improving DNA binding properties and reaching cellular activities

Triplex-forming oligonucleotides (TFOs) are powerful tools to interfere sequence-specifically with DNA-associated biological functions. (A/T,G)-containing TFOs are more commonly used in cells than (T,C)-containing TFOs, especially C-rich sequences; indeed the low intracellular stability of the non-covalent pyrimidine triplexes make the latter less active. In this work we studied the possibility to enhance DNA binding of (T,C)-containing TFOs, aiming to reach cellular activities; to this end, we used locked nucleic acid-modified TFOs (TFO/LNAs) in association with 5′-conjugation of an intercalating agent, an acridine derivative. In vitro a stable triplex was formed with the TFO-acridine conjugate: by SPR measurements at 37°C and neutral pH, the dissociation equilibrium constant was found in the nanomolar range and the triplex half-life ~10 h (50-fold longer compared with the unconjugated TFO/LNA). Moreover to further understand DNA binding of (T,C)-containing TFO/LNAs, hybridization studies were performed at different pH values: triplex stabilization associated with pH decrease was mainly due to a slower dissociation process. Finally, biological activity of pyrimidine TFO/LNAs was evaluated in a cellular context: it occurred at concentrations ~0.1 μM for acridine-conjugated TFO/LNA (or ~2 μM for the unconjugated TFO/LNA) whereas the corresponding phosphodiester TFO was inactive, and it was demonstrated to be triplex-mediated.