Triple helix formation with purine-rich phosphorothioate-containing oligonucleotides covalently linked to an acridine derivative.

Purine-rich (GA)- and (GT)-containing oligophosphorothioates were investigated for their triplex-forming potential on a 23 bp DNA duplex target. In our system, GA-containing oligophosphorothioates (23mer GA-PS) were capable of triplex formation with binding affinities lower than (GA)-containing oligophosphodiesters (23mer GA-PO). The orientation of the third strand 23mers GA-PS and GA-PO was antiparallel to the purine strand of the duplex DNA target. In contrast, (GT)-containing oligophosphorothioates (23mer GT-PS) did not support triplex formation in either orientation, whereas the 23mer GT-PO oligophosphodiester demonstrated triplex formation in the antiparallel orientation. GA-PS oligonucleotides, in contrast to GT-PS oligonucleotides, were capable of self-association, but these self-associated structures exhibited lower stabilities than those formed with GA-PO oligonucleotides, suggesting that homoduplex formation (previously described for the 23mer GA-PO sequence by Noonberg et al.) could not fully account for the decrease in triplex stability when phosphorothioate linkages were used. The 23mer GA-PS oligonucleotide was covalently linked via its 5'-end to an acridine derivative (23mer Acr-GA-PS). In the presence of potassium cations, this conjugate demonstrated triplex formation with higher binding affinity than the unmodified 23mer GA-PS oligonucleotide and even than the 23mer GA-PO oligonucleotide. A (GA)-containing oligophosphodiester with two phosphorothioate linkages at both the 5'- and 3'-ends exhibited similar binding affinity to duplex DNA compared with the unmodified GA-PO oligophosphodiester. This capped oligonucleotide was more resistant to nucleases than the GA-PO oligomer and thus represents a good alternative for ex vivo applications of (GA)-containing, triplex-forming oligonucleotides, allowing a higher binding affinity for its duplex target without rapid cellular degradation.     

Secondary binding sites for triplex-forming oligonucleotides containing bulges, loops, and mismatches in the third strand

We have used DNase I footprinting to examine the binding of five different 17-mer oligonucleotides to a 53-base oligopurine tract containing four pyrimidine interruptions. Although all the expected triplexes formed with high affinity (K(d) approximately 10-50 nM), one oligonucleotide produced a footprint at a second site with about 20-fold lower affinity. We have explored the nature of this secondary binding site and suggest that it arises when each end of the third strand forms a 7-mer triplex with adjacent regions on the duplex, generating a contiguous 14-base triplex with a bulge in the center of the third strand oligonucleotide. This unusual binding mode was examined by use of oligonucleotides that were designed with the potential to form different length third-strand loops of various base composition. We find that triplexes containing single-base bulges are generally more stable than those with dinucleotide loops, though triplexes can be formed with loops of up to nine thymines, generating complexes with submicromolar dissociation constants. These structures are much more stable than those formed by adding two separate 7-mer oligonucleotides, which do not generate DNase I footprints, though a stable complex is generated when the two halves are covalently joined by a hexa(ethylene glycol) linker. MPE produces less clear footprints, presumably because this cleavage agent binds to triplex DNA, but confirms that the oligonucleotides can bind in unexpected places. These results suggest that extra care needs to be taken when designing long triplex-forming oligonucleotides so as to avoid triplex formation at shorter secondary sites.     

Application of synthetic oligonucleotides to the diagnosis of human genetic diseases

Under appropriate conditions synthetic oligonucleotide hybridization probes display essentially absolute hybridization specificity. That is, every nucleotide must form a Watson-Crick base pair in order that the probe forms a stable duplex. All of the non-Watson-Crick base pairs, including G-T, have a destabilizing effect. Thus, it is possible to choose stringent conditions of hybridization such that, while a perfectly matched duplex between an oligonucleotide and complementary DNA will form, duplexes mismatched at one or more position will not. Mutations in a single base in the DNA sequence of a gene can and do result in genetic diseases. The hybridization of oligonucleotides to the region of DNA containing these base changes would be affected by the mutations and thus, oligonucleotide hybridization provides a means of detecting single base changes. In an attempt to develop a non-radioactive method for the detection of human genetic diseases, we have prepared biotinylated-oligonucleotides by an enzymatic method. An oligonucleotide probe (23-mer) containing a single biotinylated deoxyuridine residue at the 3'-terminus was prepared by a primer extention reaction using E. coli DNA polymerase I (Klenow fragment). The probe could be specifically and tightly bound with Avidin D in 1 M NaCl. It could be hybridized to a plasmid DNA containing a perfectly matched complementary sequence, but not to a DNA containing 5 non-consecutive non-complementary bases. The hybridized biotinylated probe could be visualized by Avidin D and biotinylated alkaline phosphatase, even when 1.8 ng of the plasmid DNA (0.5 fmol) was used. A general approach to the enzymatic synthesis of oligonucleotides containing a single biotinylated deoxyuridine at the 3' end is described.     

Specific oligonucleotide invasion into the end of DNA duplex

Phenomenon of the interaction of a double-stranded DNA fragment with an oligonucleotide complementary to the end of the duplex strand was demonstrated to occur via formation of three-stranded DNA structure with an oligonucleotide invasion. It was shown that oligonucleotides complementary to the duplex ends inhibit Holliday junction formation in solutions of homologous linear DNA fragments. This effect depends on the oligonucleotide concentration, sequence and their complementarity to the duplex ends. Formation of three-stranded complexes was demonstrated using radiolabeled oligonucleotides by agarose gel-electrophoresis followed by autoradiography. Analysis of three-stranded DNA structures by chemical cleavage of non-canonical base pairs revealed that oligonucleotide invades into duplex ends via a sequential displacement mechanism and that the level of the invasion may vary considerably.     

Cationic oligonucleotides can mediate specific inhibition of gene expression in Xenopus oocytes.

Base-specific hydrogen bonding between an oligonucleotide and the purines in the major groove of a DNA duplex provide an approach to selective inhibition of gene expression. Oligonucleotide-mediated triplex formation in vivo may be enhanced by a number of different chemical modifications. We have previously described an in vitro analysis of triplex formation using oligonucleotides containing internucleoside phosphate linkages modified with the cation N , N -diethyl-ethylenediamine (DEED). When compared with unmodified oligonucleotides of identical base composition, DEED-modified oligonucleotides were better able to form DNA triplexes under conditions that approximate the pH, magnesium and potassium levels found in vivo . Here we report the ability of DEED-modified oligonucleotides to inhibit the expression of plasmid DNA injected into Xenopus oocytes. Inhibition is specific to plasmids containing a triplex formation target and sensitive to sequence alteration in the triplex forming target site. Inhibition of gene expression was nearly complete when oligonucleotide and plasmid were mixed together prior to injection. Inhibition was partial when oligonucleotide was injected first and not evident when plasmid was injected and allowed to form chromatin prior to oligonucleotide injection. Thus, access to DNA is a determining factor in effective triplex inhibition of gene expression.     

Detection and kinetic studies of triplex formation by oligodeoxynucleotides using real-time biomolecular interaction analysis (BIA).

Real-time biomolecular interaction analysis (BIA) has been applied to triplex formation between oligodeoxynucleotides. 5'-Biotinylated oligonucleotides were immobilised on the streptavidin-coated surface of a biosensor chip and subsequently hybridised to their complementary strand. Sequence-specific triplex formation was observed when a suitable third-strand oligopyrimidine was injected over the surface-bound duplex. In addition, a single-stranded oligonucleotide immobilised on the chip surface was able to capture a DNA duplex by triplex recognition. The presence of spermine increases the rate of association between the third strand and immobilised duplex, but at elevated spermine concentrations non-specific association is observed. A preliminary kinetic analysis of triplex formation at pH 5.2 by an 11mer third strand containing thymine, cytosine and uracil is reported. Values for the association and dissociation rate constants were determined to be (1.9 +/- 0.2) x 10(3) M-1 s-1 and (8.1 +/- 1.9) x 10(-5) s-1, respectively.     

Targeted mutagenesis in mammalian cells mediated by intracellular triple helix formation.

As an alternative to standard gene transfer techniques for genetic manipulation, we have investigated the use of triple helix-forming oligonucleotides to target mutations to selected genes within mammalian cells. By treating monkey COS cells with oligonucleotides linked to psoralen, we have generated targeted mutations in a simian virus 40 (SV40) vector contained within the cells via intracellular triple helix formation. Oligonucleotide entry into the cells and sequence-specific triplex formation within the SV40 DNA deliver the psoralen to the targeted site. Photoactivation of the psoralen by long-wavelength UV light yields adducts and thereby mutations at that site. We engineered into the SV40 vector novel supF mutation reporter genes containing modified polypurine sites amenable to triplex formation. By comparing the abilities of a series of oligonucleotides to target these new sites, we show that targeted mutagenesis in vivo depends on the strength and specificity of the third-strand binding. Oligonucleotides with weak target site binding affinity or with only partial target site homology were ineffective at inducing mutations in the SV40 vectors within the COS cells. We also show that the targeted mutagenesis is dependent on the oligonucleotide concentration and is influenced by the timing of the oligonucleotide treatment and of the UV irradiation of the cells. Frequencies of intracellular targeted mutagenesis in the range of 1 to 2% were observed, depending upon the conditions of the experiment. DNA sequence analysis revealed that most of the mutations were T.A-to-A.T transversions precisely at the targeted psoralen intercalation site. Several deletions encompassing that site were also seen. The ability to target mutations to selected sites within mammalian cells by using modified triplex-forming oligonucleotides may provide a new research tool and may eventually lead to therapeutic applications.     

Monovalent cation effects on intermolecular purine-purine-pyrimidine triple-helix formation.

The binding of a 19-mer guanosine-rich oligodeoxyribonucleotide, TG3TG4TG4TG3T (ODN 1), to a complementary polypurine DNA target was investigated by DNase I footprinting and restriction endonuclease protection assays. Monovalent cations inhibited intermolecular purine-purine-pyrimidine triple-helical DNA formation, with K+ and Rb+ being most effective, followed by NH4+ and Na+. Li+ and Cs+ had little to no effect. Similar results were observed with the G/A-rich oligonucleotide AG3AG4AG4AG3AGCT. Kinetic studies indicated that monovalent cations interfered with oligonucleotide-duplex DNA association but did not significantly promote triplex dissociation. The observed order of monovalent cation inhibition of triplex formation is reminiscent of their effect on tetraplex formation with G/T-rich oligonucleotides. However, using electrophoretic mobility shift assays we found that the oligonucleotide ODN 1 did not appear to form a four-stranded species under conditions promoting tetraplex formation. Taken together, our data suggest that processes other than the self-association of oligonucleotides into tetraplexes might be involved in the inhibitory effect of monovalent cations on purine-pyrimidine-purine triplex formation.     

Specific recognition of a DNA immunogen by its elicited antibody

DNA recognition by antibodies is a key feature of autoimmune diseases, yet model systems with structural information are very limited. The monoclonal antibody ED-10 recognizes one of the strands of the DNA duplex used in the immunogenic complex. Modifications of the 5' end decrease the binding affinity and short oligonucleotides retain high binding affinity. We determined crystal structures for the Fab bound to a 6-mer oligonucleotide containing the specific sequence that raised the antibody and compared it with the unliganded Fab. Only the first two bases from the 5' end (dTdC) display electron density and we observe four key hydrogen bonds at the interface. The thymine ring is stacked between TrpH50 and TrpH95, and the cytosine ring is packed against TyrL32. Upon DNA binding, TyrH97 and TrpH95 rearrange to allow subnanomolar binding affinity, five orders of magnitude higher than other reported complexes, possibly because of having gone through affinity maturation. This structure represents the first bona fide antibody DNA immunogen complex described in atomic detail.     

Mapping U2 snRNP--pre-mRNA interactions using biotinylated oligonucleotides made of 2''-OMe RNA.

Biotinylated 2'-OMe RNA oligonucleotides complementary to two separate regions of human U2 snRNA have been used as affinity probes to study U2 snRNP--pre-mRNA interactions. Both oligonucleotides bind specifically and allow highly selective removal of U2 snRNP from HeLa cell nuclear extracts. Pre-mRNA substrates can also be specifically affinity selected through oligonucleotides binding to U2 snRNP particles in splicing complexes. Stable binding of U2 snRNP to pre-mRNA is blocked by the pre-binding of an oligonucleotide to the branch site complementary region of U2 snRNA, but not by an oligonucleotide binding to the 5' terminus of U2. Both oligonucleotides affinity select the intron product, but not the intron intermediate, when added after spliceosome assembly has taken place. The effect of 2'-OMe RNA oligonucleotides on splicing complex formation has been used to demonstrate that complexes containing U2 snRNP and unspliced pre-mRNA are precursors to functional spliceosomes.     

Site-specific intercalation at the triplex-duplex junction induces a conformational change which is detectable by hypersensitivity to diethylpyrocarbonate.

Using site-specific intercalation directed by intermolecular triplex formation, the conformation of an intercalation site in DNA was examined by footprinting with the purine-specific (A much greater than G) reagent diethylpyrocarbonate. Site specific intercalation was achieved by covalently linking an intercalator to the 5' end of a homopyrimidine oligodeoxynucleotide, which bound to a homopurinehomopyrimidine stretch in a recombinant plasmid via intermolecular triplex formation. This directs intercalation to a single site in 3kb of DNA at the 5' triplex-duplex junction. Footprinting with diethylpyrocarbonate and dimethylsulphate revealed strong protection from modification of adenine residues within the triple-helix in concordance with their Hoogsteen pairing with the third strand, and a strong hypersensitivity to diethylpyrocarbonate at the first adenine of the duplex. This result indicates that intercalation at this site induces a conformational change at the 5' triplex-duplex junction. Furthermore, the same diethlypyrocarbonate hypersensitivity was observed with an unmodified triple-strand forming oligonucleotide and a range of intercalating molecules present in solution. Thus the 5' triplex-duplex junction is a strong binding site for some intercalating molecules and the junction undergoes a conformational change which is sensitive to diethylpyrocarbonate upon insertion of the planar aromatic chromophore. This conformational change can be used to direct a single-strand cut in duplex DNA to a defined site.     

Positively charged oligonucleotides overcome potassium-mediated inhibition of triplex DNA formation.

The formation of triplex DNA using unmodified, purine-rich oligonucleotides (ODNs) is inhibited by physiologic levels of potassium. Changing negative phosphodiester bonds in a triplex forming oligonucleotide (TFO) to neutral linkages causes a small increase in triplex formation. When phosphodiester bonds in a TFO are converted to positively-charged linkages the formation of triplex DNA increases dramatically. In the absence of KCl, a 17mer TFO containing 11 positively-charged linkages at a concentration of 0.2 microM converts essentially all of a 30 bp target duplex to a triplex. Less than 15% of the target duplex is shifted by 2 microMolar of the unmodified TFO. In 130 mM KCl, triplex formation is undetectable using the unmodified TFO, while triplex formation is nearly complete with 2 microM positively-charged TFO. With increasing potassium, TFOs containing a higher proportion of modified linkages show enhanced triplex formation compared with those less modified. In contrast with unmodified TFOs, triplex formation with more heavily modified TFOs can occur in the absence of divalent cations. We conclude that replacement of phosphodiester bonds with positively-charged phosphoramidate linkages results in more efficient triplex formation, suggesting that these compounds may prove useful for in vivo applications.     

Distance and affinity dependence of triplex-induced recombination

Triplex-forming oligonucleotides (TFOs) have the potential to serve as gene therapeutic agents on the basis of their ability to mediate site-specific genome modification via induced recombination. However, high-affinity triplex formation is limited to polypurine/polypyrimidine sites in duplex DNA. Because of this sequence restriction, careful analysis is needed to identify suitable TFO target sites within or near genes of interest. We report here an examination of two key parameters which influence the efficiency of TFO-induced recombination: (1) binding affinity of the TFO for the target site and (2) the distance between the target site and the mutation to be corrected. To test the influence of binding affinity, we compared induced recombination in human cell-free extracts by a series of G-rich oligonucleotides with an identical base composition and an increasing number of mismatches in the third strand binding code. As the number of mismatches increased and, therefore, binding affinity decreased, induced recombination frequency also dropped. There was an apparent threshold at an equilibrium dissociation constant (K(d)) of 1 x 10(-)(7) M. In addition, TFO chemical modification with N,N-diethylethylenediamine (DEED) internucleoside linkages to confer improved binding was found to yield increased levels of induced recombination. To test the ability of triplex formation to induce recombination at a distance, episomal targets with informative reporter genes were constructed to contain polypurine TFO target sites at varying distances from the mutations to be corrected. TFO-induced recombination in mammalian cells between a plasmid vector and a donor oligonucleotide was detected at distances ranging from 24 to 750 bp. Together, these results indicate that TFO-induced recombination requires high-affinity binding but can affect sites hundreds of base pairs away from the position of triplex formation.     

Binding of T and T analogs to CG base pairs in antiparallel triplexes.

The goal of this study was to address antiparallel triplex formation at duplex targets that do not conform to a strict oligopurine.oligopyrimidine motif. We focused on the ability of natural bases and base analogs incorporated into oligonucleotide third strands to bind to so-called CG inversions. These are sites where a cytosine base is present in an otherwise purine-rich strand of a duplex target. Using a 26-base-triplet test system, we found that of the standard bases, only thymine (T) shows substantial binding to CG inversions. This is quantitatively similar to the report of Beal and Dervan [Science (1991), 251, 1360-1363]. Binding to CG inversions was only slightly weaker than binding to AT base pairs. Binding of T to CG inversions was also evaluated in two other sequences, with qualitatively similar results. Six different analogs of thymine were also tested for binding to CG inversions and AT base pairs. Significant changes in affinity were observed. In particular, 5-fluoro-2'-deoxyuridine was found to increase affinity for CG inversions as well as for AT base pairs. Studies with oligonucleotides containing pyridin-2-one or pyridin-4-one suggest that thymine O4 plays a critical role in the T.CG interaction. Possible models to account for these observations are discussed.     

Specific oligonucleotide invasion into an end of a DNA duplex

A new phenomenon was described: a double-stranded DNA fragment interacted with a single-stranded oligonucleotide complementary to the terminal region of one strand of the duplex to yield a complex with oligonucleotide invasion. Generation of Holliday junctions by homologous linear DNA fragments was less efficient in the presence of single-stranded oligonucleotides complementary to duplex ends. The effect depended on the oligonucleotide concentration, size, and complementarity to a duplex strand. Sequence-specific complexes with single strand invasion were detected in mixtures containing radiolabeled oligonucleotides and duplexes. A single-stranded oligonucleotide invaded a duplex even when its concentration was far lower than the duplex concentration. Complexes with single strand invasion were analyzed by chemical cleavage of noncanonical base pairs. Analysis showed that an oligonucleotide interacts with the complementary region of one strand of the duplex, gradually displacing the other strand. The extent of oligonucleotide invasion into the duplex considerably varied. Oligonucleotide invasion into duplexes became more efficient with increasing oligonucleotide size.     

Intramolecular recombination R-triplex in solution: stabilization by bis-intercalator YOYO

Recognition of double-stranded DNA with a mixed nucleotide sequence by oligonucleotide is a long-term challenge. This aim can be achieved via formation of the recombination R-triplex, accommodating two identical DNA strands in parallel orientation, and antiparallel complementary strand. In the absence of proteins the R-triplex stability is low, however, so that intermolecular R-triplex is not formed by three DNA strands in a ligand-free system. Recently, recognition of DNA with mixed base sequence by single-stranded oligonucleotide in the presence of bis-intercalator YOYO was reported. Here, we describe thermodynamic characteristics of YOYO complexes with the model oligonucleotides 5'-GT-2AP-GACTGAG TTTT CTCAGTCTACGC GAA GCGTAGACTGAG-3' (R(2AP)CW) bearing a single reporting 2-aminopurine (2AP) in place of adenine and 5'-CTCAGTCTACGC GAA GCGTAGACTGAG-3' (CW). We found that each oligonucleotide is able to bind two YOYO molecules via intercalation mode in 0.5 M LiCl. Fluorescence intensity of YOYO intercalated in triplex R(2AP)CW and in CW hairpin increased 40-fold compared to the free YOYO. Remarkably, the melting temperature of the triplex (determined using temperature dependence of the 2AP fluorescence) increased from 19 degrees C to 33 degrees C upon binding two YOYO molecules. Further increase in the YOYO concentration resulted in binding of up to five YOYO molecules to R(2AP)CW triplex and up to six YOYO molecules to CW hairpin.     

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.