Comparison of antiparallel A.AT and T.AT triplets within an alternate strand DNA triple helix

Nucleosides and nucleotides. Part 226: alternate-strand triple-helix formation by 3'-3'-linked oligodeoxynucleotides composed of asymmetrical sequences

In this paper, we describe the synthesis of the 3'-3'-linked oligonucleotides connected with pentaerythritol composed of asymmetrical sequences. Stability of the triplexes between these oligonucleotides and the DNA targets involving the adjacent oligopurine domains on alternate strands was investigated using the electrophoretic mobility shift assay (EMSA) and DNase I footprinting experiment. It was found that the 3'-3'-linked oligonucleotides composed of asymmetrical sequences formed the stable antiparallel triplexes with the DNA targets as compared with the unlinked oligonucleotides. Thus, oligonucleotides linked with pentaerythritol would be useful as antigene oligonucleotides for DNA targets consisting of the alternating oligopyrimidine-oligopurine sequences.

Optimization of alternate-strand triple helix formation at the 5"-TpA-3" and 5"-ApT-3" junctions

Alternate-strand triple helix formation was optimized at the two junction steps, the 5"-TpA-3" and 5"-ApT-3" junctions. Footprint experiments, gel retardation assays and thermal denaturation measures on a sequence appropriately designed with two adjacent alternate-strand polypurine tracts points out that the addition of an adenine residue and the removal of one nucleotide should facilitate the crossing strands at the 5"-TpA-3" junction and at the 5"-ApT-3" junction, respectively. These results provide a 'switch code' for the construction of alternate-strand triple helix forming oligonucleotides which open new possibilities for extending the range of applications of antigene strategy.

The integral divalent cation within the intermolecular purine*purine. pyrimidine structure: a variable determinant of the potential for and characteristics of the triple helical association

In vitro assembly of an intermolecular purine*purine.pyrimidine triple helix requires the presence of a divalent cation. The relationships between cation coordination and triplex assembly were investigated, and we have obtained new evidence for at least three functionally distinct potential modes of divalent cation coordination. (i) The positive influence of the divalent cation on the affinity of the third strand for its specific target correlates with affinity of the cation for coordination to phosphate. (ii) Once assembled, the integrity of the triple helical structure remains dependent upon its divalent cation component. A mode of heterocyclic coordination/chelation is favorable to triplex formation by decreasing the relative tendency for efflux of integral cations from within the triple helical structure. (iii) There is also a detrimental mode of base coordination through which a divalent cation may actively antagonize triplex assembly, even in the presence of other supportive divalent cations. These results demonstrate the considerable impact of the cationic component, and suggest ways in which the triple helical association might be positively or negatively modulated.

Spectroscopic investigation of an intramolecular DNA triplex containing both G.G:C and T.A:T triads and its complex with netropsin

The triple helix formation by the oligonucleotide 5'd(G4T4G4-[T4]-G4A4G4-[T4]-C4T4C4) ([T4] represents a stretch of 4 thymine residues) has been investigated by UV absorption spectroscopy and circular dichroism. In a 10 mM sodium cacodylate, 0.2 mM disodium EDTA (pH 7) buffer, we show the following significant results: i) In the absence of MgCl2, the oligonucleotide adopts a hairpin duplex structure with the dangling tail 5'd(G4T4G4-[T4]). This 5' extremity, which contains separated runs of four guanine residues, does not assume the expected tetraplex conformation observed when this sequence is free. ii) In the presence of MgCl2, the oligonucleotide folds back on itself twice to give a triple helix via a double hairpin formation, with [T4] single-strand loops. iii) The addition of high concentration of KCl to the preformed triplex does not disrupt the structure. Nevertheless, if the oligonucleotide is allowed to fold back in the presence of K+, triplex formation is inhibited. Circular dichroism studies demonstrate that the oligonucleotide adopts a dimeric conformation, resulting from the association of two hairpin duplexes, via the formation of an antiparallel G-quadruplex by the telomeric 5'd(G4T4G4-[T4]) extremities. iv) Under the experimental conditions used in this report, the triplex melts in a monophasic manner. v) Netropsin, a DNA minor groove ligand, binds to the central site A4/T4 of the duplex and to that of the triplex in an equimolar stoichiometry. In contrast with previous studies concerning pyr.pur:pyr triplexes, thermal denaturation experiments demonstrate that the netropsin binding stabilizes the intramolecular triplex.

Therapeutic potential and mechanism of action of oligonucleotides and ribozymes

Specific inactivation of gene expression is an attractive approach for rational drug design to combat degenerative diseases and infectious agents. Oligonucleotide-directed triple-helix formation at cis-acting elements of gene promoters, short oligonucleotides containing base sequences that are complementary to the messenger RNA (antisense oligos), and RNA enzymes (ribozymes) that specifically cleave messenger RNA molecules are currently being used both as experimental tools and as therapeutic agents. Mechanisms of action of various oligonucleotide-based drugs, recent developments in the drug-delivery approaches, and future potentials are discussed in this review.

Parallel and antiparallel A*A-T intramolecular triple helices

Intramolecular triple helices have been obtained by folding back twice oligonucleotides formed by decamers bound by non-nucleotide linkers: dA10-linker-dA10-linker-dT10 and dA10-linker-dT10-linker-dA10. We have thus prepared two triple helices with forced third strand orientation, respectively antiparallel (apA*A-T) and parallel (pA*A-T) with respect to the adenosine strand of the Watson-Crick duplex. The existence of the triple helices has been shown by FTIR, UV and fluorescence spectroscopies. Similar melting temperatures have been obtained in very different oligomer concentration conditions (micromolar solutions for thermal denaturation classically followed by UV spectroscopy, milimolar solutions in the case of melting monitored by FTIR spectroscopy) showing that the triple helices are intramolecular. The stability of the parallel triplex is found to be slightly lower than that of the antiparallel (deltaT(m) = 6 degrees C). The sugar conformations determined by FTIR are different for both triplexes. Only South-type sugars are found in the antiparallel triplex whereas both South- and North-type sugars are detected in the parallel triplex. In this case, thymidine sugars have a South-type geometry, and the adenosine strand of the Watson-Crick duplex has North-type sugars. For the antiparallel triplex the experimental results and molecular modeling data are consistent with a reverse-Hoogsteen like third-strand base pairing and South-type sugar conformation. An energetically optimized model of the parallel A*A-T triple helix with a non-uniform distribution of sugar conformations is discussed.

Nucleosome core particles inhibit DNA triple helix formation

We have used DNase I footprinting to examine the formation of DNA triple helices at target sites on DNA fragments that have been reconstituted with nucleosome core particles. We show that a 12 bp homopurine target site, located 45 bp from the end of the 160 bp tyrT(46A) fragment, cannot be targeted with either parallel (CT-containing) or antiparallel (GT-containing) triplex-forming oligonucleotides when reconstituted on to nucleosome core particles. Binding is not facilitated by the presence of a triplex-binding ligand. However, both parallel and antiparallel triplexes could be formed on a truncated DNA fragment in which the target site was located closer to the end of the DNA fragment. We suggest that intermolecular DNA triplexes can only be formed on those DNA regions that are less tightly associated with the protein core.

c-fos protooncogene transcription can be modulated by oligonucleotide-mediated formation of triplex structures in vitro

A homopurine.homopyrimidine sequence of the c-fos promoter was chosen as a target for a triple helix oligonucleotide. Eight DNA oligonucleotides that ranged from 14 to 31 bp were shown to form a triple helix with three sequences within the c-fos promoter region. Reactive derivatives of homopyrimidine oligonucleotides bearing the 5'- or 3'-terminal DNA alkylation aromatic 2-chloroethylamino group were also synthesized. It was concluded, based on the physical properties of the DNA oligonucleotide complex, that the oligonucleotide forms a colinear triplex with the duplex binding sites. We investigated in detail, using electrophoretic mobility and footprinting protection, whether such oligonucleotide.DNA complexes are of benefit in designing high-affinity probes for a natural DNA sequence in the mouse c-fos gene. Our results demonstrate that four different DNA targets within the c-fos promoter region can form triplex structures with synthetic oligonucleotides in a sequence-specific manner. Moreover, in vitro modifications of the retinoblastoma-gene-product-binding site of the c-fos promoter at position -83 in front of the cAMP/cAMP-responsive element binding site and fos-binding site 3/activator-protein-2-like (FBS3/AP-2-like) site at position -431 by triple helix forming oligonucleotides cause dramatic suppression of fos-chloramphenicol acetyltransferase activity in endothelial cells. These results provide a basis for the development of a specific oligonucleotide target forming triplex-DNA complex, and emphasize the importance of a target forming triplex as a basis for control of gene expression and cell proliferation.

Alternate strand DNA triple helix-mediated inhibition of HIV-1 U5 long terminal repeat integration in vitro

Integration of the human immunodeficiency virus (HIV) DNA into the host genome is an obligatory process in the replicative life cycle of the virus. This event is mediated in vitro by integrase, a viral protein which binds to specific sequences located on both extremities of the DNA long terminal repeats (LTRs). These sites are highly conserved in all HIV genomes and thus provide potential targets for the selective inhibition of integration. The integrase-binding site located on the HIV-1 U5 LTR end contains two adjacent purine tracts on opposite strands, 5' . . . GGAAAATCTCT-3'/3'-CCTTTTAGAGA . . . 5', in parallel orientations. A single strand oligonucleotide 5'-GGTTTTTGTGT-3' was designed to associate with these tracts via its ability to form a continuous alternate strand DNA triplex. Under neutral pH and physiological temperature, the oligonucleotide, tagged with an intercalator chromophore oxazolopyridocarbazole, formed a stable triplex with the target DNA. The occurrence of this unusual triplex was demonstrated by both DNase I footprinting and electron microscopy. The triplex inhibits the two steps of the integrase-mediated reactions, namely, the endonucleolytic cleavage of the dinucleotide 5'-GT-3' from the 3' end of the integration substrate and the integration of the substrate into the heterologous target DNA. The midpoints for both inhibition reactions were observed at oligonucleotide concentrations of 50-100 nM. We believe that these results open new possibilities for the specific targeting of viral DNA LTR ends with the view of inhibiting integration under physiological conditions.

A molecular mechanics and dynamics study of alternate triple-helices involving the integrase-binding site of the HIV-1 virus and oligonucleotides having a 3'-3' internucleotide junction

Triple helix formation by oligonucleotides can be extended beyond polypurine tracts with the help of specially designed linkers. In this paper we focus our attention on the integrase-binding site of the HIV-1 virus located on the U5 LTR end which contains two adjacent purine tracts on opposite strands. Two alternate triple helices with a 3'-3' junction in the third strand are considered: 5'-GGTTTTp3'-3'pTGTGT-5' and 5'-GGAAAAp3'-3'pAGAGA-5' The structural plausibility of these triplexes is investigated using molecular mechanics and dynamics simulations, both in vacuo and in aqua. The non-isomorphism of the triplets in the GpT steps in the first sequence, gives rise to non canonical conformations in the torsion angles, hydration appears to be crucial for this triplex. Sugar puckers are predominantly South during in vacuo simulations while they turn East in aqua. In the simulation in aqua the triplexes are shrouded by an hydration shell, however, we have not been able to detect any permanent hydrogen bond bridge between DNA and water. The solvation of ions as well as their radial distribution, appear to be relatively well behaved despite the artifacts known to be generated by the simulation procedure. The experimental feasibility of these structures is discussed.

Investigation of the intracellular stability and formation of a triple helix formed with a short purine oligonucleotide targeted to the murine c-pim-1 proto-oncogene promotor

In our previous work we have shown that the oligonucleotide 5'-GGGGAGGGGGAGG-3' gives a very stable and specific triplex with the promoter of the murine c-pim-1 proto-oncogene in vitro[Svinarchuk, F., Bertrand, J.-R. and Malvy, C.(1994)Nucleic Acids Res., 22, 3742-3747]. In the present work, we have tested triplex formation with some derivatives of this oligonucleotide which are designed to be degradation-resistant inside the cells, and we show that phosphorothioate and the oligonucleotide with a 3' terminal amino group are still able to form triplexes. Moreover these oligonucleotides, like the 13mer oligonucleotide of similar composition [Svinarchuk, F., Paoletti, J., and Malvy, C. (1995) J. Biol. Chem., 270, 14068-14071], are able to stabilize the targeted duplex. In vivo DMS footprint analysis after electroporation of the pre-formed triplex into the cell have shown the presence of the triple helix inside the cells. This triplex structure partially blocks c-pim-1 promotor activity as shown by transient assay with a c-pim-1 promoter-luciferase gene construct. To our knowledge these data are the first direct evidence that conditions inside cells are favorable for triplex stability with non-modified oligonucleotides. However we were unable to show triplex formation inside living cells using various methods of oligonucleotide delivery. We suppose that this may be due to the oligonucleotide being sequestered by cellular processes or proteins. Further work is needed to find oligonucleotide derivatives and ways of their delivery to overcome the problem of triplex formation inside the cells.

An intramolecular triplex in the human gamma-globin 5'-flanking region is altered by point mutations associated with hereditary persistence of fetal hemoglobin

The properties of an intramolecular triplex formed in vitro at the 5'-flanking region of the human gamma-globin genes were studied by chemical and physical probes. Chemical modifications performed with osmium tetroxide, chloroacetaldehyde, and diethyl pyrocarbonate revealed the presence of non-paired nucleotides on the "coding strand" at positions -209 through -217. These reactivities were induced by negative supercoiling, low pH, and magnesium ions. Downstream point mutations associated with hereditary persistence of fetal hemoglobin (HPFH) altered the extent of the modifications and some of the patterns. Specifically, C-202-->G and C-202-->T significantly decreased the reactivities, whereas the patterns were increased and altered in the T-198-->C. C-196-->T and C-195-->G caused local decreases in reactivity. Modifications at the upstream flanking duplex were modulated by the composition of the vector sequence. In summary, our data indicates the formation of an intramolecular triplex between nucleotides -209 to -217 of the "non-coding strand" and the downstream sequence containing the HPFH mutations. All of the HPFH point mutations altered the structure. More than one sequence alignment is possible for each of the triplexes. In addition, a consequence of some of the point mutations may be to facilitate slippage of the third strand relative to the Watson-Crick duplex.

The high stability of the triple helices formed between short purine oligonucleotides and SIV/HIV-2 vpx genes is determined by the targeted DNA structure

In our previous works we have shown that the oligonucleotides 5'-GGGGAGGGGGAGG-3' and 5'-GGAGGGGGAGGGG-3' give very stable and specific triplexes with their target double stranded DNAs [Svinarchuk, F., Bertrand, J.-R. and Malvy, C. (1994) Nucleic Acids Res., 22, 3742-3747; Svinarchuk, F., Paoletti, J. and Malvy, C. (1995) J. Biol. Chem., 270, 14 068-14,071]. The target for the invariable part of these oligonucleotides, 5'-GGAGGGGGAGG-3', is found in a highly conserved 20 bp long purine/pyrimidine tract of the vpx gene of the SIV and HIV-2 viruses and could be a target for oligonucleotide directed antivirus therapy. Here were report on the ability of four purine oligonucleotides with different lengths (11-, 14-, 17- and 20-mer) to form triplexes with the purine/pyrimidine stretch of the vpx gene. Triplex formation was tested by joint dimethyl sulfate (DMS) footprint, gel-retardation assay, circular dichroism (CD) and UV-melting studies. Dimethyl sulfate footprint studies revealed the antiparallel orientation of the third strand to the purine strand of the Watson-Crick duplex. However, the protection of the guanines at the ends of the target sequence decreased as the length of the third strand oligonucleotide increased. Melting temperature studies provided profiles with only one transition for all of the triplexes. The melting temperatures of the triplexes were found to be the same as for the targeted duplex in the case of the 11- and 14-mer third strands while for the 17- and 20-mer third strands the melting temperature of the triplexes were correspondingly 4 and 8 degrees C higher than for the duplex. Heating and cooling melting curves were reversible for all of the tested triplexes except one with the 20-mer third strand oligonucleotide. Circular dichroism spectra showed the ability of the target DNA to adopt an A-like DNA conformation. Upon triplex formation the A-DNA form becomes even more pronounced. This effect depends on the length of the third strand oligonucleotide: the CD spectrum shows a 'classical' A-DNA shape with the 20-mer. This is not observed with the purine/pyrimidine stretch of the HIV-1 DNA which keeps a B-like spectrum even after triplex formation. We suggest, that an A-like duplex DNA is required for the formation of a stable DNA purine(purine-pyrimidine) triplex.

Extension of DNA triple helix formation to a neighbouring (AT)n site

We have used DNase I footprinting to examine the formation of intermolecular triple helices at a fragment containing the target sequence A11(AT)6.(AT)6T11, using oligonucleotides designed to form parallel T.AT and G.TA triplets. We find that, although (TG)6 does not form a complex with (AT)6.(AT)6, T11(TG)6 forms a stable structure producing a clear footprint which includes the (AT)6 portion of the target site. This complex is not formed in the presence of magnesium, but can be stabilised by either manganese or a triplex-binding ligand.