Intramolecular triple-helix formation at (PunPyn).(PunPyn) tracts: recognition of alternate strands via Pu.PuPy and Py.PuPy base triplets

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.

Repairing the Sickle Cell mutation. III. Effect of irradiation wavelength on the specificity and type of photoproduct formed by a 3'-terminal psoralen on a third strand directed to the mutant base pair

Using a psoralen delivery system mediated by a DNA third strand that binds selectively to linear target duplexes immediately downstream from the Sickle Cell beta-globin gene mutation and the comparable wild-type beta-globin gene sequence, the kinetics of formation and yield of psoralen monoadducts and crosslinks with pyrimidine residues at and near the mutant base pair site and its wild-type counterpart were determined. By exploiting irradiation specificities at 300, 365 and 419 nm, it was possible to evaluate the orientation equilibrium of 3'-linked intercalated psoralen and to develop conditions that lead to preferential formation of each type of photoproduct in both the mutant and wild-type sequences. This makes possible the preparation of each type of photoproduct for use as a substrate for DNA repair. In this way, the base pair change(s) that each generates can be established.

Alternate stranded triplex formation of chimeric DNA composed of tandem alpha- and beta-anomeric strands

A chimeric oligoDNA composed of a natural beta-anomeric oligonucleotide portion and an unnatural alpha-anomeric oligonucleotide portion forms an alternate stranded triplex possessing enhanced thermal stability compared to the triplexes composed of the parental oligomers.

Parallel and antiparallel G*G.C base triplets in pur*pur.pyr triple helices formed with (GA) third strands

Triple helices with G*G.C and A*A.T base triplets with third GA strands either parallel or antiparallel with respect to the homologous duplex strand have been formed in presence of Na (+) or Mg(2+) counterions. Antiparallel triplexes are more stable and can be obtained even in presence of only monovalent Na(+) counterions. A biphasic melting has been observed, reflecting third strand separation around 20 degrees C followed by the duplex -> coil transition around 63 degrees C. Parallel triplexes are far less stable than the antiparallel ones. Their formation requires divalent ions and is observed at low temperature and in high concentration conditions. Different FTIR signatures of G*G.C triplets in parallel and antiparallel triple helices with GA rich third strands have been obtained allowing the identification of such base triplets in triplexes formed by nucleic acids with heterogeneous compositions. Only S-type sugars are found in the antiparallel triplex while some N-type sugar conformation is detected in the parallel triplex.

Targeting of single-stranded DNA and RNA containing adjacent pyrimidine and purine tracts by triple helix formation with circular and clamp oligonucleotides

The aim of this work was to construct an anti-messenger targeted to the pim-1 oncogene transcript, based on circular or clamp oligodeoxyribonucleotides. The formation of bimolecular triplexes by clamp or circular oligonucleotides was investigated using single-stranded targets of both DNA (5'-CCCTCCTTTGAAGAA-3') and RNA type (5'-CCCUCCUUUGAAGAA-3'). The third, 'Hoogsteen' strand of the triplex was represented by G,T-rich sequences. The secondary structures of the complexes were determined by thermal denaturation, circular dichroism and gel mobility shift experiments and shown to depend on the nature of the target strand. With DNA as target, the sequence of a clamp (or circular) oligonucleotide that formed the triple helix was 3'-GGGAGGAAACTTCTTTT-TTGTTGTTT-TT-GGTGGG-5', where the first TT dinucleotide (in italics) is a linker and the second TT (bold) represents the bridge through which the 'Hoogsteen' strand switches from one strand of the Watson-Crick duplex to the other, once the duplex is formed by the corresponding portion of the anti-messenger (underlined). The portion of the 'Hoogsteen' sequence of the triplex between the two TT dinucleotides binds to the 3' extremity of the target strand and runs parallel to it. The portion situated at the 5' end of the oligonucleotide switches to the purine tract of the complementary strand of the duplex and is antiparallel to it. In contrast, with RNA as target, for a branched clamp oligonucleotide that formed a triple helix over its entire length (5'-TTCTTCAAAGGAGGG-3' 3'-GGGTGGTTT-T-GTTGTT-5') the portion of the 'Hoogsteen' sequence that bound to the 3' extremity of the target strand had to be antiparallel to it.

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.

Repairing the sickle cell mutation. I. Specific covalent binding of a photoreactive third strand to the mutated base pair

A DNA third strand with a 3'-psoralen substituent was designed to form a triplex with the sequence downstream of the T.A mutant base pair of the human sickle cell beta-globin gene. Triplex-mediated psoralen modification of the mutant T residue was sought as an approach to gene repair. The 24-nucleotide purine-rich target sequence switches from one strand to the other and has four pyrimidine interruptions. Therefore, a third strand sequence favorable to two triplex motifs was used, one parallel and the other antiparallel to it. To cope with the pyrimidine interruptions, which weaken third strand binding, 5-methylcytosine and 5-propynyluracil were used in the third strand. Further, a six residue "hook" complementary to an overhang of a linear duplex target was added to the 5'-end of the third strand via a T(4) linker. In binding to the overhang by Watson-Crick pairing, the hook facilitates triplex formation. This third strand also binds specifically to the target within a supercoiled plasmid. The psoralen moiety at the 3'-end of the third strand forms photoadducts to the targeted T with high efficiency. Such monoadducts are known to preferentially trigger reversion of the mutation by DNA repair enzymes.

Identification of a triplex DNA-binding protein from human cells

Intramolecular or intermolecular triple helices could be recognized by specific proteins that stabilize triplex structures and might play a role in gene regulation. In order to identify such proteins, we designed a 55 nucleotide-long DNA oligomer that could fold on itself to form an intramolecular triple helix of the Py Pu x Py motif. The stability of this triplex under physiological conditions was demonstrated by gel retardation and thermal denaturation experiments. We have identified a protein from HeLa cell nuclear extracts that binds to this synthetic oligonucleotide. The protein has an apparent molecular mass of 55 kDa. Electrophoretic mobility shift assays revealed that the protein did not have any affinity for the single-stranded and double-stranded oligonucleotides corresponding respectively to the third strand and the Watson-Crick duplex of the triple helix. This protein also binds to an intramolecular Py Pu x Pu triplex but with a lower affinity than to a Py Pu x Py triple helix.

Capture in the gel: intermoleculare triplex formation during gel electrophoresis

Analysis of unusual gel mobility patterns formed by certain DNA triplexes has revealed that intermolecular triplex formation can occur during gel electrophoresis when a faster migrating single strand overtakes a slower migrating band containing a duplex of appropriate sequence. Control experiments showed that this capture of the third strand occurs by sequence-specific hybridization rather than some nonspecific retardation. This phenomenon can be used to detect triplexes by a gel-shift assay even if their lifetime is much shorter than the time of gel electrophoresis.

Binding of DNA oligonucleotides to sequences in the promoter of the human bc1-2 gene

Duplex DNA recognition by oligonucleotide-directed triple helix formation is being explored as a highly specific approach to artificial gene repression. We have identified two potential triplex target sequences in the promoter of the human bcl-2 gene, whose product inhibits apoptosis. Oligonucleotides designed to bind these target sequences were tested for their binding affinities and specificities under pseudo-physiological conditions. Electrophoretic mobility shift and dimethyl sulfate footprinting assays demonstrated that an oligonucleotide designed for simultaneous recognition of homopurine domains on alternate duplex DNA strands had the highest affinity of any oligonucleotide tested. Modifications to render this oligonucleotide nuclease-resistant did not reduce its binding affinity or specificity. In additional studies under various pH conditions, pyrimidine motif complexes at these target sequences were found to be stable at pH 8.0, despite the presumed requirement for protonation of oligonucleotide cytidines. In contrast, purine motif complexes, typically considered to be pH independent, were highly destabilized at decreasing pH values. These results indicate that a natural sequence in the human bcl-2 promoter can form a stable triplex with a synthetic oligonucleotide under pseudo-physiological conditions, and suggest that triple helix formation might provide an approach to the artificial repression of bcl-2 transcription.

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.

Prospects for the therapeutic use of antigene oligonucleotides

An outgrowth of classic nucleic acid interaction studies, oligonucleotide-directed triple helix formation is a unique method for creating highly specific chemical ligands that recognize and bind to particular sequences of duplex DNA. Under permissive conditions, these oligonucleotide-based compounds can approach or exceed the binding affinity and sequence specificity of natural DNA-binding proteins. Triple helix recognition has been found to be useful in certain cell-free applications including precise chromosome fragmentation. It has been proposed that such oligonucleotides could also form the basis for gene-targeted (antigene) drugs that might repress transcription from undesired genes in living cells. However, current strategies for oligonucleotide-directed triple helix formation suffer from important constraints involving requirements for stabilizing binding conditions, restrictions on permitted target sequences, and inefficient nuclear delivery of oligonucleotides. Implementation of oligonucleotide-directed triple helix formation as a viable approach to cancer therapy must therefore await clever solutions to a series of fascinating problems.

Targeting RNA structures by antisense oligonucleotides

The presence of folded regions in RNA competes with the binding of a complementary oligonucleotide, resulting in a weak antisense effect. Due to the key role played by a number of RNA structures in the natural regulation of gene expression it might be of interest to design antisense sequences able to selectively interact with such motifs in order to interfere with the biological processes they mediate. Different possibilities have been explored. A high affinity oligomer will disrupt the structure; if the target structure is solved one can take advantage of unpaired bases (bulges, loops) to minimize the thermodynamic cost of the binding. Alternatively, the folded structure can be accommodated within the complex via the formation of a local triple helix. Oligomers able to adapt to the RNA structure (aptamers) can be extracted by in vitro selection from randomly synthesized libraries comprising several billions of sequences.

Extension of the four-stranded intercalated cytosine motif by adenine.adenine base pairing in the crystal structure of d(CCCAAT)

The crystal structure of d(CCCAAT), refined at 2.0 A resolution, shows a four stranded molecule in which two parallel duplexes intercalate with opposite polarity, using cytosine.protonated cytosine base pairs. The intercalation motif in this structure is extended by adenine.adenine base pairs. Two topologically distinct broad grooves are found in the lath-like central part of the molecule with the phosphate groups on one side bent over towards each other, stabilized by bridging water molecules. At the 3' ends, two arrangements of intermolecular A.A.T base triplets are found, involving both asymmetric and symmetric A.A base pairs joined to thymine residues by Watson-Crick and reverse Hoogsteen base pairing, respectively.

DNA triple-helix formation: an approach to artificial gene repressors?

Certain sequences of double-helical DNA can be recognized and tightly bound by oligonucleotides. The effects of such triple-helical structures on DNA binding proteins have been studied. Stabilities of DNA triple-helices at or near physiological conditions are sufficient to inhibit DNA binding proteins directed to overlapping sites. Such proteins include restriction endonucleases, methylases, transcription factors, and RNA polymerases. These and other results suggest that oligonucleotide-directed triple-helix formation could provide the basis for designing artificial gene repressors. The general question of whether biological systems employ RNA molecules for recognition and regulation of double-helical DNA is discussed.

Physicochemical studies of the d(G3T4G3)*d(G3A4G3).d(C3T4C3) triple helix

We have targeted the d(G3A4G3).d(C3T4C3) duplex for triplex formation with d(G3T4G3) in the presence of MgCl2. The resulting triple helix, d(G3T4G3)*d(G3-A4G3).d(C3T4C3), is considerably weaker than the related triplex, d(G3A4G3)*d(G3A4G3).d(C3T4C3), and melts in a biphasic manner, with the third strand dissociating at temperatures about 20-30 degrees C below that of the remaining duplex. This is in distinct contrast to the d(G3A4G3)*d(G3A4G3).d(C3T4C3) triplex, which melts in essentially a single transition. Gel electrophoresis under non-denaturing conditions shows the presence of the d(G3T4G3)*d(G3A4G3).d(C3T4C3) triplex as a band of low mobility compared to the duplex or the single strand bands. Binding of the d(G3T4G3) third strand and the purine strand of the duplex can be monitored by imino proton NMR spectra. While these spectra are typically very broad for intermolecular triplexes, the line widths can be dramatically narrowed by the addition of two thymines to both ends of the pyrimidine strand. Thermodynamic analysis of UV melting curves shows that this triplex is considerably less stable than related triplexes formed with the same duplex. The orientation of the third strand was addressed by a combination of fluorescence energy transfer and UV melting experiments. Results from these experiments suggest that, in the unlabeled triplex, the preferred orientation of the third strand is parallel to the purine strand of the duplex.

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

We have examined the formation of alternate strand triple-helices at the target sequence A11(TC)6.(GA)6T11 using the oligonucleotides T11(AG)6 and T11(TG)6, by DNase I footprinting. These third strands were designed so as to form parallel T.AT triplets together with antiparallel G.GC and A.AT or T.AT triplets. We find that, although both oligonucleotides yield clear footprints at similar concentrations (0.3 microM) in the presence of manganese, only T11(TG)6 forms a stable complex in magnesium-containing buffers, albeit at a higher concentration (10-30 microM). Examination of the interaction of (AG)6 and (TG)6 with half the target site confirmed that the complex containing A.AT triplets was only stable in the presence of manganese. In contrast no binding of (TG)6 was detected in the presence of either metal ion, suggesting that the reverse-Hoogsteen T.AT triplet is less stable that G.GC. We suggest that, within the context of G.GC triplets, the rank order of antiparallel triplet stability is A.AT (Mn2+) > T.AT (Mn2+) > T.AT (Mg2+) > A.AT (Mg2+). Third strands containing a single base substitution in the centre of either the parallel or antiparallel portion showed a (10-fold) weaker interaction in manganese-containing buffers, and no interaction in the presence of magnesium.

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.

Alternate-strand DNA triple-helix formation using short acridine-linked oligonucleotides

We have used DNAse I footprinting to examine the formation of intermolecular DNA triple helices at sequences containing adjacent blocks of purines and pyrimidines. The target sites G6T6.A6C6 and T6G6.C6A6 were cloned into longer DNA fragments and used as substrates for DNAse I footprinting, which examined the binding of the acridine (Acr)-linked oligonucleotides Acr-T5G5 and Acr-G5T5 respectively. These third strands were designed to incorporate both G.GC triplets, with antiparallel Gn strands held together by reverse Hoogsteen base pairs, and T.AT triplets, with the two T-containing strands arranged antiparallel to each other. We find that Acr-T5G5 binds to the target sequence G6T6.-A6C6, in the presence of magnesium at pH 7.0, generating clear DNAse I footprints. In this structure the central guanine is not recognized by the third strand and is accessible to modification by dimethyl sulphate. Under these conditions no footprint was observed with Acr-G5T5 and T6G6.C6A6, though this triplex was evident in the presence of manganese chloride. Manganese also facilitated the binding of Acr-T5G5 to a second site in the fragment containing the sequence T6G6.C6A6. This represents interaction with the sequence G4ATCT6, located at the boundary between the synthetic insert and the remainder of the fragment, and suggests that this bivalent metal ion may stabilize triplexes that contain one or two mismatches. Manganese did not affect the interaction of either oligonucleotide with G6T6.A6C6.

Sequence specificity of the non-natural pyrido[2,3-d]pyrimidine nucleoside in triple helix formation

The non-natural pyrido[2,3-d]pyrimidine nucleoside F, which pairs preferentially with guanine (G) and adenine (A) within double-helical DNA, recognizes with high selectivity AT base pairs within triple-helical complexes. These observations suggest that F may exist in different tautomeric forms within double-helical and triple-helical complexes. Analysis of the base stacking properties of this extended ring system using two oligodeoxyribonucleotides containing terminal thymines and/or pyrido[2,3-d]pyrimidines bound to adjacent sites showed a decrease in free energy of binding in a triple-helical complex in the order (5'-3') TT > FT > TF > FF.

Formation of DNA triple helices incorporating blocks of G.GC and T.AT triplets using short acridine-linked oligonucleotides

We have used DNase I footprinting to assess triple helix formation at target sites containing the sequences A6G6.C6T6 and G6A6.T6C6. These sequences can be recognized by the acridine-linked oligopyrimidines Acr-T5C5 and Acr-C5T5 respectively at low pH, using well-characterised T.AT and C+.GC triplets. At pH 7.5 A6G6.C6T6 is specifically bound by Acr-G5T5, utilising G.GC and T.AT triplets in which the third strand runs antiparallel to the purine strand of the duplex. This interaction requires the presence of magnesium ions. No interaction was detected with Acr-T5G5, an oligonucleotide designed to form parallel G.GC and T.AT triplets. In contrast neither Acr-T5G5 nor Acr-G5T5 produced DNase I footprints with the target sequence G6A6.T6C6. These results suggest that, in an antiparallel R.RY triple helix, the T.AT triplet is weaker than the G.GC triplet. We find no evidence for the formation of structures containing parallel G.GC triplets.

Solution structure of a pyrimidine.purine.pyrimidine DNA triplex containing T.AT, C+.GC and G.TA triples

BACKGROUND

Under certain conditions, homopyrimidine oligonucleotides can bind to complementary homopurine sequences in homopurine-homopyrimidine segments of duplex DNA to form triple helical structures. Besides having biological implications in vivo, this property has been exploited in molecular biology applications. This approach is limited by a lack of knowledge about the recognition by the third strand of pyrimidine residues in Watson-Crick base pairs.

RESULTS

We have therefore determined the solution structure of a pyrimidine.purine.pyrimidine (Y.RY) DNA triple helix containing a guanine residue in the third strand which was postulated to specifically recognize a thymine residue in a Watson-Crick TA base pair. The structure was solved by combining NMR-derived restraints with molecular dynamics simulations conducted in the presence of explicit solvent and counter ions. The guanine of the G-TA triple is tilted out of the plane of its target TA base pair towards the 3'-direction, to avoid a steric clash with the thymine methyl group. This allows the guanine amino protons to participate in hydrogen bonds with separate carbonyls, forming one strong bond within the G-TA triple and a weak bond to an adjacent T.AT triple. Dramatic variations in helical twist around the guanine residue lead to a novel stacking interaction. At the global level, the Y.RY DNA triplex shares several structural features with the recently solved solution structure of the R.RY DNA triplex.

CONCLUSIONS

The formation of a G.TA triple within an otherwise pyrimidine.purine.pyrimidine DNA triplex causes conformational realignments in and around the G.TA triple. These highlight new aspects of molecular recognition that could be useful in triplex-based approaches to inhibition of gene expression and site-specific cleavage of genomic DNA.

Gene transfer and antisense nucleic acid techniques

Attempts to suppress a harmful genetic trait by antisense means, or to restore a normal phenotype by gene transfer, attract much publicity. This is especially the case where clinical trials incorporating such methodologies have been initiated, such as antisense oligonucleotide therapies for some types of leukaemia, antisense gene-transfer therapy for a form of lung cancer, and gene-transfer therapies for adenosine deaminase deficiency, severe combined immunodeficiency disease, and various forms of cancer including brain tumours and melanoma. However, translation of laboratory success into treatment or control of disease is unlikely to be straightforward. Here, Nick Miller and Richard Vile summarize the rationale, problems and potential of such techniques as applied to parasitic disease.

Solution structure of a purine.purine.pyrimidine DNA triplex containing G.GC and T.AT triples

BACKGROUND

Oligonucleotide-directed triple helix formation allows sequence specific recognition of double helical DNA. This powerful approach has been used to inhibit gene transcription in vitro and to mediate single site specific cleavage of a human chromosome.

RESULTS

Using a combined NMR and molecular dynamics approach (including relaxation matrix refinement), we have determined the solution structure of an intramolecular purine.purine.pyrimidine (R.RY) DNA triplex containing guanines and thymines in the third strand to high resolution. Our studies define the G.GC and T.AT base triple pairing alignments in the R.RY triplex and identify the structural discontinuities in the third strand associated with the non-isomorphism of the base triples. The 5'-d(TpG)-3' base steps exhibit a pronounced increase in axial rise and reduction in helical twist, while the reverse is observed, to a lesser extent at 5'-d(GpT)-3' steps. A third groove is formed between the purine-rich third strand and the pyrimidine strand. It is wider and deeper than the other two grooves.

CONCLUSIONS

Our structure of the R.RY DNA triplex will be important in the design of oligonucleotide probes with enhanced specificity and affinity for targeting in the genome. The third groove presents a potential target for binding additional ligands.

Polypurine-polypyrimidine sequences adopt unwound structure in pBR322 form V DNA as probed by single-hit analysis of HpaII sites

Structure at the polypurine-polypyrimidine sequences flanking the HpaII sites (CCGG) in pBR322 form V DNA was probed employing single-hit analysis using HpaII restriction endonuclease. Reduced cleavage efficiency of HpaII sites flanked by polypurine-polypyrimidine sequences suggested that under high torsional stress these sequences adopt unwound structures rendering these sites insensitive to restriction enzyme cleavage. In addition to polypurine-polypyrimidine sequences. HpaII sites flanked by alternating purine-pyrimidine sequence, a potential motif of left handed Z-DNA, were also found to be resistant to HpaII cleavage. Results obtained from various studies implicating structure sensitivity of restriction endonucleases and methylases were compiled and a direct correlation was observed between the occurrence of altered sites in a domain and its G/C content in pBR322 form V DNA.

Sequence limitations of triple helix formation by alternate-strand recognition

Until recently, oligonucleotide-directed triplex formation has been limited to oligopurine tracts of target DNA. Triplex formation by alternate-strand recognition relaxes this limitation by allowing triplexes to form at 5'-(Pu)m(Py)n-3' and 5'-(Py)m(Pu)n-3' sequences, with the third strand pairing first with purines on one strand and then switching to pair with purines on the other strand. In this study, the interaction of several oligonucleotides with the potential to form triplexes by alternate-strand recognition at the sequence 5'-A8C8A8-3' was studied by chemical probing and affinity cleaving. The results show that triplex formation can be readily accomplished at the 5'-A8C8-3' part of the sequence; however, base triplet formation is disrupted on either side of the strand switch and the Watson-Crick helix is distorted in such a way as to expose the N7 positions of purines adjoining the strand switch. Triplex formation is weak or nonexistent at the 3'-most A8 block, despite the opportunity for recruiting a spacer sequence for the second (C8-A8) strand switch by "slippage". This finding indicates that the C8-A8 strand switch is energetically unfavorable, although pairing at other 5'-(Py)n(Pu)n-3' sequences has been observed, with or without a spacer [Beal, P. A., & Dervan, P. B. (1992) J. Am. Chem. Soc. 114, 1470-1478; Jayasena, S. D., & Johnston, B. H. (1992) Nucleic Acids Res. 20, 5279-5288]. Thus, alternate-strand recognition may not be feasible for certain sequences of 5'-(Py)m(Pu)n-3', at least under the conditions examined.

Prediction of the structure of the Y+.R-.R(+)-type DNA triple helix by molecular modelling

Molecular mechanics has been used to predict the structure of the Y+.R-.R(+)-type DNA triple helix, in which a second polypurine strand binds antiparallel to the homopurine strand of a homopurine/homopyrimidine stretch of duplex DNA. From calculations on the sequence d(C)10.d(G)10.d(G)10, two likely structures emerge. One has the glycosidic torsions of the third strand bases in the anti-conformation and Hoogsteen hydrogen-bonds to the purine strand of the duplex, the other has the third strand purines in the syn orientation and uses a reverse-Hoogsteen hydrogen-bonding pattern. Despite the large structural differences between these two types of triplex, calculations performed in vacuo with a distance-dependent dielectric constant to mimic the shielding effect of solvent show them to be energetically very similar, with the latter (syn) slightly preferred. However, if explicit solvent molecules are included in the calculation, the anti conformation is found to be much preferred. This difference in the results seems to stem from an underestimation of short-range electrostatic interactions in the in vacuo simulations. When TAA or TAT base triples are substituted for the sixth CGG triple in the sequence, it is found that, for the solvated model, the third strand base of the TAA triple prefers the syn orientation while that in the TAT triple retains a preference, though reduced, for the anti conformation.

Oligonucleotide-directed triple helix formation at adjacent oligopurine and oligopyrimidine DNA tracts by alternate strand recognition

A significant limitation to the practical application of triplex DNA is its requirement for oligopurine tracts in target DNA sequences. The repertoire of triplex-forming sequences can potentially be expanded to adjacent blocks of purines and pyrimidines by allowing the third strand to pair with purines on alternate strands, while maintaining the required strand polarities by combining the two major classes of base triplets, Py.PuPy and Pu.PuPy. The formation of triplex DNA in this fashion requires no unusual bases or backbone linkages on the third strand. This approach has previously been demonstrated for target sequences of the type 5'-(Pu)n(Py)n-3' in intramolecular complexes. Using affinity cleaving and DNase I footprinting, we show here that intermolecular triplexes can also be formed at both 5'-(Pu)n(Py)n-3' and 5'-(Py)n(Pu)n-3' target sequences. However, triplex formation at a 5'-(Py)n(Pu)n-3' sequence occurs with lower yield. Triplex formation is disfavored, even at acid pH, when a number of contiguous C+.GC base triplets are required. These results suggest that triplex formation via alternate strand recognition at sequences made up of blocks of purines and pyrimidines may be generally feasible.

The influence of single base triplet changes on the stability of a pur.pur.pyr triple helix determined by affinity cleaving

The influence of sixteen base triplet changes at a single position within a pur.pur.pyr triple helix was examined by affinity cleaving. For the 15 base pair target site studied here, G.GC, A.AT and T.AT triplets stabilize a triple helix to a greater extent than the other 13 natural triplets (pH = 7.4, 25 degrees C). Weaker interactions were detected for the C.AT, A.GC and T.CG triplets. The absence of specific, highly stabilizing interactions between third strand bases and the CG or TA base pairs demonstrates a current sequence limitation to formation of this structure. Models for the two dimensional base triplet interactions for all possible 16 natural triplets are presented.