Proton NMR studies of 5'-d-(TC)(3) (CT)(3) (AG)(3)-3'--a paperclip triplex: the structural relevance of turns

In this study, we present the results of structural analysis of an 18-mer DNA 5'-T(1)C(2)T(3)C(4)T(5)C(6)C(7)T(8)C(9)T(10)C(11)T(12)A(13)G(14)A(15)G(16)A(17)G(18)-3' by proton nuclear magnetic resonance (NMR) spectroscopy and molecular modeling. The NMR data are consistent with characteristics for triple helical structures of DNA: downfield shifting of resonance signals, typical for the H3(+) resonances of Hoogsteen-paired cytosines; pH dependence of these H3(+) resonance; and observed nuclear Overhauser effects consistent with Hoogsteen and Watson-Crick basepairing. A three-dimensional model for the triplex is developed based on data obtained from two-dimensional NMR studies and molecular modeling. We find that this DNA forms an intramolecular "paperclip" pyrimidine-purine-pyrimidine triple helix. The central triads resemble typical Hoogsteen and Watson-Crick basepairing. The triads at each end region can be viewed as hairpin turns stabilized by a third base. One of these turns is comprised of a hairpin turn in the Watson-Crick basepairing portion of the 18-mer with the third base coming from the Hoogsteen pairing strand. The other turn is comprised of two bases from the continuous pyrimidine portion of the 18-mer, stabilized by a hydrogen-bond from a purine. This "triad" has well defined structure as indicated by the number of nuclear Overhauser effects and is shown to play a critical role in stabilizing triplex formation of the internal triads.     

Proton nuclear magnetic resonance assignments and structural characterization of an intramolecular DNA triplex.

Two-dimensional 1H n.m.r. spectroscopy has been used to study the 31-base DNA oligonucleotide 5'-dAGAGAGAACCCCTTCTCTCTTTTTCTCTCTT-3', which folds to form a stable intramolecular triplex in solution at acidic pH. This structure is considerably more difficult to assign than short B-DNA duplexes and requires new assignment methods. The assignment strategy and assignments of almost all of the exchangeable and nonexchangeable resonances are presented. Seven base triplets and one Watson-Crick base-pair form the core of the structure and are connected by a four C and four T loop at either end. The second pyrimidine "strand" (bases 24 to 31) in this intramolecular pyrimidine-purine-pyrimidine triplex binds via Hoogsteen base-pairs in the major groove and is parallel to the purine "strand" (bases 1 to 8). Analysis of the sugar puckers reveals that, contrary to widely accepted belief, the triplex sugars are not predominantly in the N-type (close to C3'-endo) conformation. Except for some of the C nucleotides, all sugars are predominantly S-type (close to C2'-endo). Thus, the duplex DNA does not assume N-type sugar conformations to accommodate a third strand in the major groove. A preliminary model of the triplex structure is presented.     

Nuclear magnetic resonance structural studies of intramolecular purine.purine.pyrimidine DNA triplexes in solution. Base triple pairing alignments and strand direction

Recently, P.A. Beal and P.B. Dervan, expanding on earlier observations by others, have established the formation of purine.purine.pyrimidine triple helices stabilized by G.GC, A.AT and T.AT base triples where the purine-rich third strand was positioned in the major groove of the Watson-Crick duplex and anti-parallel to its purine strand. The present nuclear magnetic resonance (n.m.r.) study characterizes the base triple pairing alignments and strand direction in a 31-mer deoxyoligonucleotide that intramolecularly folds to generate a 7-mer (R/Y-)n.(R+)n(Y-)n triplex with the strands linked by two T5 loops and stabilized by potential T.AT and G.GC base triples. (R and Y stand for purine and pyrimidine, respectively, while the signs establish the strand direction.) This intramolecular triplex gives well-resolved exchangeable and non-exchangeable proton spectra with Li+ as counterion in aqueous solution. These studies establish that the T1 to C7 pyrimidine and the G8 to A14 purine strands are anti-parallel to each other and align through Watson-Crick A.T and G.C pair formation. The T15 to G21 purine-rich third strand is positioned in the major groove of this duplex and pairs through Hoogsteen alignment with the purine strand to generate T.AT and G.GC triples. Several lines of evidence establish that the thymidine and guanosine bases in the T15 to G21 purine-rich third strand adopt anti glycosidic torsion angles under conditions where this strand is aligned anti-parallel to the G8 to A14 purine strand. We have also recorded imino proton n.m.r. spectra for an (R-)n.(R+)n(Y-)n triplex stabilized by G.GC and A.AT triples through intramolecular folding of a related 31-mer deoxyoligonucleotide with Li+ as counterion. The intramolecular purine.purine.pyrimidine triplexes containing unprotonated G.GC, A.AT and T.AT triples are stable at basic pH in contrast to pyrimidine.purine.pyrimidine triplexes containing protonated C+.GC and T.AT triples, which are only stable at acidic pH.     

Presence of divalent cation is not mandatory for the formation of intramolecular purine-motif triplex containing human c-jun protooncogene target

Modulation of endogenous gene function, through sequence-specific recognition of double helical DNA via oligonucleotide-directed triplex formation, is a promising approach. Compared to the formation of pyrimidine motif triplexes, which require relatively low pH, purine motif appears to be the most gifted for their stability under physiological conditions. Our previous work has demonstrated formation of magnesium-ion dependent highly stable intermolecular triplexes using a purine third strand of varied lengths, at the purine?pyrimidine (Pu?Py) targets of SIV/HIV-2 (vpx) genes (Svinarchuk, F., Monnot, M., Merle, A., Malvy, C., and Fermandjian, S. (1995) Nucleic Acids Res. 23, 3831-3836). Herein, we show that a designed intramolecular version of the 11-bp core sequence of the said targets, which also constitutes an integral, short, and symmetrical segment (G(2)AG(5)AG(2))?(C(2)TC(5)TC(2)) of human c-jun protooncogene forms a stable triplex, even in the absence of magnesium. The sequence d-C(2)TC(5)TC(2)T(5)G(2)AG(5)AG(2)T(5)G(2)AG(5)AG(2) (I-Pu) folds back twice onto itself to form an intramolecular triple helix via a double hairpin formation. The design ensures that the orientation of the intact third strand is antiparallel with respect to the oligopurine strand of the duplex. The triple helix formation has been revealed by non-denaturating gel assays, UV-thermal denaturation, and circular dichroism (CD) spectroscopy. The monophasic melting curve, recorded in the presence of sodium, represented the dissociation of intramolecular triplex to single strand in one step; however, the addition of magnesium bestowed thermal stability to the triplex. Formation of intramolecular triple helix at neutral pH in sodium, with or without magnesium cations, was also confirmed by gel electrophoresis. The triplex, mediated by sodium alone, destabilizes in the presence of 5'-C(2)TC(5)TC(2)-3', an oligonucleotide complementary to the 3'-oligopurine segments of I-Pu, whereas in the presence of magnesium the triplex remained impervious. CD spectra showed the signatures of triplex structure with A-like DNA conformation. We suggest that the possible formation of pH and magnesium-independent purine-motif triplexes at genomic Pu?Py sequences may be pertinent to gene regulation.     

NMR studies of triple-strand formation from the homopurine-homopyrimidine deoxyribonucleotides d(GA)4 and d(TC)4

The complexes formed by the homopurine and homopyrimidine deoxyribonucleotides d(GA)4 and d(TC)4 have been investigated by one- and two-dimensional 1H NMR. Under appropriate conditions [low pH, excess d(TC)4 strand] the oligonucleotides form a triplex containing one d(GA)4 and two d(TC)4 strands. The homopurine and one of the homopyrimidine strands are Watson-Crick base paired, and the second homopyrimidine strand is Hoogsteen base paired in the major groove to the d(GA)4 strand. Hoogsteen base pairing in GC base pairs requires hemiprotonation of C; we report direct observation of the C+ imino proton in these base pairs. Both homopyrimidine strands have C3'-endo sugar conformations, but the purine strand does not. The major triplex formed appears to have four TAT and three CGC+ triplets formed by binding of the second d(TC)4 strand parallel to the d(GA)4 strand with a 3' dangling end. In addition to the triplexes formed, at least one other heterocomplex is observed under some conditions.     

Circular dichroism and UV melting studies on formation of an intramolecular triplex containing parallel T*A:T and G*G:C triplets: netropsin complexation with the triplex.

We have used circular dichroism and UV absorption spectroscopy to characterize the formation and melting behaviour of an intramolecular DNA triple helix containing parallel T*A:T and G*G:C triplets. Our approach to induce and to stabilize a parallel triplex involves the oligonucleotide 5'-d(G4A4G4[T4]C4T4C4-[T4]G4T4G4) ([T4] represents a stretch of four thymine residues). In a 10 mM sodium cacodylate, 0.2 mM disodium EDTA (pH 7) buffer, we have shown the following significant results. (i) While in the absence of MgCl2 this oligonucleotide adopts an intramolecular hairpin duplex structure prolonged by the single strand extremity 5'-d([T4]G4T4G4), the presence of millimolar concentrations of MgCl2generates an intramolecular triplex (via double hairpin formation). (ii) In contrast to the antiparallel triplex formed by the oligonucleotide 5'-d(G4T4G4[T4]G4A4G4[T4]C4T4C4), the parallel triplex melts in a biphasic manner (a triplex to duplex transition followed by a duplex to coil transition) and is less stable than the antiparallel one. The enthalpy change associated with triplex formation (-37 kcal/mol) is approximately half that of duplex formation (-81 kcal/mol). (iii) The parallel triple helix is disrupted by increasing the concentration of KCl(>10 mM), whereas, under the same conditions, the antiparallel triplex remains stable. (iv) Netropsin, a natural DNA minor groove-binding ligand, binds to the central site A4/T4of the duplex or triplex in an equimolar stoichiometry. Its association constant K is smaller for the parallel triplex ( approximately 1 x 10(7) M-1) than for the antiparallel one ( approximately 1 x 10(8) M-1). In contrast to the antiparallel structure, netropsin binding has no apparent effect on thermal stability of the parallel triple helix.     

Solution structure of a dsDNA:LNA triplex

We have determined the NMR structure of an intramolecular dsDNA:LNA triplex, where the LNA strand is composed of alternating LNA and DNA nucleotides. The LNA oligonucleotide binds to the dsDNA duplex in the major groove by formation of Hoogsteen hydrogen bonds to the purine strand of the duplex. The structure of the dsDNA duplex is changed to accommodate the LNA strand, and it adopts a geometry intermediate between A- and B-type. There is a substantial propeller twist between base-paired nucleobases. This propeller twist and a concomitant large propeller twist between the purine and LNA strands allows the pyrimidines of the LNA strand to interact with the 5′-flanking duplex pyrimidines. Altogether, the triplex has a regular global geometry as shown by a straight helix axis. This shows that even though the third strand is composed of alternating DNA and LNA monomers with different sugar puckers, it forms a seamless triplex. The thermostability of the triplex is increased by 19°C relative to the unmodified DNA triplex at acidic pH. Using NMR spectroscopy, we show that the dsDNA:LNA triplex is stable at pH 8, and that the triplex structure is identical to the structure determined at pH 5.1.     

Molecular mechanics calculations on a triple stranded DNA involving C+.G-T and T.A+-C mismatched base triples

We have carried out molecular modeling of a triple stranded pyrimidine(Y). purine(R): pyrimidine(Y) (where ':' refers to Watson-Crick and '.' to Hoogsteen bonding) DNA, formed by a homopurine (d-TGAGGAAAGAAGGT) and homo-pyrimidine (d-CTCCTTTCTTCC). Molecular mechanics calculations using NMR constraints have provided a detailed three dimensional structure of the triplex. The entire stretches of purine and the pyrimidine nucleotides have a conformation close to B-DNA. The three strands are held by the canonical C+.G:C and T.A:T hydrogen bonds. The structure also contains two mismatch C+.G-T and T.A+-C base triples which have been characterized for the first time. In the A+-C base-pair of the T.A+-C triple, both hydrogen donors are situated on the purine (A+(1N) and A+(6N)). We observe a unique hydrogen bonding interaction scheme in case of C+.G-T where one acceptor, G(60), is bonded to three donors (C+(3NH), C+(4NH2) and T(3NH)). Though the C+.G-T base triple is less stable than C+.G:C, it is significantly more stable than T.A:T. On the other hand, T.A+-C is as stable as the T.A:T base triad.     

Proton exchange and base pair opening in a DNA triple helix

Nuclear magnetic resonance spectroscopy has been used to characterize opening reactions and stabilities of individual base pairs in two related DNA structures. The first is the triplex structure formed by the DNA 31-mer 5'-AGAGAGAACCCCTTCTCTCTTTTTCTCTCTT-3'. The structure belongs to the YRY (or parallel) family of triple helices. The second structure is the hairpin double helix formed by the DNA 20-mer 5'-AGAGAGAACCCCTTCTCTCT-3' and corresponds to the duplex part of the YRY triplex. The rates of exchange of imino protons with solvent in the two structures have been measured by magnetization transfer from water and by real-time exchange at 10 degrees C in 100 mM NaCl and 5 mM MgCl2 at pH 5.5 and in the presence of two exchange catalysts. The results indicate that the exchange of imino protons in protonated cytosines is most likely limited by the opening of Hoogsteen C+G base pairs. The base pair opening parameters estimated from imino proton exchange rates suggest that the stability of individual Hoogsteen base pairs in the DNA triplex is comparable to that of Watson-Crick base pairs in double-helical DNA. In the triplex structure, the exchange rates of imino protons in Watson-Crick base pairs are up to 5000-fold lower than those in double-helical DNA. This result suggests that formation of the triplex structure enhances the stability of Watson-Crick base pairs by up to 5 kcal/mol. This stabilization depends on the specific location of each triad in the triplex structure.     

Intramolecular triplex formation of the purine.purine.pyrimidine type

Six octadecamers with hairpin motifs have been synthesized and investigated for possible intramolecular triplex formation. Electrophoretic, hypochromic, and CD evidence suggest that d(CCCCTTTGGGGTTTGGGG) and d(GGGGTTTGGGGTTTCCCC) can form G.G.C intramolecular triplexes via double hairpin formation in neutral solutions, presumably with the terminal G tract folding back along the groove of the hairpin duplex. In contrast, d(GGGGTTTCCCCTTTGGGG) and the three corresponding 18-mers containing one G and two C tracts each forms a single hairpin duplex with a dangling single strand. The design of the sequences has led to the conclusion that the two G tracts are antiparallel to each other in such a triplex. Magnesium chloride titrations indicate that Mg2+ is not essential for such an intramolecular triplex formation. The main advantage of our constructs when compared to the intermolecular triplex formation is that the shorter triplex stem can be formed in a much lower DNA concentration. The merit of G.G.C triplex, in contrast to that of C+.G.C, lies in the fact that acidic condition is not required in its formation and will, thus, greatly expand our repertoire in the triplex strategy for the recognition and cleavage of duplex DNA. Spectral binding studies with actinomycin D (ACTD) and chromomycin A3 (CHR) as well as fluorescence lifetime measurements with ethidium bromide (EB) suggest that although hairpin duplexes bind these drugs quite well, the intramolecular triplexes bind poorly. Interestingly, the binding densities for the strong-binding hairpins obtained from Scatchard plots are about one ACTD molecule per oligomeric strand, whereas more than two drug molecules are found in the case of CHR, in agreement with the recent NMR studies indicating that CHR binds to DNA in the form of a dimer.     

Three-dimensional homonuclear NOESY-TOCSY of an intramolecular pyrimidine.purine.pyrimidine DNA triplex containing a central G.TA triple: nonexchangeable proton assignments and structural implications.

Two- and three-dimensional homonuclear 1H NMR spectroscopic techniques have been applied to obtain nearly complete nonexchangeable proton assignments for a 31-residue intramolecular pyrimidine.purine.pyrimidine DNA triplex containing a central G.TA triple in D2O. An assignment strategy for obtaining resonance assignments for DNA protons from a 3D NOESY-TOCSY spectrum is proposed. The strategy utilizes the H1'/H5 omega 3 planes and relies on the recognition of cross-peak patterns for obtaining both intraresidue as well as sequential assignments. On the basis of the cross-peaks observed in the 2D and 3D spectra, a few structural features of the triplex have been delineated qualitatively. All three strands of the triplex adopt a right-handed helical conformation, and, despite the introduction of a central purine guanosine, there is no evidence for major structural distortions in the protonated third strand on the basis of a qualitative interpretation of NMR data. Several interstrand contacts between the purine and the Hoogsteen pyrimidine strands are observed which define the relative orientation of the bases and sugars in these two strands. The presence of strong NOEs between the methyl protons of thymine and the H1' proton of guanosine defines the preferred base-pairing alignment of guanosine at the G.TA triple site. The general approaches illustrated in this study extend the range of DNA molecules accessible for detailed structural investigation by high-resolution NMR spectroscopy.     

A novel palindromic triple-stranded structure formed by homopyrimidine dodecamer d-CTTCTCCTCTTC and homopurine hexamer d-GAAGAG.

We have carried out NMR and molecular mechanics studies on a complex formed when a palindromic homopyrimidine dodecamer (d-CTTCTCCTCTTC) and a homopurine hexamer (d-GAAGAG) are mixed in 1:1 molar ratio in aqueous solutions. Such studies unequivocally establish that two strands of each oligomer combine to form a triple-stranded DNA structure with a palindromic symmetry and with six T.A:T and six C+. G:C hydrogen-bonded base triads. The two purine strands are placed head to head, with their 3' ends facing each other in the center of the structure. One-half of each pyrimidine strand contains protonated and the other half contains non-protonated cytosines. The two half segments containing protonated cytosines are hydrogen bonded to each of the two purine hexamers through Hoogsteen T.A and C+.G base pairing. The segments containing non-protonated cytosines are involved in Watson-Crick (A:T and G:C) base pairing. This leads to a palindromic triplex with a C2-dyad symmetry with respect to the center of the structure. The complex is less stable at neutral pH, but the cytosines involved in Hoogsteen base pairing remain protonated even under these conditions. Molecular mechanics calculations using NMR constraints have provided a detailed three-dimensional structure of the complex. The entire stretches of purine, and the pyrimidine nucleotides have a conformation close to B-DNA.     

Evidence for a DNA triplex in a recombination-like motif: I. Recognition of Watson-Crick base pairs by natural bases in a high-stability triplex

Data are presented on a triplex type with two parallel homologous strands for which triplex formation is almost as strong as duplex formation at least for some sequences and even at pH 7 and 0.2 M NaCl. The evidence mainly rests upon comparing thermodynamic properties of similar systems. A paperclip oligonucleotide d(A12C4T12C4A12) with two linkers C4 obviously can form a triplex with parallel back-folded adenine strand regions, because the single melting transition of this complex splits in two transitions by introducing mismatches only in the third strand region. Respectively, a hairpin duplex d(A12C4T12) and a single strand d(A12) form a triplex as a 1:1 complex in which the second adenine strand is parallel oriented to the homologous one in the Watson-Crick paired duplex. In this system the melting temperature T(m) of the triplex is practically the same as that of the duplex d(A12)-d(T12), at least within a complex concentration range of 0.2-4.0 microM. The melting behaviour of complexes between triplex stabilizing ligand BePI and the system hairpin duplex plus single strand supports the triplex model. Non-denaturing gel electrophoresis suggests the existence of a triplex for a system in which five of the twelve A-T*A base triads are substituted by C-G*C base triads. The recognition between any substituted Watson-Crick base pair (X-Y) in the hairpin duplex d(A4XA7C4T7YT4) and the correspondingly replaced base (Z) in the third strand d(A4ZA7) is mutually selective. All triplexes with matching base substitutions (Z = X) have nearly the same stability (T(m) values from 29 to 33.5 degrees C), whereas triplexes with non-matching substitutions (Z not equal X) show a clearly reduced stability (T(m) values from 15 to 22 degrees C) at 2microM equimolar oligonucleotide concentration. Most nucleic acid triple helices hitherto known are limited to homopurine-homopyrimidine sequences in the target duplex. A stable triplex formation is demonstrated for inhomogeneous sequences tolerating at least 50% pyrimidine content in the homologous strands. On the basis of the surprisingly similar thermodynamic parameters for duplex and triplex, and of the fact that this triplex type seems to be more stable than many other natural DNA triplexes known, and on the basis of semiempirical and molecule mechanical calculations, we postulate bridging interactions of the third strand with the two other strands in the triplex according to the recombination motif. This triplex, denoted by us 'recombination-like form', tolerates heterogeneous base sequences.     

"Paper-clip" type triple helix formation by 5'-d-(TC)3Ta(CT)3Cb(AG)3 (a and b = 0-4) as a function of loop size with and without the pseudoisocytosine base in the Hoogsteen strand

The formation of a DNA "paper-clip" type triple helix (triplex) with a common sequence 5'-d-(TC)(3)T(a)()(CT)(3)C(b)()(AG)(3) (a and b = 0-4) was studied by UV thermal melting experiments and CD spectra. These DNA oligomers form triplexes and duplexes under slightly acidic and neutral conditions, respectively. The stability of the formed triplexes (at pH 4.5) or duplexes (at pH 7.0 or 8.0) does not vary significantly with the size of the loops (a and b = 1-4). At pH 6.0, the triplex stability is, however, a function of a and b. It is also interesting to note that the oligomer 5'-d-(TC)(3)(CT)(3)(AG)(3) (a and b = 0) forms a stable triplex at pH 4.5 with a slightly lower T(m) value, due to dissociation of a base triad at one end and a distorted base triad at the other, observed by (1)H NMR. Thus, we have here a model system, 5'-d-(TC)(3)T(a)(CT)(3)C(b)(AG)(3), that could form a triplex effectively with (a and b = 1-4) and without (a and b = 0) loops under acidic conditions. In addition, the triplex formation of oligomers with replacement of one, two, or three 2'-deoxycytidine in the Hoogsteen strand by either 2'-deoxypseudoisocytidine (D) or 2'-O-methylpseudoisocytidine (M) was also studied in the sequence 5'-d-(TX)(3)T(2)(CT)(3)C(2)(AG)(3) (where X is C, D, or M). Both CD spectra and UV melting results showed that only D3 [(TX)(3) = (TD)(3)] and M3 [(TX)(3) = (TM)(3)] were able to form the paper-clip structure under both neutral and acidic conditions. This is because the N(3)H of a pseudoisocytosine base can serve as a proton donor without protonation. We hereby proved that the 2'-deoxypseudoisocytidine, similar to 2'-O-methylpseudoisocytidine, could replace 2'-deoxycytidine in the Hoogsteen strand to provide triplex formation at neutral pH.     

Thermodynamics of triple helix formation: spectrophotometric studies on the d(A)10.2d(T)10 and d(C+3T4C+3).d(G3A4G3).d(C3T4C3) triple helices.

We have stabilized the d(A)10.2d(T)10 and d(C+LT4C+3).d(G3A4G3).d(C3T4C3) triple helices with either NaCl or MgCl2 at pH 5.5. UV mixing curves demonstrate a 1:2 stoichiometry of purine to pyrimidine strands under the appropriate conditions of pH and ionic strength. Circular dichroic titrations suggest a possible sequence-independent spectral signature for triplex formation. Thermal denaturation profiles indicate the initial loss of the third strand followed by dissociation of the underlying duplex with increasing temperature. Depending on the base sequence and ionic conditions, the binding affinity of the third strand for the duplex at 25 degrees C is two to five orders of magnitude lower than that of the two strands forming the duplex. Thermodynamic parameters for triplex formation were determined for both sequences in the presence of 50 mM MgCl2 and/or 2.0 M NaCl. Hoogsteen base pairs are 0.22-0.64 kcal/mole less stable than Watson-Crick base pairs, depending on ionic conditions and base composition. C+.G and T.A Hoogsteen base pairs appear to have similar stability in the presence of Mg2+ ions at low pH.     

Short pyrimidine stretches containing mixed base PNAs are versatile tools to induce translation elongation arrest and truncated protein synthesis

Recently, we showed that antisense peptide nucleic acids (PNA) containing a short pyrimidine stretch (C(4)TC(3)) invade Ha-ras mRNA hairpin structures to form highly stable duplex and triplex complexes that contribute to the arrest of translation elongation. The antisense PNA targeted to codon 74 of Ha-ras was designed to bind in antiparallel configuration (the N-terminal of the PNA faces the 3'-end of target mRNA), as PNA/RNA duplexes are most stable in this configuration. In order to show that different sequences in the coding region could be targeted successfully with antisense PNAs, we extended our study to three other purine-rich targets. We show that the tridecamer PNA (targeted to codon 149) containing a CTC(3)T pyrimidine stretch forms with the complementary oligoribonucleotide (ORN) a stable (PNA)(2)/ORN triplex at neutral pH (T(m) = 50 degrees C) and arrests Ha-ras mRNA translation elongation. Interestingly, the thermal stability of triplexes formed with PNAs designed to bind to the complementary ORN in a parallel orientation (the N-terminal of the PNA faces the 5'-end of target) was higher than that formed with antiparallel oriented PNAs (T(m) = 58 degrees C). Because parallel and antiparallel PNAs form stable triplexes with target sequence, they act as translation elongation blockers. These duplex-forming and partly triplex-forming PNAs targeted to Ha-ras mRNA also arrested translation elongation at specific polypurine sites contained in the mRNA coding for HIV-integrase protein. Furthermore, the tridecamer PNA containing the C(3)TC(4) motif was more active than a bis-PNA in which the Hoogsteen recognizing strand was linked to the Watson-Crick recognizing strand by a flexible linker. Pyrimidine-rich, short PNAs that form very stable duplexes with target Ha-ras mRNA inhibit translation by a mechanism that does not involve ribosome elongation arrest, whereas PNAs forming duplex and triplex structures arrest ribosome elongation. The remarkable efficacy of the tridecamer PNAs in arresting translation elongation of HIV-1 integrase mRNA is explained by their ability to form stable triplexes at neutral pH with short purine sequences.     

The first example of a Hoogsteen base-paired DNA duplex in dynamic equilibrium with a Watson-Crick base-paired duplex--a structural (NMR), kinetic and thermodynamic study.

A single-point substitution of the O4' oxygen by a CH2 group at the sugar residue of A6 (i.e. 2'-deoxyaristeromycin moiety) in a self-complementary DNA duplex, 5'-d(C1G2C3G4A5A6T7T8C9G10C11G12)2(-3), has been shown to steer the fully Watson-Crick basepaired DNA duplex (1A), akin to the native counterpart, to a doubly A6:T7 Hoogsteen basepaired (1B) B-type DNA duplex, resulting in a dynamic equilibrium of (1A)<==>(1B): Keq = k1/k(-1) = 0.56+/-0.08. The dynamic conversion of the fully Watson-Crick basepaired (1A) to the partly Hoogsteen basepaired (1B) structure is marginally kinetically and thermodynamically disfavoured [k1 (298K) = 3.9 0.8 sec(-1); deltaHdegrees++ = 164+/-14 kJ/mol; -TdeltaS degrees++ (298K) = -92 kJ/mol giving a deltaG degrees++ 298 of 72 kJ/mol. Ea (k1) = 167 14 kJ/mol] compared to the reverse conversion of the Hoogsteen (1B) to the Watson-Crick (1A) structure [k-1 (298K) = 7.0 0.6 sec-1, deltaH degrees++ = 153 13 kJ/mol; -TdeltaSdegrees++ (298K) = -82 kJ/mol giving a deltaGdegrees++(298) of 71 kJ/mol. Ea (k-1) = 155 13 kJ/mol]. Acomparison of deltaGdegrees++(298) of the forward (k1) and backward (k-1) conversions, (1A)<==>(1B), shows that there is ca 1 kJ/mol preference for the Watson-Crick (1A) over the double Hoogsteen basepaired (1B) DNA duplex, thus giving an equilibrium ratio of almost 2:1 in favour of the fully Watson-Crick basepaired duplex. The chemical environments of the two interconverting DNA duplexes are very different as evident from their widely separated sets of chemical shifts connected by temperature-dependent exchange peaks in the NOESY and ROESY spectra. The fully Watson-Crick basepaired structure (1A) is based on a total of 127 intra, 97 inter and 17 cross-strand distance constraints per strand, whereas the double A6:T7 Hoogsteen basepaired (1B) structure is based on 114 intra, 92 inter and 15 cross-strand distance constraints, giving an average of 22 and 20 NOE distance constraints per residue and strand, respectively. In addition, 55 NMR-derived backbone dihedral constraints per strand were used for both structures. The main effect of the Hoogsteen basepairs in (1B) on the overall structure is a narrowing of the minor groove and a corresponding widening of the major groove. The Hoogsteen basepairing at the central A6:T7 basepairs in (1B) has enforced a syn conformation on the glycosyl torsion of the 2'-deoxyaristeromycin moiety, A6, as a result of substitution of the endocyclic 4'-oxygen in the natural sugar with a methylene group in A6. A comparison of the Watson-Crick basepaired duplex (1A) to the Hoogsteen basepaired duplex (1B) shows that only a few changes, mainly in alpha, sigma and gamma torsions, in the sugar-phosphate backbone seem to be necessary to accommodate the Hoogsteen basepair.     

Effect of a 5'-phosphate on the stability of triple helix.

An effect of 5'-phosphorylation on the stability of triple helical DNA containing pyrimidine:purine:pyrimidine strands has been demonstrated by both gel electrophoresis and UV melting. A 5'-phosphate on the purine-rich middle strand of a triple helix lowers the stability of triple helix formation by approximately 1 kcal/mol at 25 degrees C. The middle strand is involved in both Watson-Crick and Hoogsteen base pairing. In contrast, a 5'-phosphate on the pyrimidine-rich strands, which are involved in either Watson-Crick or Hoogsteen base pairing, has a smaller effect on the stability of triple helix. The order of stability is: no phosphate on either strand > phosphate on both pyrimidine strands > phosphate on purine strand > phosphate on all three strands. Differential stability of triple helix species is postulated to stem from an increase in rigidity due to steric hindrance from the 5'-phosphate. This result indicates that labelling with 32P affect equilibrium in triplex formation.     

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.     

Single-Stranded DNA and RNA Targeted Triplex-Formation: UV,CD and Molecular Modeling Studies of Foldback Triplexes Containing Different RNA, 2′-OMe-RNA and DNA Strand Combinations

Abstract

We studied the influence of different 2′-OMe-RNA and DNA strand combinations on single strand targeted foldback triplex formation in the Py.Pu:Py motif using ultraviolet (UV) and circular dichroism (CD) spectroscopy, and molecular modeling. The study of eight combinations of triplexes (D D:D, R* D:D, D D:R*, R* D:R*, D R:D, R* R:D, DR:R*, and R*-R:R*; where the first, middle, and last letters stand for the Hoogsteen Pyrimidine, Watson-Crick [WC] purine and WC pyrimidine strands, respectively, and D, R and R* stand for DNA, RNA and 2′-OMe-RNA strands, respectively) indicate more stable foldback triplex formation with a DNA purine strand than with an RNA purine strand. Of the four possible WC duplexes with RNA/DNA combinations, the duplex with a DNA purine strand and a 2′-O-Me-RNA pyrimidine strand forms the most thermally stable triplex, although its thermal stability is the lowest of all four duplexes. Irrespective of the duplex combination, a 2′-OMe-RNA Hoogsteen pyrimidine strand forms a stable foldback triplex over a DNA Hoogsteen pyrimidine strand confirming the earlier reports with conventional and circular triplexes. The CD studies suggest a B-type conformation for an all DNA homo-foldback triplex (D.D.D), while hetero-foldback triplex spectra suggest intermediate conformation to both Atype and B-type structures. A novel molecular modeling study has been carried out to understand the stereochemical feasibility of all the combinations of foldback triplexes using a geometric approach. The new approach allows use of different combinations of chain geometries depending on the nature of the chain (RNA vs. DNA).