Flanking sequence effects within the pyrimidine triple-helix motif characterized by affinity cleaving.

Nearest neighbor interactions affect the stabilities of triple-helical complexes. Within a pyrimidine triple-helical motif, the relative stabilities of natural base triplets T.AT, C + GC, and G.TA, as well as triplets, D3.TA and D3.CG, containing the nonnatural deoxyribonucleoside 1-(2-deoxy-beta-D-ribofuranosyl)-4-(3-benzamido)phenylimidazole (D3) were characterized by the affinity cleaving method in the context of different flanking triplets (T.AT, T.AT: T.AT, C + GC: C + GC, T.AT: G + GC, C + GC). The to be insensitive to substitutions in either the 3' or 5' directions, while the relative stabilities of triple helices containing C + GC triplets decreased as the number of adjacent C + GC triplets increased. Triple helices incorporating a G.TA interaction were most stable when this triplet was flanked by two T.AT triplets and were adversely affected when a C + GC triplet was placed in the adjacent 5' direction. Similarly, complexes containing D3.TA or D3.CG triplets were most stable when the triplet was flanked by two T.AT triplets but were destabilized when the adjacent 3' neighbor position was occupied with a C + GC triplet. This information regarding sequence composition effects in triple-helix formation establishes a set of guidelines for targeting sequences of double-helical DNA by the pyrimidine triple-helix motif.     

Sequence composition effects on the stabilities of triple helix formation by oligonucleotides containing N7-deoxyguanosine.

A nonnatural nucleoside, 7-(2-deoxy-beta-D-erythro-pento-furanosyl)-guanine (d7G), mimics protonated cytosine and specifically binds GC base pairs within a pyrimidine - purine - pyrimidine triple helix. The differences in association constants (KT) determined by quantitative footprint titration experiments at neutral pH reveal dramatic sequence composition effects on the energetics of triple helix formation by oligonucleotides containing d7G. Purine tracts of sequence composition 5'-d(AAAAAGAGAGAGAGA)-3' are bound by oligonucleotide 5'-d(TTTTT7GT7GT7GT7GT7GT)-3' three orders of magnitude less strongly than by 5'-d(TTTTTmCTmCTmCTmCTmCT)-3' (KT = 1.5 x 10(6) M(-1) and KT > or = 3 x 10(9) M(-1) respectively). Conversely, purine tracts of sequence composition 5'-d(AAAAGAAAAGGGGGGA)-3' are bound by oligonucleotide 5'-d(TTTTmCTTTT7G7G7G7G7G7GT)-3' five orders of magnitude more strongly than by 5'-d(TTTTmCTTTTmCmCmCmCmCT)-3' (KT > or = 3 x 10(9) M(-1) and KT < 5 x 10(4) M(-1) respectively). The complementary nature of d7G and mC expands the repertoire of G-rich sequences which may be targeted by triple helix formation.     

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

Triple-helical DNA shows increasing potential for applications in the control of gene expression (including therapeutics) and the development of sequence-specific DNA-cleaving agents. The major limitation in this technology has been the requirement of homopurine sequences for triplex formation. We describe a simple approach that relaxes this requirement, by utilizing both Pu.PuPy and Py.PuPy base triplets to form a continuous DNA triple helix at tandem oligopurine and oligopyrimidine tracts. [Triplex formation at such a sequence has been previously demonstrated only with the use of a special 3'-3' linkage in the third strand [Horne, D. A., & Dervan, P. B. (1990) J. Am. Chem. Soc. 112, 2435-2437].] Supporting evidence is from chemical probing experiments performed on several oligonucleotides designed to form 3-stranded fold-back structures. The third strand, consisting of both purine and pyrimidine blocks, pairs with purines in the Watson-Crick duplex, switching strands at the junction between the oligopurine and oligopyrimidine blocks but maintaining the required strand polarity without any special linkage. Although Mg2+ ions are not required for the formation of Pu.PuPy base triplets, they show enhanced stability in the presence of Mg2+. In the sequences observed. A.AT triplets appear to be more stable than G.GC triplets. As expected, triplex formation is largely independent of pH unless C+.GC base triplets are required.     

Single-strand DNA triple-helix formation

Chemical modification studies provide evidence that single-stranded oligodeoxyribonucleotides can form stable intrastrand triple helices. Two oligonucleotides of opposite polarity were synthesized, each composed of a homopurine-homopyrimidine hairpin stem linked to a pyrimidine sequence which is capable of folding back on the hairpin stem and forming specific Hoogsteen hydrogen bonds. Using potassium permanganate as a chemical modification reagent, we have found that two oligodeoxyribonucleotides of sequence composition type 5'-(purine)8(N)4(pyrimidine)8(N)6(pyrimidine)8-3' and 5'-(pyrimidine)8N6(pyrimidine)8N4(purine)8-3' undergo dramatic structural changes consistent with intrastrand DNA triple-helix formation induced by lowering the pH or raising the Mg2+ concentration. The intrastrand DNA triple helix is sensitive to base mismatches.     

Mechanism of copper mediated triple helix formation at neutral pH in Drosophila satellite repeats

The highly repeated Drosophila melanogaster AAGAGAG satellite sequence is present at each chromosome centromere of the fly. We demonstrate here how, under nearly physiological pH conditions, these sequences can form a pyrimidine triple helix containing T.A-T and CCu.G-C base triplets, stabilized by Cu2+ metal ions in amounts mirroring in vivo concentrations. Ultraviolet experiments were used to monitor the triple helix formation at pH 7.2 in presence of Cu2+ ions. Triplex melting is observed at 23 degrees C. Furthermore, a characteristic signature of triple helix formation was obtained by Fourier transform infrared spectroscopy. The stabilization of the C.G-C base triplets at pH 7.2 is shown to occur via interactions of Cu2+ ions on the third strand cytosine N3 atom and on the guanine N7 atom of the polypurine target strand forming CCu.G-C triplets. Under the same neutral pH conditions in absence of Cu2+ ions, the triple helix fails to form. Possible biological implications are discussed.     

Relative stability of triplexes containing different numbers of T.AT and C+.GC triplets.

We have used DNase I footprinting to compare the stability of parallel triple helices containing different numbers of T.AT and C+. GC triplets. We have targeted a fragment containing the 17mer sequence 5'-AGGAAGAGAAAAAAGAA with the 9mer oligonucleotides 5'-TCCTTCTCT, 5'-TTCTCTTTT and 5'-TTTTTTCTT, which form triplexes at the 5'-end, centre and 3'-end of the target site respectively. Quantitative DNase I footprinting has shown that at pH 5.0 the dissociation constants of these oligonucleotides are 0.13, 4.7 and >30 microM respectively, revealing that increasing the proportion of C+.GC triplets increases triplex stability. The results suggest that the positive charge on the protonated cytosine contributes to triplex stability, either by a favourable interaction with the stacked pisystem or by screening the charge on the phosphate groups. In the presence of a naphthylquinoline triplex binding ligand all three oligonucleotides bind with similar affinities. At pH 6.0 these triplexes only form in the presence of the triplex binding ligand, while at pH 7.5 footprints are only seen with the oligonucleotide which generates the fewest number of C+.GC triplets (TTTTTTCTT) in the presence of the ligand.     

Exclusion of RNA strands from a purine motif triple helix.

Research concerning oligonucleotide-directed triple helix formation has mainly focused on the binding of DNA oligonucleotides to duplex DNA. The participation of RNA strands in triple helices is also of interest. For the pyrimidine motif (pyrimidine.purine.pyrimidine triplets), systematic substitution of RNA for DNA in one, two, or all three triplex strands has previously been reported. For the purine motif (purine.purine.pyrimidine triplets), studies have shown only that RNA cannot bind to duplex DNA. To extend this result, we created a DNA triple helix in the purine motif and systematically replaced one, two, or all three strands with RNA. In dramatic contrast to the general accommodation of RNA strands in the pyrimidine triple helix motif, a stable triplex forms in the purine motif only when all three of the substituent strands are DNA. The lack of triplex formation among any of the other seven possible strand combinations involving RNA suggests that: (i) duplex structures containing RNA cannot be targeted by DNA oligonucleotides in the purine motif; (ii) RNA strands cannot be employed to recognize duplex DNA in the purine motif; and (iii) RNA tertiary structures are likely to contain only isolated base triplets in the purine motif.     

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.     

Triplex formation by oligonucleotides containing 5-(1-propynyl)-2'-deoxyuridine: decreased magnesium dependence and improved intracellular gene targeting

Oligonucleotides capable of sequence-specific triple helix formation have been proposed as DNA binding ligands useful for modulation of gene expression and for directed genome modification. However, the effectiveness of such triplex-forming oligonucleotides (TFOs) depends on their ability to bind to their target sites within cells, and this can be limited under physiologic conditions. In particular, triplex formation in the pyrimidine motif is favored by unphysiologically low pH and high magnesium concentrations. To address these limitations, a series of pyrimidine TFOs were tested for third-strand binding under a variety of conditions. Those containing 5-(1-propynyl)-2'-deoxyuridine (pdU) and 5-methyl-2'-deoxycytidine (5meC) showed superior binding characteristics at neutral pH and at low magnesium concentrations, as determined by gel mobility shift assays and thermal dissociation profiles. Over a range of Mg2+ concentrations, pdU-modified TFOs formed more stable triplexes than did TFOs containing 2'-deoxythymidine. At 1 mM Mg2+, a DeltaTm of 30 degreesC was observed for pdU- versus T-containing 15-mers (of generic sequence 5' TTTTCTTTTTTCTTTTCT 3') binding to the cognate A:T bp rich site, indicating that pdU-containing TFOs are capable of substantial binding even at physiologically low Mg2+ concentrations. In addition, the pdU-containing TFOs were superior in gene targeting experiments in mammalian cells, yielding 4-fold higher mutation frequencies in a shuttle vector-based mutagenesis assay designed to detect mutations induced by third-strand-directed psoralen adducts. These results suggest the utility of the pdU substitution in the pyrimidine motif for triplex-based gene targeting experiments.     

Energetics of the calcium-transporting ATPase

A thermodynamic cycle for catalysis of calcium transport by the sarcoplasmic reticulum ATPase is described, based on equilibrium constants for the microscopic steps of the reaction shown in Equation 1 under a single set of experimental (formula; see text) conditions (pH 7.0, 25 degrees C, 100 mM KCl, 5 mM MgSO4): KCa = 5.9 X 10(-12) M2, K alpha ATP = 15 microM, Kint = 0.47, K alpha ADP = 0.73 mM, K'int = 1.7, K"Ca = 2.2 X 10(-6) M2, and Kp = 37 mM. The value of K"Ca was calculated by difference, from the free energy of hydrolysis of ATP. The spontaneous formation of an acylphosphate from Pi and E is made possible by the expression of 12.5 kcal mol-1 of noncovalent binding energy in E-P. Only 1.9 kcal mol-1 of binding energy is expressed in E X Pi. There is a mutual destabilization of bound phosphate and calcium in E-P X Ca2, with delta GD = 7.6 kcal mol-1, that permits transfer of phosphate to ADP and transfer of calcium to a concentrated calcium pool inside the vesicle. It is suggested that the ordered kinetic mechanism for the dissociation of E-P X Ca2, with phosphate transfer to ADP before calcium dissociation outside and phosphate transfer to water after calcium dissociation inside, preserves the Gibbs energies of these ligands and makes a major contribution to the coupling in the transport process. A lag (approximately 5 ms) before the appearance of E-P after mixing E and Pi at pH 6 is diminished by ATP and by increased [Pi]. This suggests that ATP accelerates the binding of Pi. The weak inhibition by ATP of E-P formation at equilibrium also suggests that ATP and phosphate can bind simultaneously to the enzyme at pH 6. Rate constants are greater than or equal to 115 s-1 for all the steps in the reaction sequence to form E-32P X Ca2 from E-P, Ca2+ and [32P]ATP at pH 7. E-P X Ca2 decomposes with kappa = 17 s-1, which shows that it is a kinetically competent intermediate. The value of kappa decreases to 4 s-1 if the intermediate is formed in the presence of 2 mM Ca2+. This decrease and inhibition of turnover by greater than 0.1 mM Ca2+ may result from slow decomposition of E-P X Ca3.     

A directional nucleation-zipping mechanism for triple helix formation

A detailed kinetic study of triple helix formation was performed by surface plasmon resonance. Three systems were investigated involving 15mer pyrimidine oligonucleotides as third strands. Rate constants and activation energies were validated by comparison with thermodynamic values calculated from UV-melting analysis. Replacement of a T·A base pair by a C·G pair at either the 5′ or the 3′ end of the target sequence allowed us to assess mismatch effects and to delineate the mechanism of triple helix formation. Our data show that the association rate constant is governed by the sequence of base triplets on the 5′ side of the triplex (referred to as the 5′ side of the target oligopurine strand) and provides evidence that the reaction pathway for triple helix formation in the pyrimidine motif proceeds from the 5′ end to the 3′ end of the triplex according to the nucleation-zipping model. It seems that this is a general feature for all triple helices formation, probably due to the right-handedness of the DNA double helix that provides a stronger base stacking at the 5′ than at the 3′ duplex–triplex junction. Understanding the mechanism of triple helix formation is not only of fundamental interest, but may also help in designing better triple helix-forming oligonucleotides for gene targeting and control of gene expression.     

Cooperative binding of oligonucleotides to adjacent sites of single-stranded DNA: sequence composition dependence at the junction

The quantitative parameters of cooperative binding of deoxyribooligonucleotides to adjacent sites by double helix formation have been determined as a function of sequence composition at the junction. The base stacks 5'-Py/p-Py-3', 5'-Pu/p-Py-3' and 5'-Pu/p-Pu-3' (p is phosphate group, Py and Pu are pyrimidine and purine nucleoside, respectively) including mismatches on the 3'-side of the junction were studied using complementary addressed modification titration (CAMT) at 25 degrees C and pH 7.5, 0.16 M NaCl, 0.02 M Na2HPO4, 0.1 mM EDTA. The equilibrium binding constants of alkylating derivatives of 8-mer oligonucleotides (reagents) with 22-mer oligonucleotides (targets) were determined using the dependence of the target limit modification extents on the concentrations of the reagents. The parameters of cooperativity were calculated as the ratio of binding constants of reagents in the presence and the absence of a second 8-mer oligonucleotides (effectors) occupying the adjacent site on the 22-mer targets. For the stacks 5'-Py/p-Py-3' the parameters of cooperativity were around unity both for matched and mismatched nucleotides at the junction indicating the absence of cooperativity. The parameters of cooperativity for the stacks 5'-Pu/p-Pu-3' were higher than for the stacks 5'-Pu/p-Py-3' in perfect and non-perfect duplexes. Discrimination of mismatches was higher in nicked than in normal duplexes.     

Ethidium ion binds more strongly to a DNA double helix with a bulged cytosine than to a regular double helix

Thermodynamic parameters for ethidium intercalation were determined for the double helices formed by the oligonucleotides dCA6G + dCT6G, which form a normal helix, and dCA3CA3G + dCT6G, which form a double helix with the middle cytosine bulged outside of the helix. Ethidium intercalation was measured by monitoring the absorbance at 260 and 283 nm as a function of temperature for a number of concentrations of ethidium. The binding to the normal helix occurs equally at all the intercalation sites, with an enthalpy of binding of -8 kcal mol-1, an entropy of binding of -6 eu, and an equilibrium constant at 25 degrees C of 2.2 X 10(4) M-1. The binding to the bulged double helix was considerably stronger and is consistent with a model in which the intercalation sites on either side of the bulged base bind 10 times stronger than the other sites. Thus, there are two strong binding sites on the perturbed helix with equilibrium constants for binding of 2 X 10(5) M-1 at 25 degrees C in addition to five normal sites. Several other binding models were tested but did not fit the data satisfactorily.     

Binding characteristics of a major thyroid hormone metabolite, 3,3',5'-triiodo-L-thyronine, to bovine serum albumin as measured by fluorescence

The interaction between a major thyroid hormone metabolite, 3,3',5'-triiodo-L-thyronine and bovine serum albumin was investigated by fluorescence measurements. The apparent binding constants were obtained at various pHs assuming the equivalence and independence of the interaction sites on the protein from the fluorescence titration curves. The maximum binding was attained at pH 8.0, and the apparent binding constant was (5.28 +/- 0.13).10(5) M-1 with one binding site per albumin molecule. Thermodynamic parameters were also determined from the van't Hoff plot of the apparent binding constants at pH 7.5. The free energy change, enthalpy change and entropy change were -7.70 +/- 0.09 kcal.mol-1, -4.59 kcal.mol-1 and 10.2 e.u., respectively.     

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.     

Effects of an abasic site on triple helix formation characterized by affinity cleaving.

The stability of triple helical complexes of pyrimidine oligodeoxyribonucleotides containing one abasic 1,2-dideoxy-D-ribose (phi) residue was examined by affinity cleaving. Within a pyrimidine third strand, the triplets phi.AT, phi.GC, phi.TA and phi.CG are significantly less stable than the triplets, T.AT, C+GC and G.TA. The decrease in binding produced by an abasic residue is similar to that observed with imperfectly matched natural base triplets, with phi.AT and phi.GC being less stable than phi.TA and phi.CG triplets for the sequences studied.     

Pyrimidine morpholino oligonucleotides form a stable triple helix in the absence of magnesium ions

Oligonucleotides can be used as sequence-specific DNA ligands by forming a local triple helix. In order to form more stable triple-helical structures or prevent their degradation in cells, oligonucleotide analogues that are modified at either the backbone or base level are routinely used. Morpholino oligonucleotides appeared recently as a promising modification for antisense applications. We report here a study that indicates the possibility of a triple helix formation with a morpholino pyrimidine TFO and its comparison with a phosphodiester and a phosphoramidate oligonucleotide. At a neutral pH and in the presence of a high magnesium ion concentration (10 mM), the phosphoramidate oligomer forms the most stable triple helix, whereas in the absence of magnesium ion but at a physiological monovalent cation concentration (0.14 M) only morpholino oligonucleotides form a stable triplex. To our knowledge, this is the first report of a stable triple helix in the pyrimidine motif formed by a noncharged oligonucleotide third strand (the morpholino oligonucleotide) and a DNA duplex. We show here that the structure formed with the morpholino oligomer is a bona fide triple helix and it is destabilized by high concentrations of potassium ions or divalent cations (Mg(2+)).     

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.     

Free energy of the binding of uridylic acid oligomers with double stranded poly(A) x poly(U)

The binding parameters (K, omega) and the free energy (DeltaG(0)) of triple helix formation have been estimated for complexes of oligo(U)(n) (n = 5, 7-10) with poly(A) . poly(U) on the basis of hypochromicity measurements. The data were treated according to the formula of McGhee and von Hippel [J. Mol. Biol. 86 (1974) 469] by a computer program ALAU [H. Schütz et al., Stud. Biophys. 104 (1984) 23] which takes absorbancies and total concentrations as input. In 1 mM cacodylate buffer pH 7.0 with 10 mM NaCl and 10 mM MgCl(2) at 5 degrees C the free energy of contiguous binding was found to be a linear function of the oligomer length with a slope of DeltaG(c,U)(0) = -0.72 (+/-0.03) kcal x mol(-1) per nucleotide. The mean cooperativity coefficient (omega) was 24.5 (+/- 5.6), and the corresponding free energy of interaction between the neighbouring oligonucleotides in the third strand was DeltaG(0(omega)) = -1.74 (+/-0.13) kcal x mol(-1).