Triple-strand formation in the homopurine:homopyrimidine DNA oligonucleotides d(G-A)4 and d(T-C)4

The human insulin gene linked polymorphic region exhibits an altered DNA structure

Regulation of transcription of the human insulin gene appears to involve a series of DNA sequences in the 5' region. Hypersensitivity to DNA structural probes has previously been demonstrated in regulatory regions of cloned genomic DNA fragments, and been correlated with gene activity. To investigate the structure of the DNA in the human insulin gene, bromoacetaldehyde and S1 nuclease were reacted with a supercoiled plasmid containing a 5kb genomic insulin fragment. Both probes revealed the human insulin gene linked polymorphic region (ILPR), a region (-363) upstream of the transcriptional start site which contains multiple repeats of a 14-15mer oligonucleotide with the consensus sequence ACAGGGGT(G/C)(T/C)GGGG, as the major hypersensitive site. Fine mapping and electron microscopic analysis both show a very different behaviour of the two DNA strands in the region of the ILPR and suggest the G-rich strand may be adopting a highly structured conformation with the complementary strand remaining largely single stranded.

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.

Stabilities of double- and triple-strand helical nucleic acids

In this selected literature survey, we have seen that the stabilities of duplexes and triplexes are governed by the vertical base stacking, the horizontal specific base-paired H-bonding and the environmental parameters. The entropic contribution in the solvation/desolvation process is important in driving the aggregation of NA strands and duplex formation, but base stacking and specific H-bonding maintain the helical order. Triplex formation shares most of the physical environmental prerequisites with those of duplex NAs. However, some additional environmental conditions are often needed. Only in low pH solution is the polycytidylic strand protonated and, thus, it is possible for the strand to bind to a G.C duplex sequence to give the C+(G.C) triplex. High ionic strength is often necessary for the screening of inter-phosphate repulsion due to the high linear charge density in triplexes. The presence of specific counterions is important for complexation. In the absence of negative supercoiling, existence of an intramolecular triplex is rare except under very acidic conditions for the formation of C+(G.C)-type intramolecular triplex. As expected, the stabilities of both inter- and intramolecular triplexes increase with sequence length. The thermodynamic principles of helix-coil transition of oligo-duplex may be described by the van't Hoff relationship, which assumes a two-state cooperative melting profile. Thus, the enthalpy, entropy and free energy of transition can be evaluated from the experimental melting curves (e.g. OD, DSC). For polynucleotides, because of the non-two-state nature of transition, the simple van't Hoff relationship is no longer valid, and direct calorimetry is needed to obtain reliable thermodynamic parameters. The pH and salt concentration dependence of duplex stability can be formulated and derived from a van't Hoff equation. Base-stacking patterns are simple in duplexes but not so in triplexes due to the diversity in triplet schemes. The sequence dependence of base stacking for duplexes has been characterized and employed to predict the stability of an arbitrary sequence. In conclusion, the stability of duplex is relatively well-characterized by thermodynamic data in terms of both base stacking and specific H-bonding. Thermodynamic studies of triplexes have been far fewer in number. Oligonucleotides have found application in the detection and localization of a mRNA or its gene, the detection of bacterial or viral sequences, and the inhibition of the translation of mRNA and the transcription and replication of DNA (Englisch and Gauss, 1991). In a different approach, oligonucleotides have been targeted directly to a DNA duplex motif of a gene in order to inhibit the expression at the beginning of the transcriptional process.(ABSTRACT TRUNCATED AT 400 WORDS)

Site-specific cleavage of human chromosome 4 mediated by triple-helix formation

Direct physical isolation of specific DNA segments from the human genome is a necessary goal in human genetics. For testing whether triple-helix mediated enzymatic cleavage can liberate a specific segment of a human chromosome, the tip of human chromosome 4, which contains the entire candidate region for the Huntington's disease gene, was chosen as a target. A 16-base pyrimidine oligodeoxyribonucleotide was able to locate a 16-base pair purine target site within more than 10 gigabase pairs of genomic DNA and mediate the exact enzymatic cleavage at that site in more than 80 percent yield. The recognition motif is sufficiently generalizable that most cosmids should contain a sequence targetable by triple-helix formation. This method may facilitate the orchestrated dissection of human chromosomes from normal and affected individuals into megabase sized fragments and facilitate the isolation of candidate gene loci.

Structure and stability of X.G.C mismatches in the third strand of intramolecular triplexes

Intramolecular DNA triplexes that contain eight base triplets formed from the folding of a single DNA strand tolerate a single X.G.C mismatch in the third strand at acidic pH. The structure and relative stability of all four triplets that are possible involving a G.C Watson-Crick base pair were determined with one- and two-dimensional proton nuclear magnetic resonance techniques. Triplexes containing A.G.C, G.G.C, or T.G.C triplets were less stable than the corresponding parent molecule containing a C.G.C triplet. However, all mismatched bases formed specific hydrogen bonds in the major groove of the double helix. The relative effect of these mismatches on the stability of the triplex differs from the effect assayed (under different conditions) by two-dimensional gel electrophoresis and DNA cleavage with oligonucleotide EDTA.Fe(II).

Specificity and stringency in DNA triplex formation

Triple-helix formation can in principle serve as a general method for sequence-specific recognition and physical separation of duplex DNA molecules. Realization of this goal depends on how much the triplex is destabilized by mismatches and other defects (specificity) and on finding conditions in which perfect complexes are stable and defect complexes are not (stringency). We have addressed the question of specificity by determining the difference in free energy between perfect and defect complexes by using UV melting curves and equilibrium competition experiments. We find that third strands that bind with either single-base bulges or single mismatches are destabilized relative to the perfect triplex by 2.5-2.9 and 3.2-4.0 kcal/mol (1 cal = 4.184 J), respectively, essentially equivalent to the corresponding values determined for duplex DNA and RNA. Also, we present a method, referred to as stringency clamping, which maintains specific binding under conditions far from normal stringency. To do this, we provide for the formation of a competing structure involving the third strand with stability between that of the perfect and imperfect complexes; the competitive interaction effectively prevents triplex formation at imperfect sites even far below their melting temperature. We illustrate the phenomenon with three different stringency clamps, two of which compete for the all-pyrimidine third strand through Watson-Crick pairing and one that competes through all-pyrimidine pairing at acidic pH. We demonstrate physical separation of two duplex DNA molecules differing by a single base pair in their target sequence for triple-helix formation.

Effect of 5-methylcytosine on the stability of triple-stranded DNA--a thermodynamic study

We have previously shown that the pyrimidine oligonucleotide 5'CTTCCTCCTCT (Y11) recognizes the double-helical stem of hairpin 5'GAAGGAGGAGA-T4-TCTCCTCCTTC (h26) by triple-helix formation (1). In this paper, we report the effect on triplex formation of substituting the cytosine residues of Y11 with 5-methylcytosines (5meY11). In addition, we have studied the thermodynamics of the interaction between h26 and 5meY11. The results can be summarised as follows: (i) gel electrophoresis shows that at T = 5 degrees C and pH 5, both Y11 and 5meY11 form DNA triple helices with h26, whereas at pH 6.8 only the methylated strand binds to h26; (ii) pH-stability curves of the DNA triplexes formed from h26 + Y11 and h26 + 5meY11 show that Y11 and 5meY11 are semi-protonated at pH 5.7 and 6.7, respectively. Thus, it is concluded that cytosine methylation expands the pH range compatible with triplex formation by one pH unit; (iii) as the unmethylated triplex (h26:Y11), the methylated one (h26:5meY11) denatures in a biphasic manner, in which the low temperature transition results from the dissociation of 5meY11 from h26. The Tm of the triplex to h26 plus 5meY11 transition is strongly enhanced (about 10 degrees C) by cytosine methylation. A van 't Hoff analysis of denaturation curves is presented; (iv) DSC experiments show that triplex formation between 5meY11 and h26 is characterized by delta H = -237 +/- 25 kJ/mol and delta S = -758 +/- 75 J/Kmol, corresponding to an average delta H of -21 kJ/mol and delta S of -69 J/Kmol per Hoogsteen base pair; (v) the thermodynamic analysis indicates that the extra stability imparted to the triplex by methylcytosine is entropic in origin.

Structure and stability of X.G.C mismatches in the third strand of intramolecular triplexes

Intramolecular DNA triplexes that contain eight base triplets formed from the folding of a single DNA strand tolerate a single X.G.C mismatch in the third strand at acidic pH. The structure and relative stability of all four triplets that are possible involving a G.C Watson-Crick base pair were determined with one- and two-dimensional proton nuclear magnetic resonance techniques. Triplexes containing A.G.C, G.G.C, or T.G.C triplets were less stable than the corresponding parent molecule containing a C.G.C triplet. However, all mismatched bases formed specific hydrogen bonds in the major groove of the double helix. The relative effect of these mismatches on the stability of the triplex differs from the effect assayed (under different conditions) by two-dimensional gel electrophoresis and DNA cleavage with oligonucleotide EDTA.Fe(II).

Suppression of cyclobutane and mean value of 6-4 dipyrimidines formation in triple-stranded H-DNA

We have determined the effect of H-DNA formation on the distributions of two ultraviolet (UV) light induced photoproducts--cyclobutane dipyrimidines and mean value of 6-4 dipyrimidines. A region of DNA containing the sequence (dT-dC)18.(dA-dG)18 was treated under conditions that specifically yield the triple-stranded H-y3 or H-y5 DNA structure and then irradiated with UV. The positions of cyclobutane dipyrimidines and mean value of 6-4 dipyrimidines were determined by T4 endonuclease V cleavage and by hot piperidine cleavage, respectively. Formation of H-DNA structures greatly decreased the photoproduct yield in the (dT-dC)18.(dA-dG)18 region but not elsewhere in the DNA. Suppression of photoproduct formation is greater in half of the repeat, reflecting whether the DNA is in the H-y3 or H-y5 conformation. Within the repeat, the suppression was less in the middle and toward the ends. Models for the suppression of photoproduct formation in H-DNA and the possible utility of our findings are discussed.

On the conformation of the alpha sarcin stem-loop of 28S rRNA

A synthetic RNA that is a substrate for the cytotoxin alpha sarcin has been examined by NMR. The molecule in question includes the entire sequence of the so-called alpha sarcin loop from rat 28S rRNA (U4316-C4332), and it is cleaved at the residue that corresponds to G4325, the site of alpha sarcin cleavage in 28S rRNA. The data show that the terminal stem designed into the molecule's sequence exists, as expected, and that its loop has a definite structure, which is stable to at least 40 degrees C under ionic conditions compatible with its cleavage by alpha sarcin.

Oligonucleotide inhibition of IL2R alpha mRNA transcription by promoter region collinear triplex formation in lymphocytes

The promoter region of the IL2R alpha gene 5' flanking sequence contains enhancer elements crucial for binding nuclear factors which upregulate transcription following T lymphocyte activation. A 3' exonuclease resistant oligonucleotide (3'A-IL28p, terminated by a free amine group at its 3' end) was designed to bind to the IL2R alpha promoter region from -273 to -246, forming a collinear triplex spanning the kappa B enhancer (-266 to -256) as well as most of the serum response element (CArG box, -251 to -244). The binding site specificity of this oligonucleotide was demonstrated in electrophoretic mobility shift assays and by inhibition of restriction endonuclease (HinfI) cleavage within the segment of the target DNA predicted to form a triplex with the oligonucleotide. Intact normal lymphocytes, preincubated for 2h with 3'A-IL28p, accumulated less IL2Ralpha mRNA relative to other mRNAs (c-myc, beta-actin, IL2R beta, IL-6) for up to 12h after PHA stimulation, than did lymphocytes treated with a control oligomer of similar composition but different sequence. Nuclear run-on studies demonstrated that the rate of IL2R alpha mRNA synthesis relative to c-myc and beta-actin was also selectively diminished by treatment with 3'A-IL28p. These experiments suggest that transcription of individual genes can be selectively modulated in living cells by sequence specific collinear triplex formation in regulatory enhancer sequences.

Probing DNA triple helix structure by chemical ligation

A series of oligomeric double and triple helical DNAs with irregular sequences of homopurine and homopyrimidine strands were prepared. DNA triplexes were identified by CD spectroscopy and thermal denaturation profiles (biphasic helix-coil transition). Condensation of oligonucleotides on single and double-stranded DNA templates was performed using water-soluble carbodiimide, phosphodiester and pyrophosphate internucleotide bonds being newly formed. Such chemical ligation proved to be a sensitive monitor of changes in the sugar-phosphate backbone resulting from conversion of double to triple helix and of third-strand binding.

Mung bean nuclease cleavage pattern at a polypurine.polypyrimidine sequence upstream from the mouse metallothionein-I gene

Mung bean nuclease, an enzyme specific for single-stranded DNA, was used to probe a non-B DNA structure present in the mouse metallothionein-I gene. The region sensitive to the enzyme was constituted by a 128 base-pair long polypurine.polypyrimidine sequence located at 1.2-kb from the start of transcription. A detailed analysis of the mung bean nuclease cleavage pattern revealed that: (i) under conditions of supercoiling and low pH a triplex structure was formed, (ii) the triplex was flanked by a sequence with the potential of forming a Z-DNA structure, (iii) most of the enzymatic activity was localized at some of the junctions between double-stranded and triple-stranded DNA and at mismatches in the triplex, (iv) no unpaired bases were observed in the loop or outside the triplex, and (v) the triplex was present in more than one configuration.

Dynamics of mismatched base pairs in DNA

The structural dynamics of mismatched base pairs in duplex DNA have been studied by time-resolved fluorescence anisotropy decay measurements on a series of duplex oligodeoxynucleotides of the general type d[CGG(AP)GGC].d[GCCXCCG], where AP is the fluorescent adenine analogue 2-aminopurine and X = T, A, G, or C. The anisotropy decay is caused by internal rotations of AP within the duplex, which occur on the picosecond time scale, and by overall rotational diffusion of the duplex. The correlation time and angular range of internal rotation of AP vary among the series of AP.X mismatches, showing that the native DNA bases differ in their ability to influence the motion of AP. These differences are correlated with the strength of base-pairing interactions in the various AP.X mismatches. The interactions are strongest with X = T or C. The ability to discern differences in the strength of base-pairing interactions at a specific site in DNA by observing their effect on the dynamics of base motion is a novel aspect of the present study. The extent of AP stacking within the duplex is also determined in this study since it influences the excited-state quenching of AP. AP is thus shown to be extrahelical in the AP.G mismatch. The association state of the AP-containing oligodeoxynucleotide strand is determined from the temperature-dependent tumbling correlation time. An oligodeoxynucleotide triplex is formed with a particular base sequence in a pH-dependent manner.

Proton NMR and optical spectroscopic studies on the DNA triplex formed by d-A-(G-A)7-G and d-C-(T-C)7-T

Triplex and duplex formation of two deoxyribohexadecamers d-A-(G-A)-G (a) and d-C-(T-C)-T (b) have been studied by UV, CD, fluorescence, and proton NMR spectroscopy. Optical studies of a and b at dilute concentrations (microM range) yielded results similar to those seen for polymers of the same sequence, indicating that these hexadecamers have properties similar to the polymers in regard to triplex formation. The CD spectra of concentrated NMR samples (mM range) are similar to those observed at optical concentrations at both low and high pH, making possible a correlation between CD and NMR studies. In NMR spectra, two imido NH-N hydrogen bonded resonance envelopes at 12.6 and 13.7 ppm indicate that only the duplex conformation is present at pH greater than 7.7. Four new NH-N hydrogen-bonded resonance envelopes at 12.7, 13.5, 14.2, and 14.9 ppm are observed under acidic conditions (pH 5.6) and the two original NH-N resonances gradually disappear as the pH is lowered. Assignment of these four peaks to Watson-Crick G.C. Hoogsteen T.A Watson-Crick A.T, and Hoogsteen C+.G hydrogen-bonded imidos, respectively, confirm the formation of triple-stranded DNA NMR results also show that triplex is more stable than duplex at the same salt condition and that triplex melts to single strands directly without going through a duplex intermediate. However, in the melting studies, a structural change within the triple-stranded complex is evident at temperatures significantly below the major helix-to-coil transition. These studies demonstrate the feasibility of using NMR spectroscopy and oligonucleotide model compounds a and b for the study of DNA triplex formation.

Second structural motif for recognition of DNA by oligonucleotide-directed triple-helix formation

Relative orientations of the DNA strands within a purine.purine.pyrimidine triple helix have been determined by affinity cleaving. A purine-rich oligonucleotide bound in the major groove of double-helical DNA antiparallel to the Watson-Crick purine strand. Binding depended upon the concentration of multivalent cations such as spermine or Mg2+, and appeared to be relatively independent of pH. Two models with specific hydrogen-bonding patterns for base triplets (G.GC, A.AT, and T.AT) are proposed to explain the sequence specificity of binding. The two models differ in the conformation about the glycosyl bond (syn or anti) and the location of the phosphate-deoxyribose backbone in the major groove of DNA. This motif broadens the structural frameworks available as a basis for the design of sequence-specific DNA binding molecules.

Single-site enzymatic cleavage of yeast genomic DNA mediated by triple helix formation

Physical mapping of chromosomes would be facilitated by methods of breaking large DNA into manageable fragments, or cutting uniquely at genetic markers of interest. Key issues in the design of sequence-specific DNA cleaving reagents are the specificity of binding, the generalizability of the recognition motif, and the cleavage yield. Oligonucleotide-directed triple helix formation is a generalizable motif for specific binding to sequences longer than 12 base pairs within DNA of high complexity. Studies with plasmid DNA show that triple helix formation can limit the operational specificity of restriction enzymes to endonuclease recognition sequences that overlap oligonucleotide-binding sites. Triple helix formation, followed by methylase protection, triple helix-disruption, and restriction endonuclease digestion produces near quantitative cleavage at the single overlapping triple helix-endonuclease site. As a demonstration that this technique may be applicable to the orchestrated cleavage of large genomic DNA, we report the near quantitative single-site enzymatic cleavage of the Saccharomyces cerevisiae genome mediated by triple helix formation. The 340-kilobase yeast chromosome III was cut uniquely at an overlapping homopurine-EcoRI target site 27 base pairs long to produce two expected cleavage products of 110 and 230 kilobases. No cleavage of any other chromosome was detected. The potential generalizability of this technique, which is capable of near quantitative cleavage at a single site in at least 14 megabase pairs of DNA, could enable selected regions of chromosomal DNA to be isolated without extensive screening of genomic libraries.

Visualisation of a 2'-5' parallel stranded double helix at atomic resolution: crystal structure of cytidylyl-2',5'-adenosine

X-ray crystallographic studies on 3'-5' oligomers have provided a great deal of information on the stereochemistry and conformational flexibility of nucleic acids and polynucleotides. In contrast, there is very little information available on 2'-5' polynucleotides. We have now obtained the crystal structure of Cytidylyl-2',5'-Adenosine (C2'p5'A) at atomic resolution to establish the conformational differences between these two classes of polymers. The dinucleoside phosphate crystallises in the monoclinic space group C2, with a = 33.912(4)A, b = 16.824(4)A, c = 12.898(2)A and beta = 112.35(1) with two molecules in the asymmetric unit. Spectacularly, the two independent C2'p5'A molecules in the asymmetric unit form right handed miniature parallel stranded double helices with their respective crystallographic two fold (b axis) symmetry mates. Remarkably, the two mini duplexes are almost indistinguishable. The cytosines and adenines form self-pairs with three and two hydrogen bonds respectively. The conformation of the C and A residues about the glycosyl bond is anti same as in the 3'-5' analog but contrasts the anti and syn geometry of C and A residues in A2'p5'C. The furanose ring conformation is C3' endo, C2' endo mixed puckering as in the C3'p5'A-proflavine complex. A comparison of the backbone torsion angles with other 2'-5' dinucleoside structures reveals that the major deviations occur in the torsion angles about the C3'-C2' and C4'-C3' bonds. A right-handed 2'-5' parallel stranded double helix having eight base pairs per turn and 45 degrees turn angle between them has been constructed using this dinucleoside phosphate as repeat unit. A discussion on 2'-5' parallel stranded double helix and its relevance to biological systems is presented.

DNA triple-helix formation at physiologic pH and temperature

Oligonucleotides that form a triple helix with duplex DNA offer a novel way to site specifically regulate gene expression in vivo. Triple helices formed by homopyrimidine oligomers containing both cytosine and thymine are stabilized by acid pH and low temperature, and there is little information about triplex formation with these oligomers at both pH 7.5 and 37 degrees C. Therefore, we examined the effect of changing various conditions on triplex formation at pH 7.5. A 30-mer oligonucleotide (composed of T and 5-methyl C) at submicromolar concentrations formed a triplex with its target duplex at pH 7.5 and 37 degrees C. Association of the 30-mer oligomer with the duplex was slow, with complete association requiring about 1 h. At 37 degrees C, a 21-mer oligomer bound weakly to the target duplex but both a 25-mer and the 30-mer readily formed a triplex. This relationship of triplex formation with length was temperature dependent, as at 25 degrees C the 21-mer behaved similarly to the longer oligomers. Increasing spermine concentrations (from 0.2 to 1 mM) increased the amount of triplex formed. Spermine may be important only for the association of the oligomer to the duplex, since decreasing the spermine concentration after the triplex formed did not reduce the amount of triplex detected. At 1 mM spermine, formation of the triple-helical complex was very dependent on the concentration of KCl; increasing the KCl from 50 to 100 mM prevented triplex formation. However, the inhibitory effect of KCl could be abrogated by raising the spermine concentration to 2 mM. Our observations indicate that a triple helix can form under physiologic conditions but its formation is affected by several competing interactions.

Local supercoil-stabilized DNA structures

The DNA double helix exhibits local sequence-dependent polymorphism at the level of the single base pair and dinucleotide step. Curvature of the DNA molecule occurs in DNA regions with a specific type of nucleotide sequence periodicities. Negative supercoiling induces in vitro local nucleotide sequence-dependent DNA structures such as cruciforms, left-handed DNA, multistranded structures, etc. Techniques based on chemical probes have been proposed that make it possible to study DNA local structures in cells. Recent results suggest that the local DNA structures observed in vitro exist in the cell, but their occurrence and structural details are dependent on the DNA superhelical density in the cell and can be related to some cellular processes.

Paranemic structures of DNA and their role in DNA unwinding

A DNA structure is defined as paranemic if the participating strands can be separated without mutual rotation of the opposite strands. The experimental methods employed to detect paranemic, unwound, DNA regions is described, including probing by single-strand specific nucleases (SNN), conformation-specific chemical probes, topoisomer analysis, NMR, and other physical methods. The available evidence for the following paranemic structures is surveyed: single-stranded DNA, slippage structures, cruciforms, alternating B-Z regions, triplexes (H-DNA), paranemic duplexes and RNA, protein-stabilized paranemic DNA. The problem of DNA unwinding during gene copying processes is analyzed; the possibility that extended paranemic DNA regions are transiently formed during replication, transcription, and recombination is considered, and the evidence supporting the participation of paranemic DNA forms in genes committed to or undergoing copying processes is summarized.

Molecular Recognition by Circular Oligonucleotides. Strong Binding of Single-stranded DNA and RNA

Pyrimidine-rich circular DNA oligonucleotides 1 and 2 display very high binding affinities for complementary DNA and RNA oligomers by forming bimolecular triple helical complexes.

Thermodynamic characterization of the stability and the melting behavior of a DNA triplex: a spectroscopic and calorimetric study

We report a complete thermodynamic characterization of the stability and the melting behavior of an oligomeric DNA triplex. The triplex chosen for study forms by way of major-groove Hoogsteen association of an all-pyrimidine 15-mer single strand (termed y15) with a Watson-Crick 21-mer duplex composed of one purine-rich strand (termed u21) and one pyrimidine-rich strand (termed y21). We find that the near-UV CD spectrum of the triplex can be duplicated by the addition of the B-like CD spectrum of the isolated 21-mer duplex and the CD spectrum of the 15-mer single strand. Spectroscopic and calorimetric measurements show that the triplex (y15.u21.y21) melts by two well-resolved sequential transitions. The first transition (melting temperature, Tm, approximately 30 degrees C) is pH-dependent and involves the thermal expulsion of the 15-mer strand to form the free duplex u21.y21 and the free single strand y15. The second transition (Tm approximately 65 degrees C) is pH-independent between pH 6 and 7 and reflects the thermal disruption of the u21.y21 Watson-Crick duplex to form the component single strands. The thermal stability of the y15.u21.y21 triplex increases with increasing Na+ concentration but is nearly independent of DNA strand concentration. Differential scanning calorimetric measurements at pH 6.5 show the triplex to be enthalpically stabilized by only 2.0 +/- 0.1 kcal/mol of base triplets (1 cal = 4.184 J), whereas the duplex is stabilized by 6.3 +/- 0.3 kcal/mol of base pairs. From the calorimetric data, we calculate that at 25 degrees C the y15.u21.y21 triplex is stabilized by a free energy of only 1.3 +/- 0.1 kcal/mol relative to its component u21.y21 duplex and y15 single strand, whereas the 21-mer duplex is stabilized by a free energy of 17.2 +/- 1.2 kcal/mol relative to its component single strands. The y15 single strand modified by methylation of cytosine at the C-5 position forms a triplex with the u21.y21 duplex, which exhibits enhanced thermal stability. The spectroscopic and calorimetric data reported here provide a quantitative measure of the influence of salt, temperature, pH, strand concentration, and base modification on the stability and the melting behavior of a DNA triplex. Such information should prove useful in designing third-strand oligonucleotides and in defining solution conditions for the effective use of triplex structure formation as a tool for modulating biochemical events.

Polypurine/polypyrimidine hairpins form a triple helix structure at low pH

1D and 2D NMR investigations of the 15 residue deoxynucleotide sequence d(TCTCTC-TTT-GAGAGA) show that above pH = 6.5 the molecule adopts a B-form hairpin conformation. As the pH is lowered below 6.5 molecules progressively associate in pairs to form a partially triple helical, partially single stranded structure in which the bases of the oligopyrimidine d(TC)3 tract from one molecule form Hoogsteen pairs with the d(G-A)3 tract of the other. Imino protons of protonated cytosines can be observed at very low field (approximately 15 ppm). The enthalpy of triplex formation was estimated by NMR techniques to be -16 kcal mol-1. Intense H6 to H3' cross peaks from residues in all three strands suggest the presence of N-type sugars at some but not at all possible sites. Surprisingly strong cross peaks between H5' or H5" and non-exchangeable base protons are also observed. These suggest that certain of the O5'-C5'-C4'-C3' phosphate backbone torsion angles (gamma) are unusual.

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.

Kinetic analysis of oligodeoxyribonucleotide-directed triple-helix formation on DNA

Pyrimidine oligonucleotides recognize extended purine sequences in the major groove of double-helical DNA by triple-helix formation. The resulting local triple helices are relatively stable and can block DNA recognition by sequence-specific DNA binding proteins such as restriction endonucleases. Association and dissociation kinetics for the oligodeoxyribonucleotide 5'-CTCTTTCCTCTCTTTTTCCCC (bold C's indicate 5-methylcytosine residues) are now measured with a restriction endonuclease protection assay. When oligonucleotides are present in greater than 10-fold excess over the DNA target site, the binding reaction kinetics are pseudo first order in oligonucleotide concentration. Under our standard conditions (37 degrees C, 25 mM Tris-acetate, pH 6.8, 70 mM sodium chloride, 20 mM magnesium chloride, 0.4 mM spermine tetrahydrochloride, 10 mM beta-mercaptoethanol, 0.1 mg/mL bovine serum albumin) the value of the observed pseudo-first-order association rate constant, k2obs, is 1.8 x 10(3) +/- 1.9 x 10(2) L.(mol of oligomer-1.s-1. Measurement of the dissociation rate constant yields an equilibrium dissociation constant of approximately 10 nM. Increasing sodium ion concentration slightly decreased the association rate, substantially increased the dissociation rate, and thereby reduced the equilibrium binding constant. This effect was reversible by increasing multivalent cation concentration, confirming the significant role of multivalent cations in oligonucleotide-directed triple-helix formation under these conditions. Finally, a small reduction in association rate, a large increase in dissociation rate, and a resulting reduction in the equilibrium binding constant were observed upon increasing the pH between 6.8 and 7.2.

Thermal denaturation profiles and gel mobility shift analysis of oligodeoxynucleotide triplexes

Oligodeoxypurine- and oligodeoxypyrimidine-containing strands were mixed under conditions conducive to the formation of triple stranded assemblies. The mixtures were characterized both by their UV absorbance change with increasing temperature and by their mobility in non-denaturing polyacrylamide gels. Duplexes 34 bp long containing 15 central purines on one strand and 15 complementary pyrimidines on the other strand yielded new melting transitions and showed different gel mobilities upon combination with oligopyrimidine 15-mers. The dependence of the thermal denaturation profiles on pH, salt concentration, GC content, strand orientation, base mismatches, and strand length was investigated.

Determining local conformational variations in DNA. Nuclear magnetic resonance structures of the DNA duplexes d(CGCCTAATCG) and d(CGTCACGCGC) generated using back-calculation of the nuclear Overhauser effect spectra, a distance geometry algorithm and constrained molecular dynamics

Two-dimensional nuclear magnetic resonance (n.m.r.) spectroscopy and a variety of computational techniques have been used to generate three-dimensional structures of the two DNA duplexes d(CGCCTAATCG) and d(CGTCACGCGC). The central six base-pairs in these two decamers contain all ten dinucleotide pairs in DNA and thus, represent a model system for investigating how the local structure of DNA varies with base sequence. Resonance assignments were made for the non-exchangeable base protons and most of the C-1'-C-4' sugar protons in both decamers. Three-dimensional structures were generated using a distance geometry algorithm and these initial structures were refined by optimizing the fit of back-calculated spectra against the experimental two-dimensional nuclear Overhauser effect (NOE) spectra. This back-calculation procedure consists of calculating NOE cross relaxation rates for a given structure by solution of the Bloch equations, and directly accounts for spin diffusion effects. Use of this refinement procedure eliminates some assumptions that have been invoked when generating structures of DNA oligomers from n.m.r. data. Constrained energy minimization and constrained quenched molecular dynamics calculation were also performed on both decamers to help generate energetically favorable structures consistent with the experimental data. Analysis of the local conformational parameters of helical twist, helical rise, propeller twist, displacement and the alpha, beta, gamma, epison and zeta backbone torsion angles in these structures shows that these parameters span a large range of values relative to the X-ray data of nucleic acids. However, the glycosidic and pseudorotation angles are quite well defined in these structures. The implications that these results have for determination of local structural variations of DNA in solution, such as those predicted by Callidine's rules, are discussed. Our results differ significantly from some previous studies on determining local conformations of nucleic acids and comparisons with these studies are made.

Site-specific cleavage of a yeast chromosome by oligonucleotide-directed triple-helix formation

Oligonucleotides equipped with EDTA-Fe can bind specifically to duplex DNA by triple-helix formation and produce double-strand cleavage at binding sites greater than 12 base pairs in size. To demonstrate that oligonucleotide-directed triple-helix formation is a viable chemical approach for the site-specific cleavage of large genomic DNA, an oligonucleotide with EDTA-Fe at the 5' and 3' ends was targeted to a 20-base pair sequence in the 340-kilobase pair chromosome III of Saccharomyces cerevisiae. Double-strand cleavage products of the correct size and location were observed, indicating that the oligonucleotide bound and cleaved the target site among almost 14 megabase pairs of DNA. Because oligonucleotide-directed triple-helix formation has the potential to be a general solution for DNA recognition, this result has implications for physical mapping of chromosomes.

Formation of a stable triplex from a single DNA strand

Homopurine.homopyrimidine DNA sequences have been shown to form triple-stranded structures readily under appropriate conditions. Interest in DNA triplexes arises from potential applications of intermolecular triplexes as antisense inhibitors of gene expression and from the possibility that intramolecular triplexes may have a role in gene expression and recombination. We recently presented NMR evidence for triplex formation from the DNA oligonucleotides d(GA)4 and d(TC)4, which showed unambiguously that the second pyrimidine strand is Hoogsteen base paired and the cytosines are protonated at N3 as required. To obtain a more well defined triplex, and to provide a model for in vivo triplex structures, we have designed and synthesized a 28-base DNA oligomer with a sequence that could potentially fold to form a triplex containing both T.A.T and C+.G.C triplets. Our NMR results indicate that the conformation at pH 5.5 is an intramolecular triplex and that a significant amount of triplex remains even at pH 8.0.

Spectroscopic and calorimetric investigation on the DNA triplex formed by d(CTCTTCTTTCTTTTCTTTCTTCTC) and d(GAGAAGAAAGA) at acidic pH

The equimolar mixture of d(CTCTTCTTTCTTTTCTTTCTTCTC) (dY24) and d(GAGAAGAAAGA) (dR11) [designated (dY24).(dR11)], forms at pH = 5 a DNA triplex, which mimicks the H-DNA structure. The DNA triplex was identified by the following criteria: (i) dY24 and dR11 co-migrate in a poly-acrylamide gel, with a mobility and a retardation coefficient comparable to those observed for an 11-triad DNA triplex, previously characterized in our laboratories (1); (ii) the intercalator ethidium bromide shows a poor affinity for (dR11).(dY24) at pH = 5, and a high affinity at pH = 8; (iii) the (dR11).(dY24) mixture is not a substrate for DNase I at pH = 5; (iv) the CD spectrum of (dR11).(dY24), at pH = 5, is consistent with those previously reported for triple-stranded DNA. The (dR11).(dY24) mixture exhibits a thermally induced co-operative transition, which appears to be monophasic, reversible and concentration dependent. This transition is attributed to the disruption of the DNA triplex into single strands. The enthalpy change of the triplex-coil transition was measured by DSC (delta Hcal = 129 +/- 6 kcal/mol) and, assuming a two-state model, by analysis of UV-denaturation curves (average of two methods delta HUV = 137 +/- 13 kcal/mol). Subtracting from delta Hcal of triplex formation the contributions due to the Watson-Crick helix and to the protonation of the C-residues, we found that each pyrimidine binding into the major groove of the duplex, through a Hoogsteen base pair, is accompanied by an average delta H = -5.8 +/- 0.6 kcal/mol. The effect on the stability of the (dR11).(dY24) triplex due to the substitution of a T:A:T triad with a T:T:T one was also investigated.

Triple helix formation by oligopurine-oligopyrimidine DNA fragments. Electrophoretic and thermodynamic behavior

The 26mer oligodeoxynucleotide d(GAAGGAGGAGATTTTTCTCCTCCTTC) adopts in solution a unimolecular hairpin structure (h), with an oligopurine-oligopyrimidine (Pu-Py) stem. When h is mixed with d(CTTCCTCCTCT) (s1) the two strands co-migrate in polyacrylamide gel electrophoresis at pH 5. If s1 is substituted with d(TCTCCTCCTTC) (s2), such behavior is not observed and the two strands migrate separately. This supports the suggestion of the formation of a triple-stranded structure by h and s1 (h:s1) but not by h and s2, and confirms the strand polarity requirement of the third pyrimidine strand, which is necessary for this type of structure. The formation of a triple helix by h:s1 is supported by electrophoretic mobility data (Ferguson plot) and by enzymatic assay with DNase I. Circular dichroism measurements show that, upon triple helix formation, there are two negative ellipticities: a weaker one (delta epsilon = 80 M-1 cm-1) at 242 nm and a stronger one (delta epsilon = 210 M-1 cm-1) at 212 nm. The latter has been observed also in triple-stranded polynucleotides, and can be considered as the trademark for a Py:Pu:Py DNA triplex. Comparison of ultraviolet absorption at 270 nm and temperature measurements shows that the triple-stranded structure melts with a biphasic profile. The lower temperature transition is bimolecular and is attributable to the breakdown of the triplex to give h and s1, while the higher temperature transition is monomolecular and is due to the transition of hairpin to coil structure. The duplex-to-triplex transition is co-operative, fully reversible and with a hyperchromism of about 10%. The analysis of the melting curves, with a three-state model, allows estimation of the thermodynamic parameters of triple helix formation. We found that the duplex-to-triplex transition of h: s1 is accompanied by an average change in enthalpy (less the protonation contribution) of -73(+/- 5) kcal/mol of triplex, which corresponds to -6.6(+/- 0.4) kcal/mol of binding pyrimidine, attributable to stacking and hydrogen bonding interactions.

Structural analysis of the (dA)10.2(dT)10 triple helix

The existence of DNA triple helices in vitro has been known for some time. Recent evidence suggesting that DNA triplexes exist in vivo and showing their potential for chemotherapeutic applications has renewed interest in these triple-strand conformations. However, little structural information is currently known about these unusual nucleic acid forms. We have induced and stabilized triple-helical (dA)10.2(dT)10 with MgCl2 at neutral pH. UV mixing curves demonstrate a 1:2 (dA)10 to (dT)10 stoichiometry at suitable MgCl2 concentrations. Thermal denaturation profiles establish a melting mechanism characterized by the initial loss of the third strand, followed by dissociation of the remaining duplex. The circular dichroic spectrum of the triplex form is distinct from that of a duplex equimolar in (dA)10. NMR studies show that magnesium-induced triplex formation is accompanied by an upfield shift of several imino proton resonances present before stabilization of the triplex form with MgCl2 and the induction of new upfield imino proton resonances. Nuclear Overhauser effect spectroscopy measurements on both undeuterated and C8--H-deuterated (dA)10.2(dT)10 triplexes demonstrate dipolar contacts between resolvable imino proteins and both adenine C8--H and C2--H aromatic protons. Hence, MgCl2 stabilizes a triplex structure in which thymine N3--H imino protons are involved in both Watson-Crick and Hoogsteen base pairing.

Site-specific inhibition of EcoRI restriction/modification enzymes by a DNA triple helix

The ability of oligopyrimidines to inhibit, through triple helix formation, the specific protein-DNA interactions of the EcoRI restriction and modification enzymes (EcoRI and MEcoRI) with their recognition sequence (GAATTC) was studied. The oligonucleotides (CTT)4 and (CTT)8 formed triplexes in plasmids at (GAA)n repeats containing EcoRI sites. Cleavage and methylation of EcoRI sites within these sequences were specifically inhibited by the oligonucleotides, whereas an EcoRI site adjacent to a (GAA)n sequence was inhibited much less. Also, other EcoRI sites within the plasmid, or in exogenously added lambda DNA, were not inhibited. These results demonstrate the potential of using triplex-forming oligonucleotides to block protein-DNA interactions at specific sites, and thus this technique may be useful in chromosome mapping and in the modulation of gene expression.

Characterization of the high pH wobble structure of the 2-aminopurine.cytosine mismatch by N-15 NMR spectroscopy

Transition mutations induced by the base analogue 2-aminopurine arise via the formation of AP.C base pairs during DNA replication. We report here the results of N-15 NMR studies on a duplex oligonucleotide containing N-15 enriched AP and C residues. At high pH (8.6) the AP.C base pair is predominantly wobble. This is the first report on use of a site specifically N-15 enriched oligonucleotide as a probe of aberrant base pairing in DNA.

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.

Recognition of thymine adenine.base pairs by guanine in a pyrimidine triple helix motif

Oligonucleotide recognition offers a powerful chemical approach for the sequence-specific binding of double-helical DNA. In the pyrimidine-Hoogsteen model, a binding size of greater than 15 homopurine base pairs affords greater than 30 discrete sequence-specific hydrogen bonds to duplex DNA. Because pyrimidine oligonucleotides limit triple helix formation to homopurine tracts, it is desirable to determine whether oligonucleotides can be used to bind all four base pairs of DNA. A general solution would allow targeting of oligonucleotides (or their analogs) to any given sequence in the human genome. A study of 20 base triplets reveals that the triple helix can be extended from homopurine to mixed sequences. Guanine contained within a pyrimidine oligonucleotide specifically recognizes thymine.adenine base pairs in duplex DNA. Such specificity allows binding at mixed sites in DNA from simian virus 40 and human immunodeficiency virus.

Inhibition of DNA binding proteins by oligonucleotide-directed triple helix formation

Oligonucleotides that bind to duplex DNA in a sequence-specific manner by triple helix formation offer an approach to the experimental manipulation of sequence-specific protein binding. Micromolar concentrations of pyrimidine oligodeoxyribonucleotides are shown to block recognition of double helical DNA by prokaryotic modifying enzymes and a eukaryotic transcription factor at a homopurine target site. Inhibition is sequence-specific. Oligonucleotides containing 5-methylcytosine provide substantially more efficient inhibition than oligonucleotides containing cytosine. The results have implications for gene-specific repression by oligonucleotides or their analogs.