Evidence from CD spectra and melting temperatures for stable Hoogsteen-paired oligomer duplexes derived from DNA and hybrid triplexes.

The pyr*pur.pyr type of nucleic acid triplex has a purine strand that is Hoogsteen-paired with a parallel pyrimidine strand (pyr*pur pair) and that is Watson-Crick-paired with an antiparallel pyrimidine strand (pur.pyr pair). In most cases, the Watson-Crick pair is more stable than the Hoogsteen pair, although stable formation of DNA Hoogsteen-paired duplexes has been reported. Using oligomer triplexes of repeating d(AG)12 and d(CT)12 or r(CU)12 sequences that were 24 nt long, we found that hybrid RNA*DNA as well as DNA*DNA Hoogsteen-paired strands of triplexes can be more stable than the Watson-Crick-paired strands at low pH. The structures and relative stabilities of these duplexes and triplexes were evaluated by circular dichroism (CD) spectroscopy and UV absorption melting studies of triplexes as a function of pH. The CD contributions of Hoogsteen-paired RNA*DNA and DNA*DNA duplexes were found to dominate the CD spectra of the corresponding pyr*pur.pyr triplexes.     

Recognition of nucleic acid double helices by homopyrimidine 2', 5'-linked RNA.

We have studied the effect of a 2',5'-RNA third strand backbone on the stability of triple helices with a 'pyrimidine motif' targeting the polypurine strand of duplex DNA, duplex RNA and DNA/RNA hybrids. Comparative experiments were run in parallel with DNA and the regioisomeric RNA as third strands adopting the experimental design of Roberts and Crothers. The results reveal that 2',5'-RNA is indeed able to recognize double helical DNA (DD) and DNA (purine):RNA (pyrimidine) hybrids (DR). However, when the duplex purine strand is RNA and the duplex pyrimidine strand is DNA or RNA (i.e. RD or RR), triplex formation is not observed. These results exactly parallel what is observed for DNA third strands. Based on T m data, the affinities of 2',5'-RNA and DNA third strands towards DD and DR duplexes were similar. The RNA third strand formed triplexes with all four hairpins, as previously demonstrated. In analogy to the arabinose and 2'-deoxyribose third strands, the possible C2'- endo pucker of 2',5'-linked riboses together with the lack of an alpha-2'-OH group are believed to be responsible for the selective binding of 2',5'-RNA to DD and DR duplexes, over RR and RD duplexes. These studies indicate that the use of other oligonucleotide analogues will prove extremely useful in dissecting the contributions of backbone and/or sugar puckering to the recognition of nucleic acid duplexes.     

Stability of triple helices containing RNA and DNA strands: experimental and molecular modeling studies.

UV-absorption spectrophotometry and molecular modeling have been used to study the influence of the chemical nature of sugars (ribose or deoxyribose) on triple helix stability. For the Pyrimidine.purine* Pyrimidine motif, all eight combinations were tested with each of the three strands composed of either DNA or RNA. The chemical nature of sugars has a dramatic influence on triple helix stability. For each double helix composition, a more stable triple helix was formed when the third strand was RNA rather than DNA. No stable triple helix was detected when the polypurine sequence was made of RNA with a third strand made of DNA. Energy minimization studies using the JUMNA program suggested that interactions between the 2'-hydroxyl group of the third strand and the phosphates of the polypurine strand play an important role in determining the relative stabilities of triple-helical structures in which the polypyrimidine third strand is oriented parallel to the polypurine sequence. These interactions are not allowed when the third strand adopts an antiparallel orientation with respect to the target polypurine sequence, as observed when the third strand contains G and A or G and T/U. We show by footprinting and gel retardation experiments that an oligoribonucleotide containing G and A or G and U fails to bind double helical DNA, while the corresponding DNA oligomers form stable triple-helical complexes.     

Unique properties of purine/pyrimidine asymmetric PNA.DNA duplexes: differential stabilization of PNA.DNA duplexes by purines in the PNA strand

PNA.DNA duplexes are significantly stabilized by purine nucleobases in the PNA strand. To elucidate and understand the effect of switching the backbone in a nucleic acid duplex, we now report a thermodynamics study along with a solution conformations study of two purine/pyrimidine strand asymmetric duplexes and a strand symmetrical control by comparing the behavior of all four possible PNA/DNA combinations. In essence, we are comparing an identical basepair stack connected by either an aminoethyl glycine PNA or a deoxyribose DNA backbone. We show that the PNA.DNA duplexes containing purine-rich PNA strands are stabilized with regard to the thermal melting temperature and free energy as well as enthalpy (and concomitantly relatively less entropically disfavored). Based on our data, we find it unlikely that differences in counterion binding (identical ionic-strength dependence was observed), hydration (identical and insignificant water release was observed), or single-strand conformation can be responsible for the difference in duplex stability. The only consistent difference observed between the purine-rich PNA versus the pyrimidine-rich PNA in isosequential PNA.DNA duplexes is the significant increase in both binding enthalpy and entropy for the PNA.DNA duplexes containing pyrimidine-rich PNA in organic solvent, which would indicate that these duplexes are relatively enthalpically disfavored in water. Although our results so far do not allow us to identify the origin of the different stabilities of homopurine/homopyrimidine PNA.DNA duplexes, the evidence does point to a significant structural component, which involves enthalpic contributions both within the duplex structure and also from bound water molecules.     

DNA damage by thiol-activated neocarzinostatin chromophore at bulged sites

Bulge structures in nucleic acids are of general biological significance and are potential targets for therapeutic drugs. It has been shown in a previous study that thiol-activated neocarzinostatin chromophore is able to cleave duplex DNA selectively at a position opposite a single unpaired cytosine or thymine base on the 3' side. In this work, we studied in greater detail the nature of this type of cleavage and the basis for the selectivity of the bulge site cleavage over the usual strand cleavage at a T site in the duplex region by using duplexes containing an internal control and a bulge, which is composed of different types and number of bases. Experimental results indicated that the bulge-induced cleavage is initiated by 5' hydrogen abstraction and is greatly affected by the base composition of the bulge. A single-base bulge, especially when containing a purine, yields higher efficiency and greater selectivity for the bulge-induced cleavage. In particular, a single adenine base gives rise to the highest cleavage yield and provides over 20 times greater selectivity for cleavage at the bulge site compared with the internal control site in duplexes. The binding dissociation constants of postactivated drug for a stem-loop structure containing a one- or two-base bulge in the stem, measured by fluorescence quenching, show that the binding is about 3-4 times stronger for bulge-containing duplexes than for perfect hairpin duplexes. For RNA.DNA hybrid duplexes, where the DNA is the target strand and the RNA is the bulge-containing strand, bulge-induced cleavage was observed, although at low yield. On the other hand, when RNA is the nonbulge strand, no bulge-induced cleavage was found. When the reaction is performed in the absence of oxygen, the major product is a covalent adduct, and it is at the same location as the cleavage site under aerobic conditions.     

Spectroscopic studies on the interaction of aristololactam-beta-D-glucoside with DNA and RNA double and triple helices: A comparative study.

The interaction of aristololactam-beta-D-glucoside (ADG), a DNA intercalating alkaloid, with the DNA triplexes, poly(dT). poly(dA)xpoly(dT) and poly(dC).poly(dG)xpoly(dC+), and the RNA triplex poly(rU).poly(rA)xpoly(rU) was investigated by circular dichroic, UV melting profile, spectrophotometric, and spectrofluorimetric techniques. Comparative interaction with the corresponding Watson-Crick duplexes has also been examined under identical experimental conditions. Triplex formation has been confirmed from biphasic thermal melting profiles and analysis of temperature-dependent circular dichroic measurements. The binding of ADG to triplexes and duplexes is characterized by the typical hypochromic and bathochromic effects in the absorption spectrum, quenching of steady-state fluorescence intensity, a decrease in fluorescence quantum yield, an increase or decrease of thermal melting temperatures, and perturbation in the circular dichroic spectrum. Scatchard analysis indicates that ADG binds both to the triplexes and the duplexes in a noncooperative manner. Binding parameters obtained from spectrophotometric measurements are best fit by the neighbor exclusion model. The binding affinity of ADG to the DNA triplexes is substantially stronger than to the RNA triplex. Thermal melting study further indicates that ADG stabilizes the Hoogsteen base-paired third strand of the DNA triplexes whereas it destabilizes the same strand of RNA triplex but stabilizes its Watson-Crick strands. Comparative data reveal that ADG exhibits a stronger binding to the triple helical structures than to the respective double helical structures.     

Strong binding of single-stranded DNA by stem-loop oligonucleotides.

We report that oligodeoxynucleotides which form stem-loop hairpin structures and which have pyrimidine-rich loops can form strong complexes with complementary single-stranded DNA sequences. Stem-loop oligonucleotides were constructed with a 25-nt T-rich loop and with variable Watson-Crick stems. The complexes of these oligomers with the sequence dA8 were studied by thermal denaturation. Evidence is presented that the complexes are one-to-one, bimolecular complexes in which the pyrimidine loop bases comprise the outer strands in a pyr.pur.pyr triplex, in effect chelating the purine strand in the center of the loop. Melting temperatures for the loop complexes are shown to be up to 29 degrees C higher than Watson-Crick duplex of the same length. It is shown that the presence of a stem increases stability of the triplex relative to an analogous oligomer without a stem. The effect of stem length on the stability of such a complex is examined. Such hairpin oligomers represent a new approach to the sequence-specific binding of single-stranded RNA and DNA. In addition, the finding raises the possibility that such a complex may exist in natural RNA folded sequences.     

Insights into structure, dynamics and hydration of locked nucleic acid (LNA) strand-based duplexes from molecular dynamics simulations

Locked nucleic acid (LNA) is a chemically modified nucleic acid with its sugar ring locked in an RNA-like (C3′-endo) conformation. LNAs show extraordinary thermal stabilities when hybridized with DNA, RNA or LNA itself. We performed molecular dynamics simulations on five isosequential duplexes (LNA–DNA, LNA–LNA, LNA–RNA, RNA–DNA and RNA–RNA) in order to characterize their structure, dynamics and hydration. Structurally, the LNA–DNA and LNA–RNA duplexes are found to be similar to regular RNA–DNA and RNA–RNA duplexes, whereas the LNA–LNA duplex is found to have its helix partly unwound and does not resemble RNA–RNA duplex in a number of properties. Duplexes with an LNA strand have on average longer interstrand phosphate distances compared to RNA–DNA and RNA–RNA duplexes. Furthermore, intrastrand phosphate distances in LNA strands are found to be shorter than in DNA and slightly shorter than in RNA. In case of induced sugar puckering, LNA is found to tune the sugar puckers in partner DNA strand toward C3′-endo conformations more efficiently than RNA. The LNA–LNA duplex has lesser backbone flexibility compared to the RNA–RNA duplex. Finally, LNA is less hydrated compared to DNA or RNA but is found to have a well-organized water structure.     

Uranyl photofootprinting of triple helical DNA.

Two triple helix structures (15-mers containing only T.A-T triplets or containing mixed T.A-T and C.G-C triplets) have been studied by uranyl mediated DNA photocleavage to probe the accessibility of the phosphates of the DNA backbone. Whereas the phosphates of the pyrimidine strand are at least as accessible as in double stranded DNA, in the phosphates of the purine strand are partly shielded and more so at the 5'-end of the strand. With the homo A/T target increased cleavage is observed towards the 3'-end on the pyrimidine strand. These results show that the third strand is asymmetrically positioned along the groove with the tightest triple strand double strand interactions at the 5'-end of the third strand. The results also indicate that homo-A versus mixed A/G 'Hoogsteen-triple helices' have different structures.     

Backbone-base inclination as a fundamental determinant of nucleic acid self- and cross-pairing

The crystal structure of the duplex formed by oligo(2',3'-dideoxy-beta-d-glucopyranosyl)nucleotides (homo-DNA) revealed strongly inclined backbone and base-pair axes [Egli,M., Pallan,P.S., Pattanayek,R., Wilds,C.J., Lubini,P., Minasov,G., Dobler,M., Leumann,C.J. and Eschenmoser,A. (2006) Crystal structure of homo-DNA and nature's choice of pentose over hexose in the genetic system. J. Am. Chem. Soc., 128, 10847-10856]. This inclination is easily perceived because homo-DNA exhibits only a modest helical twist. Conversely, the tight coiling of strands conceals that the backbone-base inclinations for A- (DNA and RNA) and B-form (DNA) duplexes differ considerably. We have defined a parameter eta(B) that corresponds to the local inclination between sugar-phosphate backbone and base plane in nucleic acid strands. Here, we show its biological significance as a predictive measure for the relative strand polarities (antiparallel, aps, or parallel, ps) in duplexes of DNA, RNA and artificial nucleic acid pairing systems. The potential of formation of ps duplexes between complementary 16-mers with eight A and U(T) residues each was investigated with DNA, RNA, 2'-O-methylated RNA, homo-DNA and p-RNA, the ribopyranosyl isomer of RNA. The thermodynamic stabilities of the corresponding aps duplexes were also measured. As shown previously, DNA is capable of forming both ps and aps duplexes. However, all other tested systems are unable to form stable ps duplexes with reverse Watson-Crick (rWC) base pairs. This observation illustrates the handicap encountered by nucleic acid systems with inclinations eta(B) that differ significantly from 0 degrees to form a ps rWC paired duplex. Accordingly, RNA with a backbone-base inclination of -30 degrees , pairs strictly in an aps fashion. On the other hand, the more or less perpendicular orientation of backbone and bases in DNA allows it to adopt a ps rWC paired duplex. In addition to providing a rationalization of relative strand polarity with nucleic acids, the backbone-base inclination parameter is also a determinant of cross-pairing. Thus, systems with strongly deviating eta(B) angles will not pair with each other. Nucleic acid pairing systems with significant backbone-base inclinations can also be expected to display different stabilities depending on which terminus carries unpaired nucleotides. The negative inclination of RNA is consistent with the higher stability of duplexes with 3'- compared to those with 5'-dangling ends.     

Strong Binding of Single-stranded DNA by Stem-loop Oligonucleotides

Abstract

We report that oligodeoxynucleotides which form stem-loop hairpin structures and which have pyrimidine-rich loops can form strong complexes with complementary single-stranded DNA sequences. Stem-loop oligonucleotides were constructed with a 25-nt T-rich loop and with variable Watson-Crick stems. The complexes of these oligomers with the sequence dA_gwere studied by thermal denaturation. Evidence is presented that the complexes are one-to-one, bimolecular complexes in which the pyrimidine loop bases comprise the outer strands in a pyr · pur · pyr triplex, in effect chelating the purine strand in the center of the loop. Melting temperatures for the loop complexes are shown to be up to 29 °C higher than Watson- Crick duplex of the same length. It is shown that the presence of a stem increases stability of the triplex relative to an analogous oligomer without a stem. The effect of stem length on the stability of such a complex is examined. Such hairpin oligomers represent a new approach to the sequence-specific binding of single-stranded RNA and DNA. In addition, the finding raises the possibility that such a complex may exist in natural RNA folded sequences.     

Sequence dependent effects in methylphosphonate deoxyribonucleotide double and triple helical complexes.

Deoxyribooligonucleotides containing 19 repeating bases of A, T or U were prepared with normal phosphodiester (dA19, dT19, dU19) or methylphosphonate (dA*19, dT*19, dU*19) linkages. Complexes of these strands have been investigated at 1:1 and 1:2 molar ratios (purine:pyrimidine) by thermal melting and gel electrophoresis. There are dramatic sequence dependent differences in stabilities of complexes containing methylphosphonate strands. Duplexes of dA*19 with dT19 or dU19 have sharp melting curves, increased Tm values, and slopes of Tm versus log (sodium ion activity) plots reduced by about one half relative to their unmodified 'parent' duplexes. Duplexes of dA19 with either dT*19 or dU*19, however, have broader melting curves, reduced Tm values at most salt concentrations and slopes of less than one tenth the values for the unmodified duplexes. Duplex stabilization due to reduced phosphate charge repulsion is offset in the pyrimidine methylphosphonate complexes by steric and other substituent effects. Triple helical complexes with dA19 + 2dT19 and dA19 + 2dU19, which can be detected by biphasic melting curves and gel electrophoresis, are stable at increased Na+ or Mg+2 concentrations. Surprisingly, however, no triple helix forms, even at very high salt concentrations, when any normal strand(s) is replaced by a methylphosphonate strand. Since triple helical complexes with methylphosphonates have been reported for shorter oligomers, inhibition with larger oligomers may vary due to their length and extent of substitution.     

Radioprobing of DNA: distribution of DNA breaks produced by decay of 125I incorporated into a triplex-forming oligonucleotide correlates with geometry of the triplex.

The distribution of breaks produced in both strands of a DNA duplex by the decay of 125I carried by a triplex-forming DNA oligonucleotide was studied at single nucleotide resolution. The 125I atom was located in the C5 position of a single cytosine residue of an oligonucleotide designed to form a triple helix with the target sequence duplex. The majority of the breaks (90%) are located within 10 bp around the decay site. The addition of the free radical scavenger DMSO produces an insignificant effect on the yield and distribution of the breaks. These results suggest that the majority of these breaks are produced by the direct action of radiation and are not mediated by diffusible free radicals. The frequency of breaks in the purine strand was two times higher that in the pyrimidine strand. This asymmetry in the yield of breaks correlates with the geometry of this type of triplex; the C5 of the cytosine in the third strand is closer to the sugar-phosphate backbone of the purine strand. Moreover, study of molecular models shows that the yield of breaks at individual bases correlates with distance from the 125I decay site. We suggest the possible use of 125I decay as a probe for the structure of nucleic acids and nucleoprotein complexes.     

Oligonucleotides with conjugated dihydropyrroloindole tripeptides: base composition and backbone effects on hybridization.

The ability of conjugated minor groove binding (MGB) residues to stabilize nucleic acid duplexes was investigated by synthesis of oligonucleotides bearing a tethered dihydropyrroloindole tripeptide (CDPI3). Duplexes bearing one or more of these conjugated MGBs were varied by base composition (AT- or GC-rich oligonucleotides), backbone modifications (phosphodiester DNA, 2'-O-methyl phosphodiester RNA or phosphorothioate DNA) and site of attachment of the MGB moiety (5'- or 3'-end of either duplex strand). Melting temperatures of the duplexes were determined. The conjugated CDPI3 residue enhanced the stability of virtually all duplexes studied. The extent of stabilization was backbone and sequence dependent and reached a maximum value of 40-49 degrees C for d(pT)8. d(pA)8. Duplexes with a phosphorothioate DNA backbone responded similarly on CDPI3 conjugation, although they were less stable than analogous phosphodiesters. Modest stabilization was obtained for duplexes with a 2'-O-methyl RNA backbone. The conjugated CDPI3 residue stabilized GC-rich DNA duplexes, albeit to a lesser extent than for AT-rich duplexes of the same length.     

Pyrimidine motif triplexes containing polypurine RNA or DNA with oligo 2'-O-methyl or DNA triplex forming oligonucleotides

Triplex forming oligonucleotides (TFOs) are potentially useful in targeting RNA for antisense therapeutic applications. To determine the feasibility of targeting polypurine RNA with nuclease-resistant oligonucleotides, TFOs containing 2'-deoxy or 2'-O-methyl (2'-OMe) backbones, designed to form pyrimidine motif triplexes with RNA, were synthesized. TFOs were made which can form trimolecular triplexes, or bimolecular, 'clamp' triplexes with polypurine RNA and DNA. It was found that the relative stabilities of the triplexes formed followed the order: M.DM(clamp)>D.DD approximately M.DD>M. RM>D.DM>M.RD approximately M.DM, where M is a 2'-OMe, D is a DNA and R is an RNA backbone. The third strand is listed first, separated by a dot from the purine strand of the Watson-Crick duplex, followed by the pyrimidine strand of the duplex. The results described here provide insight into the feasibility of using TFOs containing a 2'-OMe backbone as antisense agents.     

Circular RNA oligonucleotides. Synthesis, nucleic acid binding properties, and a comparison with circular DNAs.

We report the synthesis and nucleic acid binding properties of two cyclic RNA oligonucleotides designed to bind single-stranded nucleic acids by pyr.pur.pyr-type triple helix formation. The circular RNAs are 34 nucleotides in size and were cyclized using a template-directed nonenzymatic ligation. To ensure isomeric 3'-5' purity in the ligation reaction, one nucleotide at the ligation site is a 2'-deoxyribose. One circle (1) is complementary to the sequence 5'-A12, and the second (2) is complementary to 5'-AAGAAAGAAAAG. Results of thermal denaturation experiments and mixing studies show that both circles bind complementary single-stranded DNA or RNA substrates by triple helix formation, in which two domains in a pyrimidine-rich circle sandwich a central purine-rich substrate. The affinities of these circles with their purine complements are much higher than the affinities of either the linear precursors or simple Watson-Crick DNA complements. For example, circle 1 binds rA12 (pH 7.0, 10 mM MgCl2, 100 mM NaCl) with a Tm of 48 degrees C and a Kd (37 degrees C) of 4.1 x 10(-9) M, while the linear precursor of the circle binds with a Tm of 34 degrees C and a Kd of 1.2 x 10(-6) M. The complexes of circle 2 are pH-dependent, as expected for triple helical complexes involving C(+)G.C triads, and mixing plots for both circles reveal one-to-one stoichiometry of binding either to RNA or DNA substrates. Comparison of circular RNAs with previously synthesized circular DNA oligonucleotides of the same sequence reveals similar behavior in the binding of DNA, but strikingly different behavior in the binding of RNA. The cyclic DNAs show high DNA-binding selectivity, giving relatively weaker duplex-type binding with complementary RNAs. The relative order of thermodynamic stability for the four types of triplex studied here is found to be DDD >> RRR > RDR >> DRD. The results are discussed in the context of recent reports of strong triplex dependence on RNA versus DNA backbones. Triplex-forming circular RNAs represent a novel and potentially useful strategy for high-affinity binding of RNA.     

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).     

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.     

Different conformational families of pyrimidine.purine.pyrimidine triple helices depending on backbone composition.

Different helical conformations of DNA (D), RNA (R), and DNA.RNA (DR) hybrid double and triple helices have been detected using affinity cleavage analysis. Synthetic methods were developed to attach EDTA.Fe to a single nucleotide on RNA as well as DNA oligonucleotides. Cleavage patterns generated by a localized diffusible oxidant in the major groove on the pyrimidine strand of four purine.pyrimidine double helices consisting of all DNA, all RNA, and the corresponding hybrids reveal that the relative cleavage intensity shifts to the 5' end of the purine strand increasingly in the order: DD < DR < RD < RR. These results are consistent with models derived from structural studies. In six pyrimidine.purine.pyrimidine triple helices, the altered cleavage patterns of the Watson-Crick pyrimidine strands reveal at least two conformational families: (i) D + DD, R + DD, D + DR, and R + DR and (ii) R + RD and R + RR.