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.     

Sequence dependence of the B to Z transition in crystals and aqueous NaCl solutions for deoxyoligonucleotides containing all four canonical DNA bases

A laser Raman study has been made on the conformation of a series of self-complementary octameric deoxynucleotides that contain all four canonical deoxynucleotide bases [guanine (G), cytosine (C), adenine (A), and thymine (T)] in order to determine which sequences will crystallize in the Z form and which sequences will go into the Z form in aqueous solution at high salt concentrations (4-6 M NaCl). All four octadeoxynucleotides, d(TGCGCGCA) (I), d(CACGCGTG) (II), d(CGTGCACG) (III), and d(CGCATGCG) (IV), have been crystallized from low-salt solutions. The Raman spectra of microcrystals show that I, II, and IV crystallize in a rigorous Z form while III crystallizes in the B form. Sequences I and II go into a Z form in 4-6 M NaCl solution at 0 degrees C while sequences III and IV remain in the B form in 6 M salt. There are substantial differences in the Raman spectra of oligonucleotides in the Z form found in the crystal and in high-salt solutions. The Raman spectra of the Z forms in 6 M NaCl solution at 0 degrees C are not linear combinations of the Raman spectra of the complete Z form in the crystal and the complete B form in low-salt solutions. The terminal residues of these oligomers do not appear to be in a strict Z form. A detailed analysis of the ring puckers and syn/anti conformation for all of the residues both in solution and in the crystal has been made.(ABSTRACT TRUNCATED AT 250 WORDS)     

Triplex formation by a psoralen-conjugated oligodeoxyribonucleotide containing the base analog 8-oxo-adenine.

Oligodeoxyribonucleotides containing thymidine and 8-oxo-2'-deoxyadenosine can form pyr.pur.pyr type triplexes with double-stranded DNA. Unlike triplexes whose third strands contain thymidine and deoxycytidine, the stability of these triplexes is independent of pH. We have prepared d-ps-TAAATAAATTTTTAT-L [I(A)], where A is 8-oxo-2'-deoxyadenosine, ps is 4'-hydroxymethyl-4,5',8- trimethylpsoralen and L is a 6-amino-2-(hydroxymethyl)hexyl linker. The oligomer is designed to interact with a homopurine sequence in the promoter region of the human gene coding for the 92 kDa form of collagenase type IV. Oligomer I(A) and oligomer I(C), which contains 2'-deoxycytidine in place of 8-oxo-2'-deoxycytidine, both form stable triplexes at pH 6.2, but only I(A) forms a stable triplex with a model duplex DNA target at pH 7.5, as determined by UV melting experiments. Triplex formation is stabilized by the presence of the psoralen group. Upon irradiation both I(A) and I(C) form photoadducts with the DNA target at pH 6.2, but only I(A) forms a photoadduct at pH 7.5. In these photoreactions oligomer I(A) appears to selectively form a photoadduct with a C in the purine-rich strand of the duplex target. Although a T residue is present in the pyrimidine-rich strand of the target at the duplex/triplex junction, essentially no adduct formation takes place with this strand, nor is interstrand cross-linking observed. The extent of photoadduct formation decreases with increasing temperature, behavior which is consistent with the UV melting curve of the triplex. A tetramethylrhodamine derivative of I(A) was prepared and found to cross-link less extensively than I(A) itself. Oligomer I(A) is completely resistant to hydrolysis when incubated for 24h in the presence of 10% fetal bovine serum at 37 degree C, although it is hydrolyzed by S1 nuclease. The properties of oligomer I(A) suggest that 8-oxo- containing oligomers may find utility as antigene oligonucleotide reagents.     

1,8-Naphthyridin-2,7-(1,8H)-dione is an effective mimic of protonated cytosine in peptide nucleic acid triplex recognition systems

A novel bicyclic mimic of protonated cytosine [1,8-naphthyridin-2,7-(1,8H)-dione, (K)] for Hoogsteen type triplex recognition of guanine has been designed for incorporation into peptide nucleic acids. Bis-PNA clamps with the K base incorporated in the Hoogsteen strand showed a significant stabilization of the triplexes at pH 7 as compared to similar triplexes with PNA oligomers containing either cytosine (6.7 degrees C per unit) or pseudoisocytosine (1.5 degrees C per unit). Cooperative stabilization was observed when the K units were placed in adjacent positions ( approximately 3 degrees C per unit).     

FTIR and UV spectroscopy studies of triplex formation between alpha-oligonucleotides with non-ionic phoshoramidate linkages and DNA targets

The triplexes formed by pyrimidine alpha-oligodeoxynucleotides, 15mers alpha dT(15) or 12mers alpha dCT having dimethoxyethyl (PNHdiME), morpholino (PMOR) or propyl (PNHPr) non-ionic phosphoramidate linkages with DNA duplex targets have been investigated by UV and FTIR spectroscopy. Due to the decrease in the electrostatic repulsion between partner strands of identical lengths all modifications result in triplexes more stable than those formed with unmodified phosphodiester beta-oligodeoxynucleotides (beta-ODNs). Among the alpha-ODN third strands having C and T bases and non-ionic phosphoramidate linkages (alpha dCTPN) the most efficient modification is (PNHdiME). The enhanced third strand stability of the alpha dCTPN obtained as diastereoisomeric mixtures is attenuated by the steric hindrance of the PMOR linkages or by the hydrophobicity of the PNHPr linkages. All alpha dCTPN strands form triplexes even at neutral pH. In the most favorable case (PNHdiME), we show by FTIR spectroscopy that the triplex formed at pH 7 is held by Hoogsteen T*A.T triplets and in addition by an hydrogen bond between O6 of G and C of the third strand (Tm = 30 degrees C). The detection of protonated cytosines is correlated at pH 6 with a high stabilization of the triplex (Tm = 65 degrees C). While unfavorable steric effects are overcome with alpha anomers, the limitation of the pH dependence is not completely suppressed. Different triplexes are evidenced for non pH dependent phosphoramidate alpha-thymidilate strands (alpha dT(15)PN) interacting with a target duplex of identical length. At low ionic strength and DNA concentration we observe the binding to beta dA(15) either of alpha dT(15)PN as duplex strand and beta dT(15) as third strand, or of two hydrophobic alpha dT(15)PNHPr strands. An increase in the DNA and counterion concentration stabilizes the anionic target duplex and then the alpha dT(15)PN binds as Hoogsteen third strand.     

Influence of 5-bromodeoxycytosine substitution on triplex DNA stability and conformation

Three triple-helical hairpin DNAs with substitution of 5-bromocytosine for cytosine in different strands have been investigated by molecular mechanics and Raman spectroscopy. The stability of the three substituted triplexes were compared with the corresponding unsubstituted triplex DNA by the molecular mechanics method. Base stacking interactions and strand--strand interactions of each triplex were analyzed in detail. Sugar conformations in these triplexes have been determined by both vibrational spectroscopy and molecular dynamics simulation. The hairpin triplexes with substitution occurring in strand I or both in strands I and III have the main sugar conformation of C3'-endo, while the triplex with substitution occurring in strand III is the combination of C3'-endo and C2'-endo sugar conformation. Theoretical results are basically in agreement with experiments.     

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

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

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.     

DNA triplex formation of oligonucleotide analogues consisting of linker groups and octamer segments that have opposite sugar-phosphate backbone polarities

The DNA oligomer analogues 3'd(CTTTCTTT)5'-P4-5'd(TTCTTCTT)3' (IV), 5'd-(TTTCTTTC)3'-P2-3'd(CTTTCTTT)5' (V), and 5'd(TTTCTTTC)3'-P2-3'd(CTTTCTTT)5'-P4-5'd-(TTCTTCTT)3' (VI) (P2 = P*P and P4 = P*P*P*P, where P = phosphate and * = 1,3-propanediol) have been synthesized. These oligomers consist of a linker group or groups and homopyrimidine oligonucleotides which have opposite sugar-phosphate backbone polarities. These oligomer analogues are designed to form triplexes with a duplex, 5'd(AAAGAAAGCCCTTTCTTTAAGAAGAA)3'.5'd(TTCTTCTTAAA- GAAAGGGCTTTCTTT)3' (I), which contains small homopurine clusters alternately located in both strands. The length of the linker groups, P2 and P4, was based upon a computer modeling analysis. Triplex formation by the unlinked octamers 5'd(TTCTTCTT)3' (II) and 5'd(TTTCTTTC)3' (III) and the linked oligomer analogues IV-VI with the target duplex was studied by thermal denaturation at pH 5.2. The order of stabilities of triplex formation by these oligomers was I-V much much greater than I-IV greater than I-(II, III). The mixture of I and VI showed two transitions corresponding to the dissociation of the third strand. The higher transition corresponded to the dissociation of 3'-3'-linked octamer segments, and the lower one corresponded to the dissociation of 5'-5'-linked octamer segments. The Tm of the latter transition was higher than that of the I-IV triplex; thus the triplex formed by the 5'-5'-linked octamer segment was stabilized by the triplex formed by the 3'-3'-linked octamer segments in the I-VI triplex. Triplex formation of this system was also studied in the presence of ethidium bromide.(ABSTRACT TRUNCATED AT 250 WORDS)     

FTIR and UV spectroscopy studies of triplex formation between pyrimidine methoxyethylphosphoramidates alpha-oligodeoxynucleotides and ds DNA targets

The ability of non-ionic methoxyethylphosphoramidate (PNHME) alpha-oligodeoxynucleotides (ODNs), alpha dT(15) and alpha dCT dodecamer, to form triplexes with their double-stranded DNA targets was evaluated. Thermal stability of the formed complexes was studied by UV thermal denaturation and the data showed that these PNHME alpha-ODNs formed much more stable triplexes than phosphodiester (PO) beta-ODNs did (Delta Tm = + 20 degrees C for alpha dCT PNHME). In addition, FTIR spectroscopy was used to determine the base pairing and the strand orientations of the triplexes formed by alpha dT(15) PNHME compared to phosphodiester ODNs with beta or alpha anomeric configuration. While beta dT(15) PO failed to form a triplex with a long beta dA(n) x beta dT(n) duplex, the Tm of the Hoogsteen part of the triplex formed by alpha dT(15) PNHME reached 40 degrees C. Moreover alpha dT(15) PNHME displaced the beta dT(15) strand of a shorter beta dA(15) x beta dT(15) duplex. The alpha dCT PNHME and alpha dT(15) PNHME third strands were found antiparallel in contrast to alpha dT(15) PO which is parallel to the purine strand of their duplex target. The uniform preferential Hoogsteen pairing of the nucleotides alpha dT and alpha dC combining both replacements might contribute to the improve stability of the triplexes.     

Intramolecular DNA triplexes in supercoiled plasmids. II. Effect of base composition and noncentral interruptions on formation and stability

The effects of interruptions in the homopurine bias and the G+C content of the homopurine.homopyrimidine (pur.pyr) sequences on intramolecular triplex formation and stability in supercoiled plasmids were evaluated. In addition, the interconversion of triplex and duplex, after altering the stabilizing factors (low pH or supercoiling), was studied. We conclude: (a) a 42-base pair pur.pyr sequence with three consecutive interruptions does not form a large triplex with three unpaired nucleotides in the stem. Instead, a mixture of two smaller (27- and 28-nucleotide) triplexes forms. (b) A 28-nucleotide sequence with a single interruption forms a triplex with one unpaired nucleotide in the stem. This interruption causes the triplex to be 7 degrees C less thermostable and requires more superhelical energy for formation than the control triplex. (c) As the G+C content of a pur.pyr sequence increases, the thermostability of the triplex increases and the triplex requires less supercoiling for formation. (d) The interconversion between duplex and triplex is fast. After negative supercoiling is removed, all triplex becomes duplex in about 3 min. When the pH is shifted from 8.0 to 5.2, the conversion of duplex to triplex in a negatively supercoiled plasmid is complete in less than 2 min. Hence, these kinetic properties are consistent with important biological roles for triplexes. In summary, the results from both this and the accompanying paper show that a substantial amount of sequence imperfections is tolerated for triplex formation and stability.     

Site-resolved energetics in DNA triple helices containing G*TA and T*CG triads

Recognition of specific sites in double-helical DNA by triplex-forming oligonucleotides has been limited until recently to sites containing homopurine-homopyrimidine sequences. G*TA and T*CG triads, in which TA and CG base pairs are specifically recognized by guanine or by thymine, have now extended this recognition code to DNA target sites of mixed base sequences. In the present work, we have obtained a characterization of the stabilities of G*TA and T*CG triads, and of the effects of these triads upon canonical triads, in triple-helical DNA. The three DNA triplexes investigated are formed by the folding of the 31-mers d(GAAXAGGT(5)CCTYTTCT(5)CTTZTCC) with X = G, T, or C, Y = C, A, or G, and Z = C, G, or T. We have measured the exchange rates of imino protons in each triad of the three triplexes using nuclear magnetic resonance spectroscopy. The exchange rates are used to map the local free energy of structural stabilization in each triplex. The results indicate that the stability of Watson-Crick base pairs in the G*TA and T*CG triads is comparable to that of Watson-Crick base pairs in canonical triads. The presence of G*TA and T*CG triads, however, destabilizes neighboring canonical triads, two or three positions removed from the G*TA/T*CG site. Moreover, the long-range destabilizing effects induced by the T*CG triad are larger than those induced by the G*TA triad. These findings reveal the molecular basis for the lower overall stability of G*TA- and T*CG-containing triplexes.     

Effect of divalent cations and cytosine protonation on thermodynamic properties of intermolecular DNA double and triple helices

The contribution of divalent cations and cytosine protonation to conformation and stability of duplex and triplex formation were intensively investigated and characterized by ultraviolet (UV), circular dichroism (CD), differential scanning calorimetry (DSC), and electrophoresis mobility shift assay (EMSA). CD spectra showed that the divalent cations investigated would not significantly distort nucleotide geometry, while UV and DSC melting experiments revealed that the cation binding abilities to duplexes and triplexes were clearly dependent on the types of cations under near physiological conditions. The calorimetric enthalpies were generally underestimated relative to the corresponding van't Hoff enthalpies for Hoogsteen and Watson-Crick transitions, but free energy changes derived from the DSC measurements were in good agreement with those derived from the UV measurements. The adjacent placing of the C(+) x G.C triplets in triplexes lowered the stabilities of not only Hoogsteen base-pairing but also Watson-Crick base-pairing. The protonation contribution of the given cytosine residues might depend on the local and global structure of the protonated cytosine complex. A rigid structural targeted-strand would favor the protonation of cytosine residues. The apparent pK(a) values for parallel duplex and triplex investigated were determined to be 6.4 and 7.6, respectively, which are considerably heightened by 2.1 and 3.3 pH unit as compared to the intrinsic pK(a) value of the free cytosine residues.     

Triplex formation at physiological pH by 5-Me-dC-N4-(spermine) [X] oligodeoxynucleotides: non protonation of N3 in X of X*G:C triad and effect of base mismatch/ionic strength on triplex stabilities.

Oligodeoxynucleotide (ODN) directed triplex formation has therapeutic importance and depends on Hoogsteen hydrogen bonds between a duplex DNA and a third DNA strand. T*A:T triplets are formed at neutral pH and C+*G:C are favoured at acidic pH. It is demonstrated that spermine conjugation at N4 of 5-Me-dC in ODNs 1-5 (sp-ODNs) imparts zwitterionic character, thus reducing the net negative charge of ODNs 1-5. sp-ODNs form triplexes with complementary 24mer duplex 8:9 show foremost stability at neutral pH 7.3 and decrease in stability towards lower pH, unlike the normal ODNs where optimal stability is found at an acidic pH 5.5. At pH 7.3, control ODNs 6 and 7 carrying dC or 5-Me-dC, respectively, do not show any triple helix formation. The stability order of triplex containing 5-Me-dC-N4-(spermine) with normal and mismatched duplex was found to be X*G:C approximately X*A:T > X*C:G > X*T:A. The hysteresis curve of sp-ODN triplex 3*8:9 indicated a better association with complementary duplex 8:9 as compared to unmodified ODN 6 in triplex 6*8:9. pH-dependent UV difference spectra suggest that N3 protonation is not a requirement for triplex formation by sp-ODN and interstrand interaction of conjugated spermine more than compensates for loss in stability due to absence of a single Hoogsteen hydrogen bond. These results may have importance in designing oligonucleotides for antigene applications.     

Intramolecular DNA triplexes in supercoiled plasmids. I. Effect of loop size on formation and stability

The capacity of four oligopurine.oligopyrimidine (pur.pyr) sequences with different lengths of interruptions in the center [GAA)4(N)n(GAA)4G) (n = 3, 5, 7, and 9) to adopt intramolecular DNA triplexes was evaluated in recombinant plasmids. The hyperreactive patterns of the pur.pyr inserts to specific chemical probes (OsO4, diethyl pyrocarbonate, and dimethyl sulfate) at the base pair level demonstrate that intramolecular triplexes with identical 12-base triads in the stem but with different loop sizes (4, 6, 8, and 10 bases) can form in supercoiled plasmids. Furthermore, the extent of OsO4 modification was measured as a function of temperature and of average negative supercoil density. In addition, the transition free energy of B-DNA to triplexes at pH 4.5 was determined by two-dimensional electrophoresis. These comparative studies show that longer loops require more supercoil energy for triplex formation and are less thermostable than triplexes with shorter loops. Also, it may be that not only the loop size but the base composition of the loop region affects the structural transition and triplex stability. Thus, these results significantly broaden the range of natural pur.pyr sequences that may adopt triplexes.     

5-(1-propargylamino)-2'-deoxyuridine (UP): a novel thymidine analogue for generating DNA triplexes with increased stability

We have used quantitative DNase I footprinting and UV-melting studies to examine the formation of DNA triplexes in which the third strand thymines have been replaced by 5-propargylamino-dU (UP). The intra-molecular triplex A6-L-T6-L-(UP)5T (L = two octanediol residues) shows a single UV-melting transition which is >20 degrees higher than that of the parent triplex A6-L-T6-L-T6at pH 5.5. Although a single transition is observed at all pHs, the melting temperature (Tm) of the modified oligonucleotide decreases at higher pHs, consistent with the requirement for protonation of the amino group. A similar intramolecular triplex with a longer overhanging duplex shows two melting transitions, the lower of which is stabilised by substitution of T by UP, in a pH dependent fashion. Triplex stability increases by approximately 12 K for each T to UP substitution. Quantitative footprinting studies have examined the interaction of three UP-containing 9mer oligonucleotides with the different portions of the 17mer sequence 5'-AGGAAGAGAAAAAAGAA. At pH 5.0, the UP-containing oligo-nucleotides footprint to much lower concentrations than their T-containing counterparts. In particular (UP)6CUPT binds approximately 1000-fold more tightly than the unmodified oligonucleotide T6CTT. Oligonucleotides containing fewer UP residues are stabilised to a lesser extent. The affinity of these modified third strands decreases at higher pHs. These results demonstrate that the stability of DNA triplexes can be dramatically increased by using positively charged analogues of thymine.     

Sequence dependent conformations of oligomeric DNA's in aqueous solutions and in crystals

In order to determine the sequence dependence of the conformation of deoxynucleotides, Raman spectra have been obtained for the following oligodeoxynucleotides in aqueous salt solutions and in crystals: d(CpG)(I), d(TGCGCGCA)(II), d(CACGCGTG)(III), d(CGTGCACG)(IV), d(CGCATGCG)(V), d(ACGCGCGT)(VI), d(CGCGTACGCG)(VII), d(CGCACGTGCG)(VIII) and d(CGTGCGCACG)(IX), d(GCTATAGC) (X), d(GCATATGC) (XI), d(GGTATACC) (XII) and d(GGATATCC) (XIII). The normal B type conformation is observed for all the oligomer DNA's at low salt (0.1-1.0 M NaCl) concentration in the temperature range of 0-25 degrees C. It was considered possible that all of the first nine oligomers could go into the Z form in aqueous high salt (5.0-6.0 M NaCl) solutions, and under these conditions the last four were considered candidates to go into the A form. The B-type conformation was found to exist in high salt solutions for (I), (IV), (V), (VI), (X), (XI) and (XIII); the Z or partial Z conformation appears in high salt solution for the oligomers, (II), (III), (VII), (VIII) and (IX); an A or partial A conformation appears in high salt solution for (XII). In the crystalline state, (IV), (VIII), (X), and (XI) stay in the B-form and all of the other oligomers adopt the complete Z-form except for (XII) which crystallizes in the A form. In both the crystal and in aqueous solutions, the identification of the conformation genus was made by means of Raman spectroscopy. In the crystal of (I), grown at pH7.0, guanosine is found to be in C3'-endo/syn conformation and cytidine in C2'-endo/anti, which may be taken as the ideal building block of the typical Z conformation. At pH4, (I) crystallizes in a conformation similar to the B genus. A study of the thermally induced B to Z transition has been carried out for (II) and (III). Based on the analysis of Raman spectra of the alternating pyrimidine-purine oligomers which might be expected to go into the Z form, the tendency for these oligonucleotides to adopt the Z form can be ranked as: d(CGCGCGCG) greater than (II) greater than (III) greater than (V) approximately (VI) greater than (IV) for octamers and (VII) greater than (VIII) greater than (IX) for the decamers. Similarly, those oligomers which might have a tendency to go into the A form could be ranked as (XII) greater than (XIII) approximately (X) greater than (XI). These data should provide help in formulating rules for predicting the sequence dependence of the B to A and B to Z transitions. Some possible rules are explored, but precautions should be taken.     

Base triplet nonisomorphism strongly influences DNA triplex conformation: effect of nonisomorphic G* GC and A* AT triplets and bending of DNA triplexes

Structural understanding of DNA triplexes is grossly inadequate despite their efficacy as therapeutic agents. Lack of structural similarity (isomorphism) of base triplets that figure in different DNA triplexes brings in an added complexity. Recently, we have shown that the residual twist (Deltat degrees ) and the radial difference (Deltar A) adequately define base triplet nonisomorphism in structural terms and allow assessment of their role in conferring stability as well as sequence-dependent structural variations in DNA triplexes. To further corroborate these, molecular dynamics (MD) simulations are carried out on DNA triplexes comprising nonisomorphic G* GC and A* AT base triplets under different sequential contexts. Base triplet nonisomorphism between G* GC and A* AT triplets is dominated by Deltat degrees (9.8 degrees ), in view of small Deltar (0.2 A), and is in contrast to G* GC and T* AT triplets where both Deltat degrees (10.6 degrees ) and Deltar (1.1A) are prominent. Results show that Deltat degrees alone enforces mechanistic influence on the triplex-forming purine strand so as to favor a zigzag conformation with alternating conformational features that include high (40 degrees ) and low (20 degrees ) helical twists, and high anti(G) and anti(A) glycosyl conformation. Higher thermal stability of this triplex compared to that formed with G* GC and T* AT triplets can be traced to enhanced base-stacking and counterion interactions. Surprisingly, it is found for the first time that the presence of a nonisomorphic G* GC or A* AT base triplet interrupting an otherwise mini A* AT or G* GC isomorphic triplex can induce a bend/curvature in a DNA triplex. These observations should prove useful in the design of triplex-forming oligonucleotides and in the understanding the binding affinities of this triplex with proteins.     

Stability of G,A triple helices.

In this work we selected double-stranded DNA sequences capable of forming stable triplexes at 20 or 50 degrees C with corresponding 13mer purine oligonucleotides. This selection was obtained by a double aptamer approach where both the starting sequences of the oligonucleotides and the target DNA duplex were random. The results of selection were confirmed by a cold exchange method and the influence of the position of a 'mismatch' on the stability of the triplex was documented in several cases. The selected sequences obey two rules: (i) they have a high G content; (ii) for a given G content the stability of the resulting triplex is higher if the G residues lie in stretches. The computer simulation of the Mg2+, Na+and Cl-environment around three triplexes by a density scaled Monte Carlo method provides an interpretation of the experimental observations. The Mg2+cations are statistically close to the G N7 and relatively far from the A N7. The presence of an A repels the Mg2+from adjacent G residues. Therefore, the triplexes are stabilized when the Mg2+can form a continuous spine on G N7.