Structure-Function Relationship of Three Triple-Helical Nucleic Acids

Abstract

The nucleic acid triplexes poly d(T)·poly d(A)·poly d(T), poly (U)·poly (A)·poly (U), and poly (I)·poly (A)·poly (I) display a sort of continuity between each other. However, their morphologies present their own individuality which, considering those of their parent duplexes, are quite unexpected. This comparison helps to understand triplex structure-function relationship. While helical parameters are functions of the sugar pucker, low values of WC and Hoogsteen base-pair propellers is commonplace for triplexes and the Hoogsteen base-pair geometry monitors the effects of the interstrand phosphates charge-charge repulsion.

Synopsis

The nucleic acid triplexes poly d(T)·poly d(A)·poly d(T), poly(U)·poly(A)·poly(U), and poly (I)·poly (A)·poly (I) present distinct morphologies. Considering those of their parent duplexes, they are also quite unexpected.     

Vacuum UV CD spectra of homopolymer duplexes and triplexes containing A.T or A.U base pairs.

Vacuum UV circular dichroism (CD) spectra were measured down to 174 nm for five homopolymers, five duplexes, and four triplexes containing adenine, uracil, and thymine. Near 190 nm, the CD bands of poly[d(A)] and poly[r(A)] were larger than the CD bands of the polypyrimidines, poly[d(T)], poly[d(U)], and poly[r(U)]. Little change was observed in the 190 nm region upon formation of the duplexes (poly[d(A).d(T)], poly[d(A).d(U)], poly[r(A).d(T)], poly[r(A).d(U)], and poly[r(A).r(U)]) or upon formation of two of the triplexes (poly[d(T).d(A).d(T)] and poly[d(U).d(A).d(U)]). This showed that the purine strand had the same or a similar structure in these duplexes and triplexes as when free in solution. Both A.U and A.T base pairing induced positive bands at 177 and 202 nm. For three triplexes containing poly[d(A)], the formation of a triplex from a duplex and a free pyrimidine strand induced a negative band centered between 210 and 215 nm. The induction of a band between 210 and 215 nm indicated that these triplexes had aspects of the A conformation.     

Spectroscopic and thermodynamic studies on the binding of sanguinarine and berberine to triple and double helical DNA and RNA structures

A comparative study on the interaction of sanguinarine and berberine with DNA and RNA triplexes and their parent duplexes was performed, by using a combination of spectrophotometric, UV thermal melting, circular dichroic and thermodynamic techniques. Formation of the DNA and RNA triplexes was confirmed from UV-melting and circular dichroic measurements. The interaction process was characterized by increase of thermal melting temperature, perturbation in circular dichroic spectrum and the typical hypochromic and bathochromic effects in the absorption spectrum. Scatchard analysis indicated that both the alkaloids bound to the triplex and duplex structures in a non-cooperative manner and the binding was stronger to triplexes than to parent duplexes. Thermal melting studies further indicated that sanguinarine stabilized the Hoogsteen base paired third strand of both DNA and RNA triplexes more tightly compared to their Watson-Crick strands, while berberine stabilized the third strand only without affecting the Watson-Crick strand. However, sanguinarine stabilized the parent duplexes while no stabilization was observed with berberine under identical conditions. Circular dichroic studies were also consistent with the observation that perturbations of DNA and RNA triplexes were more compared to their parent duplexes in presence of the alkaloids. Thermodynamic data revealed that binding of sanguinarine and berberine to triplexes (T.AxT and U.AxU) and duplexes (A.T and A.U) showed negative enthalpy changes and positive entropy changes but that of sanguinarine to C.GxC(+) triplex and G.C duplex exhibited negative enthalpy and negative entropy changes. Taken together, these results suggest that both sanguinarine and berberine can bind and stabilize the DNA and RNA triplexes more strongly than their respective parent duplexes.     

Enhanced stabilization of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21) and poly r(U:AU) by water structure-making solutes

A variety of organic cations, cationic lipids, low molecular weight alcohols, sodium dodecylsulfate, trehalose, glycerol, low molecular weight polyethylene glycols, and DMSO were tested for their ability to modulate the stability of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6), d(T)(21):d(A)(21);d(T)(21), poly r(U:A U) and their respective core duplexes, d(A-G)(6);d(C-T)(6), d(A)(21);d(T)(21), poly r(A-U). Very substantial enhancement of triplex stability over that in a physiological salt buffer at pH 7 is obtained with different combinations of triplex and high concentrations of these additives, e.g. trimethylammonium chloride and d(C(+)-T)(6):d(A-G)(6);d(C-T)(6); 2-propanol and d(T)(21):d(A)(21);d(T)(21); ethanol and poly r(U:A;U). Triplex formation is even observed with a 1:1 strand mixture of d(A-G)(6) and d(C-T)(6) in the presence of dimethylammonium, tetramethylammonium, and tetraethylammonium-chloride, as well as methanol, ethanol, and 2-propanol. Triplex stability follows the water structure-making ability (and in some cases the duplex unwinding ability) of the organic cations, the low molecular weight alcohols and other neutral organic compounds, whereas water structure-breaking additives decrease triplex stability. These findings are consistent with those reported in the accompanying paper that triplex formation occurs with a net uptake of water. Since the findings suggest that third strand-binding is facilitated by unwinding of the target duplex, it is inferred that triplex formation may be enhanced by nucleic acid binding proteins operating similarly.     

CD of homopolymer DNA-RNA hybrid duplexes and triplexes containing A-T or A-U base pairs.

CD spectra and difference-CD spectra of (a) two DNA X RNA hybrid duplexes (poly[r(A) X d(U)] and poly[r(A) X d(T)]) and (b) three hybrid triplexes (poly-[d(T) X r(A) X d(T)], poly[r(U) X d(A) X r(U)], and poly[r(T) X d(A) X r(T)]) were obtained and compared with CD spectra of six A X U- and A X T-containing duplex and triplex RNAs and DNAs. We found that the CD spectra of the homopolymer duplexes above 260 nm were correlated with the type of base pair present (A-U or A-T) and could be interpreted as the sum of the CD contributions of the single strands plus a contribution due to base pairing. The spectra of the duplexes below 235 nm were related to the polypurine strands present (poly-[r(A)] or poly[d(A)]). We interpret the CD intensity in the intermediate 255-235 nm region of these spectra to be mainly due to stacking of the constituent polypurine strands. Three of the five hybrids (poly[r(A) X d(U)], poly[r(A) X d(T)], and poly[d(T) X r(A) X d(T)]) were found to have heteronomous conformations, while poly[r(U) X d(A) X r(U)] was found to be the most A-like and poly[r(T) X d(A) X r(T)], the least A-like.     

Models of triple-stranded polynucleotides with optimised stereochemistry.

Detailed models are presented for the triple-stranded polynucleotide helices of poly (U)-poly (A)-poly (U) (two forms), poly (U)-poly d (A) -poly (U), poly d(C)-poly d(I)-poly d(C), poly d(T)-polyd(A)-poly d(T) and poly (I)-poly (A)-poly (I). The models were genrated using a computerized, linked-atom procedure which preserves standard bond lengths, bond anglesand sugar ring conformations, constrains the helices to have the pitches and symmetries observed in X-ray diffraction experiments, and optimises the non-bonded interatomic contacts including hydrogen bonds. The possible biological sigificance of such complexes is discussed.     

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.     

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.     

Characterization of base-pair opening in deoxynucleotide duplexes using catalyzed exchange of the imino proton

Using nuclear magnetic resonance line broadening, longitudinal relaxation and magnetization transfer from water, we have measured the imino proton exchange times in the duplex form of the 10-mer d-CGCGATCGCG and in seven other deoxy-duplexes, as a function of the concentration of exchange catalysts, principally ammonia. All exchange times are catalyst dependent. Base-pair lifetimes are obtained by extrapolation to infinite concentration of ammonia. Lifetimes of internal base-pairs are in the range of milliseconds at 35 degrees C and ten times more at 0 degrees C. Lifetimes of neighboring pairs are different, hence base-pairs open one at a time. Lifetimes of d(G.C) are about three times longer than those of d(A.T). The nature of neighbors usually has little effect, but lifetime anomalies that may be related to sequence and/or structure have been observed. In contrast, there is no anomaly in the A.T base-pair lifetimes of d-CGCGA[TA]5TCGCG, a model duplex of poly[d(A-T)].poly[d(A-T)]. The d(A.T) lifetimes are comparable to those of r(A.U) that we reported previously. End effects on base-pair lifetimes are limited to two base-pairs. The low efficiency of exchange catalysts is ascribed to the small dissociation constant of the deoxy base-pairs, and helps to explain why exchange catalysis had been overlooked in the past. This resulted in a hundredfold overestimation of base-pair lifetimes. Cytosine amino proteins have been studied in the duplex of d-CGm5CGCG. Exchange from the closed base-pair is indicated. Hence, the use of an amino exchange rate to evaluate the base-pair dissociation constant would result in erroneous, overestimated values. Catalyzed imino proton exchange is at this time the safest and most powerful, if not the only probe of base-pair kinetics. We propose that the single base-pair opening event characterized here may be the only mode of base-pair disruption, at temperatures well below the melting transition.     

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.     

Antiviral activity of poly(A)-poly(U) duplexes modified with cis-diammine-dichloroplatinum (II)]

Polyribonucleotide duplex poly(A).poly(U) was modified with cis-diammine dichloroplatinum (II) (cis-DDP). It was shown that the antiinfluenza protective activity of the modified duplex in mice increased with the degree of modification (rb) rising up to 0.2. The effect was different from that for poly(I).poly(C) and poly(G).poly(C). The interferon titers in the murine brain increased in parallel with increasing of the antiviral activity. It was assumed that the structural specificity of the poly(A).poly(U) duplex was responsible for the phenomenon and that cis-DDP interaction with N(7) atoms of the adenine heterocycles blocked the "abnormal" Hoogsteen pairing of adenines with uracils. As a result the antiviral activity increased because of lowering the quantity of the intramolecular defects and increasing the length of the regular double-stranded regions.     

DNA triple helix formation at target sites containing several pyrimidine interruptions: stabilization by protonated cytosine or 5-(1-propargylamino)dU.

DNase I footprinting has been used to study the formation of parallel triplexes at oligopurine target sequences which are interrupted by pyrimidines at regular intervals. TA interruptions are targeted with third strand oligonucleotides containing guanine, generating G x TA triplets, while CG base pairs are targeted with thymine, forming T x CG triplets. We have attempted to optimize the stability of these complexes by varying the base composition and sequence arrangement of the target sites, and by replacing the third strand thymines with the positively charged analogue 5-(1-propargylamino)dU (U(P)). For the target sequence (AAAT)(5)AA, in which pyrimidines are positioned at every fourth residue, triplex formation with TG-containing oligonucleotides is only detected in the presence of a triplex-binding ligand, though stable triplexes were detected at the target site (AAAAAT)(3)AAAA. Triplex stability at targets containing pyrimidines at every fourth residue is increased by introducing guanines into the duplex repeat unit using the targets (AGAT)(5)AA and (ATGA)(5)AA. In contrast, placing C(+) x GC triplets on the 5'-side of G x TA, using the target (AGTA)(5)TT, produces complexes of lower stability. We have attempted further to increase the stability of these complexes by using the positively charged thymine base analogue U(P), and have shown that (TU(P)TG)(5)TT forms a more stable complex with target (AAAT)(5)AA than the unmodified third strand, generating a footprint in the absence of a triplex-binding ligand. Triplex formation at (AGTA)(5)AA is improved by using the modified oligonucleotide (TCGU(P))(5)TT, generating a complex in which the charged triplets C(+) x GC and U(P) x AT alternate with uncharged triplets. In contrast, placing U(P) x AT triplets adjacent to C(+) x GC, using the third strand oligonucleotide (U(P)CGT)(5)TT, reduces triplex formation, while the third strand with both substitutions, (U(P)CGU(P))(5)TT, produces a complex with intermediate stability. It appears that, although adjacent U(P) x AT triplets form stable triplexes, placing U(P) x AT adjacent to C(+) x GC is unfavorable. Similar results were obtained with fragments containing CG inversions within the oligopurine tract, though triplexes at (AAAAAC)(3)AA were only detected in the presence of a triplex-binding ligand. Placing C(+) x GC on the 5'-side of T x CG triplets also reduces triplex formation, while a 3'-C(+) x GC produces complexes with increased stability.     

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.     

Coralyne has a preference for intercalation between TA.T triples in intramolecular DNA triple helices.

Intercalating ligands may improve both the stability and sequence specificity of triple helices. Numerous intercalating drugs have been described, including coralyne, which preferentially binds triple helices, though its sequence specificity has been reported to be low [Lee,J.S., Latimer,L.J.P. and Hampel,K.J. (1993) Biochemistry , 32, 5591-5597]. In order to analyse the sequence preferences of coralyne we have used a combination of DNase I footprinting, UV melting, UV-visible spectrophotometry, circular dichroism and NMR spectroscopy to examine defined intermolecular triplexes and intramolecular triplexes linked either by hexaethylene glycol chains or by octandiol chains. DNase I footprinting demonstrated that coralyne has a moderate preference for triplexes over duplexes, but a substantial preference for TA.T triplets compared with CG. C+triplets. The drug was found to have essentially no effect on the melting temperatures of duplexes of the kind d(A)n.d(T)n or d(GA)n.d(TC)n. In contrast, it increased the T m for triplexes of the kind d(T)nd(A)n.dTn, but had little effect on the stability of d(TC)nd(GA).d(CT)n at either low or high pH. On binding to DNA triplexes, there is a large change in the absorption spectrum of coralyne and also a substantial fluorescence quenching that can be attributed to intercalation. The changes in the optical spectra have been used for direct titration with DNA. For triplexes d(T)6d(A)6.d(T)6, the Kd at 298 K was 0.5-0.8 microM. In contrast, the affinity for d(TC) nd(GA)n.d(CT)n triplexes was 6- to 10-fold lower and was characterized by smaller changes in the absorption and CD spectra. This indicates a preference for intercalation between TAT triples over CG.C+/TA.T triples. NMR studies confirmed interaction by intercalation. However, a single, secondary binding was observed at high concentrations of ligand to the triplex d(AGAAGA-L-TCTTCT-L-TCTTCT), presumably owing to the relatively low difference in affinity between the TA.T site and the competing, neighbouring sites.     

A monoclonal antibody to triplex DNA binds to eucaryotic chromosomes.

A monoclonal antibody (Jel 318) was produced by immunizing mice with poly[d(TmC)].poly[d(GA)].poly[d(mCT) which forms a stable triplex at neutral pH. Jel 318 did not bind to calf thymus DNA or other non pyrimidine.purine DNAs such as poly[d(TG)].poly[d(CA)]. In addition the antibody did not recognize pyrimidine.purine DNAs containing mA (e.g. poly[d(TC)].poly[d(GmA)]) which cannot form a triplex since the methyl group blocks Hoogsteen base-pairing. The binding of Jel 318 to chromosomes was assessed by immunofluorescent microscopy of mouse myeloma cells which had been fixed in methanol/acetic acid. An antibody specific for duplex DNA (Jel 239) served as a control. The fluorescence due to Jel 318 was much weaker than that of Jel 239 but binding to metaphase chromosomes and interphase nuclei was observed. The staining by Jel 318 was unaffected by addition of E. coli DNA but it was obliterated in the presence of triplex. Since an acid pH favours triplex formation, nuclei were also prepared from mouse melanoma cells by fixation in cold acetone. Again Jel 318 showed weak but consistent staining of the nuclei. Therefore it seems likely that triplexes are an inherent feature of the structure of eucaryotic DNA.     

Triplex forming ability of oligonucleotides containing 2'-O-methyl-2-thiouridine or 2-thiothymidine

The triplex forming ability of oligonucleotides containing 2'-O-methyl-2-thiouridine (s2Um) and 2-thiothymidine (s2T) was studied. The UV melting experiments revealed that triplex forming oligonucleotides (TFOs) containing both s2Um or s2T stabilized significantly parallel triplexes. The main reason for stabilization of triplexes was due to the stacking effect of the 2-thiocarbonyl group. Moreover, it turned out that these modified TFOs had a high selectivity in recognition of a matched Hoogsteen base from a mismatched one.     

Mg2+ and Ni2+ ion effect on stability and structure of triple poly I.poly A.poly I helix

The effects of Mg2+ and Ni2+ ions on the absorption spectra of IMP, single-stranded poly I and three-stranded A2I in solutions with 0.1 M Na+ (pH 7) have been studied. In contrast to Mg2+ ions, the Ni2+ ions affect the absorption spectra of these polynucleotides and IMP. The concentration dependences of the intensity at the extrema in the differential UV spectra suggest that in the region of high Ni2+ concentrations ionic complexes with poly I and A2I are formed, which are characterized by the association constants K'I = 2000 M(-1) and K'A2I = 550 M(-1), respectively. The shape of the DUV spectra prompts the conclusion that these complexes are formed due to the inner-sphere interaction of Ni2+ ions with N7 of poly I and A2I presumably due to the outer-sphere Ni2+-O6 interaction. The formation of the complexes leads to destruction of A2I triplexes. The dependences of the melting temperature (T(m)) of A2I on Mg2+ and Ni2+ concentrations have been measured. The thermal stability is observed to increase at the ionic contents up to 0.01 M Mg2+ and only to 2x10(-4) M Ni2+. At higher contents of Ni2+ ions, T(m) lowers and the cooperativity of A2I melting decreases continuously. In all the cases the melting process is the A2I-->A+I+I (3-->1) transition. According to the "ligand" theory, these effects are generated by the energy-advantageous Ni2+ binding to single-stranded poly I (K'A2I < K'I) and by the greater number of binding sites which appears during the 3-->1 transition and is entropy-advantageous.     

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).     

Stabilization of nucleic acid triplexes by high concentrations of sodium and ammonium salts follows the Hofmeister series

The thermal stability of the triplexes d(C(+)-T)(6):d(A-G)(6);d(C-T)(6) and d(T)(21):d(A)(21);d(T)(21) was studied in the presence of high concentrations of the anions Cl(-), HPO(4)(2-), CH(3)COO(-), SO(4)(2-) and ClO(4)(-). Thermally-induced triplex and duplex transitions were identified by UV- and CD-spectroscopy and T(m) values were determined from melting profiles. A thermodynamic analysis of triplex transitions shows the limitations of commonly used treatments for determining the associated release or uptake of salt, solute or water. Enhancement of the stability of these triplexes follows the rank order of the Hofmeister series for anions of sodium and ammonium salts, whereas water structure-breaking solutes have the opposite effect. The rank order for the Hofmeister series ClO(4)(-)相似文献