Slow motions in A·T rich DNA sequence.

In free B-DNA, slow (microsecond-to-millisecond) motions that involve equilibrium between Watson-Crick (WC) and Hoogsteen (HG) base-pairing expand the DNA dynamic repertoire that could mediate DNA-protein assemblies. R1ρ relaxation dispersion NMR methods are powerful tools to capture such slow conformational exchanges in solution using 13C/15 N labelled DNA. Here, these approaches were applied to a dodecamer containing a TTAAA element that was assumed to facilitate nucleosome formation. NMR data and inferred exchange parameters assign HG base pairs as the minor, transient conformers specifically observed in three successive A·T base pairs forming the TAA·TTA segment. The abundance of these HG A·T base pairs can be up to 1.2% which is high compared to what has previously been observed. Data analyses support a scenario in which the three adenines undergo non-simultaneous motions despite their spatial proximity, thus optimising the probability of having one HG base pair in the TAA·TTA segment. Finally, revisiting previous NMR data on H2 resonance linewidths on the basis of our results promotes the idea of there being a special propensity of A·T base pairs in TAA·TTA tracts to adopt HG pairing. In summary, this study provides an example of a DNA functional element submitted to slow conformational exchange. More generally, it strengthens the importance of the role of the DNA sequence in modulating its dynamics, over a nano- to milli-second time scale.

HIV-1 integrase and virus and cell DNAs: complex formation and perturbation by inhibitors of integration.

HIV-1 integrase (IN) catalyzes integration of viral DNA into cell DNA through 3'-processing of viral DNA and strand transfer reactions. To learn on binding of IN to DNAs and IN inhibition we applied spectroscopy (circular dichroism, fluorescence) in a simplified model consisting in a peptide analogue (K156) of alpha4 helix involved in recognition of viral and cell DNA; an oligonucleotide corresponding to the U5' LTR DNA end; and an inhibitor (TB11) of the diketo acid (DKA) family. Results extrapolated to IN show that: the enzyme binds viral DNA with high affinity and specificity, but cell DNA with low affinity and specificity; the affinity of TB11 for IN is high enough to impair the binding of IN to cell DNA, but not to viral DNA. This explains why TB11 is an inhibitor of strand transfer but not of 3'-processing. These results can help in the search of new IN inhibitors.

NMR study of a heterochiral DNA hairpin:impact of L-enantiomery in the loop.

We carried out a structural study of the DNA heterochiral strand d (AGCTTATCAT(L)CGATAAGCT), -AT(L)C-, where T(L) (L thymine ) replaces T (natural D-thymine). -AT(L)C- is a structural analog of -ATC- that belongs to a strong topoisomerase II DNA cleavage site and which has been shown to resolve into a hairpin structure with a stem formed by eight Waston-Crick base-pairs and a single residue loop closed by an A.C sheared base-pair. Although - AT(L)C-, like its parent -ATC-, folds into a hairpin structure at low and high DNA concentrations it displays a lower stability (Tm of 56 degrees C versus 58.5 degrees C). Several NMR features in -AT(L)C- account for the disruption of the A.C pairing in the loop and a weakening of the C.G base-pair stability at the stem-loop junction. For instance, the exchange of the loop imino protons with solvent is accelerated compared with the natural oligonucleotide -ATC-. The higher flexibility of the heterochiral loop is confirmed by the results of NMR restrained molecular dynamics. In the calculated final structures of -AT(L)C-, the T10(L) residue moves the A9 and C11 residues away, thus preventing the loop closure through a C.A sheared base-pair and the achievement of a good base-base or sugar-base stacking. Actually, most of the stabilizing interactions present in -ATC- are lost in the heterochiral - AT(L)C- explaining its weaker stability.

A two B-Z junction containing DNA resolves into an all right-handed double-helix.

Natural and artificial oligonucleotides are capable of assuming many different conformations and functions. Here we present results of an NMR restrained molecular modelling study on the conformational preferences of the modified decanucleotide d((m)C1G2(m)C3G4C5(L)G6(L)(m)C7G8(m)C9G10) .d((m)C11G12(m)C13G14C15(L)G (L)16(m)C17-G18(m)C19G20 ) which contains L deoxynucleotides in its centre. This chimeric DNA was expected to form a right-left-right-handed B-type double-helix (BB*B) at low salt concentration. Actually, it matured into a fully right-handed double helix with its central C(L)pG(L) core forming a right-handed Z-DNA helix embedded in a B-DNA matrix (BZ*B). The interplay between base-base and base-sugar stackings within the core and its immediately adjacent residues was found to be critical in ensuring the stabilisation of the right-handed helix. The structure could serve as a model for the design of antisense oligonucleotides resistant to nucleases and capable of hybridising to natural DNAs and RNAs.

A DNA hairpin with a single residue loop closed by a strongly distorted Watson-Crick G x C base-pair.

Our previous NMR and modeling studies have shown that the single-stranded 19mer oligonucleotides d(AGCTTATC-ATC-GATAA GCT) -ATC- and d(AGCTTATC-GAT-GATAAGCT) -GAT- encompassing the strongest topoisomerase II cleavage site in pBR322 DNA could form stable hairpin structures. A new sheared base-pair, the pyrimidine-purine C x A, was found to close the single base -ATC- loop, while -GAT- displayed a flexible loop of three/five residues with no stabilizing interactions. Now we report a structural study on -GAC-, an analog of -GAT-, derived through the substitution of the loop residue T by C. The results obtained from NMR, non-denaturing PAGE, UV-melting, circular dichroism experiments and restrained molecular dynamics indicate that -GAC- adopts a hairpin structure folded through a single residue loop. In the -GAC- hairpin the direction of the G9 sugar is reversed relative to the C8 sugar, thus pushing the backbone of the loop into the major groove. The G9 x C11 base-pair closing the loop is thus neither a sheared base-pair nor a regular Watson-Crick one. Although G9 and C11 are paired through hydrogen bonds of Watson-Crick type, the base-pair is not planar but rather adopts a wedge-shaped geometry with the two bases stacked on top of each other in the minor groove. The distortion decreases the sugar C1'-C1' distance between the paired G9 and C11, to 8 A versus 11 A in the standard B-DNA. The A10 residue at the center of the loop interacts with the G9 x C11 base-pair, and seems to contribute to the extra thermal stability displayed by -GAC- compared to -GAT-. Test calculations allowed us to identify the experimental NOEs critical for inducing the distorted G.C Watson-Crick base-pair. The preference of -GAC- for a hairpin structure rather than a duplex is confirmed by the diffusion constant values obtained from pulse-field gradient NMR experiments. All together, the results illustrate the high degree of plasticity of single-stranded DNAs which can accommodate a variety of turn-loops to fold up on themselves.

An NMR and molecular modelling analysis of d(CTACTGCTTTAG). d(CTAAAGCAGTAG) reveals that the particular behaviour of TpA steps is related to edge-to-edge contacts of their base-pairs in the major groove.

In a previous NMR study we detected the presence of particular motions and hydration properties within the DNA fragment d(CTACTGCTTTAG).d(CTAAAGCAGTAG). Now, we report on an NMR and molecular modelling analysis of this sequence focusing our attention on the biologically important TpA steps. NOe and coupling constant restraints were introduced in three different modelling protocols: X-PLOR and JUMNA used with Flex and AMBER94 as force-fields. Despite their differences the protocols produce similar mean B-DNA structures (r.m.s.d. <1 A). The new information confirms our previous experimental results on the narrowing of the minor groove along the T8T9T10/A17A16A15 run and the sudden widening at the T10pA11 step ending this run. It is further shown that this step displays a large positive roll with its T10:A15 and A11:T14 base-pairs likely stabilised by amino-amino and amino-carbonyl interactions in the major groove. A relationship between roll values and amino-amino and amino-carbonyl distances strongly suggests that electrostatics or bifurcated hydrogen-bonds could be responsible for induction of positive rolls in TpA steps. Such edge-to-edge interactions could explain the slower motions shown by the adenine A15. The influence of these interactions on the stabilisation of particular DNA conformers is discussed using our data and those provided by the recent literature.

An intrinsic curvature towards the minor groove in the cAMP-responsive element DNA found by combined NMR and molecular modelling studies.

The cAMP-responsive element (CRE, 5'-TGACGTCA-3') is essential to the transcriptional function of numerous gene promoters in eukaryotic cells. We carried out NMR restrained molecular mechanics studies using two different force fields (Flex and "AMBER94") on a hexadecanucleotide d(GAGATGACGTCATCTC) containing CRE. Results indicated that free CRE is a B-DNA that is intrinsically curved towards the minor groove. To our knowledge, NMR restraints have not previously been useful in accounting for a global DNA curvature. In order to validate the bend in CRE, we applied a new strategy in which DNA structures displaying different curvatures were generated and then compared with NMR data. Conformations of CRE curved towards the minor groove provided the best agreement with NMR data. Our results contrast with previous results obtained from NMR restrained modelling and gel methods; these suggested conformations that were straight or curved towards the major groove, respectively. The curve in free CRE is spread along the DNA helix: several kinks are repeated in phase within the helical turn, although they are centred mainly on CpG in between the TGA half-sites, thus slightly increasing their spacing within the major groove. Comparison with the crystal structure of CRE complexed to general control protein 4 showed that the curve orientation is reversed from the minor to the major groove upon protein binding, due to a helix distortion concentrated mainly on CpG.

Comparative structural analysis by [1H,31P]-NMR and restrained molecular dynamics of two DNA hairpins from a strong DNA topoisomerase II cleavage site.

The structural analysis of two single-stranded DNAs d(AGCTTATCATCGATAAGCT) (ATC-19) and d(AGCTTATCGATGATAAGCT) (GAT-19) was performed by NMR and restrained molecular dynamics. These oligonucleotides reproduce the 15-33 segment of phage pBR322 DNA, which contains a strong cleavage site for topoisomerase II coupled to the antitumor drugs VP-16 and ellipticine. Because of their partial palindromic nature, the two oligonucleotides ATC-19 and GAT-19 may fold back into stable hairpin structures, consisting of a stem of eight base-pairs and a loop of three residues. NMR assignments and conformational parameters were determined from combined 2D NOESY, COSY and 1H-31P spectra. Conformations of ATC-19 and GAT-19 hairpins were calculated using the X-PLOR 3.1 program. Structures were generated through simulated annealing procedures starting from 50 structures with randomized torsion angles. A good convergence was observed for ATC-19 molecules, while no consensus was found for GAT-19. Within the GAT-19 loop, the base stacking was poor and no hydrogen bond could be detected. In contrast, ATC-19 displayed a well-defined three residue loop stabilized by both extensive base stackings and hydrogen bonding between the N3 atom of the adenine ring and the amino group of the cytosine ring. The results confirm our earlier ATC-19 structure obtained by a completely different calculation procedure (JUMNA) and the higher thermal stability of ATC-19 compared to GAT-19. Moreover, due to its mismatched base-pair, the ATC-19 loop may be better described as a single residue loop rather than a three residue loop. Comparison of this loop to those containing sheared purine.purine base-pairs revealed striking resemblances, particularly on the backbone angle combination. Finally, the differences observed between the ATC-19 and GAT-19 structures could help toward understanding the sequential cleavage of DNA strands by topoisomerase II.

An NMR study of d(CTACTGCTTTAG).d(CTAAAGCAGTAG) showing hydration water molecules in the minor groove of a TpA step.

The hydration properties of the non-palindromic duplex d(CTACTGCTTTAG). d(CTAAAGCAGTAG) were investigated by NMR spectroscopy. The oligonucleotide possesses a heterogeneous B-DNA structure. The H2(n)-H1'(m+1) distances reflect a minor groove narrowing within the TTT/AAA segment (approximately 3.9A) and a sudden widening at the T10:A15 base-pair (approximately 5.3A), the standard B-DNA distance being approximately 5A. The facing T10pA11 and T14pA15 steps at the end of the TTTA/AAAT segment have completely different behaviors. Only A15 ending the AAA run displays NMR features comparable to those shown by adenines of TpA steps occupying the central position of TnAn (n> or =2) segments. These involve particular chemical shifts and line broadening of the H2 and H8 protons. Positive NOESY cross-peaks were measured between the water protons and the H2 protons of A15, A16 and A17 reflecting the occurrence of hydration water molecules with residence times longer than 500 picoseconds along the minor groove of the TTT/AAA segment. In contrast no water molecules with long residence times were observed neither for A3, A20 and A23 nor for A11 ending the 5'TTTA run. We confirm thus that the binding of water molecules with long residence time to adenine residues correlates with the minor groove narrowing. In contrast, the widening of the minor groove at the A11:T14 base-pair ending the TTTA/TAAA segment, likely associated to a high negative propeller twist value at this base-pair, prevents the binding of a water molecule with long residence time to A11 but not to A15 of the preceding T10:A15 base-pair. Thus, in our non-palindromic oligonucleotide the water molecules bind differently to A11 and A15 although both adenines are part of a TpA step. The slower motions occurring at A15 compared to A11 are also well explained by the present results.

The hairpin structure of a topoisomerase II site DNA strand analyzed by combined NMR and energy minimization methods.

We report on the structural study of the single-stranded 19mer oligonucleotide d(AGCTTATC-ATC-GATAAGCT) 22(+). This corresponds to the 15-to-33(+) strand of pBR322 DNA belonging to a strong cleavage site (site 22) for topoisomerase II coupled to antitumor drugs VP-16 or ellipticine. The partially self-complementary nature of this oligonucleotide makes likely its folding into a hairpin structure. To assess this property we carried out a quantitative analysis based on joint calculations and NMR experiments. The latter required two-dimensional (NOESY, P-COSY, TOCSY and proton-detected 1H-31P), and three-dimensional (NOESY-TOCSY) spectra to achieve the assignment of the overcrowded sugar H4' ad H5'/H5" proton region. For molecular modeling, the JUMNA program was used together with NMR constraints; namely, the distances and the backbone torsion angles provided by NOEs and homo- and heteronuclear coupling constants. Experimental results proved that the 19mer oligonucleotide adopted a stable hairpin structure characterized by an eight base-pair stem and a three-membered loop (central-ATC-segment). Homonuclear 1H-1H and heteronuclear 1H-31P coupling constant measurements provided information on the conformational heterogeneity of the sugar and phosphate groups within both the stem and the loop. Restrained energy minimizations starting with different structures resulted in a family of closely related structures. All low-energy molecules presented the same, rather compact, folded structure with the base-stacking continuing into the loop, a sharp turn occurring between residues T10 and C11, and strong backbone distortions at the loop-stem junction.

Solution structure of the CpG containing d(CTTCGAAG)2 oligonucleotide: NMR data and energy calculations are compatible with a BI/BII equilibrium at CpG.

We report the analysis of the solution structure of the DNA duplex d(CTTCGAAG)2 compared to that of d(CATCGATG)2, the two oligonucleotides being related by the permutation of residues 2 and 7. An earlier study has demonstrated the malleability of CpG in the tetrad TCGA of d(CATCGATG)2 [Lefebvre et al. (1995) Biochemistry 34, 12019-12028]. Conformations of d(CTTCGAAG)2 were evaluated by (a) two-dimensional NMR, including proton and phosphorus experiments, (b) adiabatic mapping of the conformational space, (c) restrained molecular mechanics undertaken with sugar phase angle, epsilon-zeta difference angle, and NOE distances as input, and (d) back-calculation-refinement against NOE spectra at various mixing times. d(CTTCGAAG)2 like d(CATCGATG)2 exhibits a B-DNA conformation. However, significant differences are noted between the two oligonucleotides, extending up to the central CpG step, although this step resides in the same TCGA tetrad in both sequences. In structures obtained with refined NMR data, CpG adopts, for instance, a greater twist and a higher guanine phase within d(CTTCGAAG)2 compared to d(CATCGATG)2. In the former oligonucleotide, the structure of CpG resembles strikingly that found in the ACGT tetrad of the cAMP responsive element [Mauffret et al. (1992) J. Mol. Biol. 227, 852-875]. Moreover, two conformers with CpG either in the BII state (epsilon, zeta = g-, t) or in the BI state (epsilon, zeta = t, g-) are found equally stable for d(CTTCGAAG)2. The energy barrier from BI to BII comes to only 5.7 kcal/mol, and the path of the transition is very short. When calculations on d(CTTCGAAG)2 are performed taking the BI/BII equilibrium into account, the agreement with both the 1H and 31P data is found better than in the case with a single conformation taken alone. The BI/BII equilibrium may also occur in d(CATCGATG)2, but the amount of BII conformer is now found weaker compared to its analogue. The ability of the CpG phosphate groups to adopt the BII conformation could provide a satisfying explanation for the high mutation rates observed at these sites.

Dissection of the basic subdomain of the c-Jun oncoprotein: a structural analysis of two peptide fragments by CD, Fourier-transform infrared and NMR.

In a previous paper, we reported on the structural properties of a 35-residue peptide corresponding to a modified basic subdomain (bSD) of the basic zipper protein c-Jun (residues 252-281) as determined by combined use of 1H-NMR, circular dichroism (CD) and Fourier transform infrared (FT-IR) spectroscopies [Krebs, D., Dahmani, B., El Antri, S., Monnot, M., Convert, O,. Mauffret, O., Troalen, F. & Fermandjian, S. (1995) Eur. J. Biochem. 231, 370-380]. The fragments NP and CP (the N-terminal residues 1-19 and C-terminal residues 16-35 of bSD, respectively) proved to be particularly useful for the assignment of the 1H-NMR spectra of the full-length bSD, which has been achieved completely in aqueous solution and partially in trifluoroethanol. Here, we report on the structural properties of NP and CP in aqueous solution and under varying H2O/trifluoroethanol conditions, again using 1H-NMR, CD and FT-IR experiments. Both CD and FT-IR results established that the fragments are weakly structured in aqueous solution. Addition of trifluoroethanol to aqueous solutions of the peptides produced their stabilization into helix, following a profile sigmoidal for NP and nearly linear for CP. Quantitative NOEs, secondary Halpha chemical shifts, NH temperature coefficients and 3JalphaN coupling constants for the peptides in aqueous solutions provided indications for weak helix features (nascent helices) manifested within two sites (continuous dNN NOEs) in both NP and CP. For each peptide, an excellent agreement was observed between experiments and predictions with the AGADIR program for the location of these nascent helices in the sequences. Trifluoroethanol provoked both the alpha-helix stabilization within these sites and the alpha-helix propagation to adjacent amino acid residues. Finally, our results reflected the high flexibility and helix potential of the NP and CP fragments, these two properties seeming crucial for the accommodation of c-Jun to its specific DNA targets. The results demonstrated also the fragmentation's benefits in dissecting a protein or a complex peptide into smaller fragments and analyzing their structure individually.

Hairpins in a DNA site for topoisomerase II studied by 1H- and 31P-NMR.

1H- and 31P-NMR and UV-absorption studies were carried out with the oligonucleotide strands d(AGCT-TATC-ATC-GATAAGCT) (-ATC-) and d(AGCTTATC-GAT-GATAAGCT) (-GAT-) contained in the strongest and salt resistant cleavage site for topoisomerase II in pBR322 DNA. We found that the two oligonucleotides were stabilized under a hairpin structure characterized by a eight base pair stem and a three base loop at low DNA and salt concentrations. In such experimental conditions, only the -GAT- oligonucleotide displayed a partial homoduplex structure in slow equilibrium with its folded structure. Temperature dependencies of imino protons showed that the partial homoduplex of -GAT- melted at a lower temperature than the hairpin structure. It was suggested that the appearance of the partial homoduplex in -GAT- is related to the formation of two stabilizing (G.T) mismatched base pairs in the central loop of this structure. Finally, it was inferred from the dispersion of chemical shifts in the 31P-NMR spectra that the distortions affecting the backbone of the hairpin loop are larger in the case of -ATC- compared with -GAT-. At the same time NOEs proved that the base stacking was stronger within the loop of the -ATC- hairpin.

Structural behavior of the CpG step in two related oligonucleotides reflects its malleability in solution.

We report on the determination of the solution structure of two sequence-related oligonucleotides, d(GTACGTAC)2 and d(CATCGATG)2. Results have been obtained by using a combined approach of (a) two-dimensional NMR, including proton and phosphorus experiments, (b) restrained molecular mechanics performed with sugar phase angle, backbone epsilon angle, and NOE distances as input, and (c) back-calculation refinements against the NOE spectra at various mixing times. The two oligonucleotides adopt the B-DNA structure with, however, noticeable differences centered on their core sequence and especially the CpG step. Due to the permutation of its flanking residues, the CpG step modifies its twist values and backbone epsilon value; globally, the CpG step appears more flexible within the tetranucleotide TCGA than ACGT. The solution structure of d(GTACGTAC)2 differs from the previously reported X-ray structure, which was found to be A-form throughout [Takusagawa, F. (1990) J. Biomol. NMR 3, 547-568]. On the other hand, in the X-ray structure of d(CCAACGTTGG)2 [Privé et al. (1991) J. Mol. Biol. 217, 177-199] the structure of the ACGT sequence is similar to that found in solution d(GTACGTAC)2. Similarly, the central TCGA tetranucleotide of d(CATCGATG)2 presents a solution structure analogous to that observed on the X-ray structures of both d(CGATCGATCG)2 [Grzeskowiak, et al. (1991) J. Biol. Chem. 266, 8861-8883] and d(CGATCGmeATCG)2 [Baïkalov, et al. (1993) J. Mol. Biol. 231, 768-784]. At the end we discuss the possible biological significance of the particular structures exhibited by the ACGT and TCGA tetranucleotides.

The basic subdomain of the c-Jun oncoprotein. A joint CD, Fourier-transform infrared and NMR study.

The structural properties of the basic subdomain of the basic zipper (bZIP) protein c-Jun were examined by joint means of 1H-NMR, CD and Fourier-transform infrared (FTIR) spectroscopies. The basic subdomain (residues 252-281 in c-Jun) is responsible for sequence-specific recognition of DNA. A modified basic subdomain bSD (residues 1-35) and its N-terminal part and C-terminal part fragments (NP, residues 1-19; and, CP, residues 16-35) were prepared by solid-phase synthesis and purified by HPLC. In aqueous solution, in the absence of DNA, bSD behaved mostly as an unstructured peptide characterized by only 5% alpha helix. However, upon mixing bSD and a specific DNA fragment, i.e. a CRE(cAMP-responsive element)-containing hexadecanucleotide, the alpha helix was stabilized to an extent of 20% at 20 degrees C or 35% at 2 degrees C. At the same time, no significant change could be detected in the DNA spectra. Addition of trifluoroethanol to an aqueous bSD sample resulted in an increase of the alpha-helix content so that about 60% of alpha helix was found at a ratio of 75% trifluoroethanol (20 degrees C). These effects were reflected in both CD and FTIR measurements. Changes shown by the CD spectra during the process suggested a mechanism dominated by a two-state helix/unordered transition. NMR data, namely alpha H chemical shifts, NOE cross-peaks and NH temperature coefficients provided indications for extended or nascent helix structures within four short stretches dispersed along the sequence for c-Jun bSD, contrasting with the unique and continuous stretch reported for Gcn4 (yeast general control protein 4) bSD in aqueous solution. Trifluoroethanol stabilized the alpha-helix structure mainly at these four sites. The malleability of the basic subdomain of c-Jun was emphasized in relation to its ability to fit the DNA helix in adopting an alpha-helix structure. The complex formation apparently requires substantial conformational change from the peptide and only little from the oligonucleotide.

Sequence dependent effects of CpG cytosine methylation. A joint 1H-NMR and 31P-NMR study.

The impact of cytosine methylation in the central CpG step of two closely related octanucleotide duplexes d(CATCGATG)2 and d(CTTCGAAG)2 was examined by 1H-NMR and 31P-NMR experiments, and a quantitative structural analysis was performed using the NOE-derived distances, the sugar puckers and the epsilon torsion angles. The two starting oligonucleotides displayed a B-DNA conformation with, however, significant local structure differences. Although the methylated oligonucleotides retained their B-DNA conformation, different structural and thermal stability effects were observed. The magnitude of the methylation effects was to depend on the initial conformation of the CpG site, which is governed by the nature of the dinucleotide AT or TT located on the CpG flanks. As an example of sequence dependence, the methylation of CpG entailed larger conformational variation in d(CATCGATG)2 than in d(CTTCGAAG)2. In this study, the 1H and 31P chemical-shift parameters averred as extremely sensitive probes for detecting subtle conformational changes. Finally, our comparative results may aid our understanding of the structural and related biological effects produced by cytosine methylation in DNA.

Effect of distortions in the phosphate backbone conformation of six related octanucleotide duplexes on CD and 31P NMR spectra.

We examined the structural properties of six octanucleotide duplexes d(TGACGTCA), d(ACTGCAGT), d(CTTCGAAG), d(CATCGATG), d(GTACGTAC), and d(CATGCATG). Circular dichroism (CD) and 2D 31P and 1H NMR spectroscopies were used in conjunction. Although of the B-DNA type, it was possible to arrange CD spectra into two families, A and B. Family A resembled poly(dG-dC) with a positive signal at approximately 280 nm and a negative one at approximately 260 nm, while family B resembled poly(dA-dT) with a positive signal at approximately 270 nm and a negative one at approximately 250 nm. All 31P resonances were assigned through constant-time heteronuclear 31P-1H correlated spectra. J(H3'-P) coupling constants related to dihedral angeles epsilon (C4'-C3'-O3'-P) were determined from 1H-31P J-resolved selective proton-flip 2D experiments. A good correlation was observed between 31P chemical shifts and coupling constants for all oligonucleotides. The patterns of these two parameters vs the base position along the sequences were almost similar. They were confronted with CD spectra. The results indicated that the position and magnitude of the signals were mainly affected by the CpG and ApT steps whose 31P chemical shifts were the farthest away from the mean 31P chemical shift value. This is in keeping with greater rigidity at these steps and should explain the influence of the local order on the shape of the CD spectra. Lastly, both UV absorption and 31P chemical shifts vs temperature provided normal temperature melting (Tm) values for all of the octanucleotide duplexes except for d(CTTCGAAG), for which the Tm was approximately 10 degrees C lower compared to its counterpart d(CATCGATG). The decrease in the thermal stability of this octanucleotide duplex was imputed to its contained TT and AA repeats, which might be able to induce correlated base destacking and phosphate group distortion in the oligonucleotide and especially on the intermediate CpG. We demonstrate that the CpG step displayed 31P NMR properties similar to those found in mismatched nucleotides exclusively in the d(CTTCGAAG) duplex.

Structural deviations at CpG provide a plausible explanation for the high frequency of mutation at this site. Phosphorus nuclear magnetic resonance and circular dichroism studies.

CpG sites in DNA are hotspots for mutations leading to human genetic disorders. However, the structural basis for these events were still unclear and necessitated a deeper evaluation. Our experiments with phosphorus-31 nuclear magnetic resonance, ultraviolet-melting and circular dichroism on two related CpG-containing octanucleotide duplexes show that CpG is a malleable step whose conformation and thermal stability are strongly dependent on the nature of its flanking steps. We conclude that the CpG step may exert a deleterious structural influence on the helix very much like the mismatch containing steps. This peculiar property of CpG should constitute a molecular basis for its recognition by various ligands as well as for mutations affecting CpG and hence an explanation for its rarity in vertebrate genomes.

The fine structure of two DNA dodecamers containing the cAMP responsive element sequence and its inverse. Nuclear magnetic resonance and molecular simulation studies.

1H and 31P n.m.r. (nuclear magnetic resonance) spectroscopy have been used in conjunction with molecular simulation to determine the structure of two DNA dodecamers. The first of these, CATGACGTCATG, contains the octameric sequence CRE (cAMP responsive element), while the second is the reversed sequence, GTACTGCAGTAC. Structure determination was based on both NOESY (nuclear Overhauser spectroscopy) derived distances and COSY (correlated spectroscopy) dihedral angle data. Access to the 31P spectra also allowed the epsilon backbone angles to be determined. Considerable care was taken in deriving structural parameters from the n.m.r. data and an excellent level of agreement is obtained with the simulated conformations. Both dodecamers are found to belong to the B-DNA family; however, there is a striking difference between the CRE sequence and its inverse, the former conformation alone showing a strong structural heterogeneity.

Probing intercalation and conformational effects of the anticancer drug 2-methyl-9-hydroxyellipticinium acetate in DNA fragments with circular dichroism.

Circular dichroism was applied to the analysis of drug-DNA associations. With the octanucleotide d(TGACGTCA) (octanucleotide I), which is the cAMP-responsive element (CRE) in gene promoters and its reverse d(ACTGCAGT) (octanucleotide II), it was demonstrated that the anticancer polyaromatic agent celiptium intercalates into DNA base pairs with its long direction perpendicular to both the DNA-helix axis and the base-pair long axis and induces larger conformational changes in the CpG-containing octanucleotide I CRE than in its reverse-sequence octanucleotide II. It was concluded that CD is a powerful and sensitive technique to discriminate between drug-binding modes of DNA, to define the geometry of the chromophore inserted into base pairs and, finally, to measure sequence-dependent conformational changes induced by intercalation in DNA. We anticipate that these studies will contribute to a better understanding of the molecular bases that underlie the mechanism of action of those cytotoxic drugs which interfere with the DNA-nuclear-protein recognition.