The backbone states of B-DNA influence its helical parameters, groove dimensions, and overall curvature. Therefore, detection and fine characterization of these conformational states are desirable. Using routine NMR experiments on a nonlabeled B-DNA oligomer and analyzing high-resolution X-ray structures, we investigated the relationship between interproton distances and backbone conformational states. The three H2'i-H6/8i+1, H2' 'i-H6/8i+1, and H6/8i-H6/8i+1 sequential distances were found cross-correlated and linearly coupled to epsilon-zeta values in X-ray structures and 31P chemical shifts (deltaP) in NMR that reflect the interconversion between the backbone BI (epsilon-zeta < 0 degrees ) and BII (epsilon-zeta > 0 degrees) states. These relationships provide a detailed check of the NMR data consistency and the possibility to extend the set of restraints for structural refinement through various extrapolations. Furthermore, they allow translation of deltaP in terms of BI/BII ratios. Also, comparison of many published deltaP in solution to crystal data shows that the impact of sequence on the BI/BII propensities is similar in both environments and is therefore an intrinsic and general property of B-DNA. This quantification of the populations of BI and BII is of general interest because these sequence-dependent backbone states act on DNA overall structure, a key feature for DNA-protein-specific recognition.
Sugar phosphate backbone conformations are a structural element inextricably involved in a complete understanding of specific recognition nucleic acid ligand interactions, from early stage discrimination of the correct target to complexation per se, including any structural adaptation on binding. The collective results of high resolution DNA, RNA and protein/DNA crystal structures provide an opportunity for an improved and enhanced statistical analysis of standard and unusual sugar-phosphate backbone conformations together with corresponding dinucleotide sequence effects as a basis for further exploration of conformational effects on binding. In this study, we have analyzed the conformations of all relevant crystal structures in the nucleic acids data base, determined the frequency distribution of all possible epsilon, zeta, alpha, beta and gamma backbone angle arrangements within four nucleic acid categories (A-RNA and A-DNA, free and bound B-DNA) and explored the relationships between backbone angles, sugar puckers and selected helical parameters. The trends in the correlations are found to be similar regardless of the nucleic acid category. It is interesting that specific structural effects exhibited by the different unusual backbone sub-states are in some cases contravariant. Certain alpha/gamma changes are accompanied by C3' endo (north) sugars, small twist angles and positive values of base pair roll, and favor a displacement of nucleotide bases towards the minor groove compared to that of canonical B form structures. Unusual epsilon/zeta combinations occur with C2' (south) sugars, high twist angles, negative values of base pair roll, and base displacements towards the major groove. Furthermore, any unusual backbone correlates with a reduced dispersion of equilibrium structural parameters of the whole double helix, as evidenced by the reduced standard deviations of almost all conformational parameters. Finally, a strong sequence effect is displayed in the free oligomers, but reduced somewhat in the ligand bound forms. The most variable steps are GpA and CpA, and, to a lesser extent, their partners TpC and TpG. The results provide a basis for considering if the variable and non-variable steps within a biological active sequence precisely determine morphological structural features as the curvature direction, the groove depth, and the accessibility of base pair for non covalent associations.
B-DNA flexibility, crucial for DNA–protein recognition, is sequence dependent. Free DNA in solution would in principle be the best reference state to uncover the relation between base sequences and their intrinsic flexibility; however, this has long been hampered by a lack of suitable experimental data. We investigated this relationship by compiling and analyzing a large dataset of NMR 31P chemical shifts in solution. These measurements reflect the BI ↔ BII equilibrium in DNA, intimately correlated to helicoidal descriptors of the curvature, winding and groove dimensions. Comparing the ten complementary DNA dinucleotide steps indicates that some steps are much more flexible than others. This malleability is primarily controlled at the dinucleotide level, modulated by the tetranucleotide environment. Our analyses provide an experimental scale called TRX that quantifies the intrinsic flexibility of the ten dinucleotide steps in terms of Twist, Roll, and X-disp (base pair displacement). Applying the TRX scale to DNA sequences optimized for nucleosome formation reveals a 10 base-pair periodic alternation of stiff and flexible regions. Thus, DNA flexibility captured by the TRX scale is relevant to nucleosome formation, suggesting that this scale may be of general interest to better understand protein-DNA recognition.
Molecular modelling is used to study the conformational and energetic aspects of BI-BII transitions within the backbone of a B-DNA dodecamer d(CATGACGTCATG) whose fine structure has previously been determined by molecular modelling combined with NMR spectroscopy. It is shown that while the dodecamer under investigation does not contain any BII junctions, the central CpG step can most easily undergo the transition. More generally, it is also found that the base sequence and hence the backbone geometry of a DNA segment, strongly influences both the conformational impact of the transition, the associated energy barrier and the stability of the resulting BII state.
In the crystal structures of protein complexes with B-DNA, alpha and gamma DNA backbone torsion angles often exhibit non-canonical values. It is not known if these alternative backbone conformations are easily accessible in solution and can contribute to the specific recognition of DNA by proteins. We have analysed the coupled transition of the alpha and gamma torsion angles within the central GpC step of a B-DNA dodecamer by computer simulations. Five stable or metastable non-canonical alpha/gamma sub-states are found. The most favourable pathway from the canonical alpha/gamma structure to any unusual form involves a counter-rotation of alpha and gamma, via the trans conformation. However, the corresponding free energy indicates that spontaneous flipping of the torsions is improbable in free B-DNA. This is supported by an analysis of the available high resolution crystallographic structures showing that unusual alpha/gamma states are only encountered in B-DNA complexed to proteins. An analysis of the structural consequences of alpha/gamma transitions shows that the non-canonical backbone geometry influences essentially the roll and twist values and reduces the equilibrium dispersion of structural parameters. Our results support the hypothesis that unusual alpha/gamma backbones arise during protein-DNA complexation, assisting the fine structural adjustments between the two partners and playing a role in the overall complexation free energy.
The glycosyl torsion (chi) in nucleic acids has long been recognized to be a major determinant of their conformational properties. chi torsional energetics were systematically mapped in deoxyribonucleosides using high-level quantum mechanical methods, for north and south sugar puckers and with gamma in the g(+) and trans conformations. In all cases, the syn conformation is found higher in energy than the anti. When gamma is changed from g(+) to trans, the anti orientation of the base is strongly destabilized, and the energy difference and barrier between anti and syn are significantly decreased. The barrier between anti and syn in deoxyribonucleosides is found to be less than 10 kcal/mol and tends to be lower with purines than with pyrimidines. With gamma = g(+)/chi = anti, a south sugar yields a significantly broader energy well than a north sugar with no energy barrier between chi values typical of A or B DNA. Contrary to the prevailing view, the syn orientation is not more stable with south puckers than with north puckers. The syn conformation is significantly more energetically accessible with guanine than with adenine in 5-nucleotides but not in nucleosides. Analysis of nucleic acid crystal structures shows that gamma = trans/chi = anti is a minor but not negligible conformation. Overall, chi appears to be a very malleable structural parameter with the experimental chi distributions reflecting, to a large extent, the associated intrinsic torsional energetics.
Sugar-phosphate backbone conformations are an important structural element for a complete understanding of specific recognition in nucleic acid-protein interactions. They can be involved both in early stages of target discrimination and in structural adaptation upon binding. In the first part of this study, we have analyzed high-resolution structures of double-stranded B-DNA either isolated or bound to proteins, and explored the impact of both the standard BI and the unusual BII phosphate backbone conformations on neighboring sugar puckers and on selected helical parameters. Correlations are found to be similar for free and bound DNA, and in both categories, the possible facing backbone conformations (BI.BI, BI.BII, and BII.BII) define well-characterized substates in the B-DNA conformational space. Notably, BII.BII steps are characterized by specific, and sequence-independent, structural effects involving reduced standard deviations for almost all conformational parameters. In the second part of this work, we analyze four 10 ns molecular dynamics simulations in explicit solvent on the DNA targets of NF-kappaB and bovine papillomavirus E2 proteins, highlighting the multiplicity of backbone dynamical behavior. These results show sequence effects on the percentages of BI and BII conformers, the preferential state of facing backbones, the occurrence of coupled transitions. The backbone states can consequently be seen as a mechanism for transmitting information from the bases to the phosphate groups and thus for modulating the overall structural properties of the target DNA.
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