Molecular modelling of (A4T4NN)n and (T4A4NN)n: sequence elements responsible for curvature

Determinants of cyclization-decyclization kinetics of short DNA with sticky ends

Cyclization of DNA with sticky ends is commonly used to measure DNA bendability as a function of length and sequence, but how its kinetics depend on the rotational positioning of the sticky ends around the helical axis is less clear. Here, we measured cyclization (looping) and decyclization (unlooping) rates (k_loop and k_unloop) of DNA with sticky ends over three helical periods (100-130 bp) using single-molecule fluorescence resonance energy transfer (FRET). k_loop showed a nontrivial undulation as a function of DNA length whereas k_unloop showed a clear oscillation with a period close to the helical turn of DNA (∼10.5 bp). The oscillation of k_unloop was almost completely suppressed in the presence of gaps around the sticky ends. We explain these findings by modeling double-helical DNA as a twisted wormlike chain with a finite width, intrinsic curvature, and stacking interaction between the end base pairs. We also discuss technical issues for converting the FRET-based cyclization/decyclization rates to an equilibrium quantity known as the J factor that is widely used to characterize DNA bending mechanics.

Analyzing DNA curvature and its impact on the ionic environment: application to molecular dynamics simulations of minicircles

We propose a method for analyzing the magnitude and direction of curvature within nucleic acids, based on the curvilinear helical axis calculated by Curves+. The method is applied to analyzing curvature within minicircles constructed with varying degrees of over- or under-twisting. Using the molecular dynamics trajectories of three different minicircles, we are able to quantify how curvature varies locally both in space and in time. We also analyze how curvature influences the local environment of the minicircles, notably via increased heterogeneity in the ionic distributions surrounding the double helix. The approach we propose has been integrated into Curves+ and the utilities Canal (time trajectory analysis) and Canion (environmental analysis) and can be used to study a wide variety of static and dynamic structural data on nucleic acids.

[KCl] Dependence of B-DNA Groove Bending Anisotropy

The energetics of B-DNA bending toward the major and minor grooves were quantified by free energy simulations at four different KCl concentrations. Increased [KCl] led to more flexible DNA, with persistence lengths that agreed well with experimental values. At all salt concentrations, major groove bending was preferred, although preferences for major and minor groove bending were similar for the A-tract containing sequence. Since the phosphate repulsions and DNA internal energy favored minor groove bending, the preference for major groove bending was thought to originate from differences in solvation. Water in the minor groove was tighter bound than water in the major groove, and harder to displace than major groove water, which favored the compression of the major groove upon bending. Higher [KCl] decreased the persistence length for both major and minor groove bending but did not greatly affect the free energy spacing between the minor and major groove bending curves. For sequences without A-tracts, salt affected major and minor bending to nearly the same degree, and did not change the preference for major groove bending. For the A-tract containing sequence, an increase in salt concentration decreased the already small energetic difference between major and minor groove bending. Since salts did not significantly affect the relative differences in bending energetics and hydration, it is likely that the increased bending flexibilities upon salt increase are simply due to screening.

Anisotropy of B-DNA Groove Bending

DNA bending is critical for DNA packaging, recognition, and repair, and occurs toward either the major or the minor groove. The anisotropy of B-DNA groove bending was quantified for eight DNA sequences by free energy simulations employing a novel reaction coordinate. The simulations show that bending toward the major groove is preferred for non-A-tracts while the A-tract has a high tendency of bending toward the minor groove. Persistence lengths were generally larger for bending toward the minor groove, which is thought to originate from differences in groove hydration. While this difference in stiffness is one of the factors determining the overall preference of bending direction, the dominant contribution is shown to be a free energy offset between major and minor groove bending. The data suggests that, for the A-tract, this offset is largely determined by inherent structural properties, while differences in groove hydration play a large role for non-A-tracts. By quantifying the energetics of DNA groove bending and rationalizing the origins of the anisotropy, the calculations provide important new insights into a key biological process.

DNA minicircles clarify the specific role of DNA structure on retroviral integration

Chromatin regulates the selectivity of retroviral integration into the genome of infected cells. At the nucleosome level, both histones and DNA structure are involved in this regulation. We propose a strategy that allows to specifically study a single factor: the DNA distortion induced by the nucleosome. This strategy relies on mimicking this distortion using DNA minicircles (MCs) having a fixed rotational orientation of DNA curvature, coupled with atomic-resolution modeling. Contrasting MCs with linear DNA fragments having identical sequences enabled us to analyze the impact of DNA distortion on the efficiency and selectivity of integration. We observed a global enhancement of HIV-1 integration in MCs and an enrichment of integration sites in the outward-facing DNA major grooves. Both of these changes are favored by LEDGF/p75, revealing a new, histone-independent role of this integration cofactor. PFV integration is also enhanced in MCs, but is not associated with a periodic redistribution of integration sites, thus highlighting its distinct catalytic properties. MCs help to separate the roles of target DNA structure, histone modifications and integrase (IN) cofactors during retroviral integration and to reveal IN-specific regulation mechanisms.

Structural Basis for Elastic Mechanical Properties of the DNA Double Helix

In this article, we investigate the principal structural features of the DNA double helix and their effects on its elastic mechanical properties. We develop, in the pursuit of this purpose, a helical continuum model consisting of a soft helical core and two stiff ribbons wrapping around it. The proposed model can reproduce the negative twist-stretch coupling of the helix successfully as well as its global stretching, bending, and torsional rigidities measured experimentally. Our parametric study of the model using the finite element method further reveals that the stiffness of phosphate backbones is a crucial factor for the counterintuitive overwinding behavior of the duplex and its extraordinarily high torsional rigidity, the major-minor grooves augment the twist-stretch coupling, and the change of the helicity might be responsible for the transition from a negative to a positive twist-stretching coupling when a tensile force is applied to the duplex.

Mechanical properties of symmetric and asymmetric DNA A-tracts: implications for looping and nucleosome positioning

A-tracts are functionally important DNA sequences which induce helix bending and have peculiar structural properties. While A-tract structure has been qualitatively well characterized, their mechanical properties remain controversial. A-tracts appear structurally rigid and resist nucleosome formation, but seem flexible in DNA looping. In this work, we investigate mechanical properties of symmetric AnTn and asymmetric A2n tracts for n = 3, 4, 5 using two types of coarse-grained models. The first model represents DNA as an ensemble of interacting rigid bases with non-local quadratic deformation energy, the second one treats DNA as an anisotropically bendable and twistable elastic rod. Parameters for both models are inferred from microsecond long, atomic-resolution molecular dynamics simulations. We find that asymmetric A-tracts are more rigid than the control G/C-rich sequence in localized distortions relevant for nucleosome formation, but are more flexible in global bending and twisting relevant for looping. The symmetric tracts, in contrast, are more rigid than asymmetric tracts and the control, both locally and globally. Our results can reconcile the contradictory stiffness data on A-tracts and suggest symmetric A-tracts to be more efficient in nucleosome exclusion than the asymmetric ones. This would open a new possibility of gene expression manipulation using A-tracts.

Structure based sequence dependent stiffness scale for trinucleotides: a direct method

A new set of stiffness parameters for all the 32trinucleotide units has been set up directly from thethree dimensional structures of DNA molecules. It wasobserved that GAC/GTC is the stiffest trinucleotideand ACC/GGT is the most flexible one. The averagestiffness values computed for a set of operatorsequences using the new parameters correlate very wellwith the protein-DNA binding specificity and bindingfree energy change of 434 repressor and Cro repressor,respectively. The new structure based stiffness scalecan explain the protein-DNA binding specificity to thelevel of 0.92.

Molecular dynamics study of the role of the spine of hydration in DNA A-tracts in determining nucleosome occupancy

A-tracts in DNA are generally associated with reduced nucleosome occupancy relative to other sequences, such that the longer the A-tract, the less likely that nucleosomes are found. In this paper, we use molecular dynamics methods to study the structural properties of A-tracts, and in particular the role that the spine of hydration in A-tracts plays in allowing DNA to distort to the highly bent structure needed to form nucleosomes. This study includes a careful assessment of the ability of the Amber (parmbsc0), CHARMM27, and BMS force fields to describe these structural waters for the AAATTT sequence (here capped with CGC and GCG), including comparisons with X-ray results. All three force fields show a spine of hydration, but BMS and Amber show better correlation with measured properties, such as in narrowing of the minor groove width associated with the A-tract. We have used Amber to study the spine properties for several 6 and 14 base-pair A-tracts (all capped with CGC and GCG). These calculations show that the structural waters are tightly bound for "pure" A-tracts that allow for A-water-T links, and for AT steps that allow for a T-water-T link, but other sequences disfavor structural water, especially those that lead to A-water-A, G-water-G, and C-water-A structures. In addition, we show that pure A-tracts favor roll values close to the Watson-Crick value for linear DNA, while A-tract sequences containing embedded T's, C's, or G's that are less favorable to structural water are more flexible. This implies the essential role of the spine of hydration in disfavoring nucleosome formation.

Modeling DNA-bending in the nucleosome: role of AA periodicity

This paper uses atomistic molecular mechanics within the framework of the JUMNA model to study the bending properties of DNA segments, with emphasis on understanding the role of the 10 bp periodicity associated with AA repeats that has been found to dominate in nucleosomal DNA. The calculations impose a bending potential on 18 bp segments that is consistent with nucleosome structures (i.e., radius of curvature of 4.1 nm), and then determine the energies of the minimum energy structures for different values of the rotational register (a measure of the direction of bending of the DNA) subject to forces derived from the Amber force field (parm99bsc0). The results show that sequences that contain the 10 bp repeats but are otherwise random have a narrow distribution of rotational register values that minimize the energy such that it is possible to combine several minimized structures to give the 147 bp nearly planar loop structure of the nucleosome. The rotational register values that lead to minimum bending energy with 10 bp AA repeats have a narrower minor groove, which points toward the histone interior at the positions of the AA repeats, which is a result that matches the experiments. The calculations also show that these sequences have a relatively flat potential energy landscape for bending to a 4.1 nm radius of curvature. Random sequences that do not have the 10 bp AA repeats have less stable bent structures, and a flat rotational register distribution, such that low energy nearly planar loops are less likely.

A measure of bending in nucleic acids structures applied to A-tract DNA

A method is proposed to measure global bending in DNA and RNA structures. It relies on a properly defined averaging of base-fixed coordinate frames, computes mean frames of suitably chosen groups of bases and uses these mean frames to evaluate bending. The method is applied to DNA A-tracts, known to induce considerable bend to the double helix. We performed atomistic molecular dynamics simulations of sequences containing the A(4)T(4) and T(4)A(4) tracts, in a single copy and in two copies phased with the helical repeat. Various temperature and salt conditions were investigated. Our simulations indicate bending by roughly 10 degrees per A(4)T(4) tract into the minor groove, and an essentially straight structure containing T(4)A(4), in agreement with electrophoretic mobility data. In contrast, we show that the published NMR structures of analogous sequences containing A(4)T(4) and T(4)A(4) tracts are significantly bent into the minor groove for both sequences, although bending is less pronounced for the T(4)A(4) containing sequence. The bending magnitudes obtained by frame averaging are confirmed by the analysis of superhelices composed of repeated tract monomers.

Deforming DNA: from physics to biology

The DNA double helix has become a modern icon which symbolizes our understanding of the molecular basis of life. It is less widely recognized that the double helix proposed by Watson and Crick more than half a century ago is a remarkably adaptable molecule that can undergo major conformational rearrangements without being irreversibly damaged. Indeed, DNA deformation is an intrinsic feature of many of the biological processes in which it is involved. Over the last two decades, single-molecule experiments coupled with molecular modeling have transformed our understanding of DNA flexibility, while the accumulation of high-resolution structures of DNA-protein complexes have demonstrated how organisms can exploit this property as a useful feature for preserving, reading, replicating, and packaging the genetic message. In this Minireview we summarize the information now available on the extreme--and the less extreme--deformations of the double helix.

Focused Echocardiography in Life Support: The Subcostal Window : What the Surgeon Should Know for Critical Care Applications

CONTEXT

Focused echocardiography evaluation in life support (FEEL) for emergency and critical caremedicine is an innovative approach to introducing limited-in-scope echocardiography in a timely fashion into periresuscitation care. FEEL is an advanced life support-conformed concept and a simple procedure that can be readily used in shock roomor pre-hospital scenarios as an extension of focused abdominal sonography for trauma (FAST). The subcostal window plays a pivotal role in this context, because it can easilybe applied inthesupine position, and is usually better than other windows in patients with mechanical ventilation or during resuscitation maneuvers. Most information can be obtained at a glance.

AIM

As the FAST exam was not developed for implementation in resuscitation or cardiac arrest procedures, herewedescribe an accurate and easymethod that allows non-cardiologists to add FEEL to the FAST exam. As a result, it conforms to actual resuscitation guidelines. To perform the FEEL procedure and the subcostal window, a specific training seems to bemandatory. The aim of this paper is to set special emphasis on the use of the subcostal window.

The unique structure of A-tracts and intrinsic DNA bending

Short runs of adenines are a ubiquitous DNA element in regulatory regions of many organisms. When runs of 4–6 adenine base pairs (‘A-tracts’) are repeated with the helical periodicity, they give rise to global curvature of the DNA double helix, which can be macroscopically characterized by anomalously slow migration on polyacrylamide gels. The molecular structure of these DNA tracts is unusual and distinct from that of canonical B-DNA. We review here our current knowledge about the molecular details of A-tract structure and its interaction with sequences flanking them of either side and with the environment. Various molecular models were proposed to describe A-tract structure and how it causes global deflection of the DNA helical axis. We review old and recent findings that enable us to amalgamate the various findings to one model that conforms to the experimental data. Sequences containing phased repeats of A-tracts have from the very beginning been synonymous with global intrinsic DNA bending. In this review, we show that very often it is the unique structure of A-tracts that is at the basis of their widespread occurrence in regulatory regions of many organisms. Thus, the biological importance of A-tracts may often be residing in their distinct structure rather than in the global curvature that they induce on sequences containing them.

Magnitude and direction of DNA bending induced by screw-axis orientation: influence of sequence, mismatches and abasic sites

DNA-bending flexibility is central for its many biological functions. A new bending restraining method for use in molecular mechanics calculations and molecular dynamics simulations was developed. It is based on an average screw rotation axis definition for DNA segments and allows inducing continuous and smooth bending deformations of a DNA oligonucleotide. In addition to controlling the magnitude of induced bending it is also possible to control the bending direction so that the calculation of a complete (2-dimensional) directional DNA-bending map is now possible. The method was applied to several DNA oligonucleotides including A(adenine)-tract containing sequences known to form stable bent structures and to DNA containing mismatches or an abasic site. In case of G:A and C:C mismatches a greater variety of conformations bent in various directions compared to regular B-DNA was found. For comparison, a molecular dynamics implementation of the approach was also applied to calculate the free energy change associated with bending of A-tract containing DNA, including deformations significantly beyond the optimal curvature. Good agreement with available experimental data was obtained offering an atomic level explanation for stable bending of A-tract containing DNA molecules. The DNA-bending persistence length estimated from the explicit solvent simulations is also in good agreement with experiment whereas the adiabatic mapping calculations with a GB solvent model predict a bending rigidity roughly two times larger.

Kinking occurs during molecular dynamics simulations of small DNA minicircles

Recent experiments on minicircle formation suggest that a conformational mechanism other than smooth deformation may be playing a role in enhancing DNA flexibility. Both local base unpairing and kink formation have been suggested as possible explanations. Although kinks within isolated DNA were proposed 30 years ago, they have, until now, only been observed within DNA complexed with proteins. In order to test how DNA behaves in the strong bending regime, we have carried out molecular dynamics simulations of a 94 base pair minicircle in explicit solvent with two different linking numbers, corresponding to a torsionally relaxed state and a positively supercoiled state. The simulations suggest that sharp kinks can indeed arise in small minicircles. The relaxed minicircle is generally associated with a single kink, while two kinks occur with the supercoiled state. No evidence is seen of base unpaired regions.

Helices

Helices are among the simplest shapes that are observed in the filamentary and molecular structures of nature. The local mechanical properties of such structures are often modeled by a uniform elastic potential energy dependent on bending and twist, which is what we term a rod model. Our first result is to complete the semi-inverse classification, initiated by Kirchhoff, of all infinite, helical equilibria of inextensible, unshearable uniform rods with elastic energies that are a general quadratic function of the flexures and twist. Specifically, we demonstrate that all uniform helical equilibria can be found by means of an explicit planar construction in terms of the intersections of certain circles and hyperbolas. Second, we demonstrate that the same helical centerlines persist as equilibria in the presence of realistic distributed forces modeling nonlocal interactions as those that arise, for example, for charged linear molecules and for filaments of finite thickness exhibiting self-contact. Third, in the absence of any external loading, we demonstrate how to construct explicitly two helical equilibria, precisely one of each handedness, that are the only local energy minimizers subject to a nonconvex constraint of self-avoidance.

Comparative bending dynamics in DNA with and without regularly repeated adenine tracts

The macroscopic curvature of double helical DNA induced by regularly repeated adenine tracts is well known but still puzzling. Its physical origin remains controversial even though it is perhaps the best-documented sequence modulation of DNA structure. The paper reports on comparative theoretical and experimental studies of bending dynamics in 35-mer DNA fragments. This length appears large enough for the curvature to be distinguished by gel electrophoresis. Two DNA fragments, with identical base pair composition but different sequences, are compared. In the first one, a single A-tract motif is four times repeated in phase with the helical screw whereas the second sequence is "random." Both calculations and experiments indicate that the A-tract DNA is distinguished by large static curvature and characteristic bending dynamics, suggesting that the computed effect corresponds to the experimental phenomenon. The results agree poorly with the view that DNA bending is caused by the specific local geometry of base pair stacking or binding of solvent counterions, but lend additional support to the hypothesis of a compressed frustrated state of the backbone as the principal physical cause of the static curvature. Possible ways of experimental verification of this hypothesis are discussed.

ADAPT: a molecular mechanics approach for studying the structural properties of long DNA sequences

We describe an original approach to determining sequence-structure relationships for DNA. This approach, termed ADAPT, combines all-atom molecular mechanics with a multicopy algorithm to build nucleotides that contain all four standard bases in variable proportions. These nucleotides enable us to search very rapidly for base sequences that energetically favor chosen types of DNA deformation or chosen DNA-protein or DNA-ligand interactions. Sequences satisfying the chosen criteria can be found by energy minimization, combinatorial sequence searching, or genome scanning, in a manner similar to the threading approaches developed for protein structure prediction. In the latter case, we are able to analyze roughly 2000 base pairs per second. Applications of the method to DNA allomorphic transitions, DNA deformation, and specific DNA interactions are presented.

Molecular dynamics simulations of B '-DNA: sequence effects on A-tract-induced bending and flexibility

Molecular dynamics (MD) simulations including water and counterions are reported on five examples of A-tract DNA oligonucleotide dodecamer duplexes for which crystal structures are available, the homopolymeric duplex sequences poly(dA) and poly(dG), and two related sequences that serve as controls. MD was performed using the AMBER suite of programs for 3 ns on each sequence. These results, combined with previously reported MDs on 25-mer and 30-mer oligonucleotides on sequences with phased A-tracts carried out under a similar simulation protocol, are used to examine salient issues in the structural chemistry of ApA steps and A-tract induced axis bending. MD modeling successfully describes the distinctive B' structure of A-tracts in solution as essentially straight (wedge angles of <1 degrees ), more rigid than generic B-form DNA, with slight base-pair inclination, high propeller twist and a minor groove narrowing 5' to 3'. The MD structures in solution agree closely with corresponding crystal structures, supporting the idea that crystal structures provide a good model for A-tract DNA structure in solution. From the collective MD results, bending and flexibility are calculated by step. Pyrimidine-purine steps are predicted to be most intrinsically bent and also most bendable, i.e. susceptible to bending. Pyrimidine-pyrimidine ( approximately purine-purine) and purine-pyrimidine steps show less intrinsic deformation and deformability. The MD calculated flexibility correlates well with the protein-induced bendability derived independently from the protein DNA crystal structures. The MD results indicate that bending and flexibility of base-pair steps in DNA are highly correlated, i.e. steps that exhibit the most intrinsic deformation from B-form DNA turn are also the most dynamically deformable. The MD description of A-tract-induced axis bending shows most consistency with the non A-tract, general-sequence model, in which the sequence curvature originates primarily in base-pair roll towards the major groove in non-A-tract regions of the sequence, particularly pyrimidine-purine steps. The direction of curvature is towards the minor groove viewed from opposite the A-tracts, but the A-tracts per se exhibit only minor deformation. The MD results are found to be consistent with the directionality of bending inferred for DNA sequences from gel retardation and cyclization experiments.

Molecular dynamics studies of sequence-directed curvature in bending locus of trypanosome kinetoplast DNA

The macroscopic curvature induced in the double helical B-DNA by regularly repeated adenine tracts (A-tracts) plays an exceptional role in structural studies of DNA because this effect presents the most well documented example of sequence specific conformational modulations. Recently, a new hypothesis of its physical origin has been put forward. According to it, the intrinsic bends in B-DNA may represent one of the consequences of the compressed frustrated state of its backbone. The compressed backbone hypothesis agrees with many data and explains some controversial experimental observations. The original arguments of this theory came out from MD simulations of a DNA fragment with a strong bending propensity. Its sequence, however, was not experimental. It was constructed empirically so as to maximize the magnitude of bending in calculations. To make sure that our computations reproduce the experimental effect we carried out similar simulations with an A-tract repeat of a natural base pair sequence found in a bent locus of a minicircle DNA. We demonstrate spontaneous development of static curvature in the course of MD simulations excluding any initial bias except the base pair sequence. Its direction and magnitude agree with experimental estimates. The results confirm earlier qualitative conclusions and agree with the hypothesis of a compressed backbone as the origin of static bending in B-DNA.

Modeling multi-component protein-DNA complexes: the role of bending and dimerization in the complex of p53 dimers with DNA

We used molecular modeling to study the optimal conformation of the complex between two p53 DNA-binding domain monomers and a 12 base-pair target DNA sequence. The complex was constructed using experimental data on the monomer binding conformation and a new approach to deform the target DNA sequence. Combined with an internal/helicoidal coordinate model of DNA, this approach enables us to bend the target sequence in a controlled way while respecting the contacts formed with each p53 monomer. The results show that the dimeric complex favors DNA bending towards the major groove at the dimer junction by a value close to experimental findings. In contrast to inferences from earlier models, the calculation of key contributions to the free energy of the complexes indicates a determinant role for DNA in the formation of the complex with the dimer of the p53 DNA-binding domains.

Intrinsic bending in GGCC tracts as probed by fluorescence resonance energy transfer

Double-stranded oligonucleotides containing the sequence 5'-GGCC-3' can be intrinsically bent, according to X-ray crystallography and gel electrophoresis mobility studies. We have performed fluorescence resonance energy transfer (FRET) experiments with dye-labeled oligonucleotides to further investigate the solution structure of this sequence. We find that 5'-GGCC-3'-containing oligonucleotides bring 5'-attached donor and acceptor dyes much closer together than a comparable "straight" sequence that contains 5'-GCGC-3'. The bend angle for the 5'-GGCC-3' sequence is estimated to be approximately 70 degrees, much larger than the crystallographically observed 23 degrees kink but in agreement with other FRET work. In contrast to gel electrophoresis studies, divalent metal ions do not promote increased kinking in 5'-GGCC-3' above background as judged by FRET. Thus, sequence-dependent structural effects in DNA may be a complicating feature of FRET experiments.

Optimization of nucleic acid sequences

Base sequence influences the structure, mechanics, dynamics, and interactions of nucleic acids. However, studying all possible sequences for a given fragment leads to a number of base combinations that increases exponentially with length. We present here a novel methodology based on a multi-copy approach enabling us to determine which base sequence favors a given structural change or interaction via a single energy minimization. This methodology, termed ADAPT, has been implemented starting from the JUMNA molecular mechanics program by adding special nucleotides, "lexides," containing all four bases, whose contribution to the energy of the system is weighted by continuously variable coefficients. We illustrate the application of this approach in the case of double-stranded DNA by determining the optimal sequences satisfying structural (B-Z transition), mechanical (intrinsic curvature), and interaction (ligand-binding) properties.

DNA rings with multiple energy minima

Within the context of DNA rings, we analyze the relationship between intrinsic shape and the existence of multiple stable equilibria, either nicked or cyclized with the same link. A simple test, based on a perturbation expansion of symmetry breaking within a continuum elastic rod model, provides good predictions of the occurrence of such multiple equilibria. The reliability of these predictions is verified by direct computation of nicked and cyclized equilibria for several thousand DNA minicircles with lengths of 200 and 900 bp. Furthermore, our computations of equilibria for nicked rings predict properties of the equilibrium distribution of link, as calculated by much more computationally intensive Monte Carlo simulations.

Modeling DNA deformations

Recent developments have been made in modeling double-helical DNA at four levels of three-dimensional structure: the all-atom level, whereby an oligonucleotide duplex is surrounded by a shroud of solvent molecules; the base-pair level, with explicit backbone atoms; the mesoscopic level, that is, a few hundred base pairs, with the local duplex conformation described by knowledge-based harmonic energy functions; and the scale of several thousand nucleotides, with the duplex described as an ideal elastic rod. Predictions of the sequence-dependent bending and twisting of the double helix, as well as solvent- and force-induced B-->A and over-stretching conformational transitions, are compared with experimental data. These subtle conformational changes are critical to the functioning of the double helix, including its packaging in the close confines of the cell, the mutual fit of DNA and protein in nucleoprotein complexes, and the effective recognition of base pairs in recombination and transcription.

The impact of abasic sites on DNA flexibility

We use internal coordinate molecular mechanics calculations to study the impact of abasic sites on the conformation and the mechanics of the DNA double helix. Abasic sites, which are common mutagenic lesions, are shown to locally modify both the groove geometry and the curvature of DNA in a sequence dependent manner. By controlled twisting and bending, it is also shown that these lesions modify the deformability of the duplex, generally increasing its flexibility, but again to an extent which depends on the nature of the abasic site and on the surrounding base sequence. Both the conformational and mechanical influence of this type of DNA damage may be significant for recognition and repair mechanisms.

Abasic sites in duplex DNA: molecular modeling of sequence-dependent effects on conformation

Molecular modeling calculations using JUnction Minimization of Nucleic Acids (JUMNA) have been used to study sequence effects on the conformation of abasic sites within duplex DNA. We have considered lesions leading to all possible unpaired bases (X), adenine, guanine, cytosine, or thymine contained within two distinct sequence contexts, CXC and GXG. Calculations were carried out on DNA 11-mers using extensive conformational search techniques to locate the most stable abasic conformations and using Poisson-Boltzmann corrected electrostatics to account for solvation effects. The results, which are in very good agreement with available experimental data, point to strong sequence effects on both the position of the unpaired base (intra or extrahelical) and on the overall curvature induced by the abasic lesion. For CXC, unpaired purines are found to lie within the helix, while unpaired pyrimidines are either extrahelical or in equilibrium between the intra and extrahelical forms. For GXG, all unpaired bases lead to intrahelical forms, but with marked, sequence-dependent differences in induced curvature.

TIT for TAT: the properties of inosine and adenosine in TATA box DNA

The sequence dependent conformation, flexibility and hydration properties of DNA molecules constitute selectivity determinants in the formation of protein-DNA complexes. TATA boxes in which AT basepairs (bp) have been substituted by IC bp (TITI box) allow for probing these selectivity determinants for the complexation with the TATA box-binding protein (TBP) with different sequences but identical chemical surfaces. The reference promoter Adenovirus 2 Major Late Promoter (mlp) is formed by the apposition of two sequences with very different dynamic properties: an alternating TATA sequence and an A-tract. For a comparative study, we carried out molecular dynamics simulations of two DNA oligomers, one containing the mlp sequence (2 ns), and the other an analog where AT basepairs were substituted by IC basepairs (1 ns). The simulations, carried out with explicit solvent and counterinons, yield straight purine tracts, the A-tract being stiffer than the I-tract, an alternating structure for the YRYR tracts, and hydration patterns that differ between the purine tracts and the alternating sequence tracts. A detailed analysis of the proposed interactions responsible for the stiffness of the purine tracts indicates that the stacking between the bases bears the strongest correlation to stiffness. The hydration properties of the minor groove in the two oligomers are distinctly different. Such differences are likely to be responsible for the stronger binding of TBP to mlp over the inosine-substituted variant. The calculations were made possible by the development, described here, of a new set of forcefield parameters for inosine that complement the published CHARMM all-hydrogen nucleic acid parametrization.

Molecular dynamics studies of axis bending in d(G5-(GA4T4C)2-C5) and d(G5-(GT4A4C)2-C5): effects of sequence polarity on DNA curvature

Gel retardation studies and other experiments indicate that DNA sequences containing the d(GA4T4C)n motif are curved, whereas those of identical composition but with a reverse sequence polarity, the d(GT4A4C)n motif, are straight. Hydroxyl radical cleavage experiments show that d(GA4T4C)n shows a unique signature, whereas d(GT4A4C)n behaves normally. To explain these results at a molecular level, molecular dynamics (MD) simulations were performed on the DNA duplexes d(G5-(GA4T4C)2-C5) and d(G5-(GT4A4C)2-C5) to 3.0 and 2.5 ns, respectively. The MD simulations are based on the Cornell force field implemented in the AMBER 4.1 modeling package and performed in a neutral solution of anionic DNA with K+, Cl- and Mg2+ at concentrations roughly comparable to a ligase buffer. Long range interactions were treated by the particle mesh Ewald method. Analysis of the results shows that the calculated dynamical structure of d(G5-(GA4T4C)2-C5) exhibits strong gross curvature, consistent with the observed behavior. The most significant locus of curvature in the MD structure is found at the central C15-G16 step, with an average roll angle of 12.8(+/-6.40)deg. The d(G5-(GT4A4C)2-C5) MD structure exhibited significantly less gross curvature. Analysis of results indicates that the reduction in gross curvature in the d(G5-(GT4A4C)2-C5) trajectory originates from the effect of the T10-A11 and T20-A21 steps, which showed average roll angles of 12.5(+/-5)deg. These three steps, T10-A11, C15-G16 and T20-A21, are half-helix turns away from one another, and their contributions to concerted bending cancel out. The A-tracts in the MD structure are essentially straight. The dynamical structure of d(G5-(GA4T4C)2-C5) exhibited minor groove deformation comprised of expansion at the 5' end of A-tracts and progressive narrowing towards the 3' end, consistent with and elaborating the interpretation of hydroxyl radical chemical probing results.

Sequence-dependent dynamics of TATA-Box binding sites

We have carried out two nanosecond-length molecular dynamics simulations on a DNA oligomer, d(GCGTAAAAAAAACGC)2, which contains a weak binding site for the TATA-box binding protein. An analysis of the resulting trajectories shows that this oligomer behaves differently from a related oligomer [d(GCGTATATAAAACGC)2] studied earlier using the same protocol (Flatters, D., M. Young, D. L. Beveridge, and R. Lavery. 1997. Conformational properties of the TATA-box binding sequence of DNA. J. Biomol. Struct. & Dyn. 14:757-765), and which contains a strong binding site for the same protein. The two basepair mutations that relate these oligomers lead to significant changes in time-averaged structure and in dynamic behavior, which extend over entire length of the oligomer and appear to be compatible with the experimentally observed decrease of binding and functional activity. These results suggest that molecular dynamics simulations, taking into account explicit solvent and counterions, and avoiding the truncation of electrostatic interactions, are a powerful tool for investigating the indirect aspects of protein-nucleic acid recognition.

DNA bending by small, mobile multivalent cations

We propose a purely electrostatic mechanism by which small, mobile, multivalent cations can induce DNA bending. A multivalent cation binds at the entrance to the B-DNA major groove, between the two phosphate strands, electrostatically repelling sodium counterions from the neighboring phosphates. The unscreened phosphates on both strands are strongly attracted to the groove-bound cation. This leads to groove closure, accompanied by DNA bending toward the cationic ligand. We explicitly treat the dynamic character of the cation-DNA interaction using an adiabatic approximation, noting that DNA bending is much slower than the diffusion of nonspecifically bound, mobile cations. We make semiquantitative estimates of the free energy components of bending-electrostatic (with a sigmoidal distance-dependent dielectric function), elastic, and entropic cation localization-and find that the equilibrium state is bent B-DNA stabilized with a self-localized cation. This is a bending polaron, formation of which should be critically dependent on the strength of electrostatic interaction and the concentration of highly mobile cations available for self-localization. We predict that the resultant bend will be large (approximately 20-40 degrees), smooth (because it is spread over 6 bp), and infrequent. The stability of such a bend can be variable, from transient to highly stable (static) bending, observable with standard curvature-measuring techniques. We further predict that this bending mechanism will have an unusual sequence dependence: sequences with less binding specificity will be more bent, unless the specific binding site is in the major groove.

Does TATA matter? A structural exploration of the selectivity determinants in its complexes with TATA box-binding protein

The binding of the TATA box-binding protein (TBP) to a TATA sequence in DNA is essential for eukaryotic basal transcription. TBP binds in the minor groove of DNA, causing a large distortion of the DNA helix. Given the apparent stereochemical equivalence of AT and TA basepairs in the minor groove, DNA deformability must play a significant role in binding site selection, because not all AT-rich sequences are bound effectively by TBP. To gain insight into the precise role that the properties of the TATA sequence have in determining the specificity of the DNA substrates of TBP, the solution structure and dynamics of seven DNA dodecamers have been studied by using molecular dynamics simulations. The analysis of the structural properties of basepair steps in these TATA sequences suggests a reason for the preference for alternating pyrimidine-purine (YR) sequences, but indicates that these properties cannot be the sole determinant of the sequence specificity of TBP. Rather, recognition depends on the interplay between the inherent deformability of the DNA and steric complementarity at the molecular interface.

Unusual DNA conformations

DNA is on the move across conformational space. Duplexes diversity and, joined by triplexes, quadruplexes, loops, bulges and multiarmed junctions, open the route to a bewildering array of increasingly complex conformations. In addition to this structural growth, DNA has come under increasing scrutiny thanks to the development of chemical and physical techniques for deforming its conformation and probing its properties. These investigations help us to learn more about the mechanics and the activity of this remarkably versatile macromolecule.

X-ray and solution studies of DNA oligomers and implications for the structural basis of A-tract-dependent curvature

DNA containing short periodic stretches of adenine residues (known as A-tracts), which are aligned with the helical repeat, exhibit a pronounced macroscopic curvature. This property is thought to arise from the cumulative effects of a distinctive structure of the A-tract. It has also been observed by gel electrophoresis that macroscopic curvature is largely retained when inosine bases are introduced singly into A-tracts but decreases abruptly for pure I-tracts. The structural basis of this effect is unknown. Here we describe X-ray and gel electrophoretic analyses of several oligomers incorporating adenine or inosine bases or both. We find that macroscopic curvature is correlated with a distinctive base-stacking geometry characterized by propeller twisting of the base-pairs. Regions of alternating adenine and inosine bases display large propeller twisting comparable to that of pure A-tracts, whereas the values observed for pure I-tracts are significantly smaller. We also observe in the crystal structures that propeller twist leads to close cross-strand contacts between amino groups from adenine and cytosine bases, indicating an attractive NH-N interaction, which is analogous to the NH-O interaction proposed for A-tracts. This interaction also occurs between adenine bases across an A-T step and may explain in part the different behavior of A-T versus T-A steps in the context of A-tract-induced curvature. We also note that hydration patterns may contribute to propeller-twisted conformation. Based on the present data and other structural and biophysical studies, we propose that DNA macroscopic curvature is related to the structural invariance of A-tract and A-tract-like regions conferred by high propeller twist, cross-strand interactions and characteristic hydration. The implications of these findings to the mechanism of DNA bending are discussed.

DNA curvature controls termination of plus strand DNA synthesis at the centre of HIV-1 genome

In vivo and in vitro, reverse transcriptase (RT) from human immunodeficiency virus type 1 (HIV-1) terminates plus strand synthesis at the centre of the viral genome. The central termination sequence (CTS) contains curved DNA fragments located upstream of each terminator site. Two different models, relying either on the A-tract or general sequence roll assumptions, were used to predict the extent and the direction of this curvature as well as to design mutants, which abolished it. Straightening of each curved element abolished termination at the site located immediately downstream from the curvature. When synthesis was performed on the other strand and in the opposite direction, the two curved elements C1 and C2 associated with the two termination sites Ter1 and Ter2, led again to termination of DNA synthesis. Therefore, termination occurred as a nascent bent duplex was synthesized within the template primer binding cleft of RT, even when putative strand-specific motifs have been removed by the inversion. Computation of DNA paths upstream of other known arrest sites suggested that this feature was of general relevance for termination. At the CTS, termination occurred more precisely at the 3' end of an AnTm motif (n + m = 7). The possible structures, adopted by this motif, are discussed and confronted with the present crystallographic and biochemical data obtained on HIV-1 RT-DNA interactions and on HIV-1 RT processivity.