Index to Authors,Volume 3

Abstract

Results of calculations using various empirical potentials suggest that base pair buckling, which commonly occurs in DNA crystal structures, is sufficient to eliminate the steric clash at CpG steps in B-DNA, originating from the base pair propeller twisting. The buckling is formed by an inclination of cytosines while deviations of guanines from a plane perpendicular to the double helix axis are unfavorable. The buckling is accompanied by an increased vertical separation of the base pair centers but the buckled arrangement of base pairs is at least as stable as when the vertical separation is normal and buckle zero. In addition, room is created by the increased vertical separation for the bases to propeller twist as is observed in DNA crystal structures. Further stabilization of base stacking is introduced into the buckled base pair arrangement by roll opening the base pairs into the double helix minor groove. The roll may lead to the double helix bending and liberation of guanines from the strictly perpendicular orientation to the double helix axis. The liberated guanines further contribute to the base pair buckling and stacking improvement. This work also suggests a characteristic very stable DNA structure promoted by nucleotide sequences in which runs of purines follow runs of pyrimidine bases.     

Base Dependence of B-DNA Sugar Conformation in Solution and in the Solid State

Abstract

Analysis of 1H-NOESY solution data for eight short DNA duplexes has revealed pronounced differences between the sugar conformations of purine and pyrimidine nucleotides. It was found that the H1′-H4′ interproton distance is less than ca. 3.0 A. in pyrimidine sugars, while in purine sugars it is more than ca. 3.OA. This difference has been analyzed by comparison with the sugar conformations of highly resolved B-DNA crystal structures and model sugar conformations. The conclusion can be drawn that the deoxyribose conformation is of the general C2′-endo type but pyrimidine sugars are characterized by smaller phase angles of pseudorotation P (90°<P<150°), while purine sugars have larger P values that are greater than ca. 140° (140°<P<180°). There is no such clear base dependence of sugar conformation in highly resolved B-DNA crystal structures; however the similar trend can be seen as in the solution studies. Based on B-type DNA crystal structures, I-coupling constants have been calculated, and the applicability of experimental coupling measurements to the determination of sugar conformation is discussed.     

Nonplanar DNA Base Pairs

Abstract

Three-dimensional structures of a representative set of more than 30 hydrogen-bonded nucleic acids base pairs have been studied by reliable ab initio quantum mechanical methods. We show that many hydrogen-bonded nucleic acid base pairs are intrinsically nonplanar, mainly due to the partial sp³ hybridization of nitrogen atoms of their amino groups and secondary electrostatic interactions. This finding extends the variability of intermolecular interactions of DNA bases in that i) flexibility of the base pairs is larger than has been assumed before, and ii) attractive proton-proton acceptor interactions oriented out of the base pair plane are allowed. For example, all four G…A mismatch base pairs are propeller twisted, and the energy preferences for the nonplanar structures range from less than 0.1 kcal/mol to 1.8 kcal/mol. We predict that nonplanarity of the amino group of guanine in the G(anti)…A(anti) pair of the ApG step of the d(CCAAGATTGG)₂ crystal structure is an important stabilizing factor that improves the energy of this structure by almost 3 kcal/mol. Currently used empirical potentials are not accurate enough to properly cover the interactions associated with amino-group and base-pair nonplanarity.     

Sequence-specific transitions of the torsion angle gamma change the polar-hydrophobic profile of the DNA grooves: implication for indirect protein–DNA recognition

Variations of the shape and polarity of the DNA grooves caused by changes of the DNA conformation play an important role in the DNA readout. Despite the fact that non-canonical trans and gauche- conformations of the DNA backbone angle γ (O5′–C5′–C4′–C3′) are frequently found in the DNA crystal structures, their possible role in the DNA recognition has not been studied systematically. In order to fill in this gap, we analyze the available high-resolution crystal structures of the naked and complexed DNA. The analysis shows that the non-canonical γ angle conformations are present both in the naked and bound DNA, more often in the bound vs. naked DNA, and in the nucleotides with the A-like vs. the B-like sugar pucker. The alternative angle γ torsions are more frequently observed in the purines with the A-like sugar pucker and in the pyrimidines with the B-like sugar conformation. The minor groove of the nucleotides with non-canonical γ angle conformation is more polar, while the major groove is more hydrophobic than in the nucleotides with the classical γ torsions due to variations in exposure of the polar and hydrophobic groups of the DNA backbone. The propensity of the nucleotides with different γ angle conformations to participate in the protein–nucleic acid contacts in the minor and major grooves is connected with their sugar pucker and sequence-specific. Our findings imply that the angle γ transitions contribute to the process of the protein–DNA recognition due to modification of the polar/hydrophobic profile of the DNA grooves.     

The Crystal Structure of d(CCCCGGGG): A New A-Form Variant with an Extended Backbone Conformation

Abstract

The crystal structure of d(CCCCGGGG) has been determined at a resolution of 2.25Å. The oligomers crystallize as A-DNA duplexes occupying crystallographic two-fold axes. The backbone conformation is, in general, similar to that observed in previously reported crystal structures of A-DNA fragments, except for the central linkage, where it adopts an extended structure resulting from all trans conformation at the P-05′-C5′-C4′ bonds. This type of conformation facilitates interstrand stacking between the guanines at the C-G site. The local helix twist at this step is very small (25°) compared to an overall average of 33.5°. The unique structure of the C-G base-pair step, namely the extended backbone and the distinct stacking geometry, may be an important feature in the recognition mechanism between double- stranded DNA molecules and restriction endonucleases such as Msp I, which cuts the sequence CCGG very specifically with a rate unaffected by neighboring base pairs.     

Structure of the DNA Duplex d(ATTAAT)2 with Hoogsteen Hydrogen Bonds

The traditional Watson-Crick base pairs in DNA may occasionally adopt a Hoogsteen conformation, with a different organization of hydrogen bonds. Previous crystal structures have shown that the Hoogsteen conformation is favored in alternating AT sequences of DNA. Here we present new data for a different sequence, d(ATTAAT)₂, which is also found in the Hoogsteen conformation. Thus we demonstrate that other all-AT sequences of DNA with a different sequence may be found in the Hoogsteen conformation. We conclude that any all-AT sequence might acquire this conformation under appropriate conditions. We also compare the detailed features of DNA in either the Hoogsteen or Watson-Crick conformations.     

Interactions Between Amino Groups in DNA. An Ab Initio Study and a Comparison with Empirical Potentials

Abstract

An ab initio quantum chemical analysis of the close amino group contacts, existing in many DNA crystal structures, is presented. The calculations are made at the Hartree-Fock (HF) level with medium 6–31G* and 6–31 G(NH₂*) basis sets as well as with inclusion of correlation energy using the second order Møller-Plesset theory (MP2) with the 6–31G* basis set. We demonstrate that the model system (methylamine dimer, cytosine dimer) amino groups are forced to adopt significantly non-planar geometry to stabilize their mutual interaction. Comparison is made with a representative set of empirical potentials including AMBER, CHARMM and GROMOS. The empirical potentials are not reliable enough to analyze the amino group contacts occurring in the DNA double helices. We propose that the mutual amino group interactions contribute to the conformational variability of the CpG and ApT B-DNA steps.     

Non-B DNA conformations analysis through molecular dynamics simulations

BackgroundNon-B DNA conformations are molecular structures that do not follow the canonical DNA double helix. Mutagenetic instability in nuclear and mitochondrial DNA (mtDNA) genomes has been associated with simple non-B DNA conformations, as hairpins or more complex structures, as G-quadruplexes. One of these structures is Structure A, a cloverleaf-like non-B conformation predicted for a 93-nt (nucleotide) stretch of the mtDNA control region 5′-peripheral domain. Structure A is embedded in a hot spot for the 3′ end of human mtDNA deletions revealing its importance in influencing the mutational instability of the mtDNA genome.MethodsTo better characterize Structure A, we predicted its 3D conformation using state-of-art methods and algorithms. The methodologic workflow consisted in the prediction of non-B conformations using molecular dynamics simulations. The conservation scores of alignments of the Structure A region in humans, primates, and mammals, was also calculated.ResultsOur results show that these computational methods are able to measure the stability of non-B conformations by using the level of base pairing during molecular dynamics. Structure A showed high stability and low flexibility correlated with high conservation scores in mammalian, more specifically in primate lineages.ConclusionsWe showed that 3D non-B conformations can be predicted and characterized by our methodology. This allowed the in-depth analysis of the structure A, and the main results showed the structure remains stable during the simulations.General significanceThe fine-scale atomic molecular determination of this type of non-B conformation opens the way to perform computational molecular studies that can show their involvement in mtDNA cellular mechanisms.     

Structural Studies of DNA Fragments: The G·T Wobble Base Pair in A,B and Z DNA; The G·A Base Pair in B-DNA

Abstract

The crystal structures of five double helical DNA fragments containing non-Watson-Crick complementary base pairs are reviewed. They comprise four fragments containing G·T base pairs: two deoxyoctamers d(GGGGCTCC) and d(GGGGTCCC) which crystallise as A type helices; a deoxydodecamer d(CGCGAATTTGCG) which crystallises in the B-DNA conformation; and the deoxyhexamer d(TGCGCG), which crystallises as a Z-DNA helix. In all four duplexes the G and T bases form wobble base pairs, with bases in the major tautomer forms and hydrogen bonds linking N1 of G with 02 of T and 06 of G with N3 of T. The X-ray analyses establish that the G·T wobble base pair can be accommodated in the A, B or Z double helix with minimal distortion of the global conformation. There are, however, changes in base stacking in the neighbourhood of the mismatched bases. The fifth structure, d(CGCGAATTAGCG), contains the purine purine mismatch G·A where G is in the anti and A in the syn conformation. The results represent the first direct structure determinations of base pair mismatches in DNA fragments and are discussed in relation to the fidelity of replication and mismatch recognition.     

Mediation of the A/B-DNA helix transition by G-tracts in the crystal structure of duplex CATGGGCCCATG

The crystal structure of the DNA dodecamer duplex CATGGGCCCATG lies on a structural continuum along the transition between A- and B-DNA. The dodecamer possesses the normal vector plot and inclination values typical of B-DNA, but has the crystal packing, helical twist, groove width, sugar pucker, slide and x-displacement values typical of A-DNA. The structure shows highly ordered water structures, such as a double spine of water molecules against each side of the major groove, stabilizing the GC base pairs in an A-like conformation. The different hydration of GC and AT base pairs provides a physical basis for solvent-dependent facilitation of the A↔B helix transition by GC base pairs. Crystal structures of CATGGGCCCATG and other A/B-DNA intermediates support a ‘slide first, roll later’ mechanism for the B→A helix transition. In the distribution of helical parameters in protein–DNA crystal structures, GpG base steps show A-like properties, reflecting their innate predisposition for the A conformation.     

The Infrared and Raman Spectra of the Duplex of d(GGTATACC) in the Crystal Show Bands Due to Both the A-form and the B-form of DNA

Abstract

The deoxyoligonucleotide, d(GGTATACC), forms a duplex structure that crystallizes in the DNA A form. This has been shown by both X-ray diffraction studies and Raman spectroscopy (1,2). The presence of the DNA B form has been reported using diffuse X-ray scattering from a crystal of the closely related sequence d(GGBrUABrUACC)(3). In this paper the infrared spectrum of the d(GGTATACC) crystal is presented and curve resolution of both the Raman and IR spectra have been carried out. The percentage of A and B forms have been estimated. The %B form in the crystal has been estimated from the IR spectra to be about 15% and from Raman to be about 20%. Moreover the IR spectrum of the A conformation in the crystal is slightly different from the IR spectrum of the A conformation in polynucleotide fibers in particular in the region of the phosphate stretching vibrations and of the in-plane double bond vibrations of the bases. We show that it is feasible to obtain IR as well as Raman spectra of small crystals of oligonucleotides and that this is a good method of identifying all of the different conformations that may be in the crystal.     

Novel Hoogsteen-like Bases for Recognition of the C-G Base Pair by DNA Triplex Formation

Effective sequence-specific recognition of duplex DNA is possible by triplex formation with natural oligonucleotides via Hoogsteen H-bonding. However, triplex formation is in practice limited to pyrimidine oligonucleotides that bind duplex A-T or G-C base pair DNA sequences specifically at homopurine sites in the major groove as T·A-T and C⁺ ·G-C triplets. Here we report the successful modelling of novel unnatural nucleosides that recognize the C-G DNA base pair by Hoogsteen-like major groove interaction. These novel Hoogsteen nucleotides are examined within model A-type and B-type conformation triplex structures since the DNA triplex can be considered to incorporate A-type and/or B-type configurational properties. Using the same deoxyribose-phosphodiester and base-deoxyribose dihedral angle configuration, a triplet comprised of a C-G base pair and the novel Hoogsteen nucleotide, Y2, replaces the central T·A-T triplet in the triplex. The presence of any structural or energetic perturbations due to the central triplet in the energy-minimized triplex is assessed with respect to the unmodified energy minimized (T·A-T)₁₁ starting structures. Incorporation of this novel triplet into both A-type and B-type natural triplex structures provokes minimal change in the configuration of the central and adjacent triplets.     

Base pair buckling can eliminate the interstrand purine clash at the CpG steps in B-DNA caused by the base pair propeller twisting

Results of calculations using various empirical potentials suggest that base pair buckling, which commonly occurs in DNA crystal structures, is sufficient to eliminate the steric clash at CpG steps in B-DNA, originating from the base pair propeller twisting. The buckling is formed by an inclination of cytosines while deviations of guanines from a plane perpendicular to the double helix axis are unfavorable. The buckling is accompanied by an increased vertical separation of the base pair centers but the buckled arrangement of base pairs is at least as stable as when the vertical separation is normal and buckle zero. In addition, room is created by the increased vertical separation for the bases to propeller twist as is observed in DNA crystal structures. Further stabilization of base stacking is introduced into the buckled base pair arrangement by roll opening the base pairs into the double helix minor groove. The roll may lead to the double helix bending and liberation of guanines from the strictly perpendicular orientation to the double helix axis. The liberated guanines further contribute to the base pair buckling and stacking improvement. This work also suggests a characteristic very stable DNA structure promoted by nucleotide sequences in which runs of purines follow runs of pyrimidine bases.     

Interatomic Potentials in Conducting Polymer Systems

Abstract

Although the crystal structures of some ion-doped lattices of polyacetylene and polyparaphenylene have been investigated by diffraction methods there remain ambiguities both in the overall structures and in the precise locations of the dopant ions. We have used bonding and non-bonding interatomic potentials developed from empirical and quantum chemical data in a CASCADE atomistic lattice simulation method which permits full optimization of the lattic geometry. These calculations lead to stable structures which are consistent with diffraction data, and suggest the tendency of these lattices towards polymorphism.     

Electronmicroscopy and Circular Dichroism of the Dynamics of the Formation and Dissolution of Supramolecular Forms of Z-DNA

Abstract

Previous electronmicroscopic studies had shown that N-acetylaminofluorene (AAF)- substituted poly(dG-dC)·poly(dG-dC) in the Z conformation, in lOmM Mg^{+ +}, condensed into periodically banded, branched structures. We now show that similar structures are seen when poly(dG-dC) ·poly(dG-dC) is converted to the Z conformation by heating to 60°C in ImM Mn⁺⁺ or to 65°C in the presence of 0.5mM Mn^{+ +}. We demonstrate that these banded structures form in solution, i.e. they are not artifacts of the preparative procedures used for electronmicroscopy, by crosslinking the Z conformers in solution with DL-diepoxybutane (DEB), and then restoring the solution to conditions that favor return to the B conformation. Circular dichroism (CD) and immunochemical studies showed that the Z conformation was maintained and the banded supramolecular structures were still seen by electronmicroscopy. Electronmicroscopy and CD were also used to follow the dissolution of the supramolecular structures by controlled scission of the crosslinks with the eventual return to the short double stranded molecules typical of the B conformers. During this process, supercoiled structures, both toroidal and interwound, were observed. The relationship of the toroids to the banded structure is discussed in the context of two possible structures for the condensed polynucleotide. We conclude that DNA, whether in the B or Z conformation, is extremely flexible in the presence of appropriate counter ions, and we present evidence that earlier estimates of their persistence lengths are too high. The inherent tendency to form condensed, highly organized structures is a property of DNA that could play an important role in its “packaging,” and in its functions, and might have been critical for the evolution and replication of early life forms.     

Alternation of DNA and Solvent Layers in the A Form of d(GGCGCC) Obtainhted by Ethanol Crystallization

Abstract

We have determined by X-ray crystallography the structure of the hexamer duplex d(GGCGCC)₂ in the A-form using ethanol as a precipitant. The same sequence had previously been crystallized in the B-form, but with 2-methyl-2, 4-pentanediol as a precipitant. It appears that ethanol precipitation is a useful method to induce the formation of A-form crystals of DNA. Packing of the molecules in the crystal has unique features: the known interaction of A-DNA duplexes between terminal base-pairs and the minor groove of neighbor molecules is combined with a superstructure consisting in an alternation of DNA layers and solvent layers (water/ions). This organization in layers has been observed before, also with hexamers in the A conformation which crystallize in the same space group (C222 ₁). The solvent layer has a precise thickness, although very few ordered water molecules can be detected. Another feature of this crystal is its large unit cell, which gives rise to an asymmetric unit with three hexamer duplexes. One of the three duplexes is quite different from the other two in several aspects: the number of base pairs per turn, the twist pattern, the mean value of the twist angle and the fact that one terminal base-pair is not stacked as part of the duplex and appears to be disordered. So the variability in conformation of this sequence is remarkable.     

Left-handed DNA Crossovers. Implications for DNA-DNA Recognition and Structural Alterations

Abstract

The close approach of DNA segments participates in many biological functions including DNA condensation and DNA processing. Previous crystallographic studies have shown that B-DNA self-fitting by mutual groove-backbone interaction produces right-handed DNA crossovers. These structures have opened new perspectives on the role of close DNA-DNA interactions in the architecture and activity the DNA molecule. In the present study, the analysis of the crystal packing of two B-DNA decamer duplexes d(CCIIICCCGG) and d(CCGCCGGCGG) reveals the existence of new modes of DNA crossing. Symmetric left- handed crossovers are produced by mutual fitting of DNA grooves at the crossing point. New sequence patterns contribute to stabilize longitudinal fitting of the sugar-phosphate backbone into the major groove. In addition, the close approach of DNA segments greatly influences the DNA conformation in a sequence dependent manner. This study provides new insights into the role of DNA sequence and structure in DNA-DNA recognition. In providing detailed molecular views of DNA crossovers of opposite chirality, this study can also help to elucidate the role of symmetry and chirality in the recognition of complex DNA structures by protein dimers or tetramers, such as topoisomerase II and recombinase enzymes. These results are discussed in the context of the possible relationships between DNA condensation and DNA processing.     

Prediction of atomic structure from sequence for double helical DNA oligomers

DNA can adopt different conformations depending on the base sequence, solvent, electrolyte composition and concentration, pH, temperature, and interaction with proteins. Here we present a model for calculating the three-dimensional atomic structure of double-stranded DNA oligomers. A theoretical energy function is used for calculating the interactions within the base steps and an empirical backbone function is used to restrict the conformational space accessible to the bases and to account for the conformational coupling of neighboring steps in a sequence. Conformational searching on large structures or a large number of structures is possible, because each base step can be described by just two primary degrees of freedom (slide and shift). A genetic algorithm is used to search for low-energy structures in slide-shift space, and this allows very rapid optimization of DNA oligomers. The other base step parameters have been previously optimized for all possible slide-shift sequence combinations, and a heuristic algorithm is used to add the atomic details of the backbone conformation in the final step of the calculation. The structures obtained by this method are very similar to the corresponding X-ray crystal structures observed experimentally. The average RMSD is 2.24 Angstroms for a set of 20 oligomer structures. For 15 of these sequences, the X-ray crystal structure is the global energy minimum. The other 5 are bistable sequences that have B-form global energy minima but crystallize as A-DNA.     

Interaction Between the Guanine Amino Group and the Adenine Six Membered Ring Stabilizes the Unusual Conformation of the CpA Step in B-DNA

Abstract

The CpA step is dramatically overwound in several B-DNA oligonucleotide crystal structures and its AT pair is substantially shifted towards the cytosine of the preceding base pair and towards the minor groove. We show using a geometrical analysis of the crystal data and empirical potential calculations that a strong interaction between the guanine amino group and the adenine six membered ring is responsible for the unique conformational properties of the CpA step.     

Conformational Properties of the TATA-Box Binding Sequence of DNA

Abstract

Nanosecond scale molecular dynamics simulations in water demonstrate that the DNA oligomer, GCGTATATAAAACGC, which contains a target site for the TATA-box binding protein (TBP), has an intrinsic preference to adopt an A-like conformation in the region of the TATA-box and undergoes bending related to that seen within in the TBP complex. This result is obtained from two independent simulations using different starting structures. In line with earlier suggestions of Guzikevich-Guerstein and Shakked, these simulations imply that an A-DNA conformation may be an important intermediate step in forming the strongly distorted DNA observed within the crystallographically determined complex with TBP. These results also support modeling studies by Lebrun et al. which suggest that the TBP binding mechanism can be broken down into a backbone transition to an A-like form coupled with a mechanical distortion which locally stretches and unwinds the DNA.