Structural properties of hybrid triplex of polycation deoxyribonucleic S-methylthiourea (DNmt) strands with a complementary DNA strand, probed by nanosecond molecular dynamics

The replacement of phosphodiester linkages of the polyanion DNA with S-methylthiourea linkers provides the polycation deoxyribonucleic S-methylthiourea (DNmt). Molecular dynamics studies to 1,220 ps of the hybrid triplex formed from octameric DNmt strands d(Tmt)8 with a complementary DNA oligomer strand d(Ap)8 have been carried out with explicit water solvent and Na+Cl- counterions under periodic boundary conditions using the CHARMM force field and the Ewald summation method. The Watson-Crick and Hoogsteen hydrogen-bonding patterns of the A/T tracts remained intact without any structural restraints for triplex structures throughout the simulation. The duplex portion of the triplex structure equilibrated at a B-DNA conformation in terms of the helical rise and other helical parameters. The dynamic structures of the DNmt x DNA x DNmt triplex were determined by examining histograms from the last 800 ps of the dynamics run. These included the hydrogen-bonding pattern (sequence recognition), three-centered bifurcating occurrences, minor groove width variations, and bending of tracts for the hybrid triplex structures. Together with the Watson-Crick hydrogen-bondings, the strong Hoogsteen hydrogen-bondings, the partially maintained three-centered bifurcatings in the Watson-Crick pair, and the medium-strength three-centered bifurcatings in the Hoogsteen pair suggest that the hybrid triplex is energetically favorable as compared to a duplex with similar base stacking, van der Waals interactions, and helical parameters. This is in agreement with our previously reported thermodynamic study, in which only triplex structures were observed in solution. The bending angle measured between the local axis vectors of the first and last helical axis segments is about 20 degrees for the Watson-Crick portion of the averaged structure. Propeller twist (associated with three-centered hydrogen-bonding) up to -30 degrees, native to DNA AT base pairing, was also observed for the triplex structure. The sugar pseudorotation phase angles and the ring rotation angles for the DNA strand are within the C3'-endo domain and C2'-endo domain for the DNmt strand. Water spines are observed in both minor and major grooves throughout the dynamics run. The molecular dynamics simulations of the structural properties of DNmt x DNA x DNmt hybrid triplex is compared to the DNG x DNA x DNG hybrid triplex (In DNG the -O-(PO2-)-O- linkers in DNA is replaced by -NH-C(=N+H2)-NH-).     

Superhelical DNA with local substructures. A generalization of the topological constraint in terms of the intersection number and the ladder-like correspondence surface

The presence of certain local structural elements in superhelical DNA, such as cruciforms and denatured loops, complicates the topological and geometric analysis of these molecules. In particular, the duplex axis is often difficult to define. In consequence, the usual conservation condition, Lk = Tw + Wr, is often inapplicable as formulated in terms of the winding of either strand of the DNA about the duplex axis. We present here a more general formulation of the topological conservation condition in terms of a model in which the two strands of DNA are regarded as twisting about one another, and in which one of the two strands is considered to writhe. We define a ladder-like correspondence surface, which connects the two strands nd is independent of whether or not a unique duplex axis is locally available. These considerations lead to the definition of a new topological property of superhelical DNA, the intersection number, In. This quantity describes the complexity of a local structural element; in the case of a cruciform, for example, the intersection number is a measure of the number of duplex turns removed from the major segment of the DNA by the cruciform formation. In more general terms, the topological constraint applicable to closed circular DNA is given by Lk(W,C) + In(S,C) = Tw(W,C) + Wr (C), where W and C represent the two strands of the DNA and S is the ladder-like correspondence surface that connects the two strands.     

Type I DNA topoisomerases from mammalian cell nuclei interlock strains and promote renaturation of denatured closed circular PM2 DNA

Type I DNA topoisomerases from mouse ascites cell nuclei and from rat liver cell nuclei act on denatured viral closed circular PM2 DNA to produce molecules with a highly contracted structure as well as fully duplex non-supercoiled covalently closed circular molecules. Highly contracted DNA molecules contain a novel type of topological linkage in which a strand in one region of the double-stranded molecule passes between the strands in another region of the circular molecule one or more times. Since it is also found that the action of the topoisomerase promotes renaturation of complementary strands in denatured closed circular DNA, it is suggested that formation of contracted DNA structures proceeds through renatured, duplex intermediates with highly negative superhelix densities that contain small single-stranded regions.     

Topological constraints in nucleic acid hybridization kinetics

A theoretical examination of kinetic mechanisms for forming knots and links in nucleic acid structures suggests that molecules involving base pairs between loops are likely to become topologically trapped in persistent frustrated states through the mechanism of ‘helix-driven wrapping’. Augmentation of the state space to include both secondary structure and topology in describing the free energy landscape illustrates the potential for topological effects to influence the kinetics and function of nucleic acid strands. An experimental study of metastable complementary ‘kissing hairpins’ demonstrates that the topological constraint of zero linking number between the loops effectively prevents conversion to the minimum free energy helical state. Introduction of short catalyst strands that break the topological constraint causes rapid conversion to full duplex.     

Structural Properties of Hybrid Triplex of Polycation Deoxyribonucleic S-methylthiourea (DNmt) Strands with a Complementary DNA Strand,Probed by Nanosecond Molecular Dynamics

Abstract

The replacement of phosphodiester linkages of the polyanion DNA with S-methylthiourea linkers provides the polycation deoxyribonucleic S-methylthiourea (DNmt). Molecular dynamics studies to 1,220 ps of the hybrid triplex formed from octameric DNmt strands d(Tmt)₈ with a complementary DNA oligomer strand d(Ap)₈ have been carried out with explicit water solvent and Na counterions under periodic boundary conditions using the CHARMM force field and the Ewald summation method. The Watson-Crick and Hoogsteen hydrogen-bonding patterns of the A/T tracts remained intact without any structural restraints for triplex structures throughout the simulation. The duplex portion of the triplex structure equilibrated at a B-DNA conformation in terms of the helical rise and other helical parameters. The dynamic structures of the DNmt·DNA·DNmt triplex were determined by examining histograms from the last 800 ps of the dynamics run. These included the hydrogen-bonding pattern (sequence recognition), three-centered bifurcating occurrences, minor groove width variations, and bending of tracts for the hybrid triplex structures. Together with the Watson-Crick hydrogen-bondings, the strong Hoogsteen hydrogen-bondings, the partially maintained three-centered bifurcatings in the Watson-Crick pair, and the medium-strength three-centered bifurcatings in the Hoogsteen pair suggest that the hybrid triplex is energetically favorable as compared to a duplex with similar base stacking, van der Waals interactions, and helical parameters. This is in agreement with our previously reported thermody- namic study, in which only triplex structures were observed in solution. The bending angle measured between the local axis vectors of the first and last helical axis segments is about 20° for the Watson-Crick portion of the averaged structure. Propeller twist (associated with three-centered hydrogen-bonding) up to ?30°, native to DNA AT base pairing, was also observed for the triplex structure. The sugar pseudorotation phase angles and the ring rotation angles for the DNA strand are within the C3′-endo domain and C2′-endo domain for the DNmt strand. Water spines are observed in both minor and major grooves throughout the dynamics run. The molecular dynamics simulations of the structural properties of DNmt·DNA·DNmt hybrid triplex is compared to the DNG·DNA·DNG hybrid triplex (In DNG the -O-(PO₂-)-O- linkers in DNA is replaced by -NH-C(=N₂)-NH-).     

Parallel stranded duplex DNA.

Three linear 21-nt oligonucleotides (C2, C3, C7) have been synthesized with different sequences of A and T residues. One pairwise combination, (C3, C7), hybridizes to form a conventional antiparallel duplex (aps-C3.C7), whereas the pair C2, C3 forms a duplex (ps-C2.C3) in which the two strands are in a parallel orientation and the A.T base-pairs in a reverse Watson-Crick configuration. The existence of the novel ps helical structure was established from the following criteria: (i) The electrophoretic mobilities of the ps and aps duplexes in native and denaturing polyacrylamide gels are similar. (ii) The ps duplex is not a substrate for T4 DNA ligase. (iii) Salt-dependent thermal transitions are observed for the two duplexes, but the melting temperatures of the ps molecules are 15 degrees C lower. (iv) The ultraviolet absorption and circular dichroism spectra of the ps duplex are indicative of a base-paired structure, but differ systematically from that of the aps helix. (v) Based on fluorescent measurements, the bis-benzimidazole drug BBI-258 shows a lower affinity for the ps compared to the aps duplex, whereas the opposite preference holds for the intercalator ethidium bromide. We conclude from the present study that parallel stranded DNA is a stable conformation which can arise by interaction between two conventional strands with appropriate sequence homology.     

Topological consideration in the theory of replication of DNA

Summary An obvious difficulty of the Watson-Crick model of DNA is that the intertwining of the strands would seem to hinder their separation during replication. The nature of the difficulty is here made precise and is called the alignment problem. It is shown that the swivelase theory, found in current textbooks and thought to overcome the difficulty, does not in fact do so. The various conceivable solutions of the alignment problem are considered and rejected, leading to the conclusion that chromosomal DNA is not double-helical. An alternative model of DNA is discussed. In addition a topological classification of DNA denaturation processes is given, and an alternative interpretation of the gel electrophoresis experiments on circular duplex DNA is suggested.     

Physical and topological properties of circular DNA

Several types of circular DNA molecules are now known. These are classified as single-stranded rings, covalently closed duplex rings, and weakly bonded duplex rings containing an interruption in one or both strands. Single rings are exemplified by the viral DNA from φX174 bacteriophage. Duplex rings appear to exist in a twisted configuration in neutral salt solutions at room temperature. Examples of such molecules are the DNA''s from the papova group of tumor viruses and certain intracellular forms of φX and λ-DNA. These DNA''s have several common properties which derive from the topological requirement that the winding number in such molecules is invariant. They sediment abnormally rapidly in alkaline (denaturing) solvents because of the topological barrier to unwinding. For the same basic reason these DNA''s are thermodynamically more stable than the strand separable DNA''s in thermal and alkaline melting experiments. The introduction of one single strand scission has a profound effect on the properties of closed circular duplex DNA''s. In neutral solutions a scission appears to generate a swivel in the complementary strand at a site in the helix opposite to the scission. The twists are then released and a slower sedimenting, weakly closed circular duplex is formed. Such circular duplexes exhibit normal melting behavior, and in alkali dissociate to form circular and linear single strands which sediment at different velocities. Weakly closed circular duplexes containing an interruption in each strand are formed by intramolecular cyclization of viral λ-DNA. A third kind of weakly closed circular duplex is formed by reannealing single strands derived from circularly permuted T2 DNA. These reconstituted duplexes again contain an interruption in each strand though not necessarily regularly spaced with respect to each other.     

Spectroscopic studies on the interaction of aristololactam-beta-D-glucoside with DNA and RNA double and triple helices: A comparative study.

The interaction of aristololactam-beta-D-glucoside (ADG), a DNA intercalating alkaloid, with the DNA triplexes, poly(dT). poly(dA)xpoly(dT) and poly(dC).poly(dG)xpoly(dC+), and the RNA triplex poly(rU).poly(rA)xpoly(rU) was investigated by circular dichroic, UV melting profile, spectrophotometric, and spectrofluorimetric techniques. Comparative interaction with the corresponding Watson-Crick duplexes has also been examined under identical experimental conditions. Triplex formation has been confirmed from biphasic thermal melting profiles and analysis of temperature-dependent circular dichroic measurements. The binding of ADG to triplexes and duplexes is characterized by the typical hypochromic and bathochromic effects in the absorption spectrum, quenching of steady-state fluorescence intensity, a decrease in fluorescence quantum yield, an increase or decrease of thermal melting temperatures, and perturbation in the circular dichroic spectrum. Scatchard analysis indicates that ADG binds both to the triplexes and the duplexes in a noncooperative manner. Binding parameters obtained from spectrophotometric measurements are best fit by the neighbor exclusion model. The binding affinity of ADG to the DNA triplexes is substantially stronger than to the RNA triplex. Thermal melting study further indicates that ADG stabilizes the Hoogsteen base-paired third strand of the DNA triplexes whereas it destabilizes the same strand of RNA triplex but stabilizes its Watson-Crick strands. Comparative data reveal that ADG exhibits a stronger binding to the triple helical structures than to the respective double helical structures.     

The mechanics of winding and unwinding helices in recombination: torsional stress associated with strand transfer promoted by RecA protein

Homologous recombination usually involves the production of heteroduplex DNA, DNA containing strands contributed from two different duplexes. RecA protein of E. coli can promote the formation of heteroduplex DNA in vitro by the exchange of DNA strands between two helical structures, duplex DNA and a helical recA nucleoprotein filament containing a single strand of DNA. Complete unwinding of the parental duplex and the rewinding of one strand with a new complement requires rotation of the helical structures about one another, or about their respective longitudinal axes. The observations described here demonstrate an association of torsional stress with strand exchange, and suggest that exchange is accomplished principally by concomitant rotation of duplex DNA and the recA nucleoprotein filament, each about its longitudinal axis.     

Unlinked strands as a topological constraint on chromosomal DNA,plasmid integration,and DNA repair

It is proposed that circular chromosomal DNA must be constrained such that the two strands are topologically unlinked. This structure can be replicated without strand breakage (nicking) by locally acting enzymes. The recently discovered form V DNA satisfies this topological constraint. The structure is likely to consist of left-handed and right-handed segments of double helix. The constraint of zero linkage has to be preserved by DNA repair, plasmid insertion and by crossing over. The argument presented in this paper is a topological one, following W. F. Pohl, that linkage is a global property that cannot be measured by locally acting enzymes. In contrast to Pohl no argument in favor of a side-by-side structure is presented. A zero linkage constraint would be hereditary and compatible with a multitude of local structures.     

Structural competition involving G-quadruplex DNA and its complement

Structural competition between the G-quadruplex, the I-motif, and the Watson-Crick duplex has been implicated for repetitive DNA sequences, but the competitive mechanism of these multistranded structures still needs to be elucidated. We investigated the effects of sequence context, cation species, and pH on duplex formation by the G-quadruplex of dG(3)(T(2)AG(3))(3) and its complement the I-motif of d(C(3)TA(2))(3)C(3), using ITC, DSC, PAGE, CD, UV, and CD stopped-flow kinetic techniques. ITC and PAGE experiments confirmed Watson-Crick duplex formation by the complementary strands. The binding constant of the two DNA strands in the presence of 10 mM Mg(2+) at pH 7.0 was shown to be 5.28 x 10(7) M(-1) at 20 degrees C, about 400 times larger than that in the presence of 100 mM Na(+) at pH 5.5. The dynamic transition traces of the duplex formation from the equimolar mixture of G-/C-rich complementary sequences were obtained at both pH 7.0 and pH 5.5. Fitting to a single-exponential function gave an observed rate of 8.06 x 10(-3) s(-1) at 20 degrees C in 10 mM Mg(2+) buffer at pH 7.0, which was about 10 times the observed rate at pH 5.5 under the same conditions. Both of the observed rates increased as temperature rose, implying that the dissociation of the single-stranded structured DNAs is the rate-limiting step for the WC duplex formation. The difference between the apparent activation energy at pH 7.0 and that at pH 5.5 reflects the fact that pH significantly influences the structural competition between the G-quadruplex, the I-motif, and the Watson-Crick duplex, which also implies a possible biological role for I-motifs in biological regulation.     

Homologous pairing and topological linkage of DNA molecules by combined action of E. coli recA protein and topoisomerase I

E. coil RecA protein and topolsomerase I, acting on superhelical DNA and circular single strands in the presence of ATP and Mg²⁺, topologically link single-stranded molecules to one another, and single-stranded molecules to duplex DNA. When super-helical DNA is relaxed by prior incubation with topoisomerase, it is a poor substrate for catenation. Extensive homology stimulates the catenation of circular single-stranded DNA and superhelical DNA, whereas little reaction occurs between these forms of the closely related DNAs of phages φX174 and G4, indicating that, in conjunction with topoisomerase I, RecA protein can discriminate perfect or nearly perfect homology from a high degree of relatedness. Circular single-stranded G4 DNA reacts with superhelical DNA of a chimeric phage, M13Goril, to form catenanes, at least half of which survive heating at 80°C following restriction cleavage in the M13 region, but few of which survive following restriction cleavage in the G4 region. Electron microscopic examination of catenated molecules cleaved in the M13 region reveals that in most cases the single-stranded G4 DNA is joined to the linear duplex M13(G4) DNA in the homologous G4 region. The junction frequently has the appearance of a D loop, with an extent equivalent to 100 or more bp. We conclude that a significant fraction of catenanes were hemicatenanes, in which the single-stranded circle was topologically linked, probably by multiple turns, to its complementary strand in the duplex DNA. These observations support the previous conclusion that RecA protein can pair a single strand with its complementary strand in duplex DNA in a side-by-side fashion without a free end in any of the three strands.     

Parallel nucleic acid helices with hoogsteen base pairing: Symmetry and structure

Molecular structures for parallel DNA and RNA double helices with Hoogsteen pairing are proposed for the first time. The DNA helices have sugars in the C2′-endo region and the phosphodiester conformations are (trans, gauche^?), and the RNA helices have sugars in the C3′-endo region and the phosphodiester conformations are (gauche^?, gauche^?). A pseudorotational symmetry relates the two parallel strands of DNA helices and a screw symmetry relates the two strands of RNA helices, which have an associated tilt of the The conformational space of parallel helices with Hoogsteen base pairing, unlike the Watson-Crick duplex, is highly restricted due to the unique positioning of the symmetry axis in the former case. The features of the parallel double helix with Hoogsteen pairing are compared with the Watson-Crick duplex and the corresponding triple helix. © 1994 John Wiley & Sons, Inc.     

Probing structural factors stabilizing antisense oligonucleotide duplexes: NMR studies of a DNA.DNA duplex containing a formacetal linkage.

The duplex formed by annealing the formacetal backbone modified dodecamer d-(CGCGTTOCH2OTTGCGC) to its complementary strand, d(GCGCAAAACGCG) (duplex I), has been studied by NMR techniques and analyzed with reference to its unmodified counterpart (duplex II). Comparison of parameters such as 2D cross-peak intensities, coupling constants, and spectral patterns indicates that structural perturbations caused by the incorporation of the formacetal linkage are minimal and localized to the central T4.A4 block. Duplex I adopts a B-type helical conformation with regular Watson-Crick base pairing and normal minor groove width. The methylene group is accommodated along the phosphate backbone in a conformation similar to that of the PO2 group found in the B-form DNA family. The central T6-T7 base pairs of duplex I melt simultaneously with the duplex, indicating a cooperative transition to single strands. Although the formacetal linkage affects global melting, as evidenced by a 3 degree C reduction in Tm for duplex I with respect to duplex II, the present study indicates that this is not the result of localized premelting at the formacetal site of duplex I but rather reflects the subtle interplay of several structural and energy factors which need to be further explored.     

RecA protein promoted homologous pairing in vitro. Pairing between linear duplex DNA bound to HU Protein (nucleosome cores) and nucleoprotein filaments of recA protein-single-stranded DNA

RecA protein promotes two distinct types of synaptic structures between circular single strands and duplex DNA; paranemic joints, where true intertwining of paired strands is prohibited and the classically intertwined plectonemic form of heteroduplex DNA. Paranemic joints are less stable than plectonemic joints and are believed to be the precursors for the formation of plectonemic joints. We present evidence that under strand exchange conditions the binding of HU protein, from Escherichia coli, to duplex DNA differentially affects homologous pairing in vitro. This conclusion is based on the observation that the formation of paranemic joint molecules was not affected, whereas the formation of plectonemic joint molecules was inhibited from the start of the reaction. Furthermore, introduction of HU protein into an ongoing reaction stalls further increase in the rate of the reaction. By contrast, binding of HU protein to circular single strands has neither stimulatory nor inhibitory effect. Since the formation of paranemic joint molecules is believed to generate positive supercoiling in the duplex DNA, we have examined the ability of positive superhelical DNA to serve as a template in the formation of paranemic joint molecules. The inert positively supercoiled DNA could be converted into an active substrate, in situ, by the action of wheat germ topoisomerase I. Taken collectively, these results indicate that the structural features of the bacterial chromosome which include DNA supercoiling and organization of DNA into nucleosome-like structures by HU protein modulate homologous pairing promoted by the nucleoprotein filaments of recA protein single-stranded DNA.     

Molecular structure of deoxycytidyl-3''-methylphosphonate (RP) 5''-deoxyguanidine, d[Cp(CH3)G]. A neutral dinucleotide with Watson-Crick base pairing and a right handed helical twist.

The crystal structure of d[Cp(CH3)G] has been determined as part of a project to study the mechanism of the B----Z transition in DNA. The asymmetric unit contains two dinucleotides and the equivalent of 7.5 water molecules, partially disordered over 12 definable positions. The two symmetry-independent dinucleotides form a duplex with Watson-Crick base-pairing and a right-handed helical sense. Comparison with previously determined structures of the B and A conformation showed that this duplex is closer to B than to A but significantly different from B. It corresponds to a stretched out helix with a 4 A rise per base pair and a helical twist of 32 degrees. This structure may serve as a model for the bending of DNA in certain situations. The configuration at the methyl phosphonate is RP, and a mechanism, based on this assignment, is presented for the B----Z transition in DNA.     

Local mobility of nucleic acids as determined from crystallographic data. II. Z-form DNA

Directions and magnitudes of the local mobility of the Z-DNA hexamer duplex CpGpCpGpCpG have been determined by crystallographic refinement of anisotropic displacement parameters using the observed X-ray diffraction data. The cytidine and guanosine residues demonstrate different modes of mobility, implying that a dinucleotide is the smallest repeating unit in terms of flexibility as well as structure. Directions of librational and translational mobility of the cytidine and guanosine residues of Z-DNA are similar to those observed for the same nucleotides in B-DNA. This suggests that the local mobility of DNA is primarily determined by the individual nucleotide type and by the constraints of Watson-Crick base-pairing, rather than by helical form. Differences in the magnitudes of mobility may be responsible for some of the different physical properties of B-DNA and Z-DNA. The B to Z transition is discussed in terms of the observed flexibilities of these two helical forms.