Geometry of a branched DNA structure in solution

Molecular Insight into the Structural Dynamics of Holliday Junctions Modulated by Integration Host Factor

The integration host factor (IHF) in Escherichia coli is a nucleoid-associated protein with multifaceted roles that encompass DNA packaging, viral DNA integration, and recombination. IHF binds to double-stranded DNA featuring a 13-base pair (bp) consensus sequence with high affinity, causing a substantial bend of approximately 160° upon binding. Although wild-type IHF (WtIHF) is principally involved in DNA bending to facilitate foreign DNA integration into the host genome, its engineered counterpart, single-chain IHF (ScIHF), was specifically designed for genetic engineering and biotechnological applications. Our study delves into the interactions of both IHF variants with Holliday junctions (HJs), pivotal intermediates in DNA repair, and homologous recombination. HJs are dynamic structures capable of adopting open or stacked conformations, with the open conformation facilitating processes such as branch migration and strand exchange. Using microscale thermophoresis, we quantitatively assessed the binding of IHF to four-way DNA junctions that harbor specific binding sequences H' and H1. Our findings demonstrate that both IHF variants exhibit a strong affinity for HJs, signifying a structure-based recognition mechanism. Circular dichroism (CD) experiments unveiled the impact of the protein on the junction's conformation. Furthermore, single-molecule Förster resonance energy transfer (smFRET) confirmed the influence of IHF on the junction's dynamicity. Intriguingly, our results revealed that WtIHF and ScIHF binding shifts the population toward the open conformation of the junction and stabilizes it in that state. In summary, our findings underscore the robust affinity of the IHF for HJs and its capacity to stabilize the open conformation of these junctions.

Atomistic Picture of Opening-Closing Dynamics of DNA Holliday Junction Obtained by Molecular Simulations

Holliday junction (HJ) is a noncanonical four-way DNA structure with a prominent role in DNA repair, recombination, and DNA nanotechnology. By rearranging its four arms, HJ can adopt either closed or open state. With enzymes typically recognizing only a single state, acquiring detailed knowledge of the rearrangement process is an important step toward fully understanding the biological function of HJs. Here, we carried out standard all-atom molecular dynamics (MD) simulations of the spontaneous opening-closing transitions, which revealed complex conformational transitions of HJs with an involvement of previously unconsidered "half-closed" intermediates. Detailed free-energy landscapes of the transitions were obtained by sophisticated enhanced sampling simulations. Because the force field overstabilizes the closed conformation of HJs, we developed a system-specific modification which for the first time allows the observation of spontaneous opening-closing HJ transitions in unbiased MD simulations and opens the possibilities for more accurate HJ computational studies of biological processes and nanomaterials.

Interactions of small molecules with DNA junctions

The four natural DNA bases (A, T, G and C) associate in base pairs (A=T and G≡C), allowing the attached DNA strands to assemble into the canonical double helix of DNA (or duplex-DNA, also known as B-DNA). The intrinsic supramolecular properties of nucleobases make other associations possible (such as base triplets or quartets), which thus translates into a diversity of DNA structures beyond B-DNA. To date, the alphabet of DNA structures is ripe with approximately 20 letters (from A- to Z-DNA); however, only a few of them are being considered as key players in cell biology and, by extension, valuable targets for chemical biology intervention. In the present review, we summarise what is known about alternative DNA structures (what are they? When, where and how do they fold?) and proceed to discuss further about those considered nowadays as valuable therapeutic targets. We discuss in more detail the molecular tools (ligands) that have been recently developed to target these structures, particularly the three- and four-way DNA junctions, in order to intervene in the biological processes where they are involved. This new and stimulating chemical biology playground allows for devising innovative strategies to fight against genetic diseases.

Computational investigation of the impact of core sequence on immobile DNA four-way junction structure and dynamics

Immobile four-way junctions (4WJs) are core structural motifs employed in the design of programmed DNA assemblies. Understanding the impact of sequence on their equilibrium structure and flexibility is important to informing the design of complex DNA architectures. While core junction sequence is known to impact the preferences for the two possible isomeric states that junctions reside in, previous investigations have not quantified these preferences based on molecular-level interactions. Here, we use all-atom molecular dynamics simulations to investigate base-pair level structure and dynamics of four-way junctions, using the canonical Seeman J1 junction as a reference. Comparison of J1 with equivalent single-crossover topologies and isolated nicked duplexes reveal conformational impact of the double-crossover motif. We additionally contrast J1 with a second junction core sequence termed J24, with equal thermodynamic preference for each isomeric configuration. Analyses of the base-pair degrees of freedom for each system, free energy calculations, and reduced-coordinate sampling of the 4WJ isomers reveal the significant impact base sequence has on local structure, isomer bias, and global junction dynamics.

The structural ensemble of a Holliday junction determined by X-ray scattering interference

The DNA four-way (Holliday) junction is the central intermediate of genetic recombination, yet key aspects of its conformational and thermodynamic properties remain unclear. While multiple experimental approaches have been used to characterize the canonical X-shape conformers under specific ionic conditions, the complete conformational ensemble of this motif, especially at low ionic conditions, remains largely undetermined. In line with previous studies, our single-molecule Förster resonance energy transfer (smFRET) measurements of junction dynamics revealed transitions between two states under high salt conditions, but smFRET could not determine whether there are fast and unresolvable transitions between distinct conformations or a broad ensemble of related states under low and intermediate salt conditions. We therefore used an emerging technique, X-ray scattering interferometry (XSI), to directly probe the conformational ensemble of the Holliday junction across a wide range of ionic conditions. Our results demonstrated that the four-way junction adopts an out-of-plane geometry under low ionic conditions and revealed a conformational state at intermediate ionic conditions previously undetected by other methods. Our results provide critical information to build toward a full description of the conformational landscape of the Holliday junction and underscore the utility of XSI for probing conformational ensembles under a wide range of solution conditions.

Flexibility defines structure in crystals of amphiphilic DNA nanostars

DNA nanostructures with programmable shape and interactions can be used as building blocks for the self-assembly of crystalline materials with prescribed nanoscale features, holding a vast technological potential. Structural rigidity and bond directionality have been recognised as key design features for DNA motifs to sustain long-range order in 3D, but the practical challenges associated with prescribing building-block geometry with sufficient accuracy have limited the variety of available designs. We have recently introduced a novel platform for the one-pot preparation of crystalline DNA frameworks supported by a combination of Watson-Crick base pairing and hydrophobic forces (Brady et al 2017 Nano Lett. 17 3276-81). Here we use small angle x-ray scattering and coarse-grained molecular simulations to demonstrate that, as opposed to available all-DNA approaches, amphiphilic motifs do not rely on structural rigidity to support long-range order. Instead, the flexibility of amphiphilic DNA building-blocks is a crucial feature for successful crystallisation.

Amphiphilic-DNA Platform for the Design of Crystalline Frameworks with Programmable Structure and Functionality

The reliable preparation of functional, ordered, nanostructured frameworks would be a game changer for many emerging technologies, from energy storage to nanomedicine. Underpinned by the excellent molecular recognition of nucleic acids, along with their facile synthesis and breadth of available functionalizations, DNA nanotechnology is widely acknowledged as a prime route for the rational design of nanostructured materials. Yet, the preparation of crystalline DNA frameworks with programmable structure and functionality remains a challenge. Here we demonstrate the potential of simple amphiphilic DNA motifs, dubbed "C-stars", as a versatile platform for the design of programmable DNA crystals. In contrast to all-DNA materials, in which structure depends on the precise molecular details of individual building blocks, the self-assembly of C-stars is controlled uniquely by their topology and symmetry. Exploiting this robust self-assembly principle, we design a range of topologically identical, but structurally and chemically distinct C-stars that following a one-pot reaction self-assemble into highly porous, functional, crystalline frameworks. Simple design variations allow us to fine-tune the lattice parameter and thus control the partitioning of macromolecules within the frameworks, embed responsive motifs that can induce isothermal disassembly, and include chemical moieties to capture target proteins specifically and reversibly.

Probing the Ion Binding Site in a DNA Holliday Junction Using Förster Resonance Energy Transfer (FRET)

Holliday Junctions are critical DNA intermediates central to double strand break repair and homologous recombination. The junctions can adopt two general forms: open and stacked-X, which are induced by protein or ion binding. In this work, fluorescence spectroscopy, metal ion luminescence and thermodynamic measurements are used to elucidate the ion binding site and the mechanism of junction conformational change. Förster resonance energy transfer measurements of end-labeled junctions monitored junction conformation and ion binding affinity, and reported higher affinities for multi-valent ions. Thermodynamic measurements provided evidence for two classes of binding sites. The higher affinity ion-binding interaction is an enthalpy driven process with an apparent stoichiometry of 2.1 ± 0.2. As revealed by Eu(3+) luminescence, this binding class is homogeneous, and results in slight dehydration of the ion with one direct coordination site to the junction. Luminescence resonance energy transfer experiments confirmed the presence of two ions and indicated they are 6-7 Å apart. These findings are in good agreement with previous molecular dynamics simulations, which identified two symmetrical regions of high ion density in the center of stacked junctions. These results support a model in which site-specific binding of two ions in close proximity is required for folding of DNA Holliday junctions into the stacked-X conformation.

Self-assembly of DNA double multi-arm junctions (DMaJs)

Expanding the legendary DNA double crossover (DX) motif: pairs of multiple-arm DNA junctions have been coupled into well-behaved DX-like nanomotifs for nanoconstruction.

Crystallographic and spectroscopic studies of d(CCGGTACCGG)

The decanucleotide sequence d(CCGGTACCGG) crystallizes as a four-way junction at low cobalt ion concentrations (i.e., 1 mM). When the cobalt concentration in the crystallization solution is increased to 5 mM, the sequence crystallizes as resolved B-DNA duplexes. Gel retardation studies of the decamer show both a faint slow-moving band and a much thicker fast-moving band at low cobalt ion concentrations, and only the intense fast-moving band at higher ion concentration. Circular dichroism (CD) spectroscopy of the decamer indicates a structural transition as the cobalt ion concentration in the solution is increased, probably from B-type to A-type DNA. These studies revealed that the oligomer sequence has several conformations and structures accessible to it, in a manner dependent on sequence, ion concentration, and DNA concentration. [Supplementary materials are available for this article. Go to the publisher's online edition of Nucleosides, Nucleotides & Nucleic Acids for the following free supplemental resources(s): Supplementary Figures 1, 2, and 3.].

Molecular dynamics of a DNA Holliday junction: the inverted repeat sequence d(CCGGTACCGG)₄

All-atom molecular dynamics (MD) computer simulations have been applied successfully to duplex DNA structures in solution for some years and found to give close accord with observed results. However, the MD force fields have generally not been parameterized against unusual DNA structures, and their use to obtain dynamical models for this class of systems needs to be independently validated. The four-way junction (4WJ), or Holliday junction, is a dynamic DNA structure involved in central cellular processes of homologous replication and double strand break repair. Two conformations are observed in solution: a planar open-X form (OPN) with a mobile center and four duplex arms, and an immobile stacked-X (STX) form with two continuous strands and two crossover strands, stabilized by high salt conditions. To characterize the accuracy of MD modeling on 4WJ, we report a set of explicit solvent MD simulations of ∼100 ns on the repeat sequence d(CCGGTACCGG)(4) starting from the STX structure (PDB code 1dcw), and an OPN structure built for the same sequence. All 4WJ MD simulations converged to a stable STX structure in close accord with the crystal structure. Our MD beginning in the OPN form converts to the STX form spontaneously at both high and low salt conditions, providing a model for the conformational transition. Thus, these simulations provide a successful account of the dynamical structure of the STX form of d(CCGGTACCGG)(4) in solution, and provide new, to our knowledge, information on the conformational stability of the junction and distribution of counterions in the junction interior.

DNA nanostructures as models for evaluating the role of enthalpy and entropy in polyvalent binding

DNA nanotechnology allows the design and construction of nanoscale objects that have finely tuned dimensions, orientation, and structure with remarkable ease and convenience. Synthetic DNA nanostructures can be precisely engineered to model a variety of molecules and systems, providing the opportunity to probe very subtle biophysical phenomena. In this study, several such synthetic DNA nanostructures were designed to serve as models to study the binding behavior of polyvalent molecules and gain insight into how small changes to the ligand/receptor scaffolds, intended to vary their conformational flexibility, will affect their association equilibrium. This approach has yielded a quantitative identification of the roles of enthalpy and entropy in the affinity of polyvalent DNA nanostructure interactions, which exhibit an intriguing compensating effect.

Analysis of branched nucleic acid structure using comparative gel electrophoresis

Electrophoresis in polyacrylamide gels provides a simple yet powerful means of analyzing the relative disposition of helical arms in branched nucleic acids. The electrophoretic mobility of DNA or RNA with a central discontinuity is determined by the angle subtended between the arms radiating from the branchpoint. In a multi-helical branchpoint, comparative gel electrophoresis can provide a relative measure of all the inter-helical angles and thus the shape and symmetry of the molecule. Using the long-short arm approach, the electrophoretic mobility of all the species with two helical arms that are longer than all others is compared. This can be done as a function of conditions, allowing the analysis of ion-dependent folding of branched DNA and RNA species. Notable successes for the technique include the four-way (Holliday) junction in DNA and helical junctions in functionally significant RNA species such as ribozymes. Many of these structures have subsequently been proved correct by crystallography or other methods, up to 10 years later in the case of the Holliday junction. Just as important, the technique has not failed to date. Comparative gel electrophoresis can provide a window on both fast and slow conformational equilibria such as conformer exchange in four-way DNA junctions. But perhaps the biggest test of the approach has been to deduce the structures of complexes of four-way DNA junctions with proteins. Two recent crystallographic structures show that the global structures were correctly deduced by electrophoresis, proving the worth of the method even in these rather complex systems. Comparative gel electrophoresis is a robust method for the analysis of branched nucleic acids and their complexes.

Key experimental approaches in DNA nanotechnology

DNA nanotechnology combines unusual DNA motifs with sticky-ended cohesion to build polyhedral objects, topological targets, nanomechanical devices, and both crystalline and aperiodic arrays. The goal of DNA nanotechnology is control of the structure of macroscopic matter on the finest possible scale. Applications are expected to arise in the areas of X-ray crystallography, nanoelectronics, nanorobotics, and DNA-based computation. DNA and its close molecular relatives appear extremely well suited for these goals. This overview covers the generation of new DNA motifs, construction methods (synthesis, hybridization, phosphorylation, ligation), and a variety of methods for characterization of motifs, devices, and arrays. Finally, the use of DNA nanotechnology as a tool in biochemistry is discussed.

The stacked-X DNA Holliday junction and protein recognition

The crystal structure of the four-stranded DNA Holliday junction has now been determined in the presence and absence of junction binding proteins, with the extended open-X form of the junction seen in all protein complexes, but the more compact stacked-X structure observed in free DNA. The structures of the stacked-X junction were crystallized because of an unexpected sequence dependence on the stability of this structure. Inverted repeat sequences that contain the general motif NCC or ANC favor formation of stacked-X junctions, with the junction cross-over occurring between the first two positions of the trinucleotides. This review focuses on the sequence dependent structure of the stacked-X junction and how it may play a role in structural recognition by a class of dimeric junction resolving enzymes that themselves show no direct sequence recognition.

Stereospecific effects determine the structure of a four-way DNA junction

Conversion of a centrally located phosphate group to an electrically neutral methyl phosphonate in a four-way DNA junction can exert a major influence on its conformation. However, the effect is strongly dependent on stereochemistry. Substitution of the proR oxygen atom by methyl leads to conformational transition to the stacking conformer that places this phosphate at the point of strand exchange. By contrast, corresponding modification of the proS oxygen destabilizes this conformation of the junction. Single-molecule analysis shows that both molecules are in a dynamic equilibrium between alternative stacking conformers, but the configuration of the methyl phosphonate determines the bias of the conformational equilibrium. It is likely that the stereochemical environment of the methyl group affects the interaction with metal ions in the center of the junction.

Observing spontaneous branch migration of Holliday junctions one step at a time

Genetic recombination occurs between homologous DNA molecules via a four-way (Holliday) junction intermediate. This ancient and ubiquitous process is important for the repair of double-stranded breaks, the restart of stalled replication forks, and the creation of genetic diversity. Once formed, the four-way junction alone can undergo the stepwise exchange of base pairs known as spontaneous branch migration. Conventional ensemble assays, useful for finding average migration rates over long sequences, have been unable to examine the affect of sequence and structure on the migration process. Here, we present a single-molecule spontaneous branch migration assay with single-base pair resolution in a study of individual DNA junctions that can undergo one step of migration. Junctions exhibit markedly different dynamics of exchange between stacking conformers depending on the point of strand exchange, allowing the moment at which branch migration occurs to be detected. The free energy landscape of spontaneous branch migration is found to be highly nonuniform and governed by two types of sequence-dependent barriers, with unmediated local migration being up to 10 times more rapid than the previously deduced average rate.

Conformational model of the Holliday junction transition deduced from molecular dynamics simulations

Homologous recombination plays a key role in the restart of stalled replication forks and in the generation of genetic diversity. During this process, two homologous DNA molecules undergo strand exchange to form a four-way DNA (Holliday) junction. In the presence of metal ions, the Holliday junction folds into the stacked-X structure that has two alternative conformers. Experiments have revealed the spontaneous transitions between these conformers, but their detailed pathways are not known. Here, we report a series of molecular dynamics simulations of the Holliday junction at physiological and elevated (400 K) temperatures. The simulations reveal new tetrahedral intermediates and suggest a schematic framework for conformer transitions. The tetrahedral intermediates bear resemblance to the junction conformation in complex with a junction-resolving enzyme, T7 endonuclease I, and indeed, one intermediate forms a stable complex with the enzyme as demonstrated in one simulation. We also describe free energy minima for various states of the Holliday junction system, which arise during conformer transitions. The results show that magnesium ions stabilize the stacked-X form and destabilize the open and tetrahedral intermediates. Overall, our study provides a detailed dynamic model of the Holliday junction undergoing a conformer transition.

Functional domains of the yeast chromatin protein Sin1p/Spt2p can bind four-way junction and crossing DNA structures

Sin1p/Spt2p is a yeast chromatin protein that, when mutated or deleted, alters the transcription of a family of genes presumably by modulating local chromatin structure. In this study, we investigated the ability of different domains of this protein to bind four-way junction DNA (4WJDNA) since 4WJDNA can serve as a model for bent double helical DNA and for the crossed structure formed at the exit and entry of DNA to the nucleosomes. Sequence alignment of Sin1p/Spt2p homologues from 11 different yeast species showed conservation of several domains. We found that three domains of Sin1p/Spt2p fused to glutathione S-transferase can each bind independently in a structure-specific manner to 4WJDNA as measured in a gel mobility shift assay. A feature common to these domains is a cluster of positively charged amino acids. Modification of this cluster resulted in either abolishment of binding or a change in the binding properties. One of the domains tested clearly bound superhelical DNA, although it failed to induce bending in a circularization assay. Poly-l-lysine, which may be viewed as a cluster of positively charged amino acids, bound 4WJDNA as well. Phenotypic analysis showed that disruption of any of these domains resulted in suppression of a his4-912delta allele, indicating that each domain has functional significance. We propose that Sin1p/Spt2p is likely to modulate local chromatin structure by binding two strands of double-stranded DNA at their crossover point.

Variation of the acceptor-anticodon interstem angles among mitochondrial and non-mitochondrial tRNAs

A cloverleaf secondary structure and the concomitant "L"-shaped tertiary conformation are considered the paradigm for tRNA structure, since there appears to be very little deviation from either secondary or tertiary structural forms among the more than one dozen canonical (cloverleaf) tRNAs that have yielded to crystallographic structure determination. However, many metazoan mitochondrial tRNAs deviate markedly from the canonical secondary structure, and are often highly truncated (i.e. missing either a dihydrouridine or a TPsiC arm). These departures from the secondary cloverleaf form call into question the universality of the tertiary (L-shaped) conformation, suggesting that other structural constraints may be at play for the truncated tRNAs. To examine this issue, a set of 11 tRNAs, comprising mitochondrial and non-mitochondrial, and canonical and non-canonical species, has been examined in solution using the method of transient electric birefringence. Apparent interstem angles have been determined for each member of the set, represented as transcripts in which the anticodon and acceptor stems have each been extended by approximately 70 bp of duplex RNA helix. The measurements demonstrate much more variation in global structure than had been supposed on the basis of crystallographic analysis of canonical tRNAs. In particular, the apparent acceptor-anticodon interstem angles are more obtuse for the metazoan mitochondrial tRNAs that are truncated (missing either a dihydrouridine or a TPsiC arm) than for the canonical (cloverleaf) tRNAs. Furthermore, the magnesium dependence of this interstem angle differs for the set of truncated tRNAs compared to the canonical species.

Electrostatic Interactions and the Folding of the Four-way DNA Junction: Analysis by Selective Methyl Phosphonate Substitution

The structure and dynamics of the four-way (Holliday) junction are strongly dependent on the presence of metal ions. In this study, the importance of phosphate charge in and around the point of strand exchange has been explored by selective replacement with electrically neutral methyl phosphonate groups, guided by crystal structures of the junction in the folded, stacked X conformation. Junction conformation has been analysed by comparative gel electrophoresis and fluorescence resonance energy transfer (FRET). Three of sets of phosphate groups on the exchanging strands have been analysed; those at the point of strand exchange and those to their 3' and 5' sides. The exchanging and 3' phosphate groups form a box of negatively charged groups on the minor groove face of the junction, while the 5' phosphate groups face each other on the major groove side, with their proR oxygen atoms directed at one another. The largest effects are observed on substitution of the exchanging phosphate groups; replacement of both groups leads to the loss of the requirement for addition of metal ions to allow junction folding. When the equivalent phosphate groups on the continuous strands were substituted, a proportion of the junction folded into the alternative conformer so as to bring these phosphate groups onto the exchanging strands. These species did not interconvert, and thus this is likely to result from the alternative diasteromeric forms of the methyl phosphonate group. This shows that some of the conformational effects result from more than purely electrostatic interactions. Smaller but significant effects were observed on substitution of the flanking phosphate groups. All methyl phosphonate substitutions at these positions allowed folding to proceed at a reduced concentration of magnesium ions, with double substitutions more effective than single substitutions. Substitution of 5' phosphates resulted in a greater degree of folding at a given ionic concentration compared to the corresponding 3' phosphate substitutions. These results show that the phosphate groups at the point of strand exchange exert the largest electrostatic effect on junction folding, but a number of phosphate groups in the vicinity of the exchange region contribute to the overall effects.

Definitions and analysis of DNA Holliday junction geometry

A number of single-crystal structures have now been solved of the four-stranded antiparallel stacked-X form of the Holliday junction. These structures demonstrate how base sequence, substituents, and drug and ion interactions affect the general conformation of this recombination intermediate. The geometry of junctions had previously been described in terms of a specific set of parameters that include: (i) the angle relating the ends of DNA duplexes arms of the junction (interduplex angle); (ii) the relative rotation of the duplexes about the helix axes of the stacked duplex arms (J(roll)); and (iii) the translation of the duplexes along these helix axes (J(slide)). Here, we present a consistent set of definitions and methods to accurately calculate each of these parameters based on the helical features of the stacked duplex arms in the single-crystal structures of the stacked-X junction, and demonstrate how each of these parameters contributes to an overall conformational feature of the structure. We show that the values for these parameters derived from global rather than local helical axes through the stacked bases of the duplex arms are the most representative of the stacked-X junction conformation. In addition, a very specific parameter (J(twist)) is introduced which relates the relative orientation of the stacked duplex arms across the junction which, unlike the interduplex angle, is length independent. The results from this study provide a general means to relate the geometric features seen in the crystal structures to those determined in solution.

Topological effects on the electrophoretic mobility of rigid rodlike DNA in polyacrylamide gels

The electrophoretic migration of rigid rodlike DNA structures with well defined topologies has been investigated in polyacrylamide (PA) hydrogels prepared by copolymerization of acrylamide and N, N'-methylenebisacrylamide. Previous studies have reported structural and dynamic characteristics of linear and branched DNA during electrophoresis in PA gels using a variety of experimental parameters. However, a thorough investigation aimed at establishing specific relationships between topological features of rigid rodlike DNA structures and their electrophoretic behavior is still needed. In order to study these topological effects on mobility, an intensive examination of the electrophoretic mobility of small linear and starlike DNA was performed. A series of model DNA structures with well-defined branched topologies were synthesized with varying molecular parameters, such as number of arms surrounding the branch point and arm length. The electrophoretic mobility of these structures was then contrasted with a series of data obtained using linear DNA of comparable molecular size. When large DNA stars (M >/= 60 bp) were compared with linear DNA of identical molecular weight, the Ferguson plots were quite different. However, small DNA stars (24-32 bp) and linear analogues had identical Ferguson plots. This indicates that a different motional mode or greater interaction with the gel exists for the larger DNA stars. When the total molecular weight of the DNA stars was held constant and the number of arms varied, the Ferguson plots for all the stars were identical. Additionally, a critical pore size was reached when the ratio of linear DNA mobility to star DNA mobility increased dramatically. Thus, while the incorporation of a single branch point can produce a large reduction in mobility, above a critical molecular size, the incorporation of additional branch points does not appear to provide further reduction in mobility. This finding is consistent with the transport properties of large synthetic star polymers, where a large reduction in their diffusion coefficient is observed when a single branch is added. When additional arms are incorporated, large synthetic stars do not display an appreciable further reduction in diffusion coefficient. The effect of arm length on mobility for rigid rod DNA stars was also studied. For four-arm DNA stars, the mobility was found to scale as an exponential function of the arm length. Finally, a recently proposed phenomenological model was used to successfully fit the mobility data for linear rigid rod DNA at various concentrations of PA.

The inherent properties of DNA four-way junctions: comparing the crystal structures of holliday junctions

Holliday junctions are four-stranded DNA complexes that are formed during recombination and related DNA repair events. Much work has focused on the overall structure and properties of four-way junctions in solution, but we are just now beginning to understand these complexes at the atomic level. The crystal structures of two all-DNA Holliday junctions have been determined recently from the sequences d(CCGGGACCGG) and d(CCGGTACCGG). A detailed comparison of the two structures helps to distinguish distortions of the DNA conformation that are inherent to the cross-overs of the junctions in this crystal system from those that are consequences of the mismatched dG.dA base-pair in the d(CCGGGACCGG) structure. This analysis shows that the junction itself perturbs the sequence-dependent conformational features of the B-DNA duplexes and the associated patterns of hydration in the major and minor grooves only minimally. This supports the idea that a DNA four-way junction can be assembled at relatively low energetic cost. Both structures show a concerted rotation of the adjacent duplex arms relative to B-DNA, and this is discussed in terms of the conserved interactions between the duplexes at the junctions and further down the helical arms. The interactions distant from the strand cross-overs of the junction appear to be significant in defining its macroscopic properties, including the angle relating the stacked duplexes across the junction.

The crystal structures of DNA Holliday junctions

Nearly 40 years ago, Holliday proposed a four-stranded complex or junction as the central intermediate in the general mechanism of genetic recombination. During the past two years, six single-crystal structures of such DNA junctions have been determined by three different research groups. These structures all essentially adopt the antiparallel stacked-X conformation, but can be classified into three distinct categories: RNA-DNA junctions; ACC trinucleotide junctions; and drug-induced junctions. Together, these structures provide insight into how local and distant interactions help to define the detailed and general physical features of Holliday junctions at the atomic level.

The junction-resolving enzymes

Junction-resolving enzymes are ubiquitous nucleases that are important for DNA repair and recombination and act on DNA molecules containing branch points, especially four-way junctions. They show a pronounced selectivity for the structure of the DNA substrate but, despite its importance, the structural selectivity is not well understood. This poses an intriguing challenge in molecular recognition on a relatively large scale.

Charge transport through DNA four-way junctions

Long range oxidative damage as a result of charge transport is shown to occur through single crossover junctions assembled from four semi-complementary strands of DNA. When a rhodium complex is tethered to one of the arms of the four-way junction assembly, thereby restricting its intercalation into the pi-stack, photo-induced oxidative damage occurs to varying degrees at all guanine doublets in the assembly, though direct strand scission only occurs at the predicted site of intercalation. In studies where the Mg(2+) concentration was varied, so as to perturb base stacking at the junction, charge transport was found to be enhanced but not to be strongly localized to the arms that preferentially stack on each other. These data suggest that the conformations of four-way junctions can be relatively mobile. Certainly, in four-way junctions charge transport is less discriminate than in the more rigidly stacked DNA double crossover assemblies.

The crystal structures of psoralen cross-linked DNAs: drug-dependent formation of Holliday junctions

The single-crystal structures are presented for two DNA sequences with the thymine bases covalently cross-linked across the complementary strands by 4'-hydroxymethyl-4,5',8-trimethylpsoralen (HMT). The HMT-adduct of d(CCGCTAGCGG) forms a psoralen-induced Holliday junction, showing for the first time the effect of this important class of chemotheraputics on the structure of the recombination intermediate. In contrast, HMT-d(CCGGTACCGG) forms a sequence-dependent junction. In both structures, the DNA duplex is highly distorted at the thymine base linked to the six-member pyrone ring of the drug. The psoralen cross-link defines the intramolecular interactions of the drug-induced junction, while the sequence-dependent structure is nearly identical to the native Holliday junction of d(CCGGTACCGG) alone. The two structures contrast the effects of drug- and sequence-dependent interactions on the structure of a Holliday junction, suggesting a role for psoralen in the mechanism to initiate repair of psoralen-lesions in mammalian DNA.

DNA binding by single HMG box model proteins

The HMG1/2 family is a large group of proteins that share a conserved sequence of approximately 80 amino acids rich in basic, aromatic and proline side chains, referred to as an HMG box. Previous studies show that HMG boxes can bind to DNA in a structure-specific manner. To define the basis for DNA recognition by HMG boxes, we characterize the interaction of two model HMG boxes, one a structure-specific box, rHMGb from the rat HMG1 protein, the other a sequence-specific box, Rox1 from yeast, with oligodeoxynucleotide substrates. Both proteins interact with single-stranded oligonucleotides in this study to form 1:1 complexes. The stoichiometry of binding of rHMGb to duplex or branched DNAs differs: for a 16mer duplex we find a weak 2:1 complex, while a 4:1 protein:DNA complex is detected with a four-way DNA junction of 16mers in the presence of Mg(2+). In the case of the sequence-specific Rox1 protein we find tight 1:1 and 2:1 complexes with its cognate duplex sequence and again a 4:1 complex with four-way branched DNA. If the DNA branching is reduced to three arms, both proteins form 3:1 complexes. We believe that these multimeric complexes are relevant for HMG1/2 proteins in vivo, since Mg(2+) is present in the nucleus and these proteins are expressed at a very high level.

The Holliday junction in an inverted repeat DNA sequence: sequence effects on the structure of four-way junctions

Holliday junctions are important structural intermediates in recombination, viral integration, and DNA repair. We present here the single-crystal structure of the inverted repeat sequence d(CCGGTACCGG) as a Holliday junction at the nominal resolution of 2. 1 A. Unlike the previous crystal structures, this DNA junction has B-DNA arms with all standard Watson-Crick base pairs; it therefore represents the intermediate proposed by Holliday as being involved in homologous recombination. The junction is in the stacked-X conformation, with two interconnected duplexes formed by coaxially stacked arms, and is crossed at an angle of 41.4 degrees as a right-handed X. A sequence comparison with previous B-DNA and junction crystal structures shows that an ACC trinucleotide forms the core of a stable junction in this system. The 3'-C x G base pair of this ACC core forms direct and water-mediated hydrogen bonds to the phosphates at the crossover strands. Interactions within this core define the conformation of the Holliday junction, including the angle relating the stacked duplexes and how the base pairs are stacked in the stable form of the junction.

Thermodynamic properties of an intramolecular DNA four-way junction

We have investigated the thermodynamic properties of two homologous DNA four-way junctions, J4 and J4M, based on 46-mer linear DNA molecules. J4 and J4M have the same base sequence with the only difference that the latter contains an uncharged methylene-acetal linkage, -O3'-CH2-O5', instead of the phosphodiester linkage, -O3'-PO2-O5'-, between the residues T18 and C19. The comparison of the thermal unfolding of the J4 junction and J4M junction serves to investigate the effect of the uncharged methylene-acetal linkage on the stability of the junction. Our analysis is based on CD, UV absorbance spectroscopy, DSC, and chemical footprinting. The aim is to characterize in detail the structure and stability of the junctions. As demonstrated before by NMR, in the presence of 5 mM MgCl2 +/- 50 mM NaCl, both J4 and J4M form a complete four-way junction. This is now evidenced by protection from OsO4 cleavage (chemical footprinting). We can assume that full base pairing occurs throughout the arms even at the center of the junction. CD spectra suggest that the helices within the junctions adopt the regular B-DNA conformation. Almost identical melting temperatures and unfolding enthalpies are obtained for J4 and J4M both by UV and DSC. Furthermore, the Van't Hoff enthalpy (DeltaHVH) derived from UV melting equals the calorimetric enthalpy (DeltaHcal), which means that the melting process of the structures proceeds in a two-state manner. All results taken together support the conclusion that there are no major conformational and energetic differences between J4 and J4M. The inclusion of the uncharged methylene-acetal group into the junction has no effect on its stability.

DNA-sequence asymmetry directs the alignment of recombination sites in the FLP synaptic complex

The FLP recombinase promotes site-specific recombination in the 2 micrometer circle of Saccharomyces cerevisiae. FLP recognizes a 48 bp target site (FLP recombination target, or FRT) consisting of three 13 bp protein binding sites, or symmetry elements, flanking an 8 bp spacer region. Efficient recombination also occurs with DNA substrates that have minimal FRT sites, consisting only of the spacer and two surrounding 13 bp symmetry elements arranged in inverse orientation; thus, the wild-type spacer sequence is the main asymmetric feature of the minimal recombination site. FLP carries out recombination with many minimal target sites bearing symmetric or asymmetric mutant spacer sequences; however, the overall directionality of recombination defined in terms of inversion or excision of a DNA domain is determined by spacer-sequence asymmetry. In order to evaluate the potential influence of spacer-sequence asymmetry on structures formed during early steps in recombination, we used electron microscopy to investigate the structure of the FLP synaptic complex, which is the intermediate protein-DNA complex involved in site pairing and strand exchange. Using linear substrate DNAs that have minimal FRTs with wild-type spacer sequences, we find that 85 to 90% of the FLP synaptic complexes examined contain the two FRTs aligned in parallel. This strong preference for parallel site alignment stands in contrast with prevailing models for lambda integrase-class recombination systems, which postulate antiparallel site alignment, and results from biophysical studies on synthetic, immobile four-way DNA junctions. Our results show that the strong preference for parallel alignment can be attributed to conformational preferences of Holliday junctions present in the synaptosome.

Sequence-dependent extrusion of a small DNA hairpin at the N4 virion RNA polymerase promoters

Bacteriophage N4 virion RNA polymerase promoters contain five to seven-base inverted repeats separated by three bases and centered at position -12 from the site of transcription initiation. We have previously shown that these inverted repeats extrude as hairpins at physiological superhelical densities in a Mg(II)-dependent manner. Mg(II)-dependent hairpin extrusion at promoters P1 and P2 displays quantitative differences in reactivity to structural probes at different DNA superhelical densities, with extrusion at P2 being more favored at low superhelical density. Analyses of mutant promoters using structure-specific probes revealed that specific sequences, at the closing base-pair of the hairpin and at the loop (i.e. 5'-C-GXA-G-3' where X=G, A, T), are required for extrusion of the small promoter hairpins at physiological superhelical density. The sequence-dependent requirements for extrusion of the small N4 promoter hairpins may be generally applicable for other such sequences found both in prokaryotic and eukaryotic genomes.

Excess counterion binding and ionic stability of kinked and branched DNA

We compute the excess number of counterions associated with kinked and branched DNA, and the ionic stabilities of these structures as a function of chain length and both sodium and magnesium salt concentration, using numerical counterion condensation theory. The DNA structures are modeled as two or more finite lines of phosphate charges radiating from the kink or junction center. The number of excess counterions around the (40-90 degrees) kinked duplex is very small (at most four). The geometries of large three- and four-way DNA junctions (with > 50 base pairs per arm) in solutions containing low to moderate NaCl concentrations, by contrast, accumulate a substantial number of excess sodium ions (> 20) but no more than 15 magnesium counterions. The excess number of counterions surrounding the kinked linear chain and the branched DNA structures either remains invariant or increases with chain length, tending to reach a plateau value. Open configurations, such as the planar Y-shaped three-way junction (with three 120 degrees inter-arm angles) and the 90 degrees cross-shaped four-way junction, are ionically more stable than compact geometries, such as pyramidal three-way junctions and X-shaped four-way junctions, over the entire range of salt concentration considered (10(-5)-10(-1) M NaCl or MgCl2). The ionic stabilities of the compact forms increase with increasing salt concentration and become comparable to those of the extended geometries at high salt (especially when magnesium is the supporting salt).

Structural alterations and conformational dynamics in Holliday junctions induced by binding of a site-specific recombinase

Binding of a cleavage-incompetent mutant of the Flp recombinase induces a roughly square-planar geometry in synthetic immobile Holliday junctions. The branch points, which are rigidly fixed in these junctions in their free forms, tend to be more flexible in their protein-bound forms. Our results (1) suggest a plausible mechanism for the switching of the recombination complex from the Holliday-forming mode to the Holliday-resolving mode, (2) provide a rationale for previous observations that Flp resolves preformed immobile Holliday structures in the parental or in the recombinant mode in a relatively unbiased manner, and (3) accommodate two modes of DNA cleavage by Flp (transhorizontal or transdiagonal) in Holliday substrates.

HMG box proteins bind to four-way DNA junctions in their open conformation

The HMG box is an 80 amino acid domain found in a variety of eukaryotic chromosomal proteins and transcription factors. Binding to DNA is associated with recognition of structural distortion or manipulation of DNA structure. All the HMG box domains bind to four-way DNA junctions, which must therefore present some feature that is common to the binding targets of this wide variety of proteins. Since the four-way junction can itself adopt a variety of structures depending upon conditions, it is important to determine in which form it exists in complexes with HMG boxes. We find that a single HMG box domain is bound exclusively to the open square form of the junction and that conditions that stabilize the stacked X structure significantly lower affinity for the HMG box. We suggest that the HMG domain binds to one arm of the junction in the minor groove at the point of strand exchange and we present a model for the structure of the complex.

Processing of recombination intermediates by the RuvABC proteins

The RuvA, RuvB, and RuvC proteins in Escherichia coli play important roles in the late stages of homologous genetic recombination and the recombinational repair of damaged DNA. Two proteins, RuvA and RuvB, form a complex that promotes ATP-dependent branch migration of Holliday junctions, a process that is important for the formation of heteroduplex DNA. Individual roles for each protein have been defined, with RuvA acting as a specificity factor that targets RuvB, the branch migration motor to the junction. Structural studies indicate that two RuvA tetramers sandwich the junction and hold it in an unfolded square-planar configuration. Hexameric rings of RuvB face each other across the junction and promote a novel dual helicase action that "pumps" DNA through the RuvAB complex, using the free energy provided by ATP hydrolysis. The third protein, RuvC endonuclease, resolves the Holliday junction by introducing nicks into two DNA strands. Genetic and biochemical studies indicate that branch migration and resolution are coupled by direct interactions between the three proteins, possibly by the formation of a RuvABC complex.

Effect of DNA topology on Holliday junction resolution by Escherichia coli RuvC and bacteriophage T7 endonuclease I

Holliday junctions are key intermediates in homologous genetic recombination. Their resolution requires specialised nucleases that nick pairs of strands at the junction point, leading to the separation of mature recombinants. Resolution occurs in either of two orientations, according to which DNA strands are cut. We show that DNA topology can determine the efficiency and outcome of a recombination reaction. Using two Holliday junction resolvases, Escherichia coli RuvC protein and T7 endonuclease I, we observed that supercoiled figure-8 DNA molecules containing Holliday junctions were resolved with a specific orientation bias, and that this bias was reversed by the presence of a topological tether (catenation). In contrast, when all topological constraints were removed by restriction digestion, the recombination intermediates were resolved equally in the two orientations. These results show that topological constraints affecting Holliday junction structure influence the orientation of resolution by cellular resolvases.

Analysis of birefringence decay profiles for nucleic acid helices possessing bends: the tau-ratio approach

For nucleic acid helices in the 100-200-bp range, a central bend or point of flexibility increases the rate of rotational diffusion. In a transient electric birefringence (TEB) experiment, this increase is manifest as a reduction in the terminal (slowest) birefringence decay time. Previous experimental and theoretical work has demonstrated that the ratio of the decay times for a bent/flexible molecule and its fully duplex (linear) counterpart represents a sensitive, quantifiable measure of the apparent bend angle (tau-ratio approach). In the current work, we have examined the influence of helix parameters (e.g., persistence length, helix rise, diameter) on the tau-ratio for a given bend. The tau-ratio is found to be remarkably insensitive to variations and/or uncertainties in the helix parameters, provided that one employs bent and control molecules with the same sequence and length (apart from the bend itself). Although a single tau-ratio determination normally does not enable one to distinguish between fixed and flexible bends, such a distinction can be made from a set of tau-ratios for molecules possessing two variably phased bends. A number of additional uncertainties are examined, including errors in the estimation of the dimensions of nonhelix elements that are responsible for bends; such errors can, in principle, be estimated by performing a series of measurements for molecules of varying length.

Recognition and manipulation of branched DNA structure by junction-resolving enzymes

The junction-resolving enzymes are a class of nucleases that introduce paired cleavages into four-way DNA junctions. They are important in DNA recombination and repair, and are found throughout nature, from eubacteria and their bacteriophages through to higher eukaryotes and their viruses. These enzymes exhibit structure-selective binding to DNA junctions; although cleavage may be more or less sequence-dependent, binding affinity is purely related to the branched structure of the DNA. Binding and cleavage events can be separated for a number of the enzymes by mutagenesis, and mutant proteins that are defective in cleavage while retaining normal junction-selective binding have been isolated. Critical acidic residues have been identified in several resolving enzymes, suggesting a role in the coordination of metal ions that probably deliver the hydrolytic water molecule. The resolving enzymes all bind to junctions in dimeric form, and the subunits introduce independent cleavages within the lifetime of the enzyme-junction complex to ensure resolution of the four-way junction. In addition to recognising the structure of the junction, recent data from four different junction-resolving enzymes indicate that they also manipulate the global structure. In some cases this results in severe distortion of the folded structure of the junction. Understanding the recognition and manipulation of DNA structure by these enzymes is a fascinating challenge in molecular recognition.

Supercoil-induced extrusion of a regulatory DNA hairpin

Bacteriophage N4 virion RNA polymerase (N4 vRNAP) promoters contain inverted repeats, which form a 5- to 7-base-pair stem, 3-base loop hairpin that is required for vRNAP recognition. We show that, contrary to certain theoretical predictions, hairpin extrusion can occur at physiological superhelical densities in a Mg2+-dependent manner. Specific sequences on the template strand are required for hairpin extrusion. These sequences define stable DNA hairpins that are relatively unreactive to single strand-specific probes. In addition, a specific stable hairpin-inducing sequence can regulate transcription in vivo. Thus, a DNA structure, in its natural environment, is involved in transcriptional regulation.

The resolving enzyme CCE1 of yeast opens the structure of the four-way DNA junction

Junction-resolving enzymes exhibit structure-selective binding to DNA, but may also manipulate the DNA structure. CCE1 is a junction-resolving enzyme found in the yeast mitochondrion. To facilitate the analysis of the CCE1-junction interaction, we have exploited the sequence dependence of the cleavage reaction to devise a junction that is refractory to cleavage by this enzyme, even in the presence of magnesium ions. On binding to four-way DNA junctions, pure recombinant CCE1 opens the global structure into a 4-fold symmetrical configuration of arms with an open, chemically reactive centre. The structure of the CCE1-junction complex is independent of the sequence of the junction, and of the presence or absence of magnesium or other ions. This and other functional properties of CCE1 are strikingly similar to those of RuvC resolving enzyme of Escherichia coli.

Analysis of substrate specificity of the RuvC holliday junction resolvase with synthetic Holliday junctions

The Escherichia coli RuvC protein endonucleolytically resolves Holliday junctions, which are formed as intermediates during genetic recombination and recombination repair. Previous studies using model Holliday junctions suggested that a certain size of central core of homology and a specific sequence in the junction were required for efficient cleavage by RuvC, although not for binding. To determine the minimum length of sequence homology required for RuvC cleavage, we made a series of synthetic Holliday junctions with various lengths of homologous sequence in the core region. It was demonstrated that a monomobile junction possessing only 2 base pairs of the homology core was efficiently cleaved by RuvC. To study the sequence specificity for cleavage, we made 16 bimobile junctions, which differed only in the homologous core sequence. Among them, 6 junctions were efficiently cleaved. Cleavage occurred by introduction of nicks symmetrically at the 3'-side of thymine in all cases. However, the nucleotide bases at the 3'-side of the thymines were not always identical between the two strands nicked. These results suggest that RuvC recognizes mainly topological symmetry of the Holliday junction but not the sequence symmetry per se, that the thymine residue at the cleavage site plays an important role for RuvC-mediated resolution, and that a long homologous core sequence is not essential for cleavage.

Inverted repeats, stem-loops, and cruciforms: significance for initiation of DNA replication

Inverted repeats occur nonrandomly in the DNA of most organisms. Stem-loops and cruciforms can form from inverted repeats. Such structures have been detected in pro- and eukaryotes. They may affect the supercoiling degree of the DNA, the positioning of nucleosomes, the formation of other secondary structures of DNA, or directly interact with proteins. Inverted repeats, stem-loops, and cruciforms are present at the replication origins of phage, plasmids, mitochondria, eukaryotic viruses, and mammalian cells. Experiments with anti-cruciform antibodies suggest that formation and stabilization of cruciforms at particular mammalian origins may be associated with initiation of DNA replication. Many proteins have been shown to interact with cruciforms, recognizing features like DNA crossovers, four-way junctions, and curved/bent DNA of specific angles. A human cruciform binding protein (CBP) displays a novel type of interaction with cruciforms and may be linked to initiation of DNA replication.

Sometimes a great motion: the application of transient electric birefringence to the study of macromolecular structure

First described in the late 1800s, the phenomenon of electric birefringence is becoming increasingly useful as a probe of the solution conformations of proteins and nucleic acids. The birefringence response to a transient electric field is a sensitive indicator of the rotational motions (and hence the physical dimensions) of macromolecules in solution. Recent advances, both in instrumentation and in the efficient production of high-quality biopolymers, have dramatically increased the sensitivity and range of applicability of the method.