Presence of Nonlinear Excitations in DNA Structure and their Relationship to DNA Premelting and to Drug Intercalation

Abstract

We propose that collectively localized nonlinear excitations (solitons) exist in DNA structure. These arise as a consequence of an intrinsic nonlinear ribose inversion instability that results in a modulated β alternation in sugar puckering along the polymer backbone. In their bound state, soliton-antisoliton pairs contain β premelted core regions capable of undergoing breathing motions that facilitate drug intercalation. We call such bound state structures—β premeltons. The stability of a β premelton is expected to reflect the collective properties of extended DNA regions and to be sensitive to temperature, pH, ionic strength and other thermodynamic factors. Its tendency to localize at specific nucleotide base sequences may serve to initiate site-specific DNA premelting and melting. We suggest that β premeltons provide nucleation centers important for RNA polymerase-promoter recognition. Such nucleation centers could also correspond to nuclease hypersensitive sites.     

Single-molecule studies of the stringency factors and rates governing the polymerization of RecA on double-stranded DNA

RecA is a key protein in homologous recombination. During recombination, one single-stranded DNA (ssDNA) bound to site I in RecA exchanges Watson-Crick pairing with a sequence-matched ssDNA that was part of a double-stranded DNA molecule (dsDNA) bound to site II in RecA. After strand exchange, heteroduplex dsDNA is bound to site I. In vivo, direct polymerization of RecA on dsDNA through site I does not occur, though it does in vitro. The mechanisms underlying the difference have been unclear. We use single-molecule experiments to decouple the two steps involved in polymerization: nucleation and elongation. We find that elongation is governed by a fundamental clock that is insensitive to force and RecA concentration from 0.2 and 6 μM, though rates depend on ionic conditions. Thus, we can probe nucleation site stability by creating nucleation sites at high force and then measuring elongation as a function of applied force. We find that in the presence of ATP hydrolysis a minimum force is required for polymerization. The minimum force decreases with increasing RecA or ATP concentrations. We propose that force reduces the off-rate for nucleation site binding and that nucleation site stability is the stringency factor that prevents in vivo polymerization.     

Enhanced recA protein binding to Z DNA represents a kinetic perturbation of a general duplex DNA binding pathway

recA protein binding to duplex DNA is enhanced when a B form DNA substrate is replaced with a left-handed Z form helix. This represents a kinetic rather than an equilibrium effect. Binding to Z DNA is much faster than binding to B DNA. In other respects, binding to the two DNA forms is quite similar. recA protein binds to B or Z DNA with a stoichiometry of 1 monomer/4 base pairs. The final protein filament exhibits a right-handed helical structure when either B or Z form DNAs are bound. There are only two evident differences: the kcat for ATP hydrolysis is reduced 3-4-fold when Z DNA is bound, and recA binding at equilibrium is less stable on Z DNA than on B DNA. At steady state, the binding favors B DNA in competition experiments. The results indicate that Z DNA binding by recA protein follows the same pathway as for recA binding to B DNA, but that the nucleation step is faster on the Z form helix.     

Visualizing the assembly and disassembly mechanisms of the MuB transposition targeting complex

MuB, a protein essential for replicative DNA transposition by the bacteriophage Mu, is an ATPase that assembles into a polymeric complex on DNA. We used total internal reflection fluorescence microscopy to observe the behavior of MuB polymers on single molecules of DNA. We demonstrate that polymer assembly is initiated by a stochastic nucleation event. After nucleation, polymer assembly occurs by a mechanism involving the sequential binding of small units of MuB. MuB that bound to A/T-rich regions of the DNA assembled into large polymeric complexes. In contrast, MuB that bound outside of the A/T-rich regions failed to assemble into large oligomeric complexes. Our data also show that MuB does not catalyze multiple rounds of ATP hydrolysis while remaining bound to DNA. Rather, a single ATP is hydrolyzed, then MuB dissociates from the DNA. Finally, we show that "capping" of the enhanced green fluorescent protein-MuB polymer ends with unlabeled MuB dramatically slows, but does not halt, dissociation. This suggests that MuB dissociation occurs through both an end-dependent mechanism and a slower mechanism wherein subunits dissociate from the polymer interior.     

Two time constants for the binding of proteins to DNA from micromechanical data

Recent experimental advances allow the direct measurement of the force/extension behavior for DNA in the presence of strongly binding proteins. Such experiments reveal information about the cooperative mechanism of protein binding. We have studied the irreversible binding of such proteins to DNA using a simple simulation and present a method for estimating quantitative rate constants for the nucleation and growth of linear domains of proteins bound to DNA. Such rate constants also give information about the relative energetics of the two binding processes. We discuss our results in the context of recent data for the DNA-recA-ATPgammas system, for which the nucleation time is 4.7 x 10(4) min per recA binding site and the total growth rate of each domain is 1400 recA/min.     

DNA structure and aspartate 276 influence nucleotide binding to human DNA polymerase beta. Implication for the identity of the rate-limiting conformational change

Structures of DNA polymerase (pol) beta bound to single-nucleotide gapped DNA had revealed that the lyase and pol domains form a "doughnut-shaped" structure altering the dNTP binding pocket in a fashion that is not observed when bound to non-gapped DNA. We have investigated dNTP binding to pol beta-DNA complexes employing steady-state and pre-steady-state kinetics. Although pol beta has a kinetic scheme similar to other DNA polymerases, polymerization by pol beta is limited by at least two partially rate-limiting steps: a conformational change after dNTP ground-state binding and product release. The equilibrium binding constant, K(d)((dNTP)), decreased and the insertion efficiency increased with a one-nucleotide gapped DNA substrate, as compared with non-gapped DNA. Valine substitution for Asp(276), which interacts with the base of the incoming nucleotide, increased the binding affinity for the incoming nucleotide indicating that the negative charge contributed by Asp(276) weakens binding and that an interaction between residue 276 with the incoming nucleotide occurs during ground-state binding. Since the interaction between Asp(276) and the nascent base pair is observed only in the "closed" conformation of pol beta, the increased free energy in ground-state binding for the mutant suggests that the subsequent rate-limiting conformational change is not the "open" to "closed" structural transition, but instead is triggered in the closed pol conformation.     

Influence of ligands characteristic of selective binding to a certain type of base pairs on DNA helix-coil transition I. Model. Theory

The DNA helix-coil transition in the presence of ligands interacting selectively with a certain type or types of base pairs has been considered. A calculation method for estimation the influence of lignads on the melting process for which the knowledge of DNA primary structure is not required was proposed. It has been shown that the reverse temperature shift caused by ligands bound to a given type of base pairs at given kind of regions (helix or coli) is in direct proportion to the fist derivative with respect to the degree of helicity from ratio beta ji/n, where beta ji--number of nitrogen bases of i-type at the regions of j-kind; N--total number of DNA base pairs. It was assumed earlier that this shift was in direct proportion to beta ji/Nj, where Nj--number of base pairs in DNA regions of j-kind. The specificity of lignads interaction with given kinds of bases alters the manner of the melting process of the heteropolynucleotide in comparison with homopolynucleotide only in the case when the DNA primary structure has a strong influence on the position of helix and coli regions along the DNA chain. Only when this conditions is fulfilled the inversion of thermostability of AT- and GC-pairs may affect the shape of the melting curve.     

BstYI bound to noncognate DNA reveals a "hemispecific" complex: implications for DNA scanning

DNA recognition by proteins is essential for specific expression of genes in a living organism. En route to a target DNA site, a protein will often sample noncognate DNA sites through nonspecific protein-DNA interactions, resulting in a variety of conformationally different binding states. We present here the crystal structure of endonuclease BstYI bound to a noncognate DNA. Surprisingly, the structure reveals the enzyme in a "hemispecific" binding state on the pathway between nonspecific and specific recognition. A single base pair change in the DNA abolishes binding of only one monomer, with the second monomer bound specifically. We show that the enzyme binds essentially as a rigid body, and that one end of the DNA is accommodated loosely in the binding cleft while the other end is held tightly. Another intriguing feature of the structure is Ser172, which has a dual role in establishing nonspecific and specific contacts. Taken together, the structure provides a snapshot of an enzyme in a "paused" intermediate state that may be part of a more general mechanism of scanning DNA.     

Structure of PvuII endonuclease with cognate DNA.

We have determined the structure of PvuII endonuclease complexed with cognate DNA by X-ray crystallography. The DNA substrate is bound with a single homodimeric protein, each subunit of which reveals three structural regions. The catalytic region strongly resembles structures of other restriction endonucleases, even though these regions have dissimilar primary sequences. Comparison of the active site with those of EcoRV and EcoRI endonucleases reveals a conserved triplet sequence close to the reactive phosphodiester group and a conserved acidic pair that may represent the ligands for the catalytic cofactor Mg2+. The DNA duplex is not significantly bent and maintains a B-DNA-like conformation. The subunit interface region of the homodimeric protein consists of a pseudo-three-helix bundle. Direct contacts between the protein and the base pairs of the PvuII recognition site occur exclusively in the major groove through two antiparallel beta strands from the sequence recognition region of the protein. Water-mediated contacts are made in the minor grooves to central bases of the site. If restriction enzymes do share a common ancestor, as has been proposed, their catalytic regions have been very strongly conserved, while their subunit interfaces and DNA sequence recognition regions have undergone remarkable structural variation.     

Nucleotide binding to DNA gyrase causes loss of DNA wrap

DNA gyrase negatively supercoils DNA in a reaction coupled to the binding and hydrolysis of ATP. Limited supercoiling can be achieved in the presence of the non-hydrolysable ATP analogue, 5'-adenylyl beta,gamma-imidodiphosphate (ADPNP). In order to negatively supercoil DNA, gyrase must wrap a length of DNA around itself in a positive sense. In previous work, the effect of ADPNP on the gyrase-DNA interaction has been assessed but has produced conflicting results; the aim of this work was to resolve this conflict. We have probed the wrapping of DNA around gyrase in the presence and in the absence of ADPNP using direct observation by atomic force microscopy (AFM). We confirm that gyrase indeed generates a significant curvature in DNA in the absence of nucleotide and we show that the addition of ADPNP leads to a complete loss of wrap. These results have been corroborated using a DNA relaxation assay involving topoisomerase I. We have re-analysed previous hydroxyl-radical footprinting and crystallography data, and highlight the fact that the gyrase-DNA complex is surprisingly asymmetric in the absence of nucleotide but is symmetric in the presence of ADPNP. We suggest a revised model for the conformation of DNA bound to the enzyme that is fully consistent with these AFM data, in which a closed loop of DNA is stabilised by the enzyme in the absence of ADPNP and is lost in the presence of nucleotide.     

RecO and RecR Are Necessary for RecA Loading in Response to DNA Damage and Replication Fork Stress

RecA is central to maintaining genome integrity in bacterial cells. Despite the near-ubiquitous conservation of RecA in eubacteria, the pathways that facilitate RecA loading and repair center assembly have remained poorly understood in Bacillus subtilis. Here, we show that RecA rapidly colocalizes with the DNA polymerase complex (replisome) immediately following DNA damage or damage-independent replication fork arrest. In Escherichia coli, the RecFOR and RecBCD pathways serve to load RecA and the choice between these two pathways depends on the type of damage under repair. We found in B. subtilis that the rapid localization of RecA to repair centers is strictly dependent on RecO and RecR in response to all types of damage examined, including a site-specific double-stranded break and damage-independent replication fork arrest. Furthermore, we provide evidence that, although RecF is not required for RecA repair center formation in vivo, RecF does increase the efficiency of repair center assembly, suggesting that RecF may influence the initial stages of RecA nucleation or filament extension. We further identify single-stranded DNA binding protein (SSB) as an additional component important for RecA repair center assembly. Truncation of the SSB C terminus impairs the ability of B. subtilis to form repair centers in response to damage and damage-independent fork arrest. With these results, we conclude that the SSB-dependent recruitment of RecOR to the replisome is necessary for loading and organizing RecA into repair centers in response to DNA damage and replication fork arrest.     

Translesion replication by DNA polymerase beta is modulated by sequence context and stimulated by fork-like flap structures in DNA

Mutations in the human genome are clustered in hot-spot regions, suggesting that some sequences are more prone to accumulate mutations than others. These regions are therefore more likely to lead to the development of cancer. Several pathways leading to the creation of mutations may be influenced by the DNA sequence, including sensitivity to DNA damaging agents, and repair mechanisms. We have analyzed sequence context effects on translesion replication, the error-prone repair of single-stranded DNA regions carrying lesions. By using synthetic oligonucleotides containing systematic variations of sequences flanking a synthetic abasic site, we show that translesion replication by the repair polymerase DNA polymerase beta is stimulated to a moderate extent by low stacking levels of the template nucleotides downstream of the lesion, combined with homopolymeric runs flanking the lesion both upstream and downstream. A strong stimulation of translesion replication by DNA polymerase beta was seen when fork-like flap structures were introduced into the DNA substrate downstream of the lesion. Unlike for gapped substrates, this stimulation was independent of the presence of a phosphate group at the 5' terminus of the flap. These results suggest that DNA polymerase beta may participate in cellular DNA transactions involving higher order structures. The significance of these results for in vivo translesion replication is discussed.     

Occurrence of DNA structures which differ from the canonic B-form in sites of highly specific interaction with chromatin proteins

According to the three-dimensional structure of DNase I and the mechanism of its action on linear double-stranded DNA, helix regions in conformations considerably different from the canonical B-form should be resistant to endonucleolysis. A number of DNA sequences specifically bound by nonhistone factors within 5'-flanking regions of the chicken beta A-globin, beta H-globin and c-myc genes are shown to contain short DNase I-resistant DNA domains. Several examples of the occurrence of such DNase I-resistant domains within the sites for high-specific recognition by different proteins are given. The role of the DNA structural polymorphism in site-specific interaction with protein factors is discussed.     

Sequence-selective binding of phleomycin to DNA.

The binding of phleomycin and bleomycin to DNA has been investigated by studying their effects on cleavage by DNAase I and micrococcal nuclease. In the presence of cobalt, cleavage of DNA by the antibiotics is suppressed, yet they still provide protection from nuclease attack in regions surrounding the drug cleavage sites. We conclude that cleavage by phleomycin occurs at bonds around which the antibiotic is already selectively bound.     

Tightly bound to DNA proteins: possible universal substrates for intranuclear processes

Tightly bound to DNA proteins (TBPs) are a protein group that remains attached to DNA after its deproteinization by phenol, chloroform or salting-out. TBP are bound to DNA with covalent phosphotriester or non-covalent ion and hydrogen bonds. They appear to be a vast protein group involved in numerous intranuclear processes. The TBPs fraction co-purified with DNA deproteinized by mild procedures is extremely heterogeneous, tissue and species-specific. The protein fraction co-purified with DNA after harsh deproteinization procedures appears to be formed from few polypeptides common to different species and tissues. Interaction sites between DNA and TBPs depend on the physiological status of the cell. The binding sites of TBPs to DNA do not co-localize with the nuclear matrix attachment regions. We hypothesize that TBPs form a universal substrate for intranuclear processes.