A unified model for the origin of DNA sequence-directed curvature

The fine structure of the DNA double helix and a number of its physical properties depend upon nucleotide sequence. This includes minor groove width, the propensity to undergo the B-form to A-form transition, sequence-directed curvature, and cation localization. Despite the multitude of studies conducted on DNA, it is still difficult to appreciate how these fundamental properties are linked to each other at the level of nucleotide sequence. We demonstrate that several sequence-dependent properties of DNA can be attributed, at least in part, to the sequence-specific localization of cations in the major and minor grooves. We also show that effects of cation localization on DNA structure are easier to understand if we divide all DNA sequences into three principal groups: A-tracts, G-tracts, and generic DNA. The A-tract group of sequences has a peculiar helical structure (i.e., B*-form) with an unusually narrow minor groove and high base-pair propeller twist. Both experimental and theoretical studies have provided evidence that the B*-form helical structure of A-tracts requires cations to be localized in the minor groove. G-tracts, on the other hand, have a propensity to undergo the B-form to A-form transition with increasing ionic strength. This property of G-tracts is directly connected to the observation that cations are preferentially localized in the major groove of G-tract sequences. Generic DNA, which represents the vast majority of DNA sequences, has a more balanced occupation of the major and minor grooves by cations than A-tracts or G-tracts and is thereby stabilized in the canonical B-form helix. Thus, DNA secondary structure can be viewed as a tug of war between the major and minor grooves for cations, with A-tracts and G-tracts each having one groove that dominates the other for cation localization. Finally, the sequence-directed curvature caused by A-tracts and G-tracts can, in both cases, be explained by the cation-dependent mismatch of A-tract and G-tract helical structures with the canonical B-form helix of generic DNA (i.e., a cation-dependent junction model).     

Sequence-dependent bending of DNA and phasing of nucleosomes

Conformational analysis has revealed anisotropic flexibility of the B-DNA double helix: it bends most easily into the grooves, being the most rigid when bent in a perpendicular direction. This result implies that DNA in a nucleosome is curved by means of relatively sharp bends ("mini-kinks") which are directed into the major and minor grooves alternatively and separated by 5-6 base pairs. The "mini-kink" model proved to be in keeping with the x-ray structure of the B-DNA dodecamer resolved later, which exhibits two "annealed kinks", also directed into the grooves. The anisotropy of B DNA is sequence-dependent: the pyrimidine-purine dimers (YR) favor bending into the minor groove, and the purine-pyrimidine dinucleotides (RY), into the minor one. The RR and YY dimers appear to be the most rigid dinucleotides. Thus, a DNA fragment consisting of the interchanging oligopurine and oligopyrimidine blocks 5-6 base pairs long should manifest a spectacular curvature in solution. Similarly, a nucleotide sequence containing the RY and YR dimers separated by a half-pitch of the double helix is the most suitable for wrapping around the nucleosomal core. Analysis of the numerous examples demonstrating the specific alignment of nucleosomes on DNA confirms this concept. So, the sequence-dependent "mechanical" properties of the double helix influence the spatial arrangement of DNA in chromatin.     

Localization of some molecules within the grooves of DNA by modification of their complexes with dimethyl sulphate

The comparative methylation with [³H] dimethyl sulphate (DMS) of free DNA and DNA in chromatin and nuclei within the minor and major grooves of the DNA double helix and its single stranded regions was measured.The results suggest that histones lie partly inside the major groove and partly out of the grooves of DNA in chromatin leaving the minor groove open; most of the non-histone proteins of chromatin are not buried in the DNA grooves; the content of single stranded DNA in chromatin does not exceed 0.5%.     

Localization of chromatin proteins within DNA grooves by methylation of chromatin with dimethyl sulphate

The use of the comparative modification with ³H-dimethyl sulphate (DMS) of free DNA and DNA in different complexes is proposed to evaluate the shielding of the minor and major grooves of the DNA double helix and to determine the presence of single-stranded DNA in the complexes.Glucosyl groups in DNA of T6 phage protect, as expected, the major groove, and actinomycin d in its complex with DNA shields the minor groove against methylation with DMS.The data obtained suggest that histones and protamine in reconstituted nucleohistone and nucleoprotamine are allocated within partly the major groove leaving the minor groove open, while polylysine does not seem to be buried within either of the grooves, and cations of cetyltrimethylammonium lie within the minor groove of DNA.     

Preferential protection of the minor groove of non-operator DNA by lac repressor against methylation by dimethyl sulphate.

The binding of lactose repressor to non-operator DNA was studied by the modification of several DNA's, including glycosylated DNA, with dimethyl sulphate, which affects the minor and major grooves of DNA and single stranded DNA regions. The non-specific binding of the repressor to DNA protected the minor groove but apparently not the major groove of the DNA double helix against methylation and did not increase the content of single stranded DNA regions. This suggests that the repressor on binding to non-operator DNA makes contacts mainly in the minor groove of DNA and does not uncoil the DNA double helix. This is different from the interaction of the repressor with lactose operator DNA which occurs, as shown by Gilbert et al. (1), along both the major and the minor groove.     

Sequence-Dependent Bending of DNA and Phasing of Nucleosomes

Abstract

Conformational analysis has revealed anisotropic flexibility of the B-DNA double helix: it bends most easily into the grooves, being the most rigid when bent in a perpendicular direction. This result implies that DNA in a nucleosome is curved by means of relatively sharp bends (“mini-kinks”) which are directed into the major and minor grooves alternatively and separated by 5–6 base pairs. The “mini-kink” model proved to be in keeping with the x-ray structure of the B-DNA dodecamer resolved later, which exhibits two “annealed kinks”, also directed into the grooves.

The anisotropy of B DNA is sequence-dependent: the pyrimidine-purine dimers (YR) favor bending into the minor groove, and the purine-pyrimidine dinucleotides (RY), into the minor one. The RR and YY dimers appear to be the most rigid dinucleotides. Thus, a DNA fragment consisting of the interchanging oligopurine and oligopyrmidine blocks 5–6 base pairs long should manifest a spectacular curvature in solution.

Similarly, a nucleotide sequence containing the RY and YR dimers separated by a half-pitch of the double helix is the most suitable for wrapping around the nucleosomal core. Analysis of the numerous examples demonstrating the specific alignment of nucleosomes on DNA confirms this concept. So, the sequence-dependent “mechanical” properties of the double helix influence the spatial arrangement of DNA in chromatin.     

(+)-CC-1065 as a structural probe of Mu transposase-induced bending of DNA: overcoming limitations of hydroxyl-radical footprinting.

Phage Mu transposase (A-protein) is primarily responsible for transposition of the Mu genome. The protein binds to six att sites, three at each end of Mu DNA. At most att sites interaction of a protein monomer with DNA is seen to occur over three minor and two consecutive major grooves and to result in bending up to about 90 degrees. To probe the directionality and locus of these A-protein-induced bends, we have used the antitumor antibiotic (+)-CC-1065 as a structural probe. As a consequence of binding within the minor groove, (+)-CC-1065 is able to alkylate N3 of adenine in a sequence selective manner. This selectivity is partially determined by conformational flexibility of the DNA sequence, and the covalent adduct has a bent DNA structure in which narrowing of the minor groove has occurred. Using this drug in experiments in which either gel retardation or DNA strand breakage are used to monitor the stability of the A-protein--DNA complex or the (+)-CC-1065 alkylation sites on DNA (att site L3), we have demonstrated that of the three minor grooves implicated in the interaction with A-protein, the peripheral two are 'open' or accessible to drug bonding following protein binding. These drug-bonding sites very likely represent binding at at least two A-protein-induced bending sites. Significantly, the locus of bending at these sites is spaced approximately two helical turns apart, and the bending is proposed to occur by narrowing of the minor groove of DNA. The intervening minor groove between these two peripheral sites is protected from (+)-CC-1065 alkylation. The results are discussed in reference to a proposed model for overall DNA bending in the A-protein att L3 site complex. This study illustrates the utility of (+)-CC-1065 as a probe for protein-induced bending of DNA, as well as for interactions of minor groove DNA bending proteins with DNA which may be masked in hydroxyl radical footprinting experiments.     

Modelling and refinement of the crystal structure of nucleoprotamine from Gibbula divaricata

The molecular structure of nucleoprotamine from Gibbula divaricata and its packing in oriented fibers has been modelled both to fit the X-ray diffraction pattern and to avoid steric compression. The representative model consists of 51 poly (dinucleotide) B-DNA helices with 51 poly(hexapeptide) chains associated with the major grooves. The prevailing peptide conformation is beta. The four arginine residues present are hydrogen-bonded to DNA phosphates while neutral peptides protrude into the minor grooves of neighboring nucleoprotamine molecules which are packed 2.61 nm apart in a screw-disordered, quasi-hexagonal lattice. This model reconciles a number of earlier, apparently conflicting experimental results and explains the remarkable stability of nucleoprotamines.     

DNA-cation interactions: The major and minor grooves are flexible ionophores.

Several crystallographic, solution-state and theoretical studies carried out this past year provide new support for the sequence-specific nature of monovalent and divalent cation coordination within the DNA major and minor grooves. Correlations observed between groove width and cation coordination indicate that the grooves are flexible and respond to cation binding.     

Fibroblasts on micromachined substrata orient hierarchically to grooves of different dimensions

Contact guidance was studied by light, scanning (SEM) and transmission electron microscopy (TEM) in cultures of human gingival fibroblasts cultured on grooved surfaces. The grooves were originally produced in silicon wafers by micromachining, a process which is based on the methods used to fabricate microelectronic components, and the grooved surfaces were then replicated in Epon. Micromachining enables precise control of groove depth, groove spacing, and groove shape to be obtained. In silicon wafers with appropriate crystal orientation, a second smaller set of grooves, called the minor grooves, is found on the floor of the major grooves. The minor grooves are oriented at a 54 degree angle to the major grooves, so that cells cultured on such surfaces are concurrently exposed to grooves of different dimensions which direct cell migration in different directions. Marked fibroblast alignment with the major grooves was observed both within the grooves and in the intervening flat ridges between the grooves. In addition, shallow and closely spaced grooves in epon or titanium-coated polymer or silicon were also capable of orienting fibroblasts. Although the minor grooves were able to orient fibroblasts in the absence of any other orienting influence, when fibroblasts were concurrently exposed to major and minor grooves the cells aligned themselves with the major grooves. TEM showed that the cellular filamentous cytoskeletal elements reflected the orientation of the cell as a whole. Fibroblasts on grooved substrata appeared to have more filopodia and to round up more frequently than fibroblasts cultured on flat substrata. It is suggested that both the mechanical properties of the cytoskeleton as well as the durability of the cellular attachment to groove edges may play a role in the contact guidance effected by grooved surfaces produced by micromachining.     

Comparison of positively charged DNG with DNA duplexes: a computational approach

Molecular dynamics is used to investigate the structural properties of the cationic DNA analogue deoxynucleic guanidine (DNG), in which a guanidinium group replaces the phosphate moiety of DNA. This study examines the DNG duplex dodecamers d(Ag)(12).d(Tg)(12) and d(Gg)(12).d(Cg)(12), as well as their DNA counterparts. Watson-Crick base-pairing is maintained in the solvated DNG duplex models during the 5ns simulations. The idealized DNG dodecamers assume many parameters characteristic of the corresponding native DNA, assuming B-DNA conformations. Several helical parameters are rather unique to DNG, including buckle, slide, inclination, propeller, and X-displacement. Fewer transitions in backbone torsions occur in the DNG duplexes compared to those of the DNA, which may result from the greater rigidity of the sp(2) hybridized guanidinium group verses the flexible sp(3) phosphate group. The DNG helices have exceptionally shallow major grooves and very deep minor grooves. The major and minor groove widths of DNG are narrower than those of the respective DNA counterparts.     

Saturation mutagenesis of the DNA site bound by the small carboxy-terminal domain of gamma delta resolvase.

We have analyzed the sequence requirements for the binding of the carboxy-terminal (DNA binding) domain of gamma delta resolvase to its recognition site. Using an efficient procedure for saturation mutagenesis we have obtained 31 of the possible 36 base substitutions within the 12 bp minimal binding sequence (using a modified right half of resolvase binding site I as the model sequence). Binding assays in vitro with the 43 residue DNA binding domain show that certain substitutions at eight of the 12 positions strongly inhibit complex formation, increasing the dissociation constant by 100-fold or more. The critical positions fall into two groups: the outside 6 bp of the binding sequence (positions 1-6) and positions 9-10. These positions correspond to the regions where the DNA binding domain spans the major and minor grooves, respectively, of its binding site. Base substitutions at the intervening positions (7 and 8) have more modest (less than 20-fold) effects on binding while substitutions at the inner two positions (11 and 12) are virtually neutral. The hierarchies of base preferences within each critical segment suggest that resolvase makes base-specific contacts in both major and minor grooves.     

Modelling and Refinement of the Crystal Structure of Nucleoprotamine from Gibbuta Divaricata

Abstract

The molecular structure of nucleoprotamine from Gibbula divaricata and its packing in oriented fibers has been modelled both to fit the X-ray diffraction pattern and to avoid steric compression. The representative model consists of 5₁ poly(dinucleotide) B-DNA helices with 5₁ poly(hexapeptide) chains associated with the major grooves. The prevailing peptide conformation is β, The four arginine residues present are hydrogen-bonded to DNA phosphates while neutral peptides protrude into the minor grooves of neighboring nucleoprotamine molecules which are packed 2.61 nm apart in a screw-disordered, quasi-hexagonal lattice. This model reconciles a number of earlier, apparently conflicting experimental results and explains the remarkable stability of nucleoprotamines.     

Mode of reversible binding of neocarzinostatin chromophore to DNA: evidence for binding via the minor groove

Two general approaches have been taken to understand the mechanism of the reversible binding of the nonprotein chromophore of neocarzinostatin to DNA: (1) measurement of the relative affinity of the chromophore for various DNAs that have one or both grooves blocked by bulky groups and (2) studies on the influence of adenine-thymine residue-specific, minor groove binding agents such as the antibiotics netropsin and distamycin on the chromophore-DNA interaction. Experiments using synthetic DNAs containing halogen group (Br, I) substituents in the major groove or natural DNAs with glucosyl moieties projecting into the major groove show that obstruction of the major groove does not decrease the binding stoichiometry or the binding constant for the DNA-chromophore interaction. Chemical methylation of bases in both grooves of calf thymus DNA, resulting in 13% methylation of N-7 of guanine in the major groove and 7% methylation of N-3 of adenine in the minor groove, decreases the binding affinity and increases the size of the binding site for neocarzinostatin chromophore. Similar results were obtained whether binding parameters were determined directly by spectroscopic measurements or indirectly by measuring the ability of the DNA to protect the chromophore against degradation. On the other hand, netropsin and distamycin compete with neocarzinostatin chromophore for binding to the minor groove of DNA, as shown by their decrease in the ability of poly(dA-dT) to protect the chromophore against degradation and their reduction in chromophore-induced DNA damage as measured by thymine release.(ABSTRACT TRUNCATED AT 250 WORDS)     

Physical Models for Exploring DNA Topology

Abstract

Two types of physical models have been developed for treating DNA molecules whose topology is of interest The two model motifs combine jacks-and-straws molecular representations with flexible tubing in different proportions. Both motifs present a low-resolution construct of DNA that retains helix axes, strand individuality and the distinguishabiity of the major and minor grooves. Molecules whose double helix axes are branched are modelled by stiff double helices and flexible branch sites. Supercoiled and knotted DNA molecules are modelled on a smaller scale, in a system in which a flexible backbone is supported by a series of stiff helical struts; removal of this scaffolding immediately reveals the linking of the strands. The models are light and easy to construct. They may be used either for demonstrations or as a research tool that assists the interpretation data.     

Crystal structure of the excisionase-DNA complex from bacteriophage lambda

The excisionase (Xis) protein from bacteriophage lambda is the best characterized member of a large family of recombination directionality factors that control integrase-mediated DNA rearrangements. It triggers phage excision by cooperatively binding to sites X1 and X2 within the phage, bending DNA significantly and recruiting the phage-encoded integrase (Int) protein to site P2. We have determined the co-crystal structure of Xis with its X2 DNA-binding site at 1.7A resolution. Xis forms a unique winged-helix motif that interacts with the major and minor grooves of its binding site using an alpha-helix and an ordered beta-hairpin (wing), respectively. Recognition is achieved through an elaborate water-mediated hydrogen-bonding network at the major groove interface, while the preformed hairpin forms largely non-specific interactions with the minor groove. The structure of the complex provides insights into how Xis recruits Int cooperatively, and suggests a plausible mechanism by which it may distort longer DNA fragments significantly. It reveals a surface on the protein that is likely to mediate Xis-Xis interactions required for its cooperative binding to DNA.     

Three-dimensional structure prediction of bovine AP lyase, BAP1: prediction of interaction with DNA and alterations as a result of Arg176-->Ala, Asp282-->Ala, and His308-->Asn mutations

BAP1 is an apurinic/apyrimidinic lyase (AP lyase) that plays an important role in the repair of DNA damage. The present study deals with the prediction of the 3D structure of bovine AP lyase based on its sequence homology with human AP lyase. The predicted 3D model of bovine AP1 shows remarkable similarity with human endonuclease in the overall 3D fold. However, significant differences in the model and the X-ray structure were located at some of the important sites. We have analyzed the active center of the enzyme and other sites that are involved in DNA repair. A number of amino acids bind the bases located in the major/minor grooves of DNA. An insertion of Arg176 in the major groove and Met270 in the minor groove caps the DNA bound enzyme's active site, stabilizing the extra helical AP site conformation and effectively locking the protein onto the AP-DNA. Three BAP1 mutants were also modeled and analyzed as regards the changes in the structure. Substitution of Arg176-->Ala leads to the loss of DNA binding whereas mutation of Asp282-->Ala and His308-->Asn leads to a decrease in the enzymatic activity.