The crystallographic study of left-handed Z-DNA d(CGCGCG)2 and thermine complexes crystallized at various temperatures and at various concentration of cations

In crystals of complexes of thermine and d(CGCGCG)₂ molecules grown at 4, 10, and 20 °C, the numbers of thermine molecules connected to the DNA molecule were dependent on the temperature of the crystallization. Two molecules of thermine and one Mg²⁺ ion were connected to DNA molecule when thermine and d(CGCGCG)₂ were co-crystallized at 4 and at 20 °C. When an increased concentration of magnesium and thermine molecules were co-crystallized with d(CGCGCG)₂ molecules at 10 °C, three Mg²⁺ ions and only one thermine molecule were bound with a d(CGCGCG)₂ molecule. The number of polyamines and of Mg²⁺ ions connected to DNA was dependent on the atomic values of the polyamine and of the metal ion. The binding of more Mg²⁺ ions occurred when the atomic value of Mg²⁺ exceeded that of the corresponding mono- or polyamine, and when the Mg²⁺ ion concentration was elevated. Furthermore, this study is the first documentation of a naturally occurring polyamine bound to the minor groove of DNA in a crystal structure.     

Modelling of the binding specificity in the interactions of cationic porphyrins with DNA.

A theoretical investigation is performed of the complexes of a tetracationic porphyrin, tetra-(4-N-methylpyridyl)-porphyrin, (T4MPyP), with the hexanucleotides d(CGCGCG)2 and d(TATATA)2, considering the possibility of both the intercalative and the groove binding interactions. These computations demonstrate that T4MPyP manifests a significant preference for intercalation in its complex with d(CGCGCG)2 but for non intercalative binding in the minor groove in its complex with d(TATATA)2. Such a dual binding behaviour of T4MPyP as a function of the sequence to which it is attached is fully consistent with available experimental data. It demonstrates that intercalation and groove binding may be viewed as two potential wells on a continuous energy surface. In agreement with experiment, the computations indicate that in the here considered case the deepest well is associated with intercalation.     

The 1.19 A X-ray structure of 2'-O-Me(CGCGCG)(2) duplex shows dehydrated RNA with 2-methyl-2,4-pentanediol in the minor groove

The crystal and molecular structure of 2′-O-Me(CGCGCG)₂ has been determined at 1.19 Å resolution, at 100 K, using synchrotron radiation. The structure in space group P3₂12 is a half-turn right-handed helix that includes two 2-methyl-2,4-pentanediol (MPD) molecules bound in the minor groove. The structure deviates from A-form RNA. The duplex is overwound with an average value of 9.7 bp per turn, characterised as having a C3′-endo sugar pucker, very low base pair rise and high helical twist and inclination angles. The structure includes 65 ordered water molecules. Only a single row of water molecules is observed in the minor groove due to the presence of hydrophobic 2′-O-methyl groups. As many as five magnesium ions are located in the structure. Two are in the major groove and interact with O⁶ and N⁷ of guanosine and N⁴ of cytidine residues through their hydration spheres. This work provides the first example of molecular interactions of nucleic acids with MPD, which was used as a precipitant, cryo-solvent and resolution enhancing agent. The two MPD molecules intrude into the hydration network in the minor groove, each forming hydrogen bonds between their secondary hydroxyl group and exo-amino functions of guanosine residues. Comparison of the 2′-O-Me(CGCGCG)₂ structure in the P3₂12 and P6₁22 crystals delineates stability of the water network within the minor groove to dehydration by MPD and is of interest for evaluating factors governing small molecule binding to RNA. Intrusion of MPD into the minor groove of 2′-O-Me(CGCGCG)₂ is discussed with respect to RNA dehydration, a prerequisite of Z-RNA formation.     

The rare crystallographic structure of d(CGCGCG)(2): the natural spermidine molecule bound to the minor groove of left-handed Z-DNA d(CGCGCG)(2) at 10 degrees C

Several crystal structure analyses of complexes of synthetic polyamine compounds, including N(1)-(2-(2-aminoethylamino))ethyl)ethane-1,2-diamine PA(222) and N(1)-(2-(2-(2-aminoethylamino)ethylamino)ethyl)ethane-1,2-diamine PA(2222), and left-handed Z-DNA d(CGCGCG)(2) have been reported. However, until now, there have been no examples of naturally occurring polyamines bound to the minor groove of the left-handed Z-DNA of d(CGCGCG)(2) molecule. We have found that spermidine, a natural polyamine, is connected to the minor groove of left-handed Z-DNA of d(CGCGCG)(2) molecule in a crystalline complex grown at 10 degrees C. The electron density of the DNA molecule was clear enough to determine that the spermidine was connected in the minor groove of two symmetry related molecules of left-handed Z-DNA d(CGCGCG)(2). This is the first example that a spermidine molecule can form a bridge conformation between two symmetry related molecules of left-handed Z-DNA d(CGCGCG)(2) in the minor groove.     

A Theoretical Investigation on the Sequence Selective Binding of Daunomycin to Double-Stranded Polynucleotides

Abstract

Theoretical computations are performed on the structural and energetical factors involved in the sequence selective binding of daunomycin (DNM) to six representative self- complementary double-stranded hexanucleotides: d(CGTACG)₂, d(CGATCG)₂, d(CITACI)₂, d(TATATA)₂, d(CGCGCG)₂ and d(TACGTA)₂. The conformational angles of the hexanucleotides are fixed in values found in the representative crystal structure of the d(CGTACG)₂- DNM complex. The intermolecular DNM-hexanucleotide interaction energies and the conformational energy changes of DNM upon binding are computed and optimized in the framework of the SIBFA procedure, which uses empirical formulas based on ab initio SCF computations. Among the two regularly alternating hexanucleotides, d(TATATA)₂ and d(CGCGCG)₂, a stronger binding is predicted for the former, in agreement with experimental results obtained with poly(dA-dT)-poly(dA-dT) and poly(dG-dC)<<poly(dG-dC). Altogether, however, among the six investigated sequences, the strongest complexes are computed for the mixed hexanucleotides d(CGATCG)₂ and d(CGTACG)₂, containing the intercalation site between two CG base pairs and an adjacent TA base pair. This situation may be related to the increased affinity of DNM for GC rich DNA's and to the situation in the crystal structure of the DNM-d(CGTACG)₂ complex. Analysis of the intrinsic base sequence preferences expressed by the individual constituents of DNM, namely the daunosamine side chain, the chromophore ring and its two 9-hydroxyl and 9-acetoxy substituents, reveals that the overall sequence preference found is the result of a rather intricate interplay of intrinsic sequence preferences, in particular at the level of daunosamine and the 9-hydroxyl substituent. Altogether, it is seen that the selective base pair recognition by daunomycin cannot, in general, be defined in terms of the two base pairs implicated in the intercalation site alone (with the exception of homogeneous AT or GC base sequences) but must be expressed in terms of a triplet of base pairs.     

Sequence discrimination of the Zα domain of human ADAR1 during B-Z transition of DNA duplexes

The Zα domain of human ADAR1 (Zα_ADAR1) preferentially binds Z-DNA rather than B-DNA with high binding affinity. Zα_ADAR1 binds to the Z-conformation of both non-CG-repeat DNA duplexes and a d(CGCGCG)₂ duplex similarly. We performed NMR experiments on complexes between the Zα_ADAR1 and non-CG-repeat DNA duplexes, d(CACGTG)₂ or d(CGTACG)₂, with a variety of protein-DNA molar ratios. Comparison of these results with those from the analysis of d(CGCGCG)₂ in the previous study suggests that Zα_ADAR1 exhibits the sequence preference of d(CGCGCG)₂ ? d(CACGTG)₂ > d(CGTACG)₂ through multiple sequence discrimination steps during the B-Z transition.     

The Interactions of Ruthenium Hexaammine with Z-DNA: Crystal Structure of a RU(NH3)+3 6 Salt of d(CGCGCG) at 1.2 Å Resolution

Abstract

Acrystalofd(CGCGCG)in the Z-DNA lattice was soaked with ruthenium(III) hexaammine and its structure refined at 1.2 Å resolution. Three unique metal complexes were found adsorbed to each hexamer duplex. In addition, two symmetry-related binding sites were located, yielding a total of five ruthenium complexes bound to each d(CGCGCG) duplex. One unique site and its symmetry related site are nearly identical to the binding site of cobalt(III) hexaammine on Z-DNA. At that position, the metal complex bridges the convex surfaces of two adjacent Z-DNA strands by hydrogen bonds to the N7 and 06 functional groups of the guanine bases. The remaining three ruthenium(III) hexaammine binding sites are not present in the cobalt(III) hexaammine Z-DNA structure. Of these, two are related by symmetry and span the gap between the convex outer surface of one Z-DNA strand and the helical groove crevice of a neighboring strand. The third ruthenium site has no symmetry mate and involves interactions with only the deep groove. In this interaction, the metal complex hydrogen bonds to both the phosphate backbone and to a set of primary shell water molecules that extend the hydrogen bonding potential of the deep groove crevice out to the surface of the molecule. Solution studies comparing the circular dichroism spectra of low salt poly(dG-dC) · poly(dG-dC) samples in the presence of ruthenium(III) and cobalt(III) hexaammine show that the ruthenium complex does stabilize Z-DNA in solution, but not as effectively as the cobalt analogue. This suggests that some of the interactions available for the larger ruthenium complex may not be important for stabilization of the left-handed DNA conformation.     

A theoretical investigation of the base sequence preferences of monointercalating polymethylene carboxamide derivatives 9-aminoacridine.

Theoretical computations are performed of the comparative binding affinities of five polymethylene carboxamide derivatives of 9-aminoacridine to a series of double-stranded hexanucleotides. The purpose of this investigation is to ascertain whether minor groove recognition of a guanine base adjacent to the intercalation site can occur, and be preferentially stabilized, for a given length of the polymethylene side chain, encompassing from n = 2 up to n = 6 methylene groups. For that purpose, several representative sequences were investigated, in which intercalation of the 9-aminoacridine chromophore occurred at a central d(CpG) or d(TpA) step. Investigated were the self-complementary sequences d(CGCGCG)2, d(GCCGGC)2, d(TATATA)2 and d(ATTAAT)2, as well as the 'mixed' sequences d(ACTAAT) .d(ATTAGT) and d(TGTATA). d(TATACA). For n = 3 up to n = 6, such a recognition was enabled only when the guanine base was located downstream of the intercalation site, i.e. with steps d(CGG) and d(TAG). It occurred by means of a bidentate interaction involving, on the one hand, H(N2) and N3 of the base, and, on the other hand, the carbonyl oxygen and the cis amino hydrogen of the terminal formamide moiety of the ligand. Because of the flexibility of the side chain, however, alternative binding modes were also found to occur competitively, involving backbone-only interactions of the side chain. On the basis of the present computations, upon binding to the sequence d(GCCGGC)2, an optimal value of n = 5 could be derived, with the corresponding acridine derivative eliciting both a significant prevalence of the bidentate over backbone only binding mode, and the most favourable energy balance within the investigated series. This privileged value of n = 5 is fully consistent with the experimental results of Markovits et al. and Gaugain et al. The very flexibility of the side chain, however, hampered any preferential recognition of a triplet sequence with a downstream guanine, such as d(CGG) or d(TAG), to be elicited over sequences such as d(TAA), d(TAT) or d(TAC).     

The Effect of Methylation of the 6 Oxygen of Guanine on the Structure and Stability of Double Helical DNA

Abstract

The effect of methylation of the 0–6 position of guanine in short segments of double helical DNA has been investigated by molecular mechanical simulations on the sequences d(CGCGCG)₂, d(CGC+AFs-OMG+AF0-CG)₂, d(CGT+AFs-OMG+AF0-CG)₂, d(CGC+AFs-OMC+AF0-CG/(CGCGCG), d(CGC+AFs-OMG+AF0-CG/d(CGTGCG), d(CGCGAATTCGCG)₂ and d(CGCGAATTC+AFs-OMG+AF0-CG)₂. Guanines methylated at the 0–6 position are found to form hydrogen bonds of roughly equal strength to cytosine and thymine. The optimum structure of these modified base pairs are not dramatically different from normal GC pairs, but both involve some bifurcation of the proton donors of cytosine (4NH₂) or thymine (3NH) between the guanine N3 and O6 groups.     

NMR study of hydrogen exchange during the B-Z transition of a DNA duplex induced by the Zα domains of yatapoxvirus E3L

The Yaba-like disease viruses (YLDV) are members of the Yatapoxvirus family and have double-stranded DNA genomes. The E3L protein, which is essential for pathogenesis in the vaccinia virus, consists of two domains: an N-terminal Z-DNA binding domain and a C-terminal RNA binding domain. The crystal structure of the E3L orthologue of YLDV (yabZα_E3L) bound to Z-DNA revealed that the overall structure of yabZα_E3L and its interaction with Z-DNA are very similar to those of hZα_ADAR1. Here we have performed NMR hydrogen exchange experiments on the complexes between yabZα_E3L and d(CGCGCG)₂ with a variety of protein-to-DNA molar ratios. This study revealed that yabZα_E3L could efficiently change the B-form helix of the d(CGCGCG)₂ to left-handed Z-DNA via the active-mono B-Z transition pathway like hZα_ADAR1.     

A Study of the Interaction of Cr(III) Complexes and Their Selective Binding with B-DNA: A Molecular Modeling Approach

Abstract

Molecular modeling and energy minimisation calculations have been used to investigate the interaction of chromium(III) complexes in different ligand environments with various sequences of B-DNA. The complexes are [Cr(salen)(H₂O)₂]⁺; salen denotes 1, 2 bis-salicylideneaminoethane, [Cr(salprn)(H₂O)₂]⁺; salprn denotes 1, 3 bis- salicylideneamino-propane, [Cr(phen)₃]³⁺; phen denotes 1, 10 phenanthroline and [Cr(en)₃]³⁺; en denotes eth- ylenediamine. All the chromium(III) complexes are interacted with the minor groove and major groove of d(AT)₁₂, d(CGCGAATTCGCG)₂ and d(GC)₁₂ sequences of DNA. The binding energy and hydrogen bond parameters of DNA-Cr complex adduct in both the groove have been determined using molecular mechanics approach. The binding energy and formation of hydrogen bonds between chromium(III) complex and DNA has shown that all complexes of chromium(III) prefer minor groove interaction as the favourable binding mode.     

Discrimination Between A-type and B-type Conformations of Double Helical Nucleic Acid Fragments in Solution by Means of Two-dimensional Nuclear Overhauser Experiments

Abstract

The solution structure of two double helical nucleic acid fragments, viz. r(CGCGCG) and d(CGCGCG), was probed by means of two-dimensional nuclear Overhauser effect spectroscopy. The two compounds were selected as models for the A-type and B-type double helical conformations, respectively, and it is shown that for each of the two model compounds the intensities of the NOE cross peaks between base- and H2′ (deoxy)ribose proteins are qualitatively in correspondence with the relative NOE intensities expected on basis of the supposed duplex conformations. Thus our results indicate that NOE-data can be used to differentiate between A- and B-type double helical conformations in solution.

Coupling constant data show that, except for G(6), all ribose rings in r(CGCGCG) adopt pure N (C3′-endo) conformations thereby manifesting that this molecule takes up a regular A-type double helical conformation in solution. In contrast, the deoxyribose rings in d(CGCGCG) retain conformational freedom in the duplex state, albeit that the N/S- equilibrium is biased towards the S (C2′-endo) sugar conformation. This finding indicates that in solution the B-DNA backbone is highly dynamic.     

Modelling basic features of specificity in the binding of a dicationic steroid diamine to double-stranded oligonucleotides.

An investigation of the intrinsically preferred binding modes of a steroid diamine, dipyrandium, to the double-stranded hexanucleotides d(TATATA)2, d(ATATAT)2, and d(CGCGCG)2 is carried out by the energy minimization procedure JUMNA. Several alternative binding modes are compared: groove binding in which the conformation of the oligonucleotide remains close to that of B-DNA, intercalation between base-pairs and interaction with variously kinked structures in which base pairs of dinucleoside steps open towards the groove in which the binding occurs. The favored binding configuration occurs at the d(TpA) step of the AT kinked nucleotides in which the kink opens the base pairs towards the minor groove. Thus, for the d(T1A2T3A4T5A6)2 sequences the preferred complexation involves the kink at the T3A4 step facing the cyclohexane rings A, B, and C of the ligand. For the d(A1T2A3T4A5T6)2 sequence, the kink occurs at the T2A3 step facing the cationic pyrrolidine ring linked to ring A. The binding of dipyrandium to d(CGCGCG)2 is found to be considerably less favourable than for either of the two (AT) sequences.     

Spectroscopic studies of 9-hydroxyellipticine binding to DNA

The binding of 9-hydroxyellipticine to calf thymus DNA, poly[d(A-T)]₂, and poly-[d(G-C)]₂ has been studied in detail by means of CD, linear dichroism, resonance light scattering, and molecular dynamics. The transition moment polarizations of 9-hydroxyelliptiycine were determined in polyvinyl alcohol stretched film. Spectroscopic solution studies of the DNA/drug complex are combined with theoretical CD calculations using the final 50 ps of a series of molecular dynamics simulations as input. The spectroscopic data shows 9-hydroxyellipticine to adopt two main binding modes, one intercalative and the other a stacked binding mode involving the formation of drug oligomers in the DNA major groove. Analysis of the intercalated binding mode in poly[d(A-T)]₂ suggests the 9-hydroxyellipticine hydroxyl group lies in the minor groove and hydrogen bonds to water with the pyridine ring protruding into the major groove. The stacked binding mode was examined using resonance light scattering and it was concluded that the drug was forming small oligomer stacks rather than extended aggregates. Reduced linear dichroism measurements suggested a binding geometry that precluded a minor groove binding mode where the plane of the drug makes a 45° angle with the plane of the bases. Thus it was concluded that the drug stacks in the major groove. No obvious differences in the mode of binding of 9-hydroxyellipticine were observed between different DNA sequences; however, the stacked binding mode appeared to be more favorable for calf thymus DNA and poly[d(G-C)]₂ than for poly[d(A-T)]₂, an observation that could be explained by the slightly greater steric hindrance of the poly[d(A-T)]₂ major groove. A strong concentration dependence was observed for the two binding modes where intercalation is favored at very low drug load, with stacking interactions becoming more prominent as the drug concentration is increased. Even at DNA : drug mixing ratios of 70:1 the stacked binding mode was still important for GC-rich DNAs. © 1998 John Wiley & Sons, Inc. Biopoly 46: 127–143, 1998     

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

Abstract

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

Binding Modes of Thioflavin-T to the Single-Layer β-Sheet of the Peptide Self-Assembly Mimics

Although the amyloid dye thioflavin-T (ThT) is among the most widely used tools in the study of amyloid fibrils, the mechanism by which ThT binds to fibrils and other β-rich peptide self-assemblies remains elusive. The development of the water-soluble peptide self-assembly mimic (PSAM) system has provided a set of ideal model proteins for experimentally exploring the properties and minimal dye-binding requirements of amyloid fibrils. PSAMs consist of a single-layer β-sheet (SLB) capped by two globular domains, which capture the flat, extended β-sheet features common among fibril-like surfaces. Recently, a PSAM that binds to ThT with amyloid-like affinity (low micromolar K_d) has been designed, and its crystal structure in the absence of bound ThT was determined. This PSAM thus provides a unique opportunity to examine the interactions of ThT with a β-rich structure. Here, we present molecular dynamics simulations of the binding of ThT to this PSAM β-sheet. We show that the primary binding site for ThT is along a shallow groove formed by adjacent Tyr and Leu residues on the β-sheet surface. These simulations provide an atomic-scale rationale for this PSAM's experimentally determined dye-binding properties. Together, our results suggest that an aromatic-hydrophobic groove spanning across four consecutive β-strands represents a minimal ThT binding site on amyloid fibrils. Grooves formed by aromatic-hydrophobic residues on amyloid fibril surfaces may therefore offer a generic mode of recognition for amyloid dyes.     

INTERACTION OF DISTAMYCIN A AND NETROPSIN WITH QUADRUPLEX AND DUPLEX STRUCTURES: A COMPARATIVE 1H-NMR STUDY

ABSTRACT

Homonuclear NMR techniques have been used to investigate the interactions of the minor groove binding agents distamycin A (Dist-A) and the related drug netropsin (Net) with three quadruplexes characterized by different groove widths: [d(TGGGGT)]₄ (Q1), [d(GGGGTTTTGGGG)]₂ (Q2), and d(GGGGTTGGGGTGTGGGGTTGGGG) (Q3). Netropsin has been found to be in a fast chemical exchange with all three kinds of quadruplexes, whereas Dist-A interacts tightly with Q1 and, at a less extent, with Q2. In order to determine the degree of selectivity of Dist-A for two- rather than four-stranded DNA, we titrated with Dist-A an equimolar solution of Q1 and the duplex d(CGCAAATTTGCG)₂ (D). This comparative ¹H-NMR study allowed us to conclude that Dist-A and, consequently, Net possess higher affinity for duplex DNA.     

Investigation of DNA Binding Modes for a Symmetrical Cyanine Dye Trication: Effect of DNA Sequence and Structure

Abstract

The DNA binding behavior of a tricationic cyanine dye (DiSC₃₊(5)) was studied using the [Poly(dA-dT)]₂, [Poly(dI-dC)]₂ and Poly(dA)?Poly(dT) duplex sequences and the Poly(dA) ?2Poly(dT) triplex. Optical spectroscopy and viscometry results indicate that the dye binds to the triplex structure by intercalation, to the nonalternating Poly(dA)?Poly(dT) duplex through minor groove binding and to the alternating [Poly(dA-dT)]₂ duplex by a combination of two binding modes: intercalation at low concentration and dimerization within the minor groove at higher concentration. Dimerization occurs at lower dye concentrations for the [Poly(dI-dC)]₂ sequence, consistent with our previous investigations on an analogous monocationic cyanine dye. [Seifert, J.L., et al. (1999) J. Am. Chem. Soc. 121, 2987–2995] These studies illustrate the diversity of DNA binding modes that are available to a given ligand structure.     

The interactions of ruthenium hexaammine with Z-DNA: crystal structure of a Ru(NH3)6+3 salt of d(CGCGCG) at 1.2 A resolution

A crystal of d(CGCGCG) in the Z-DNA lattice was soaked with ruthenium(III) hexaammine and its structure refined at 1.2 A resolution. Three unique metal complexes were found absorbed to each hexamer duplex. In addition, two symmetry-related binding sites were located, yielding a total of five ruthenium complexes bound to each d(CGCGCG) duplex. One unique site and its symmetry related site are nearly identical to the binding site of cobalt(III) hexaammine on Z-DNA. At that position, the metal complex bridges the convex surfaces of two adjacent Z-DNA strands by hydrogen bonds to the N7 and O6 functional groups of the guanine bases. The remaining three ruthenium three ruthenium(III) hexaammine binding sites are not present in the cobalt(III) hexaammine Z-DNA structure. Of these, two are related by symmetry and span the gap between the convex outer surface of one Z-DNA strand and the helical groove crevice of a neighboring strand. The third ruthenium site has no symmetry mate and involves interactions with only the deep groove. In this interaction, the metal complex hydrogen bonds to both the phosphate backbone and to a set of primary shell water molecules that extend the hydrogen bonding potential of the deep groove crevice out to the surface of the molecule. Solution studies comparing the circular dichroism spectra of low salt poly(dG-dC).poly(dG-dC) samples in the presence of ruthenium(III) and cobalt(III) hexammine show that the ruthenium complex does stabilize Z-DNA in solution, but not as effectively as the cobalt analogue. This suggests that some of the interactions available for the larger ruthenium complex may not be important for stabilization of the left-handed DNA conformation.