Determination of the NMR solution structure of the Hoechst 33258-d(GTGGAATTCCAC)2 complex and comparison with the X-ray crystal structure

In silico studies of the interaction of the minor groove binder Hoechst 33258 with B-DNA

Interaction of the minor groove binder, Hoechst 33258, with the Dickerson-Drew DNA dodecamer sequence has been investigated using docking, MM/QM, MM/GBSA and molecular dynamics computations to study the modes of binding and the interactions responsible for the binding. Besides the original Hoechst 33258 ligand (HT), a total of 12 ionization and stereochemical states for the ligand are obtained at the physiological pH and have been docked into B-DNA. These states have one or the other or both benzimidazole rings in protonated states, apart from the piperazine nitrogen, which has a quaternary nitrogen in all the states. Most of these states are found to exhibit good docking scores and free energy of binding with B-DNA. The best docked state has been taken further for molecular dynamics simulations and compared with the original HT. This state is protonated at both benzimidazole rings besides the piperazine ring and hence has very highly negative coulombic interaction energy. In both cases, there are strong coulombic interactions, but these are offset by the almost equally unfavorable solvation energies. Thus, the nonpolar forces, particularly van der Waals contacts, dominate the interaction, and the polar interactions highlight subtle changes in the binding energies, leading to more highly protonated states having more negative binding energies.Communicated by Ramaswamy H. Sarma.

Novel genosensor for probing DNA mismatches and UV-induced DNA damage: Sequence-specific recognition

Human genome is continuously susceptible to changes that may lead to undesirable mutations causing various diseases and cancer. Vast majority of techniques has investigated the discrimination between base-pair mismatched nucleic acid, but many of these techniques are time-consuming, complex, expensive, and limited to the detection of specific type of dsDNA mismatches. In this study, we introduce a simple mix-and-read assay for the sensitive and cost-effective analysis of DNA base mismatches and UV-induced DNA damage using Hoechst genosensor dye (H258). This dye is a minor groove binder that undergoes a drastic conformational change upon binding with mismatch DNA. The difference in binding affinity between perfectly matched and mismatched DNA was studied for sequences at different base mismatch locations and finally, extended for the detection of dsDNA damage by UVC radiation in calf thymus DNA. In addition, a comparative DNA damage kinetic study was performed using H258 (minor groove binder) and EvaGreen (intercalating) dye to get insight on assay selectivity and sensitivity with dye binding mechanism. The result shows good reproducibility making H258 genosensor a cheaper alternative for DNA mismatch and damage studies with possibility of extension for in-vitro detection of hot spots of DNA mutations.

Two novel "release-on-demand" fluorescent biosensors for probing UV-induced DNA damage induced in single stranded and double stranded DNA: Comparative study

Light in the UVC spectral region damages both single-strand (ssDNA) and double-strand DNA (dsDNA), and contributes to the formation of mutagenic photoproducts. In-vivo studies show greater damage for ssDNA compared to dsDNA. However, excited-state spectroscopy shows that dsDNA has longer excited-state lifetime than ssDNA, which increases the probability of damage for dsDNA. However, lack of a direct comparison of in-vitro ssDNA and dsDNA damage rates precludes the development of a model that elucidates the molecular factors responsible for damage. In this work, two novel sensitive "release-on-demand" biosensors are developed for the selective probing of DNA-damage and comparing the rate of DNA damage in ssDNA and dsDNA. The two biosensors involve the use of EvaGreen and Hoechst dyes for the sensitive probing of DNA-damage. The results show that ssDNA is damaged at a faster rate than dsDNA in the presence of UVC light (200-295 nm). Furthermore, we examined the effect of G/C composition on the damage rate for mostly A/T ssDNA and dsDNA oligonucleotides. Our results show that DNA damage rates are highly dependent on the fraction of guanines in the sequence, but that in-vitro dsDNA always exhibits an overall slower rate of damage compared to ssDNA, essentially independent of sequence.

First Structure of a Designed Minor Groove Binding Heterocyclic Cation that Specifically Recognizes Mixed DNA Base Pair Sequences

The high-resolution NMR structure of the first heterocyclic, non-amide, organic cation that strongly and selectively recognizes mixed AT/GC bp (bp=base pair) sequences of DNA in a 1:1 complex is described. Compound designs of this type provide essential methods for control of functional, non-genomic DNA sequences and have broad cell uptake capability, based on studies from animals to humans. The high-resolution structural studies described in this report are essential for understanding the molecular basis for the sequence-specific binding as well as for new ideas for additional compound designs for sequence-specific recognition. The molecular features, in this report, explain the mechanism of recognition of both A⋅T and G⋅C bps and are an interesting molecular recognition story. Examination of the experimental structure and the NMR restrained molecular dynamics model suggests that recognition of the G⋅C base pair involves two specific H-bonds. The structure illustrates a wealth of information on different DNA interactions and illustrates an interfacial water molecule that is a key component of the complex.

Defining RNA-Small Molecule Affinity Landscapes Enables Design of a Small Molecule Inhibitor of an Oncogenic Noncoding RNA

RNA drug targets are pervasive in cells, but methods to design small molecules that target them are sparse. Herein, we report a general approach to score the affinity and selectivity of RNA motif-small molecule interactions identified via selection. Named High Throughput Structure-Activity Relationships Through Sequencing (HiT-StARTS), HiT-StARTS is statistical in nature and compares input nucleic acid sequences to selected library members that bind a ligand via high throughput sequencing. The approach allowed facile definition of the fitness landscape of hundreds of thousands of RNA motif-small molecule binding partners. These results were mined against folded RNAs in the human transcriptome and identified an avid interaction between a small molecule and the Dicer nuclease-processing site in the oncogenic microRNA (miR)-18a hairpin precursor, which is a member of the miR-17-92 cluster. Application of the small molecule, Targapremir-18a, to prostate cancer cells inhibited production of miR-18a from the cluster, de-repressed serine/threonine protein kinase 4 protein (STK4), and triggered apoptosis. Profiling the cellular targets of Targapremir-18a via Chemical Cross-Linking and Isolation by Pull Down (Chem-CLIP), a covalent small molecule-RNA cellular profiling approach, and other studies showed specific binding of the compound to the miR-18a precursor, revealing broadly applicable factors that govern small molecule drugging of noncoding RNAs.

Imino proton NMR guides the reprogramming of A•T specific minor groove binders for mixed base pair recognition

Sequence-specific binding to DNA is crucial for targeting transcription factor-DNA complexes to modulate gene expression. The heterocyclic diamidine, DB2277, specifically recognizes a single G•C base pair in the minor groove of mixed base pair sequences of the type AAAGTTT. NMR spectroscopy reveals the presence of major and minor species of the bound compound. To understand the principles that determine the binding affinity and orientation in mixed sequences of DNA, over thirty DNA hairpin substrates were examined by NMR and thermal melting. The NMR exchange dynamics between major and minor species shows that the exchange is much faster than compound dissociation determined from biosensor–surface plasmon resonance. Extensive modifications of DNA sequences resulted in a unique DNA sequence with binding site AAGATA that binds DB2277 in a single orientation. A molecular docking result agrees with the model representing rapid flipping of DB2277 between major and minor species. Imino spectral analysis of a ¹⁵N-labeled central G clearly shows the crucial role of the exocyclic amino group of G in sequence-specific recognition. Our results suggest that this approach can be expanded to additional modules for recognition of more sequence-specific DNA complexes. This approach provides substantial information about the sequence-specific, highly efficient, dynamic nature of minor groove binding agents.

Binding of Hoechst 33258 and its derivatives to DNA

In the present work, we employed UV-VIS spectroscopy, fluorescence methods, and circular dichroism spectroscopy (CD) to study the interaction of dye Hoechst 33258, Hoechst 33342, and their derivatives to poly[d(AT)].poly[d(AT)], poly(dA).poly(dT), and DNA dodecamer with the sequence 5'-CGTATATATACG-3'. We identified three types of complexes formed by Hoechst 33258, Hoechst 33342, and methylproamine with DNA, corresponding to the binding of each drug in monomer, dimer, and tetramer forms. In a dimer complex, two dye molecules are sandwiched in the same place of the minor DNA groove. Our data show that Hoechst 33258, Hoechst 33342, and methylproamine also form complexes of the third type that reflects binding of dye associates (probably tetramers) to DNA. Substitution of a hydrogen atom in the ortho position of the phenyl ring by a methyl group has a little effect on binding of monomers to DNA. However it reduces strength of binding of tetramers to DNA. In contrast, a Hoechst derivative containing the ortho-isopropyl group in the phenyl ring exhibits a low affinity to poly(dA).poly(dT) and poly[d(AT)].poly[d(AT)] and binds to DNA only in the monomer form. This can be attributed to a sterical hindrance caused by the ortho-isopropyl group for side-by-side accommodation of two dye molecules in the minor groove. Our experiments show that mode of binding of Hoechst 33258 derivatives and their affinity for DNA depend on substituents in the ortho position of the phenyl ring of the dye molecule. A statistical mechanical treatment of binding of Hoechst 33258 and its derivatives to a polynucleotide lattice is described and used for determination of binding parameters of Hoechst 33258 and its derivatives to poly[d(AT)].poly[d(AT)] and poly(dA).poly(dT).

Multiple Binding Modes for Dicationic Hoechst 33258 to DNA

The binding of dicationic Hoechst 33258 (ligand) to DNA was characterized by means of the fluorescence spectra, fluorescence intensity titration, time-resolved fluorescence decay, light scattering, circular dichroism, and fluorescence thermal denaturation measurements, and two binding modes were distinguished by the experimental results. Type 1 binding has the stoichiometry of one ligand to more than 12 base pairs, and it is defined as quasi-minor groove binding which has the typical prolonged fluorescence lifetime of about 4.4 ns. In type 1 binding, planar conformation of the ligand is favorable. Type 2 binding with phosphate to ligand ratio (P/L) < 2.5 has the stoichiometry of one ligand to two phosphates. It is defined as a highly dense and orderly stacked binding with DNA backbone as the template. Electrostatic interactions between doubly protonated ligands and negatively charged DNA backbone play a predominant role in the type 2 binding mode. The characteristics of this type of binding result in a twisted conformation of the ligand that has a fluorescence lifetime of less than 1 ns. The results also indicate that the binding is in a cooperative manner primarily by stacking of the aromatic rings of the neighboring ligands. Type 1 binding is only observed for double-stranded DNA (dsDNA) with affinity constant of 1.83 x 10(7) M-1. In the type 2 binding mode, the binding affinity constants are 4.9 x 10(6) and 4.3 x 10(6) M-1 for dsDNA and single-stranded DNA (ssDNA), respectively. The type 2 binding is base pair independent while the type 1 binding is base pair related. The experiments described in this paper revealed that the dication bindings are different from the monocation bindings reported by previous study. The dication binding leads to stronger aggregation at low ligand concentration and results in orderly arrangements of the ligands along DNA chains. Furthermore the dication binding is demonstrated to be beneficial for enhancing the DNA's stability.

An Experimental and Computational Analysis on the Differential Role of the Positional Isomers of Symmetric Bis-2-(pyridyl)-1H-benzimidazoles as DNA Binding Agents

Three symmetrical positional isomers of bis-2-(n-pyridyl)-1H-benzimidazoles (n=2, 3, 4) were synthesized and DNA binding studies were performed with these isomeric derivatives. Like bisbenzimidazole compound Hoechst 33258, these molecules also demonstrate AT-specific DNA binding. The binding affinities of 3-pyridine (m-pyben) and 4-pyridine (p-pyben) derivatized bisbenzimidazoles to double-stranded DNA were significantly higher compared to 2-pyridine derivatized benzimidazole o-pyben. This has been established by combined experimental results of isothermal fluorescence titration, circular dichroism, and thermal denaturation of DNA. To rationalize the origin of their differential binding characteristics with double-stranded DNA, computational structural analyses of the uncomplexed ligands were performed using ab initio/Density Functional Theory. The molecular conformations of the symmetric head-to-head bisbenzimidazoles have been computed. The existence of intramolecular hydrogen bonding was established in o-pyben, which confers a conformational rigidity to the molecule about the bond connecting the pyridine and benzimidazole units. This might cause reduction in its binding affinity to double-stranded DNA compared to its para and meta counterparts. Additionally, the predicted stable conformations for p-, m-, and o-pyben at the B3LYP/6-31G* and RHF/6-31G* levels were further supported by experimental pKa determination. The results provide important information on the molecular recognition process of such symmetric head to head bisbenzimidazoles toward duplex DNA.

Topoisomerase I-mediated DNA cleavage induced by the minor groove-directed binding of bibenzimidazoles to a distal site

Many agents (e.g. camptothecins, indolocarbazoles, indenoisoquinolines, and dibenzonaphthyridines) stimulate topoisomerase I (TOP1)-mediated DNA cleavage (a behavior termed topoisomerase I poisoning) by interacting with both the DNA and the enzyme at the site of cleavage (typically by intercalation between the -1 and +1 base-pairs). The bibenzimidazoles, which include Hoechst 33258 and 33342, are a family of DNA minor groove-directed agents that also stimulate topoisomerase I-mediated DNA cleavage. However, the molecular mechanism by which these ligands poison TOP1 is poorly understood. Toward this goal, we have used a combination of mutational, footprinting, and DNA binding affinity analyses to define the DNA binding site for Hoechst 33258 and a related derivative that results in optimal induction of TOP1-mediated DNA cleavage. We show that this DNA binding site is located downstream from the site of DNA cleavage, encompassing the base-pairs from position +4 to +8. The distal nature of this binding site relative to the site of DNA cleavage suggests that minor groove-directed agents like the bibenzimidazoles poison TOP1 via a mechanism distinct from compounds like the camptothecins, which interact at the site of cleavage.

DNA Sequence Dependent Monomer−Dimer Binding Modulation of Asymmetric Benzimidazole Derivatives

A number of studies indicate that DNA sequences such as AATT and TTAA have significantly different physical and interaction properties. To probe these interaction differences in detail and determine the influence of charge, we have synthesized three bisbenzimidazole derivatives, a diamidine, DB185, and monoamidines, DB183 and DB210, that are related to the well-known minor groove agent, Hoechst 33258. Footprinting studies with several natural and designed DNA fragments indicate that the synthetic compounds bind at AT sequences in the minor groove and interact more weakly at sites with TpA steps relative to sites without such steps. Circular dichroism spectroscopy also indicates that the compounds bind in the DNA minor groove. Surprisingly, Tm studies as a function of ratio indicate that the monoamidines bind to TTAA sequences as dimers, whereas the diamidine binds as a monomer. Biosensor-surface plasmon resonance (SPR) studies allowed us to quantitate the interaction differences in more detail. SPR results clearly show that the monoamidine compounds bind to the TTAA sequence in a cooperative 2:1 complex but bind as monomers to AATT. The dication binds to both sequences in monomer complexes but the binding to AATT is significantly stronger than binding to TTAA. Molecular dynamics simulations indicate that the AATT sequence has a narrow time-average minor groove width that is a very good receptor site for the bisbenzimidazole compounds. The groove in TTAA sequences is wider and the width must be reduced to form a favorable monomer complex. The monocations thus form cooperative dimers that stack in an antiparallel orientation and closely fit the structure of the TTAA minor groove. The amidine groups in the dimer are oriented in the 5' direction of the strand to which they are closest. Charge repulsion in the dication apparently keeps it from forming the dimer. It instead reduces the TTAA groove width, in an induced fit process, sufficiently to form a minor groove complex. The dimer-binding mode of DB183 and DB210 is a new DNA recognition motif and offers novel design concepts for selective targeting of DNA sequences with a wider minor groove, including those with TpA steps.

Temperature induced hyperchromism exhibited by Hoechst 33258: evidence of drug aggregation from UV-melting method

UV-thermal denaturation is a simple optical method widely employed for determination of DNA stability and interaction with ligands. Thermal denaturation of DNA and DNA-ligand complex is usually monitored at 260 nm. These data are generally presented as a function of the absorption increase of DNA alone with no consideration of the temperature dependent hyperchromism of the free ligand. Since not every ligand has absorption at 260 nm, usually this property of the ligand is ignored. Here, we report the temperature dependent hyperchromicity exhibited by Hoechst 33258 in the presence and absence of DNA. The presence of Hoechst, added to the duplex (monophasic profile, T(m)=75 degrees C) in various ratios generates a new transition at lower temperature displaying biphasic thermal transition profiles. We attributed this new transition (hyperchromic), a mere contribution from Hoechst, which might exist in aggregated forms. The extent of drug aggregation/self-association is concentration dependent. We suggest that prior to UV-melting studies the thermal dependence of the free ligand should be investigated.

Influence of phenyl ring disubstitution on bisbenzimidazole and terbenzimidazole cytotoxicity: synthesis and biological evaluation as radioprotectors

DNA minor groove binders, Hoechst 33258 and Hoechst 33342, have been reported to protect against radiation-induced DNA-strand breakage, but their mutagenicity and cytotoxicity limit their use as protectors of normal tissue during radiotherapy and as biological radioprotectors during accidental radiation exposure. On the basis of these observations, two new nontoxic disubstituted benzimidazoles were synthesized, one having two methoxy groups (5-(4-methylpiperazin-1-yl)-2-[2'-(3,4-dimethoxyphenyl)-5'-benzimidazolyl]benzimidazole, 5) and another having a methoxy and a hydroxyl group (5-(4-methylpiperazin-1-yl)-2-[2'[2''-(4-hydroxy-3-methoxyphenyl)-5' '-benzimidazolyl]-5'-benzimidazolyl]benzimidazole, 6) ortho to each other on the phenyl ring. The radiomodifying effects of these nontoxic ligands were investigated with a human glioma cell line exposed to low linear energy transfer radiation by determining cell survival and cell proliferation compared with effects of the parent compound, Hoechst 33342. Cytotoxicity assayed by analyzing clonogenicity, cell growth, and metabolic viability showed that both 5 and 6 were nontoxic at 100 microM after 72 h of exposure, whereas Hoechst 33342 resulted in lysis of 77% of these cells in 24 h. Macrocolony assay (clonogenicity) showed that 73%, 92%, and 10% of the cells survived when treated with 100 microM 5, 6, and Hoechst 33342, respectively. Both 5 and 6 did not affect the growth of BMG-1 cells. At 10 microM, 5 and 6 showed 82% and 37% protection against radiation-induced cell death (macrocolony assay) while 100% protection was observed against growth inhibition. Disubstitution of the phenyl ring has not only reduced cytotoxicity but also enhanced DNA-ligand stability, conferring high degree of radioprotection.

Sequence-specific minor groove binding by bis-benzimidazoles: water molecules in ligand recognition

The binding of two symmetric bis-benzimidazole compounds, 2,2-bis-[4'-(3"-dimethylamino-1"-propyloxy)phenyl]-5,5-bi-1H-benzimidazole and its piperidinpropylphenyl analog, to the minor groove of DNA, have been studied by DNA footprinting, surface plasmon resonance (SPR) methods and molecular dynamics simulations in explicit solvent. The footprinting and SPR methods find that the former compound has enhanced affinity and selectivity for AT sequences in DNA. The molecular modeling studies have suggested that, due to the presence of the oxygen atom in each side chain of the former compound, a water molecule is immobilized and effectively bridges between side chain and DNA base edges via hydrogen bonding interactions. This additional contribution to ligand-DNA interactions would be expected to result in enhanced DNA affinity, as is observed.

NMR characterization of the DNA binding properties of a novel Hoechst 33258 analogue peptide building block

A novel aryl-bis-benzimidazole amino acid analogue of the DNA-binding compound Hoechst 33258 has recently been designed for incorporation in peptide combinatorial libraries by replacing the N-methylpiperazine group with a carboxyl group and the hydroxy group with an amino-methyl group. The DNA-binding properties of the aryl-bis-benzimidazole monomer with the C-terminus derivatized with 3-(dimethylamino)-propylamine has been investigated in this paper by (1)H NMR studies of two different complexes with two different DNA sequences: A(5) d(5'-GCCA(5)CG-3'):d(5'-CGT(5)GGC-3') and A(3)T(3) d(5'-CGA(3)T(3)CG-3')(2). Chemical shift footprinting shows that the ligand binds at the center of the A(3)T(3) sequence but at the 3'-end of A(5). A large number of NOEs show a well-defined complex with the ligand situated at the center of the palindromic A(3)T(3) but with the asymmetric A(5) the ligand binds with an orientational preference with the bis-benzimidazole moiety displaced toward the 3'-end from the center of the duplex. Two families of models of the complexes with A(5) and A(3)T(3) were derived with restrained molecular dynamics based on a large set of 70 and 61, respectively, intermolecular ligand NOEs. Both models give a picture of a tightly fitting ligand with close van der Waals contacts with the walls of the minor groove and with the two benzimidazole and the amide hydrogens involved in bifurcated cross-strand hydrogen bonds to adenine N3 and thymine O2. The minor groove width of the models correlate well with the binding site of the ligand, and the orientational preference is argued to be a consequence of the minor groove width and hydrogen bonding.

Tris-benzimidazole derivatives: design, synthesis and DNA sequence recognition

Two tris-benzimidazole derivatives have been designed and synthesized based on the known structures of the bis-benzimidazole stain Hoechst 33258 complexed to short oligonucleotide duplexes derived from single crystal X-ray studies and from NMR. In both derivatives the phenol group has been replaced by a methoxy-phenyl substituent. Whereas one tris-benzimidazole carries a N-methyl-piperazine at the 6-position, the other one has this group replaced by a 2-amino-pyrrolidine ring. This latter substituent results in stronger DNA binding. The optimized synthesis of the drugs is described. The two tris-benzimidazoles exhibit high AT-base pair (bp) selectivity evident in footprinting experiments which show that five to six base pairs are protected by the tris-benzimidazoles as compared to four to five protected by the bis-benzimidazoles. The tris-benzimidazoles bind well to sequences like 5'-TAAAC, 5'-TTTAC and 5'-TTTAT, but it is also evident that they can bind weakly to sequences such as 5'-TATGTT-3' where the continuity of an AT stretch is interrupted by a single G*C base pair.

A simple, high-resolution method for establishing DNA binding affinity and sequence selectivity

Full details of the development of a simple, nondestructive, and high-throughput method for establishing DNA binding affinity and sequence selectivity are described. The method is based on the loss of fluorescence derived from the displacement of ethidium bromide or thiazole orange from the DNA of interest or, in selected instances, the change in intrinsic fluorescence of a DNA binding agent itself and is applicable for assessing relative or absolute DNA binding affinities. Enlisting a library of hairpin deoxyoligonucleotides containing all five base pair (512 hairpins) or four base pair (136 hairpins) sequences displayed in a 96-well format, a compound's rank order binding to all possible sequences is generated, resulting in a high-resolution definition of its sequence selectivity using this fluorescent intercalator displacement (FID) assay. As such, the technique complements the use of footprinting or affinity cleavage for the establishment of DNA binding selectivity and provides the information at a higher resolution. The merged bar graphs generated by this rank order binding provide a qualitative way to compare, or profile, DNA binding affinity and selectivity. The 96-well format assay (512 hairpins) can be conducted at a minimal cost (presently ca. $100 for hairpin deoxyoligonucleotides/assay with ethiduim bromide or less with thiazole orange), with a rapid readout using a fluorescent plate reader (15 min), and is adaptable to automation (Tecan Genesis Workstation 100 robotic system). Its use in generating a profile of DNA binding selectivity for several agents including distamycin A, netropsin, DAPI, Hoechst 33258, and berenil is described. Techniques for establishing binding constants from quantitative titrations are compared, and recommendations are made for use of a Scatchard or curve fitting analysis of the titration binding curves as a reliable means to quantitate the binding affinity.

Induced fit DNA recognition by a minor groove binding analogue of Hoechst 33258: fluctuations in DNA A tract structure investigated by NMR and molecular dynamics simulations

NMR analysis and molecular dynamics simulations of d(GGTAATTACC)(2) and its complex with a tetrahydropyrimidinium analogue of Hoechst 33258 suggest that DNA minor groove recognition in solution involves a combination of conformational selection and induced fit, rather than binding to a preorganised site. Analysis of structural fluctuations in the bound and unbound states suggests that the degree of induced fit observed is primarily a consequence of optimising van der Waals contacts with the walls of the minor groove resulting in groove narrowing through: (i) changes in base step parameters, including increased helical twist and propeller twist; (ii) changes to the sugar-phosphate backbone conformation to engulf the bound ligand; (iii) suppression of bending modes at the TpA steps. In contrast, the geometrical arrangement of hydrogen bond acceptors on the groove floor appears to be relatively insensitive to DNA conformation (helical twist and propeller twist). We suggest that effective recognition of DNA sequences (in this case an A tract structure) appears to depend to a significant extent on the sequence being flexible enough to be able to adopt the geometrically optimal conformation compatible with the various binding interactions, rather than involving 'lock and key' recognition.

Binding of a desmetallo-porphyrin conjugate of Hoechst 33258 to DNA. III. Strong bonding to single-strand oligonucleotides

The binding of the conjugate of Hoechst 33258 with 5,10,15,20-tetrakis (1-methyl-4-pyridyl)-21H,23H-porphyrin (PORHOE) to single-strand DNA has been detected by UV-vis spectrophotometry and 1H-NMR. The red-shift of porphyrin Soret band with strong hypochromicity indicates that the porphyrin moiety dominates in the interaction of the PORHOE with ssDNA. The affinity constants of PORHOE for d(GCATACAATTCG) or d(CGAATTGTATGC) were determined to be >10(5) M(-1), with strong cooperativity.

Quantitative and sequence-specific analysis of DNA-ligand interaction by means of fluorescent intercalator probes

A novel method of analysis of double-stranded DNA-ligand interaction is presented. The interaction is monitored by the fluorescence of a DNA bis-intercalator oxazole homodimer YoYo-3. The fluorescence intensity or its decay time reflects the modification of the DNA double helix. The DNA sequence is scanned by hybridization with short oligomers having consecutively overlapping complementary sequences to analyse the sequence specificity of binding. In our experiments we used as ligands the minor groove binders netropsin, SN6999 (both with AT-preference), the GC-specific ligand chromomycin A3 as well as the derivative SN6113 (non-specific interaction), which displace the bis-intercalator YoYo-3 or influence the duplex structure in such away that the fluorescence intensity and lifetime decrease in comparison to a ligand-free screening. The changes of fluorescence emission clearly define the binding motif and indicate minor groove interactions with a reduced DNA binding site. Titration of the ligand quantitatively characterizes its binding by determining the dependence of the binding constant on the oligonucleotide sequence.

Sequence-dependent variation in DNA minor groove width dictates orientational preference of Hoechst 33258 in A-tract recognition: solution NMR structure of the 2:1 complex with d(CTTTTGCAAAAG)(2)

The solution structure of the dodecamer duplex d(CTTTTGCAAAAG)(2)and its 2:1 complex with the bis -benzimidazole Hoechst 33258 has been investigated by NMR and NOE-restrained molecular dynamics (rMD) simulations. Drug molecules are bound in each of the two A-tracts with the bulky N-methylpiperazine ring of each drug located close to the central TG (CA) step, binding essentially to the narrow minor groove of each A-tract. MD simulations over 1 ns, using an explicit solvation model, reveal time-averaged sequence-dependent narrowing of the minor groove from the 3'-end towards the 5'-end of each TTTT sequence. Distinct junctions at the TpG (CpA) steps, characterised by large positive roll, low helical and propeller twists and rapid AT base pair opening rates, add to the widening of the groove at these sites and appear to account for the bound orientation of the two drug molecules with the N-methylpiperazine ring binding in the wider part of the groove close to the junctions. Comparisons between the free DNA structure and the 2:1 complex (heavy atom RMSD 1.55 A) reveal that these sequence-dependent features persist in both structures. NMR studies of the sequence d(GAAAAGCTTTTC)(2), in which the A-tracts have been inverted with the elimination of the TpG junctions, results in loss of orientational specificity of Hoechst 33258 and formation of multiple bound species in solution, consistent with the drug binding in a number of different orientations.

A terbenzimidazole that preferentially binds and conformationally alters structurally distinct DNA duplex domains: a potential mechanism for topoisomerase I poisoning

The terbenzimidazoles are a class of synthetic ligands that poison the human topoisomerase I (TOP1) enzyme and promote cancer cell death. It has been proposed that drugs of this class act as TOP1 poisons by binding to the minor groove of the DNA substrate of TOP1 and altering its structure in a manner that results in enzyme-mediated DNA cleavage. To test this hypothesis, we characterize and compare the binding properties of a 5-phenylterbenzimidazole derivative (5PTB) to the d(GA4T4C)2 and d(GT4A4C)2 duplexes. The d(GA4T4C)2 duplex contains an uninterrupted 8-bp A.T domain, which, on the basis of x-ray crystallographic data, should induce a highly hydrated "A-tract" conformation. This duplex also exhibits anomalously slow migration in a polyacrylamide gel, a feature characteristic of a noncanonical global conformational state frequently described as "bent." By contrast, the d(GT4A4C)2 duplex contains two 4-bp A.T tracts separated by a TpA dinucleotide step, which should induce a less hydrated "B-like" conformation. This duplex also migrates normally in a polyacrylamide gel, a feature further characteristic of a global, canonical B-form duplex. Our data reveal that, at 20 degrees C, 5PTB exhibits an approximately 2. 3 kcal/mol greater affinity for the d(GA4T4C)2 duplex than for the d(GT4A4C)2 duplex. Significantly, we find this sequence/conformational binding specificity of 5PTB to be entropic in origin, an observation consistent with a greater degree of drug binding-induced dehydration of the more solvated d(GA4T4C)2 duplex. By contrast with the differential duplex affinity exhibited by 5PTB, netropsin and 4',6-diamidino-2-phenylindole (DAPI), two AT-specific minor groove binding ligands that are inactive as human TOP1 poisons, bind to both duplexes with similar affinities. The electrophoretic behaviors of the ligand-free and ligand-bound duplexes are consistent with 5PTB-induced bending and/or unwinding of both duplexes, which, for the d(GA4T4C)2 duplex, is synergistic with the endogenous sequence-directed electrophoretic properties of the ligand-free duplex state. By contrast, the binding to either duplex of netropsin or DAPI induces little or no change in the electrophoretic mobilities of the duplexes. Our results demonstrate that the TOP1 poison 5PTB binds differentially to and alters the structures of the two duplexes, in contrast to netropsin and DAPI, which bind with similar affinities to the two duplexes and do not significantly alter their structures. These results are consistent with a mechanism for TOP1 poisoning in which drugs such as 5PTB differentially target conformationally distinct DNA sites and induce structural changes that promote enzyme-mediated DNA cleavage.

Designer DNA-binding drugs: the crystal structure of a meta-hydroxy analogue of Hoechst 33258 bound to d(CGCGAATTCGCG)2

An analogue of the DNA binding compound Hoechst 33258, which has the para hydroxyl group altered to be at the meta position, together with the replacement of one benzimidazole group by pyridylimidazole, has been cocrystallized with the dodecanucleotide sequence d(CGCGAATTCGCG)2. The X-ray structure has been determined at 2.2 A resolution and refined to an R factor of 20.1%. The ligand binds in the minor groove at the sequence 5'-AATTC with the bulky piperazine group extending over the CxG base pair. This binding is stabilised by hydrogen bonding and numerous close van der Waals contacts to the surface of the groove walls. The meta-hydroxyl group was found in two distinct orientations, neither of which participates in direct hydrogen bonds to the exocyclic amino group of a guanine base. The conformation of the drug differs from that found previously in other X-ray structures of Hoechst 33258-DNA complexes. There is significant variation between the minor groove widths in the complexes of Hoechst 33258 and the meta-hydroxyl derivative as a result of these conformational differences. Reasons are discussed for the inability of this derivative to actively recognise guanine.

Intrinsic conformational preferences of the Hoechst dye family and their influence of DNA binding

Quantum mechanical calculations have been used to investigate the molecular conformation of the Hoechst family of DNA-binding dyestuffs. Compounds in which the phenolic substituent adopts either a meta or para position were studied. Two different environments have been considered, which are the gas phase and aqueous solution; the conformation in aqueous solution has been modeled through a self-consistent reaction field strategy. The results clearly indicate that Hoechst dyes do not adopt a planar conformation and that the degree of planarity is controlled by the external environment. A comparison with experimental data reveals that the conformation of Hoechst dyes in the gas phase is similar to that observed in DNA complexes by X-ray crystallography. In aqueous solution, the conformation deviates from planarity more than in the gas phase, since non-bonded interactions with the solvent offset the loss of conjugative interactions. The role of the drug conformation in the binding mechanism with DNA is discussed.

Homooligomeric dA.dU and dA.dT sequences in parallel and antiparallel strand orientation: consequence of the 5-methyl groups on stability, structure and interaction with the minor groove binding drug Hoechst 33258

Oligodeoxyribonucleotides containing dA.dU base combinations were shown to form parallel stranded DNA. CD spectra and hyperchromicity profiles provide evidence that the structure is very similar to that of a related parallel stranded dA.dT oligomer. Thermal denaturation studies show that these parallel dA.dU sequences are significantly less stable than their dA.dT analogues in either antiparallel or parallel stranded orientations. The stabilizing effect of the 5-methyl group is similar for parallel and antiparallel sequences. The minor groove binding drug Hoechst 33258 binds with similar affinity to APS dA.dT and APS dA.dU sequences. However, binding to the PS dA.dT hairpin is significantly impaired as a consequence of the different groove dimensions and the presence of thymine methyl groups at the binding site. This results in an 8.6 kJmol-1 reduced free energy of binding for the PS dA.dT sequence. Replacement of the bulky methyl group with a hydrogen (ie. T-->U) results in significantly stronger Hoechst 33258 binding to the parallel dA.dU sequences with a penalty of only 4.1 kJmol-1. Our data demonstrate that although Hoechst 33258 detects the altered groove, it is still able to bind a PS duplex containing dA.dU base pairs with high affinity, despite the large structural differences from its regular binding site in APS DNA.

The width of the minor groove affects the binding of the bisquaternary heterocycle SN-6999 to duplex DNA

A complex between d(GGGAAAAACGG).d(CCGTTTTTCCC) and the minor groove binding drug SN-6999 has been studied by 1H nuclear magnetic resonance spectroscopy. The drug is found to bind in the d(A)5 tract, but with interactions extending one residue in the 3'-direction along each strand. Doubling of resonances in the complex indicates slow to intermediate exchange between two binding modes. An orientational preference (7:3) is found, the first such example in an SN-6999 complex. Furthermore, the upper limit of the lifetime for the major species is longer than was found for SN-6999 with other DNA duplexes. The preferred orientation of SN-6999 has the pyridinium ring near the 5'-end of the (+) strand; the minor binding mode has the reverse orientation. The orientational preference and slower exchange rate relative to other SN-6999 complexes is attributed to increased stabilization from van der Waals interactions due to better shape complementarity between the DNA duplex and ligand. The comparison of these results with studies of SN-6999 complexed to other DNA duplexes reveals the sensitivity of the binding properties to the delicate interplay between the molecular structure of the ligand and the specific characteristics of the DNA minor groove.

DNA structure, hydration and dynamics

Although the double helical model of DNA structure is now 40 years old, there is still considerable effort being made to elucidate the range of conformations that can be adopted by this flexible molecule. We review the current state of our knowledge of DNA structure which is available from both experimental and computational approaches.

Mode of DNA binding of bis-benzimidazoles and related structures studied by electric linear dichroism

The binding mode of a series of bis-benzimidazole analogues of Hoechst 33258 to a variety of DNAs and polynucleotides has been investigated by electric linear dichroism. Two groups of compounds were examined: (i) benzoxazole and pyridoimidazole derivatives and (ii) pyridoimidazole analogs substituted with an N-alkoxyalkyl group either directed towards the minor groove or directed away from the minor groove. The ELD data indicate that the mode of binding of these drugs varies significantly with the sequence of the target DNA sequence. The DNA binding properties of these drugs are related to their topoisomerase inhibitory properties.

Sequence-dependent effects in drug-DNA interaction: the crystal structure of Hoechst 33258 bound to the d(CGCAAATTTGCG)2 duplex

The bis-benzimidazole drug Hoechst 33258 has been co-crystallized with the dodecanucleotide sequence d(CGCAAATTTGCG)2. The structure has been solved by molecular replacement and refined to an R factor of 18.5% for 2125 reflections collected on a Xentronics area detector. The drug is bound in the minor groove, at the five base-pair site 5'-ATTTG and is in a unique orientation. This is displaced by one base pair in the 5' direction compared to previously-determined structures of this drug with the sequence d(CGCGAATTCGCG)2. Reasons for this difference in behaviour are discussed in terms of several sequence-dependent structural features of the DNA, with particular reference to differences in propeller twist and minor-groove width.