Conditional Cooperativity in DNA Minor-Groove Recognition by Oligopeptides.

The recognition of specific DNA sequences in processes such as transcription is associated with a cooperative binding of proteins. Some transcription regulation mechanisms involve additional proteins that can influence the binding cooperativity by acting as corepressors or coactivators. In a conditional cooperativity mechanism, the same protein can induce binding cooperativity at one concentration and inhibit it at another. Here, we use calorimetric (ITC) and spectroscopic (UV, CD) experiments to show that such conditional cooperativity can also be achieved by the small DNA-directed oligopeptides distamycin and netropsin. Using a global thermodynamic analysis of the observed binding and (un)folding processes, we calculate the phase diagrams for this system, which show that distamycin binding cooperativity is more pronounced at lower temperatures and can be first induced and then reduced by increasing the netropsin or/and Na+ ion concentration. A molecular interpretation of this phenomenon is suggested.

Thermodynamic Study of Interactions of Distamycin A with Chromatin in Rat Liver Nuclei in the Presence of Polyamines.

We studied the thermodynamics of melting of isolated rat liver nuclei with different degrees of chromatin condensation determined by the concentration of polyamines (PA) and the solution ionic strength, as well as the effect of the antibiotic distamycin A (DM) on melting. Differential scanning calorimetry (DSC) profiles of nuclear preparations contained three peaks that reflected melting of three main chromatin domains. The number of peaks did not depend on the degree of condensation; however, nuclei with more condensed chromatin had a higher total enthalpy. DM stabilized peaks II and III corresponding to the melting of relaxed and topologically strained DNA, respectively, but destabilized peak I corresponding to the melting of nucleosome core histones. At the saturating concentration (DM/DNA molar ratio = 0.1), DM increased Tm of peaks II and III by ~5°C and decreased Tm of peak I by ~2.5°C. Based on the dependence of ΔH on DM concentration, we established that at low DM/DNA ratio (≤0.03), when DM interacted predominantly with AT-rich DNA regions, the enthalpy of peak II decreased in parallel with the increase in the enthalpy of peak III, which indicated that DM induces structural transitions in the nuclear chromatin associated with the increase in torsional stress in DNA. An increase in free energy under saturation conditions was equal to the change in the free energy of DM interaction with DNA. However, the increase in the enthalpy of melting of the nuclei in the presence of DM was much greater than the enthalpy of titration of nuclei with DM. This indicates a significant increase in the strength of interaction between the two DNA strands apparently due, among other things, to changes in the torsional stress of DNA in the nuclei. Titration of the nuclei with increasing PA concentrations resulted in the decrease in the number of DM-binding sites and the non-monotonous dependence of the enthalpy and entropy contribution to the binding free energy on the PA content. We suggested that the observed differences in the thermodynamic parameters were due to the different width of the minor groove in the nuclear chromatin DNA, which depends on PA concentration.

Differential scanning calorimetric study of antibiotic distamycin A binding with chromatin within isolated rat liver nuclei.

CONTEXT: Natural oligopeptide antibiotic distamycin A (Dst) biosynthesized by Streptomyces distallicus is traditionally used in medical practice as an anti-inflammatory and antitumour drug. OBJECTIVE: Dst was investigated for its effect on the structural components of native chromatin directly within isolated rat liver nuclei in the presence of physiologically significant cations (magnesium or spermine and spermidine). MATERIALS AND METHODS: Differential scanning calorimetry (DSC) was used to study the Dst action at molar ratio Dst/DNA = 0.1 and 0.15 mM Dst on the melting profile of nuclei suspension in different conditions. RESULTS: Results showed that the thermodynamic parameters of control nuclei in the presence of polyamines or Mg2+ were different. The incubation of nuclei with Dst raised transition temperatures of relaxed (peak II) and topologically constrained DNA (peak III) by 6-8 °C and decreased by 2-4 °C that of core-histones (peak I). The total excess transition enthalpy (ΔHexc) in buffer with polyamines (24.7 kJ/mol DNA nucleotides) increased by1.5 times versus control but in buffer with Mg2+, the value of ΔHexc (35.8 kJ/mol DNA nucleotides) remained unchanged. CONCLUSIONS: The association of Dst with chromatin in the nucleus weakens histone-DNA contacts and causes additional strengthening of interaction between two complementary DNA chains. Our results contribute towards validation of DSC to test drug ability to modulate chromatin structure in the physiological environment and to clarify the mechanism of these modulations.

DNA Minor Groove Binders-Inspired by Nature.

The synthesis and biological activity of a variety of analogues to the naturally occurring antibacterial and antifungal Distamycin A were explored by a number of authors. These compounds were subject to a large array of assays. Some of these compounds showed high activity against a range of Gram-positive, Gram-negative bacteria as well as fungi. To explore the anti-parasitic activity of this class of compounds, specific modifications had to be made. A number of these compounds proved to be active against Trypanosoma brucei. The binding of a number of these compounds to short sequences of DNA were also examined using footprinting assays as well as NMR spectroscopy. Computer modelling was employed on selected compounds to understand the way these compounds bind to specific DNA sequences. A large number of variations were made to the standard structure of Distamycin. These changes involved the replacement of the pyrrole moieties as well as the head and tail groups with a number of heterocyclic compounds. Some of these minor groove binders (MGBs) were also investigated for their capability for the treatment of cancer and in particular lung cancer.

Minor groove binder distamycin remodels chromatin but inhibits transcription.

The condensed structure of chromatin limits access of cellular machinery towards template DNA. This in turn represses essential processes like transcription, replication, repair and recombination. The repression is alleviated by a variety of energy dependent processes, collectively known as "chromatin remodeling". In a eukaryotic cell, a fine balance between condensed and de-condensed states of chromatin helps to maintain an optimum level of gene expression. DNA binding small molecules have the potential to perturb such equilibrium. We present herein the study of an oligopeptide antibiotic distamycin, which binds to the minor groove of B-DNA. Chromatin mobility assays and circular dichroism spectroscopy have been employed to study the effect of distamycin on chromatosomes, isolated from the liver of Sprague-Dawley rats. Our results show that distamycin is capable of remodeling both chromatosomes and reconstituted nucleosomes, and the remodeling takes place in an ATP-independent manner. Binding of distamycin to the linker and nucleosomal DNA culminates in eviction of the linker histone and the formation of a population of off-centered nucleosomes. This hints at a possible corkscrew type motion of the DNA with respect to the histone octamer. Our results indicate that distamycin in spite of remodeling chromatin, inhibits transcription from both DNA and chromatin templates. Therefore, the DNA that is made accessible due to remodeling is either structurally incompetent for transcription, or bound distamycin poses a roadblock for the transcription machinery to advance.

Molecular basis for the inhibition of HMGA1 proteins by distamycin A.

The molecular mechanism for the displacement of HMGA1 proteins from DNA is integral to disrupting their cellular function, which is linked to many metastatic cancers. Chemical shift and NOESY NMR experiments provide structural evidence for the displacement of an AT hook peptide (DNA binding motif of HMGA1 proteins) by both monomeric and dimeric distamycin. However, the displaced AT hook alters distamycin binding by weakening the distamycin:DNA complex, while slowing monomeric distamycin dissociation when AT hook is in excess. The central role of the AT hook was evaluated by monitoring full-length HMGA1a protein binding using fluorescence anisotropy. HMGA1a was effectively displaced by distamycin, but the cooperative binding exhibited by distamycin was eliminated by displaced HMGA1a. Additionally, these studies indicate that HMGA1a is displaced from the DNA by 1 equiv of distamycin, suggesting the ability to develop therapeutics that take advantage of the positively cooperative nature of HMGA1a binding.

Minor groove to major groove, an unusual DNA sequence-dependent change in bend directionality by a distamycin dimer.

DNA sequence-dependent conformational changes induced by the minor groove binder, distamycin, have been evaluated by polyacrylamide gel electrophoresis. The distamycin binding affinity, cooperativity, and stoichiometry with three target DNA sequences that have different sizes of alternating AT sites, ATAT, ATATA, and ATATAT, have been determined by mass spectrometry and surface plasmon resonance to help explain the conformational changes. The results show that distamycin binds strongly to and bends five or six AT base pair minor groove sites as a dimer with positive cooperativity, while it binds to ATAT as a weak, slightly anticooperative dimer. The bending direction was evaluated with an in phase A-tract reference sequence. Unlike other similar monomer minor groove binding compounds, such as netropsin, the distamycin dimer changes the directionality of the overall curvature away from the minor groove to the major groove. This distinct structural effect may allow designed distamycin derivatives to have selective therapeutic effects.

Interaction of minor groove ligands with G-quadruplexes: thermodynamic contributions of the number of quartets, T-U substitutions, and conformation.

In the presence of specific metal ions, DNA oligonucleotides containing guanine repeat sequences can adopt G-quadruplex structures. In this work, we used a combination of spectroscopic and calorimetric techniques to investigate the conformation and unfolding thermodynamics of the K(+)-form of five G-quadruplexes with sequences: d(G(2)T(2)G(2)TGTG(2)T(2)G(2)), G2, d(G(3)T(2)G(3)TGTG(3)T(2)G(3)), G3, their analogs where T is replaced with U, G2-U and G3-U, and r(G(2)U(2)G(2)UGUG(2)U(2)G(2)), rG2. These G-quadruplexes show CD spectra characteristic of the "chair" conformation (G2 and G2-U), or "basket" conformation (rG2); or a mixture of these two conformers (G3 and G3-U). Thermodynamic profiles show that the favorable folding of each G-quadruplex results from the typical compensation of a favorable enthalpy and unfavorable entropy contributions. G-quadruplex stability increase in the following order (in ΔG°(20)): rG2 (-1.3 kcal/mol) < G2 < G2-U

A more detailed picture of the interactions between virtual screening-derived hits and the DNA G-quadruplex: NMR, molecular modelling and ITC studies.

The growing amount of literature about G-quadruplex DNA clearly demonstrates that such a structure is no longer viewed as just a biophysical strangeness but it is instead being considered as an important target for the treatment of various human disorders such as cancers or venous thrombosis. In this scenario, with the aim of finding brand new molecular scaffolds able to interact with the groove of the DNA quadruplex [d(TGGGGT)](4), we recently performed a successful structure-based virtual screening (VS) campaign. As a result, six molecules were found to be somehow groove binders. Herein, we report the results of novel NMR titration experiments of these VS-derived ligands with modified quadruplexes, namely [d(TGG(Br)GGT)](4) and [d(TGGGG(Br)T)](4). The novel NMR spectroscopy experiments combined with molecular modelling studies, allow for a more detailed picture of the interaction between each binder and the quadruplex DNA. Noteworthy, isothermal titration calorimetry (ITC) measurements on the above-mentioned compounds revealed that 2, 4, and 6 besides their relatively small dimensions bind the DNA quadruplex [d(TGGGGT)](4) with higher affinity than distamycin A, to the best of our knowledge, the most potent groove binder identified thus far.

Structural and conformational requisites in DNA quadruplex groove binding: another piece to the puzzle.

The study of DNA G-quadruplex stabilizers has enjoyed a great momentum in the late years due to their application as anticancer agents. The recognition of the grooves of these structural motifs is expected to result in a higher degree of selectivity over other DNA structures. Therefore, to achieve an enhanced knowledge on the structural and conformational requisites for quadruplex groove recognition, distamycin A, the only compound for which a pure groove binding has been proven, has been chemically modified. Surprisingly, structural and thermodynamic studies revealed that the absence of Coulombic interactions results in an unprecedented binding position in which both the groove and the 3' end of the DNA are occupied. This further contribution adds another piece to the so far elusive puzzle of the recognition between ligands and DNA quadruplexes and will serve as a platform for a rational design of new groove binders.

Liposomes- and ethosomes-associated distamycins: a comparative study.

The present article describes a comparative study of the performances of liposomes and ethosomes as specialized delivery systems for distamycin A (DA) and two of its derivatives. Liposomes and ethosomes were prepared by classical methods, extruded through polycarbonate filters, and characterized in terms of dimensions, morphology, and encapsulation efficiency. It was found that DA was associated with vesicles (either liposomes or ethosomes) by around 16.0%, while both derivatives of DA showed a percentage of association around 80% in the case of liposomes and around 50% in the case of ethosomes. In vitro antiproliferative activity experiments performed on cultured human and mouse leukemic cells demonstrated that vesicles were able to increase the activity of both derivatives of DA. In addition, it was demonstrated that the aging of both liposomes- and ethosomes-associated distamycin suspensions did not heavily influence the vesicle size, while all samples showed a relevant drug leakage with time. Moreover, according to the different physicochemical characteristics of DA and its derivatives (i.e., log P), vesicle-associated DA showed the highest loss of drug with respect to both its derivatives. In conclusion, the enhancement of drug activity expressed by these specialized delivery systems-associated DD could be interesting to obtain an efficient therapeutic effect aimed at reducing or minimizing toxic effects occurring with distamycins administration.

Design, synthesis, and DNA binding properties of photoisomerizable azobenzene-distamycin conjugates: an experimental and computational study.

Here, we present the synthesis, photochemical, and DNA binding properties of three photoisomerizable azobenzene-distamycin conjugates in which two distamycin units were linked via electron-rich alkoxy or electron-withdrawing carboxamido moieties with the azobenzene core. Like parent distamycin A, these molecules also demonstrated AT-specific DNA binding. Duplex DNA binding abilities of these conjugates were found to depend upon the nature and length of the spacer, the location of protonatable residues, and the isomeric state of the conjugate. The changes in the duplex DNA binding efficiency of the individual conjugates in the dark and with their respective photoirradiated forms were examined by circular dichroism, thermal denaturation of DNA, and Hoechst displacement assay with poly[d(A-T).d(T-A)] DNA in 150 mM NaCl buffer. Computational structural analyses of the uncomplexed ligands using ab initio HF and MP2 theory and molecular docking studies involving the conjugates with duplex d[(GC(AT)10CG)]2 DNA were performed to rationalize the nature of binding of these conjugates.

Targeting DNA quadruplexes with distamycin A and its derivatives: an ITC and NMR study.

The use of small molecules that bind and stabilize G-quadruplex structures is emerging as a promising way to inhibit telomerase activity in tumor cells. In this paper, isothermal titration calorimetry (ITC) and 1H NMR studies have been conducted to examine the binding of distamycin A and its two carbamoyl derivatives (compounds 1 and 2) to the target [d(TGGGGT)]4 and d[AG3(T2AG3)3] quadruplexes from the Tetrahymena and human telomeres, respectively. The interactions were examined using two different buffered solutions containing either K+ or Na+ at a fixed ionic strength, to evaluate any influence of the ions present in solution on the binding behaviour. Experiments reveal that distamycin A and compound 1 bind the investigated quadruplexes in both solution conditions; conversely, compound 2 appears to have a poor affinity in any case. Moreover, these studies indicate that the presence of different cations in solution affects the stoichiometry and thermodynamics of the interactions.

Preferential formation of (5S,6R)-thymine glycol for oligodeoxyribonucleotide synthesis and analysis of drug binding to thymine glycol-containing DNA.

We previously reported the chemical synthesis of oligonucleotides containing thymine glycol, a major form of oxidative DNA damage. In the preparation of the phosphoramidite building block, the predominant product of the osmium tetroxide oxidation of protected thymidine was (5R,6S)-thymidine glycol. To obtain the building block of the other isomer, (5S,6R)-thymidine glycol, in an amount sufficient for oligonucleotide synthesis, the Sharpless asymmetric dihydroxylation (AD) reaction was examined. Although the reaction was very slow, (5S,6R)-thymidine glycol was obtained in preference to the (5R,6S) isomer. The ratio of (5S,6R)- and (5R,6S)-thymidine glycols was 2:1, and a trans isomer was also formed. When an ionic liquid, 1-butyl-3-methylimidazolium hexafluorophosphate, was used as a co-solvent, the reaction became faster, and the yield was improved without changing the preference. The phosphoramidite building block of (5S,6R)-thymidine glycol was prepared, and oligonucleotides containing 5S-thymine glycol were synthesized. One of the oligonucleotides was used to analyze the binding of distamycin A to thymine glycol-containing DNA by Circular dichroism (CD) spectroscopy and surface plasmon resonance (SPR) measurements. Distamycin A bound to a duplex containing either isomer of thymine glycol within the AATT target site, and its binding was observed even when the thymine glycol was placed opposite cytosine.

The binding of DNA intercalating and non-intercalating compounds to A-form and protonated form of poly(rC).poly(rG): spectroscopic and viscometric study.

Polymorphic RNA conformations may serve as potential targets for structure specific antiviral agents. As an initial step in the development of such drugs, the interaction of a wide variety of compounds which are characterized to bind to DNA through classical or partial intercalation or by mechanism of groove binding, with the A-form and the protonated form of poly(rC).poly(rG), been evaluated by multifaceted spectroscopic and viscometric techniques. Results of this study suggest that (i) ethidium intercalates to the A-form of RNA, but does not intercalate to the protonated form, (ii) methylene blue intercalates to the protonated form of the RNA but does not intercalate to the A-form, (iii) actinomycin D does not bind to either conformations of the RNA, and (iv) berberine binds to the protonated form by partial intercalation process, while its binding to the A-form is very weak. The DNA groove binder distamycin A has much higher affinity to the protonated form of the RNA compared to the A-form and binds to both structures by non-intercalative mechanism. We conclude that the binding affinity characteristics of these DNA binding molecules to the RNA conformations are vastly different and may serve as data for the development of RNA based antiviral drugs.

Carbohydrate-based DNA ligands: sugar-oligoamides as a tool to study carbohydrate-nucleic acid interactions.

Sugar-oligoamides have been designed and synthesized as structurally simple carbohydrate-based ligands to study carbohydrate-DNA interactions. The general design of the ligands 1-3 has been done as to favor the bound conformation of Distamycin-type gamma-linked covalent dimers which is a hairpin conformation. Indeed, NMR analysis of the sugar-oligoamides in the free state has indicated the presence of a percentage of a hairpin conformation in aqueous solution. The DNA binding activity of compounds 1-3 was confirmed by calf thymus DNA (ct-DNA) NMR titration. Interestingly, the binding of the different sugar-oligoamides seems to be modulated by the sugar configuration. Semiquantitative structural information about the DNA ligand complexes has been derived from NMR data. A competition experiment with Netropsin suggested that the sugar-oligoamide 3 bind to DNA in the minor groove. The NMR titrations of 1-3 with poly(dA-dT) and poly(dG-dC) suggested preferential binding to the ATAT sequence. TR-NOE NMR experiments for the sugar-oligoamide 3-ct-DNA complex both in D(2)O and H(2)O have confirmed the complex formation and given information on the conformation of the ligand in the bound state. The data confirmed that the sugar-oligoamide ligand is a hairpin in the bound state. Even more relevant to our goal, structural information on the conformation around the N-glycosidic linkage has been accessed. Thus, the sugar asymmetric centers pointing to the NH-amide and N-methyl rims of the molecule have been characterized.

Molecular dynamics simulations and free energy calculations of netropsin and distamycin binding to an AAAAA DNA binding site.

Molecular dynamics simulations have been performed on netropsin in two different charge states and on distamycin binding to the minor groove of the DNA duplex d(CGCGAAAAACGCG).d(CGCGTTTTTCGCG). The relative free energy of binding of the two non-covalently interacting ligands was calculated using the thermodynamic integration method and reflects the experimental result. From 2 ns simulations of the ligands free in solution and when bound to DNA, the mobility and the hydrogen-bonding patterns of the ligands were studied, as well as their hydration. It is shown that even though distamycin is less hydrated than netropsin, the loss of ligand-solvent interactions is very similar for both ligands. The relative mobilities of the ligands in their bound and free forms indicate a larger entropic penalty for distamycin when binding to the minor groove compared with netropsin, partially explaining the lower binding affinity of the distamycin molecule. The detailed structural and energetic insights obtained from the molecular dynamics simulations allow for a better understanding of the factors determining ligand-DNA binding.

Combinatorial identification of a novel consensus sequence for the covalent DNA-binding polyamide tallimustine.

Many agents successfully used in cancer chemotherapy either directly or indirectly covalently modify DNA. Examples include cisplatin, which forms a covalent adduct with guanines, and doxorubicin, which traps a cleavage intermediate between topoisomerase II and torsionally strained DNA. In most cases, the efficacy of these drugs depends on the efficiency and specificity of their DNA binding, as well as the discrimination between normal and neoplastic cells in their handling of the drug-DNA adducts. While much is known about the chemistry of drug-DNA adducts, little is known regarding the overall specificity of their formation, especially in the context of a whole human genome, where potentially billions of binding sites are possible. We used the combinatorial selection method restriction endonuclease protection, selection, and amplification (REPSA) to determine the DNA-binding specificity of the semisynthetic covalent DNA-binding polyamide tallimustine, which contains a benzoic acid nitrogen mustard appended to the minor groove DNA-binding natural product distamycin A. After investigating over 134 million possible sequences, we found that the highest affinity tallimustine binding sites contained one of two consensus sequences, either the expected distamycin hexamer binding sites followed by a CG base pair (e.g., 5'-TTTTTTC-3' and 5'-AAATTTC-3') or the unexpected sequence 5'-TAGAAC-3'. Curiously, we found that tallimustine preferentially alkylated the N7 position of guanines located on the periphery of these consensus sequences. These findings suggested a cooperative binding model for tallimustine in which one molecule noncovalently resides in the DNA minor groove and locally perturbs the DNA structure, thereby facilitating alkylation by a second tallimustine of an exposed guanine on another side of the DNA.

[Stabilization of G x C-containing DNA duplexes by polyamides with parallel orientation in the minor groove]. / Stabilizatsiia G x C-soderzhashchikh DNK-dupleksov poliamidami s parallel'noi orientatsiei v maloi borozdke.

The polyamides based on 4-amino-1-methylpyrrol-2-carboxylic acid, 4-amino-1-methylimidazole-2-carboxylic acid, and beta-alanine that stabilize oligonucleotide duplexes consisting of G x C pairs through parallel packing in the minor groove were studied. The initial duplex TTGCGCp x GCGCAA melts at 28 degrees C; the TTGCGCp[NH(CH2)3COPyIm betaImNH(CH2)3NH(CH3)2][NH(CH2)3COIm betaImPyNH(CH2)3N(CH3)2] x GCGCAA duplex (bisphosphoramidate with parallel orientation of ligands, where Py, Im, and beta are the residues of 1-methyl-4-aminopyrrol-2-carboxylic and 1-methyl-4-aminoimidazole-2-carboxylic acids and beta-alanine, respectively), at 48 degrees C; and the TTGCGCp[NH(CH2)3COIm betaImPyNH(CH2)3COIm betaImPyNH(CH2)3N(CH3)2] x GCGCAA duplex (a hairpin structure with antiparallel orientation), at 56 degrees C. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2004, vol. 30, no. 5; see also http: // www.maik.ru.

Binding of distamycin A to UV-damaged DNA.

We have found that distamycin A can bind to DNA duplexes containing the (6-4) photoproduct, one of the major UV lesions in DNA, despite the changes, caused by photoproduct formation, in both the chemical structure of the base moiety and the local tertiary structure of the helix. A 20-mer duplex containing the target site, AATT.AATT, was designed, and then one of the TT sequences was changed to the (6-4) photoproduct. Distamycin binding to the photoproduct-containing duplex was detected by CD spectroscopy, whereas specific binding did not occur when the TT site was changed to a cyclobutane pyrimidine dimer, another type of UV lesion. Distamycin binding was analyzed in detail using 14-mer duplexes. Curve fitting of the CD titration data and induced CD difference spectra revealed that the binding stoichiometry changed from 1:1 to 2:1 with photoproduct formation. Melting curves of the drug-DNA complexes also supported this stoichiometry.