Thermodynamic characterization of human telomere quadruplex unfolding.

The 3'-terminal extensions of eukaryotic chromosomes are unique examples of functional single-stranded DNA. Human telomeres are constructed of the repeated DNA sequence 5'-d(TTAGGG). Four-repeats of human telomeric DNA have been characterized by high-resolution techniques to be capable of forming at least five distinct monomeric conformations. The predominant solution topology is influenced by solution conditions and the presence of 3'- or 5'-flanking residues. This study describes the unfolding mechanisms for human telomeric quadruplexes formed by eight sequence variants that form three unique antiparallel topologies in K(+) solution. Thermal unfolding monitored by circular dichroism is analyzed by singular value decomposition to enumerate the number of significant spectral species required to model the unfolding process. Thermal denaturation of all quadruplexes studied is found to be best modeled by a four-state sequential mechanism with two populated intermediates. The thermal unfolding was also investigated in 50% (v/v) acetonitrile in which a parallel topology is favored. Under these dehydrating conditions, quadruplex thermal denaturation is best modeled by a three-state sequential unfolding mechanism with one populated intermediate. Dehydrated parallel quadruplexes demonstrate increased thermal stability. The spectral properties of the unfolding intermediate suggest that it is most likely a triple-helical structure.

Binding of netropsin to several DNA constructs: evidence for at least two different 1:1 complexes formed from an -AATT-containing ds-DNA construct and a single minor groove binding ligand.

Isothermal titration calorimetry, ITC, has been used to determine the thermodynamics (DeltaG, DeltaH, and -TDeltaS) for binding netropsin to a number of DNA constructs. The DNA constructs included: six different 20-22mer hairpin forming sequences and an 8-mer DNA forming a duplex dimer. All DNA constructs had a single -AT-rich netropsin binding with one of the following sequences, (A(2)T(2))(2), (ATAT)(2), or (AAAA/TTTT). Binding energetics are less dependent on site sequence than on changes in the neighboring single stranded DNA (hairpin loop size and tail length). All of the 1:1 complexes exhibit an enthalpy change that is dependent on the fractional saturation of the binding site. Later binding ligands interact with a significantly more favorable enthalpy change (partial differential DeltaH(1-2) from 2 to 6 kcal/mol) and a significantly less favorable entropy change (partial differential (-TDeltaS(1-2))) from -4 to -9 kcal/mol). The ITC data could only be fit within expected experimental error by use of a thermodynamic model that includes two independent binding processes with a combined stoichiometry of 1 mol of ligand per 1 mol of oligonucleotide. Based on the biophysical evidence reported here, including theoretical calculations for the energetics of "trapping" or structuring of a single water molecule and molecular docking computations, it is proposed that there are two modes by which flexible ligands can bind in the minor groove of duplex DNA. The higher affinity binding mode is for netropsin to lay along the floor of the minor groove in a bent conformation and exclude all water from the groove. The slightly weaker binding mode is for the netropsin molecule to have a slightly more linear conformation and for the required curvature to be the result of a water molecule that bridges between the floor of the minor groove and two of the amidino nitrogens located at one end of the bound netropsin molecule.

Analysis and interpretation of ligand-DNA binding isotherms.

Binding studies provide information of fundamental and central importance for the complete understanding of ligand-DNA interactions. Studies of ligand binding to long natural DNA samples, to synthetic deoxypolynucleotides of simple repeating sequence, and to oligonucleotides of defined sequence are all needed to begin to understand the interaction in detail. Binding studies provide entry into the thermodynamics of the DNA interactions, which in turn provides great insight into the molecular forces that drive the binding process. This chapter summarizes both model-dependent and -independent approaches for the analysis and interpretation of binding isotherms, and should serve as a concise guide for handling experimental data.

An octakis-intercalating molecule.

Herein we report the synthesis and characterization of a polyintercalator with eight potential intercalating l,4,5,8-naphthalenetetracarboxylic diimide (NDI) units linked in a head-to-tail arrangement via a peptide linker. UV spectroscopy and viscometry measurements indicated the molecule binds to double-stranded DNA with all eight NDI units intercalated simultaneously. Competition dialysis and DNAse 1 footprinting studies revealed a preference for GC-rich regions of DNA, and circular dichroism studies revealed significant distortion of B-form DNA upon binding. Our so-called "octamer" represents, to the best of our knowledge, the first intercalator that binds as an octakis-intercalator, capable of spanning at least 16 base pairs of DNA.

Hydration changes for DNA intercalation reactions.

The hydration changes that accompany the DNA binding of five intercalators (ethidium, propidium, proflavine, daunomycin, and 7-aminoactinomycin D) were measured by the osmotic stress method with use of the osmolytes betaine, sucrose, and triethylene glycol. Water uptake was found to accompany complex formation for all intercalators except ethidium. The difference in the number of bound water molecules between the complex and the free reactants (Deltan(w)) was different for each intercalator. The values found for Deltan(w) were the following: propidium, +6; daunomycin, +18; proflavine, +30; and 7-aminoactinomycin D, +32. For ethidium binding to DNA a value of Deltan(w) = +0.25(+/-0.3) was found, indicating that within experimental error no water was released or taken up upon complex formation. Intercalation association constants measured in D2O were found to increase relative to values measured in H2O for all compounds except ethidium. A positive correlation between the ratio of binding constants (K(D2O)/K(H2O)) and Deltan(w) was found. These combined studies identify water as an important thermodynamic participant in the formation of certain intercalation complexes.

Equilibrium unfolding of Bombyx mori glycyl-tRNA synthetase.

Unfolding of Bombyx mori glycyl-tRNA synthetase was examined by multiple spectroscopic techniques. Tryptophan fluorescence of wild type enzyme and an N-terminally truncated form (N55) increased at low concentrations of urea or guanidine-HCl followed by a reduction in intensity at intermediate denaturant concentrations; a transition at higher denaturant was detected as decreased fluorescence intensity and a red-shifted emission. Solute quenching of fluorescence indicated that tryptophans become progressively solvent-exposed during unfolding. Wild type enzyme had stronger negative CD bands between 220 and 230 nm than the mutant, indicative of greater alpha-helical content. Urea or guanidine-HCl caused a reduction in ellipticity at 222 nm at low denaturant concentration with the wild type enzyme, a transition that is absent in the mutant; both enzymes exhibited a cooperative transition at higher denaturant concentrations. Both enzymes dissociate to monomers in 1.5 m urea. Unfolding of wild type enzyme is described by a multistate unfolding and a parallel two state unfolding; the two-state component is absent in the mutant. Changes in spectral properties associated with unfolding were largely reversible after dilution to low denaturant. Unfolding of glycyl-tRNA synthetase is complex with a native state, a native-like monomer, partially unfolded states, and the unfolded state.

DNA binding properties of the indolocarbazole antitumor drug NB-506.

Indolocarbazoles derived from the antibiotic rebeccamycin represent an important group of antitumor agents. Several indolocarbazoles are currently undergoing clinical trials. These compounds inhibit topoisomerase 1 to produce DNA breaks that are responsible for cell death. Unlike classical topoisomerase I poisons like camptothecin, glycosyl indolocarbazoles can form stable complexes with DNA even in the absence of topoisomerase I. At least in part, their mode of action is reminiscent of that of the anthracyclines, which also bind to nucleic acids and interfere with topoisomerase II. The lead synthetic compound in the series is the uncharged drug NB-506, which bears a glucose residue attached to the indolocarbazole chromophore substituted with two hydroxyl groups at positions 1 and 11. Here we report a detailed biophysical study aimed at characterizing the DNA binding properties of NB-506. Molecular modeling was used to compare the conformation and electronic properties of NB-506 and its analogue ED-571 bearing the two hydroxyl groups at positions 2 and 10. Surface plasmon resonance experiments, performed with DNA hairpin oligomers, indicate that NB-506 binds almost equally well to both AT and GC base pairs, and the binding affinity (K = 10(5) M(-1)) is similar to that of certain classical intercalators such as amsacrine and bisantrene. Isothermal titration calorimetry experiments show that the binding of NB-506 is enthalpy-driven (deltaH = -7.2 kcal/mol). The binding enthalpy measured for NB-506 is similar to that obtained with doxorubicin but the DNA interaction processes for the two drugs differ markedly in terms of entropy and deltaG. The free energy of NB-506 binding to DNA is considerably less favorable than that of doxorubicin. These biophysical data help us to understand further how rebeccamycin-type anticancer drugs interact with DNA.

Formaldehyde-induced alkylation of a 2'-aminoglucose rebeccamycin derivative to both A.T and G.C base pairs in DNA.

Rebeccamycin derivatives represent a promising class of antitumor agents. In this series, two glycosylated indolocarbazoles, NB-506 and NSC-655649, are currently undergoing clinical trials. Their anticancer activities are associated with their capacities to interact with DNA and to inhibit DNA topoisomerases. Previous studies revealed that the planar indolocarbazole chromophore can intercalate into DNA, locating the appended carbohydrate residue in one of the two helical grooves, probably the minor groove as is the case with the anthracyclines and other DNA-binding antibiotics. The sugar residue contributes significantly to the DNA binding free energy of NB-506. However, the exact positioning of the glycosyl residue of rebeccamycin derivatives in the drug-DNA complex remains poorly understood. To better understand how glycosylated indolocarbazoles interact with DNA, we investigated the interaction of a rebeccamycin derivative (85) bearing a 2'-amino group on the sugar residue. We show that the presence of the 2'-amino function permits the formation of covalent drug-DNA complexes in the presence of formaldehyde. Complementary biochemical and spectroscopic measurements attest that 85 reacts covalently with the 2-amino group of guanines exposed in the minor groove of the double helix, as is the case with daunomycin. In contrast to daunomycin, 85 also forms cross-links with an oligonucleotide containing only A.T base pairs. The covalent binding to A.T base pairs was detected using a gel mobility shift assay and was independently confirmed by thermal denaturation studies and by fluorescence measurements using a series of synthetic polynucleotides. The HCHO-mediated alkylation reaction of the drug with A.T base pairs apparently involves the 6-amino group of adenines exposed in the major groove whereas the covalent attachment to G.C base pairs implicates the 2-amino group of guanines situated in the opposite minor groove. Therefore, the results suggest that either the drug is able to switch grooves in response to sequence or it can simultaneously bind to both the minor and major grooves of the double helix. This study will help to guide the rational design of new DNA-binding antitumor indolocarbazole drugs and also provides a general experimental approach for probing minor versus major groove interactions between small molecules and DNA.

Allosteric, chiral-selective drug binding to DNA.

The binding interactions of (-)-daunorubicin (WP900), a newly synthesized enantiomer of the anticancer drug (+)-daunorubicin, with right- and left-handed DNA, have been studied quantitatively by equilibrium dialysis, fluorescence spectroscopy, and circular dichroism. (+)-Daunorubicin binds selectively to right-handed DNA, whereas the enantiomeric WP900 ligand binds selectively to left-handed DNA. Further, binding of the enantiomeric pair to DNA is clearly chirally selective, and each of the enantiomers was found to act as an allosteric effector of DNA conformation. Under solution conditions that initially favored the left-handed conformation of [poly(dGdC)](2), (+)-daunorubicin allosterically converted the polynucleotide to a right-handed intercalated form. In contrast, under solution conditions that initially favored the right-handed conformation of [poly(dGdC)](2), WP900 converted the polynucleotide to a left-handed form. Molecular dynamics studies by using the amber force field resulted in a stereochemically feasible model for the intercalation of WP900 into left-handed DNA. The chiral selectivity observed for the DNA binding of the daunorubicin/WP900 enantiomeric pair is far greater than the selectivity previously reported for a variety of chiral metal complexes. These results open a new avenue for the rational design of potential anticancer agents that target left-handed DNA.

Energetics of DNA intercalation reactions.

Isothermal titration calorimetry has been used to determine the binding enthalpy and heat capacity change (DeltaC(p)()) for a series of DNA intercalators, including ethidium, propidium, daunorubicin, and adriamycin. Temperature-dependent binding enthalpies were measured directly for the ligands, from which DeltaC(p)() values of -140 to -160 cal mol(-)(1) K(-)(1) were calculated. Published van't Hoff plots were reanalyzed to obtain DeltaC(p)() values of -337 to -423 cal mol(-)(1) K(-)(1) for the binding of actinomycin D to several DNA oligonucleotide duplexes with defined sequences. Heat capacity changes for DNA intercalation were found to correlate with the alterations in solvent-accessible surface area calculated from available high-resolution structural data. Multiple linear regression was used to derive the relationship DeltaC(p)() = 0. 382(+/-0.026)DeltaA(np) - 0.121(+/-0.077)DeltaA(p) cal mol(-)(1) K(-)(1), where DeltaA(np) and DeltaA(p) are the binding-induced changes in nonpolar and polar solvent-accessible surface areas (in square angstroms), respectively. The DeltaC(p)() terms were used to estimate the hydrophobic contribution to intercalative binding free energies, yielding values that ranged from -11.2 (ethidium) to -30 kcal mol(-)(1) (actinomycin D). An attempt was made to parse the observed binding free energies of ethidium and propidium into five underlying contributions. Such analysis showed that the DNA binding behavior of these simple intercalators is driven almost equally by hydrophobic effects and van der Waals contacts within the intercalation site.

NB-506, an indolocarbazole topoisomerase I inhibitor, binds preferentially to triplex DNA.

A novel competition dialysis method was used to study the structural selectivity of the nucleic acid binding of NB-506, a promising indolocarbazole anticancer agent. A pronounced preference for NB-506 binding to the DNA triplex poly [dA]:(poly[dT])(2) was observed among potential binding to 12 different nucleic acid structures and sequences. Structures included in the assay ranged from single-stranded DNA, through a variety of right-handed DNA duplexes, to multistranded triplex and tetraplex forms. RNA and left-handed Z DNA were also included in the assay. The preferential binding to triplex was confirmed by UV melting experiments. The novel and unexpected structural selectivity shown by NB-506 may arise from a complementary shape between its extended aromatic ring system and the planar triplex stack.

Sequence and structural selectivity of nucleic acid binding ligands.

The sequence and structural selectivity of 15 different DNA binding agents was explored using a novel, thermodynamically rigorous, competition dialysis procedure. In the competition dialysis method, 13 different nucleic acid structures were dialyzed against a common ligand solution. More ligand accumulated in the dialysis tube containing the structural form with the highest ligand binding affinity. DNA structural forms included in the assay ranged from single-stranded forms, through a variety of duplex forms, to multistranded triplex and tetraplex forms. Left-handed Z-DNA, RNA, and a DNA-RNA hybrid were also represented. Standard intercalators (ethidium, daunorubicin, and actinomycin D) served as control compounds and were found to show structural binding preferences fully consistent with their previously published behavior. Standard groove binding agents (DAPI, distamycin, and netropsin) showed a strong preference for AT-rich duplex DNA forms, along with apparently strong binding to the poly(dA)-[poly(dT)](2) triplex. Thermal denaturation studies revealed the apparent triplex binding to be complex, and perhaps to result from displacement of the third strand. Putative triplex (BePI, coralyne, and berberine) and tetraplex [H(2)TmPyP, 5,10,15, 20-tetrakis[4-(trimethylammonio)phenyl]-21H,23H-porphine, and N-methyl mesoporphyrin IX] selective agents showed in many cases less dramatic binding selectivity than anticipated from published reports that compared their binding to only a few structural forms. Coralyne was found to bind strongly to single-stranded poly(dA), a novel and previously unreported interaction. Finally, three compounds (berenil, chromomycin A, and pyrenemethylamine) whose structural preferences are largely unknown were examined. Pyrenemethylamine exhibited an unexpected and unprecedented preference for duplex poly(dAdT).

Substitution at the F-ring N-imide of the indolocarbazole antitumor drug NB-506 increases the cytotoxicity, DNA binding, and topoisomerase I inhibition activities.

The antitumor drug NB-506, which is currently undergoing phase I/II clinical trials, contains a DNA-intercalating indolocarbazole chromophore substituted with a glucose residue. In addition to interacting with DNA, the drug stabilizes the topoisomerase I-DNA covalent complex. To reinforce the DNA binding and anti-topoisomerase I activities of NB-506, an analogue containing a new substituent on the naphthalimide ring F was synthesized. The N-formylamino group of NB-506 has been replaced with a more hydrophilic group, N-bis(hydroxymethyl)methylamino. In this study we show that the incorporation of a longer substituent on the N6 position effectively reinforces both the interaction with DNA and the capacity of the drug to maintain the integrity of the topoisomerase I-DNA covalent complexes. The strength and the mode of binding of the drugs to DNA were studied by complementary biophysical techniques including absorption, fluorescence, and circular and linear dichroism. Various biochemical procedures were applied to investigate the effects on human topoisomerase I using plasmid DNA as well as restriction fragments. The drug binding sites and the positions of the topoisomerase I-mediated cleavage sites were mapped with nucleotide resolution using footprinting and sequencing techniques. Cytotoxicity measurements performed with various human cancer cell lines (HCT-116, DLD-1, MKN-45) indicate that the newly designed drug is 3 to 4 times more toxic to colon and gastric cancer cells than NB-506. Therefore, the results suggest that the antitumor activity of indolocarbazole-based drugs can be enhanced by incorporating DNA and/or topoisomerase I reactive groups. They also support the hypothesis that the substituent on the imide nitrogen on the F ring of NB-506 has direct interaction with the molecular target. The study helps to define the structure-activity relationships in the indolocarbazole series of antitumor agents targeting topoisomerase I.

Calories from carbohydrates: energetic contribution of the carbohydrate moiety of rebeccamycin to DNA binding and the effect of its orientation on topoisomerase I inhibition.

BACKGROUND: Only a few antitumor drugs inhibit the DNA breakage-reunion reaction catalyzed by topoisomerase. One is the camptothecin derivative topotecan that has recently been used clinically. Others are the glycosylated antibiotic rebeccamycin and its synthetic analog NB-506, which is presently in phase I of clinical trials. Unlike the camptothecins, rebeccamycin-type compounds bind to DNA. We set out to elucidate the molecular basis of their interaction with duplex DNA, with particular emphasis on the role of the carbohydrate residue. RESULTS: We compared the DNA-binding and topoisomerase-I-inhibition activities of two isomers of rebeccamycin that contain a galactose residue attached to the indolocarbazole chromophore via an alpha (axial) or a beta (equatorial) glycosidic linkage. The modification of the stereochemistry of the chromophore-sugar linkage results in a marked change of the DNA-binding and topoisomerase-I- poisoning activities. The inverted configuration at the C-1' of the carbohydrate residue abolishes intercalative binding of the drug to DNA thereby drastically reducing the binding affinity. Consequently, the alpha isomer has lost the capacity to induce topoisomerase-I-mediated cleavage of DNA. Comparison with the aglycone allowed us to determine the energetic contribution of the sugar residue. CONCLUSIONS: The optimal interaction of rebeccamycin analogs with DNA is controlled to a large extent by the stereochemistry of the sugar residue. The results clarify the role of carbohydrates in stereospecific drug-DNA interactions and provide valuable information for the rational design of new rebeccamycin-type antitumor agents.