Interaction of the antimalarial drug fluoroquine with DNA,tRNA, and poly(A): 19F-NMR chemical-shift and relaxation,optical absorption,and fluorescence studies

The interaction of the fluorinated antimalarial drug fluoroquine [7-fluoro-4-(diethyl-amino-1-methylbutylamino)quinoline] with DNA, tRNA, and poly(A) has been investigated by optical absorption, fluorescence, and ¹⁹F-nmr chemical-shift and relaxation methods. Optical absorption and fluorescence experiments indicate that fluoroquine binds to nucleic acids in a similar manner to that of its well-known analog chloroquine. At low drug-to-base pair ratios, binding of both drugs appears to be random. Fluoroquine and chloroquine also elevate the melting temperature (T_m) of DNA to a comparable extent. Binding of fluoroquine to DNA, tRNA, or poly(A) results in a downfield shift of about 1.5 ppm for the ¹⁹F-nmr resonance. The chemical shift of free fluoroquine depends on the isotopic composition of the solvent (D₂O vs H₂O). The solvent isotope shift is virtually eliminated by fluoroquine binding to any one of the nucleic acids. ¹⁹F-nmr relaxation experiments were carried out to measure the spin-lattice relaxation time (T₁), ¹⁹F{¹H} nuclear Overhauser effect (NOE), off-resonance intensity ratio (R), off-resonance rotating-frame spin-lattice relaxation time (T), and linewidth for fluoroquine in the nucleic acid complexes. By accounting for intramolecular proton-fluorine dipolar and chemical-shift anisotropy contributions to the fluorine relaxation, all of the relaxation parameters for the fluoroquine–DNA complex can be well described by a motional model incorporating long-range DNA bending on the order of a microsecond and an internal motion of the drug on the order of a nanosecond. Selective NOE experiments indicate that the fluorine in the drug is near the ribose protons in the RNA complexes, but not in the DNA complex. Details of the binding evidently differ for the two types of nucleic acids. This study provides the foundation for an investigation of fluoroquine in intact cells.     

19 F-NMR studies of oxygen binding to hemoglobin

The binding of oxygen to hemoglobin has been investigated by ¹⁹F-nuclear magnetic resonance spectroscopy. The ¹⁹F-nmr spectrum of hemoglobin trifluoroacetonylated at cysteine β 93 exhibits chemical shift changes on binding of ligands, which differ depending on which chains are undergoing complexation. Comparison of these changes to the fractional ligation of all chains, determined concurrently from the fractional change in the visible spectrum, shows that initial oxygen molecules bind preferentially to α-chains. The ¹⁹F-nmr spectrum of partially oxygenated hemoglobin contains resonances at the normal chemical shift positions of the oxygenated and deoxy species, in addition to two small resonances at intermediate positions. Analysis of the relativ magnitudes of these four peaks as functions of oxygen pressure permits identification of the intermediate species     

The interaction of ellipticine derivatives with nucleic acids studied by optical and 1H-nmr spectroscopy: Effect of size of the heterocyclic ring system

The DNA interaction of derivatives of ellipticine with heterocyclic ring systems with three, four, or five rings and a dimethylaminoethyl side chain was studied. Optical spectroscopy of drug complexes with calf thymus DNA, poly [(dA-dT) · (dA-dT)], or poly [(dG-dC) · (dG-dC)] showed a 10 nm bathochromic shift of the light absorption bands of the pentacyclic and tetracyclic compounds upon binding to the nucleic acids, which indicates binding by intercalation. For the tricyclic compound a smaller shift of 1–3 nm was observed upon binding to the nucleic acids. Flow linear dichroism studies show that the geometry of all complexes is consistent with intercalation of the ring system, except for the DNA and poly [(dG-dC) · (dG-dC)] complexes of the tricyclic compound, where the average angle between the drug molecular plane and the DNA helix axis was found to be 65°. One-dimensional ¹H-nmr spectroscopy was used to study complexes between d(CGCGATCGCG)₂ and the tricyclic and pentacyclic compounds. The results on the pentacyclic compound show nonselective broadening due to intermediate chemical exchange of most oligonucleotide resonances upon drug binding. The imino proton resonances are in slow chemical exchange, and new resonances with upfield shifts approaching 1 ppm appear upon drug binding, which supports intercalative binding of the pentacyclic compound. The results on the tricyclic compound show more rapid binding kinetics and very selective broadening of resonances. The data suggest that the tricyclic compound is in an equilibrium between intercalation and minor groove binding, with a preference to bind close to the AT base pairs with the side chain residing in the minor groove. © 1994 John Wiley & Sons, Inc.     

Site-specific protein backbone and side-chain NMR chemical shift and relaxation analysis of human vinexin SH3 domain using a genetically encoded 15N/19F-labeled unnatural amino acid

SH3 is a ubiquitous domain mediating protein-protein interactions. Recent solution NMR structural studies have shown that a proline-rich peptide is capable of binding to the human vinexin SH3 domain. Here, an orthogonal amber tRNA/tRNA synthetase pair for ¹⁵N/¹⁹F-trifluoromethyl-phenylalanine (¹⁵N/¹⁹F-tfmF) has been applied to achieve site-specific labeling of SH3 at three different sites. One-dimensional solution NMR spectra of backbone amide (¹⁵N)¹H and side-chain ¹⁹F were obtained for SH3 with three different site-specific labels. Site-specific backbone amide (¹⁵N)¹H and side-chain ¹⁹F chemical shift and relaxation analysis of SH3 in the absence or presence of a peptide ligand demonstrated different internal motions upon ligand binding at the three different sites. This site-specific NMR analysis might be very useful for studying large-sized proteins or protein complexes.     

The binding of n-butyl isocyanide to human hemoglobin

The binding of n-butyl isocyanide to hemoglobin has been investigated by ¹⁹F-nuclear magnetic resonance spectroscopy. The ¹⁹F-nmr spectrum of hemoglobin trifluoroacetonylated at cysteine β93 exhibits chemical shift changes on binding of ligands to the β chains. Comparison of these changes to the fractional change in the visible spectrum, shows that in the presence of diphosphoglyceric acid initial ligands bind preferentially to α chains. In the absence of DPG, ligation of β chains increases linearly with overall fractional ligation, indicating that binding to α and β chains is random under these conditions.     

Multinuclear magnetic resonance studies of monomers and dimers containing 2'-fluoro-2'-deoxyadenosine

A series of 2′-fluorinated adenosine compounds, dAfl, dAflp, pdAfl, dAfl-A, A-dAfl, and dAfl-dAfl, have been investigated by nmr spectroscopies. The ¹H-, ¹⁹F-, and ³¹P-nmr data provide structural information from different parts of these moleucles. The pK_a of the phosphate group of these two 2′-fluoro-2′-deoxyadenosine monophosphates was found to be the same as that of hte parent adenosine monophosphate. As for the pentose conformation, the ³E population is greatly increased as a result of the fluorine substitution at the C_2′ position. However, the populations of conformers of gg (C_4′-C_5′) and g′g′ (C_5′-O_5′) and the average angle ?′(C_3′-O_3′) of the 2′-fluoro compounds remain unchanged as compared to the natural riboadenosine monomer and dimer (A-A). Thefefore, the backbone conformation of the 2′-fluoro-2′-deoxy-adenosine, its monophosphates and dimers, resembles that of RNA. The extent of base-base overlapping in these 2′-fluoro-2′-deoxy-adenosine-containing dimers is also found to be similar to or even greater than A-A. Thus, the conformations of these compounds can be considered as those in the RNA family. These fluorocompounds also serve as models for a careful study on the ¹⁹F-nmr in nucleic acid. The ¹⁹F chemical-shift values are sensitive to the environment of the fluorine atom such as ionic structure of the neighboring group(s) (phosphate of base), solvation, and ring-ruccent anisotropic effect from the base(s). Qualitatively, the change of the ¹⁹F chemical-shift values (up to 2 ppm) is much larger than that of ¹H-nmr (up to 0.5 ppm) in the dimers. Using dAfl·poly(U), poly(dAfl)·poly(dAfl), and poly(dAfl)·poly(U) helix–coil transition as model systems, the linewidth of ¹⁹F in dAfl- residues reflects effectively the mobility of the unit in the nucleic acid complex as calibrated by uv data and by ¹H-nmr. Therefore, application of ¹⁹F-nmr spectroscopy on fluorine-substituted nucleic acid can also be used to detect nucleic acid-nucleic acid interaction in complicated systems.     

An Unexpected Major Groove Binding of Netropsin and Distamycin A to tRNAphe

Abstract

Crystalline complexes of yeast tRNA^phe and the oligopeptide antibiotics netropsin and distamycin A were prepared by diffusing drugs into crystals of tRNA. X-ray structure analyses of these complexes reveal a single common binding site for both drugs which is located in the major or deep groove of the tRNA T-stem. The netropsin-tRNA complex is stabilized by specific hydrogen bonds between the amide groups of the drug and the tRNA bases G51 0(6), U52 0(4) and G53 N(7) on one strand, and is further stabilized by electrostatic interactions between the positively charges guanidino side chain of the drug and the tRNA phosphate P53 on the same strand and the positively charged amidino propyl side chain and the phosphates P61, P62 and P63 on the opposite strand of the double helix. These results are in contrast to the implicated minor groove binding of these drugs to non-guanine sequences in DNA. The binding to the GUG sequence in tRNA implies that major groove binding to certain DNA sequences is possible.     

Nucleic acid binding properties of allicin: Spectroscopic analysis and estimation of anti-tumor potential

Background

Allicin has received much attention due to its anti-proliferative activity and not-well elucidated underlying mechanism of action. This work focuses towards determining the cellular toxicity of allicin and understanding its interaction with nucleic acid at molecular level.

Methods

MTT assay was used to assess the cell viability of A549 lung cancer cells against allicin. Fourier transform infrared (FTIR) and UV-visible spectroscopy were used to study the binding parameters of nucleic acid-allicin interaction.

Results

Allicin inhibits the proliferation of cancer cells in a concentration dependent manner. FTIR spectroscopy exhibited that allicin binds preferentially to minor groove of DNA via thymine base. Analysis of tRNA allicin complex has also revealed that allicin binds primarily through nitrogenous bases. Some amount of external binding with phosphate backbone was also observed for both DNA and RNA. UV visible spectra of both DNA allicin and RNA allicin complexes showed hypochromic shift with an estimated binding constant of 1.2 × 10⁴ M^- 1 for DNA and 1.06 × 10³ M^− 1for RNA binding. No major transition from the B-form of DNA and A-form of RNA is observed after their interaction with allicin.

Conclusions

The results demonstrated that allicin treatment inhibited the proliferation of A549 cells in a dose-dependent manner. Biophysical outcomes are suggestive of base binding and helix contraction of nucleic acid structure upon binding with allicin.

General significance

The results describe cytotoxic potential of allicin and its binding properties with cellular nucleic acid, which could be helpful in deciphering the complete mechanism of cell death exerted by allicin.     

Irreversible binding of reductively activated streptonigrin to nucleic acids in the presence of metals

The binding of streptonigrin (SN) to nucleic acids was studied in the presence of reducing agents and metals. Incubation of chemically reduced SN with DNA in vitro resulted in irreversible binding and complexes containing 1 mol of SN per 250 nucleotides were obtained. The presence of Zn²⁺ increased this binding considerably to give complexes containing 1 mol of SN per 80 nucleotides. On the other hand, Mg²⁺ decreased this binding. More drug was bound to the denatured DNA than to the native DNA. Maximum binding was obtained when SN was reduced in the presence of DNA. Increased binding was also obtained when the fully reduced SN was incubated with DNA. Considerably more SN was bound to DNA when activated enzymatically than with NaBH₄. Studies with synthetic polynucleotides in the presence of Zn²⁺ suggested that while SN has a high affinity for guanine residues, cytosine and adenine residues also serve as excellent substrates.These studies indicate that the active intermediate that binds to nucleic acids is unstable and may be derived from the fully reduced drug. These in vitro studies further suggest that Zn²⁺ plays an important role in the binding of SN to DNA and may have implications for the biological actions of SN if similar reactions occurred in vivo.     

Biphasic helix–coil transition of the ethidium bromide·poly(dA-dT) and the propidium diiodide·poly(dA-dT) Complexes. Stabilization of base-pair regions centered about the intercalation site

The nonexchangeable base and sugar proton nmr resonances and the 260 and 278-nm uv-absorbance bands of the nucleic acid were utilized to monitor the temperature-dependent duplex-to-strand transition of the alternating purine–pyrimidine deoxyribopolynucleotide poly(dA-dT) in the absence and presence of ethidium bromide (EB) at phosphate/drug = 50, 28, and 15 and propidium diiodide (PI) at P/D = 50, 25, 15, 10, and 5 in 0.1 M salt between 50° and 100°C. The nmr and optical methods monitor a biphasic duplex-to strand transition for the drug–poly(dA-dT) complexes. We have monitored the dissociation of the drug from the complex at the ethidium bromide phenanthridine ring and side-chain proton nmr resonances and the propidium diiodide 494 and 535-nm uv-absorbance bands and demonstrate that dissociation of the drug corresponds to the higher temperature transition in the biphasic nucleic acid melting curves. The lower temperature cooperative transition is assigned to the opening of drug-free AT base-pair regions in the drug–poly(dA-dT) complex and exhibits an increase in transition midpoint and a decrease in cooperativity with increasing drug concentration. The higher temperature cooperative transition is assigned to the opening of AT base-pair regions centered about the bound drug in the complex and exhibits an increase in the transition midpoint on raising the drug concentration. The large upfield shifts of the phenanthridine ring (but not side chain) protons of ethidium bromide on complex formation demonstrate intercalation of the drug between base pairs of the poly(dA-dT) duplex. The nucleic acid base and sugar resonances of poly(dA-dT) in 0.1 M phosphate undergo chemical shift changes between 0° and 50°C indicative of premelting conformational transition(s).     

Stabilization of hydrolytically labile iron(II)–cysteine peptide thiolate complexes in aqueous triton X-100 micelle solution: Spectroscopic properties mimicking of reduced rubredoxin

The absorption, CD, and ¹H- and ¹⁹F-nmr spectroscopic features of Fe(II) complexes with a series of cysteine-containing oligopeptides were investigated in aqueous (H₂O or D₂O) 10% Triton X-100 micelle solution. The complexes with distal aromatic rings, [Fe(Z-cys-Pro-Leu-cys-Gly-X)₂]²⁻ (Z = benzyloxycarbonyl; X = NH-C₆H₄-p-F, NH-CH₂-CH₂-C₆H₄-p-F, and Phe-OMe), were found to be quite stable in such aqueous micelle solution. The coordination of cysteine–peptide ligands to the Fe(II) ion is revealed by isotropically shifted ¹H-nmr signals due to the Cys C_βH₂ protons occurring at 120 ∼ 250 ppm in a D₂O Triton X-100 micelle solution (10%) at 60°C that are very similar to those reported for native reduced rubredoxin. The high stability of these cysteine peptide–Fe(II) complexes in aqueous micellar system was explained by the combined contributions from NH—S hydrogen bonds and the effect of the proximity of aromatic groups. The existence of such NH—S hydrogen bonds and interactions between aromatic ring and sulfur atom was confirmed by ¹⁹F-nmr spectral and ¹⁹F spin–lattice relaxation times (T₁) measurements. © 1998 John Wiley & Sons, Inc. Biopoly 46: 1–10, 1998     

Interactions of DNA with divalent metal ions. I. 31P-nmr studies

³¹P-nmr has been used to investigate the specific interaction of three divalent metal ions, Mg²⁺, Mn²⁺, and Co⁺², with the phosphate groups of DNA. Mg²⁺ is found to have no significant effect on any of the ³¹P-nmr parameters (chemical shift, line-width, T₁, T₂, and NOE) over a concentration range extending from 20 to 160 mM. The two paramagnetic ions, Mn²⁺ and Co²⁺, on the other hand, significantly change the ³¹P relaxation rates even at very low levels. From an analysis of the paramagnetic contributions to the spin–lattice and spin–spin relaxation rates, the effective internuclear metal–phosphorus distances are found to be 4.5 ± 0.5 and 4.1 ± 0.5 Å for Mn²⁺ and Co²⁺, respectively, corresponding to only 15 ± 5% of the total bound Mn²⁺ and Co²⁺ being directly coordinated to the phosphate groups (inner-sphere complexes). This result is independent of any assumptions regarding the location of the remaining metal ions which may be bound either as outer-sphere complexes relative to the phosphate groups or elsewhere on the DNA, possibly to the bases. Studies of the temperature effects on the ³¹P relaxation rates of DNA in the absence and presence of Mn²⁺ and Co²⁺ yielded kinetic and thermodynamic parameters which characterize the association and dissociation of the metal ions from the phosphate groups. A two-step model was used in the analysis of the kinetic data. The lifetimes of the inner-sphere complexes are 3 × 10^?7 and 1.4 × 10^?5 s for Mn²⁺ and Co²⁺, respectively. The rates of formation of the inner-sphere complexes with the phosphate are found to be about two orders of magnitude slower than the rate of the exchange of the water of hydration of the metal ions, suggesting that expulsion of water is not the rate-determining step in the formation of the inner-sphere complexes. Competition experiments demonstrate that the binding of Mg²⁺ ions is 3–4 times weaker than the binding of either Mn²⁺ or Co²⁺. Since the contribution from direct phosphate coordination to the total binding strength of these metal ion complexes is small (～15%), the higher binding strength of Mn²⁺ and Co²⁺ may be attributed either to base binding or to formation of stronger outer-sphere metal–phosphate complexes. At high levels of divalent metal ions, and when the metal ion concentration exceeds the DNA–phosphate concentration, the fraction of inner-sphere phosphate binding increases. In the presence of very high levels of Mg²⁺ (e.g., 3.1M), the inner-sphere ? outer-sphere equilibrium is shifted toward ～100% inner-sphere binding. A comparison of our DNA results and previous results obtained with tRNA indicates that tRNA and DNA have very similar divalent metal ion binding properties. A comparison of the present results with the predictions of polyelectrolyte theories is presented.     

Deciphering binding affinity,energetics, and base specificity of plant alkaloid Harmane with AT and GC hairpin duplex DNA

Insights into binding efficacy and thermodynamic aspects of small molecules are important for rational drug designing and development. Here, the interaction of Harmane (Har), a very important bioactive indole alkaloid, with AT and GC hairpin duplex−DNAs has been reported using various biophysical tools. Detailed molecular mechanism with special emphasis on binding nature, base specificity, and thermodynamics have been elucidated via probing nucleic acids with varying base compositions. Har bound to both the DNA strands exhibited hypochromic effect in absorbance whereas bathochromic and hypochromic effects in fluorescence spectra. The binding constants estimated were in the order of 10⁵ M⁻¹ (higher for GC sequence compared with AT) with 1:1 stoichiometry. Noncooperative binding mode has been observed via intercalation in both the cases. The thermodynamic profile was obtained from temperature-dependent fluorescence experiments. Both Har–AT and Har–GC complexations were exothermic in nature associated with positive entropy and negative enthalpy changes. Salt-dependent studies revealed that the binding interaction was governed by nonpolyelectrolytic and hydrophobic interaction forces. The ligand-induced structural perturbation of the DNA structures was evident from the circular dichroism data. Molecular modelling data indicated towards the involvement of hydrophobic forces and hydrogen bonding.     

The binding of copper ions to daunomycin and adriamycin

Using visible absorption, CD, ¹H nmr, and epr spectroscopy, the Cu(II) binging properties of daunomycin, adriamycin, and N-trifluoroacetyl daunomycin in water and ethanol have been explored. The drugs form two water soluble complexes having Cu-drug stoichiometries of 1:1 and 1:2, and with apparent pK_as of formation of 5.6 and 6.5, respectively. At pH values above ～8, the drugs form insoluble polymeric complexes with Cu(II). Similar species are also observed in ethanol. The structure of the compounds have been interpreted in terms of binding of the deprotonated hydroxyquinone portion of the drug to the copper ion. No evidence for the binding of the amino group on daunosamine was found.     

The effect of hyperoxia on superoxide production by lung submitochondrial particles

Terbium ion (Tb³⁺), like other rare earth lanthanides, has traditionally been viewed as binding nucleic acids at or near their ionized phosphate groups only. Here evidence is presented from ¹H NMR studies that confirms this mode of binding in Tb³⁺-mono-nucleotide complexes. However, in polynucleotides, we find that Tb³⁺ coordinately binds at two distinct sites, the phosphate moiety and electron donor groups on purine and pyrimidine bases. This two-site binding is best illustrated by complexes of Tb³⁺-polyuridylic acid, where the relative sensitivities of the uracil protons H5 and H6 to induced chemical shift and nuclear spin relaxation are the inverse of that seen in Tb³⁺-uridine monophosphate complexes. These data substantiate recently reported results derived from ultraviolet absorption and fluorescence spectroscopy (D. S. Gross and H. Simpkins, 1981, J. Biol. Chem.256, 9593–9598) that two-site binding is characteristic of the terbium(III)-polynucleotide interaction.     

35-Cl nuclear magnetic resonance studies of anion-binding sites in proteins: lactate dehydrogenase.

³⁵Cl nmr relaxation rate measurements have been used to study anion-binding sites in pig heart lactate dehydrogenase. These studies reveal two types of sites, one is intimately associated with the active site, the other is not. The nonactive site has been ascribed to a subunit site in analogy with crystallographic results from the dogfish M₄ enzyme. The binding of either the reduced or the oxidized form of NAD results in an increase in the ³⁵Cl nmr relaxation rate by a factor of 1.8–2. The enhanced nmr relaxation rate of the binary lactate dehydrogenase-NAD complex is reduced on binding of the substrate inhibitor molecules oxamate or oxalate to a value less than that exhibited by lactate dehydrogenase alone. The enhancement of the nmr relaxation rate is attributed to a decrease in the dissociation constant of Cl for the enzyme. The K_p values for Cl binding to the active center site of lactate dehydrogenase is 0.85 m and for lactate dehydrogenase-NADH is 0.25 m. The ratio of these constants, 3.4, agrees well with the measured enhancement value 3.7. The effect of coenzyme analogs on the ³⁵Cl nmr relaxation rate has been examined. 3-Acetylpyridine NAD produces an enhancement of 4.3, thionicotinamide NAD of 2.3, whereas 3-pyridinealdehyde, adenosinediphosphoribose, and adenosine diphosphate do not affect the nmr relaxation state of Cl bound to lactate dehydrogenase.     

Helix formation in model peptides based on nucleolin TPAKK motifs

The structures formed by peptide models of the N-terminal domain of the nucleolar protein nucleolin were studied by CD and nmr. The sequences of the peptides are based on the putative nucleic acid binding sequence motif TPAKK: The peptides TP1 and TP2 have the sequence acetyl-G(ATPAKKAA)_nG-amide, with n = 1 and 2, respectively. CD measurements indicate structural changes in both peptides when the lysine side chains are uncharged by increasing the pH or acetylation of the side-chain amines. When trifluoroethanol (TFE) is added, more extensive structural changes are observed, resembling helical structure based on nmr nuclear Overhauser effect (NOE) and C^α proton chemical shift changes, and CD spectra. The structure formed in 0.5M NaClO₄ as observed by nmr is similar to that when the lysine side chains are acetylated, due presumably to interactions of perchlorate ion with side-chain charges on lysines. The helical structure observed in TPAKK motifs may be stabilized via N-capping interactions involving threonine. The structures observed in TFE suggest that the Thr-Pro sequence initiates short helical segments in TPAKK motifs, and these helical structures might interact with nucleic acids, presumably via interactions between lysines and threonines of nucleolin. © 1995 John Wiley & Sons, Inc.     

Interaction of resveratrol and genistein with nucleic acids

Resveratrol (RES) and genistein (GEN) are the dietary natural products known to possess chemopreventive property and also the ability to repair DNA damage induced by mutagens/carcinogens. It is believed that the therapeutic activity of these compounds could be primarily due to their interaction with nucleic acids but detailed reports are not available. We here explore the interaction of these drugs with nucleic acids considering DNA and RNA as a potential therapeutic target. The interaction of RES and GEN has been analysed in buffered solution with DNA [saline sodium citrate (SSC)] and RNA [tris ethylene diammine tetra acetic acid (TE)] using UV-absorption and Fourier transform infrared (FTIR) spectroscopy. The UV analysis revealed lesser binding affinity with nucleic acids at lower concentration of RES (P/D = 5.00 and 10.00), while at higher drug concentration (P/D = 0.75, 1.00 and 2.50) hyperchromic effect with shift in the lambda(max) is noted for DNA and RNA. A major RES-nucleic acids complexes was observed through base pairs and phosphate backbone groups with K = 35.782 M(-1) and K = 34.25 M(-1) for DNARES and RNA-RES complexes respectively. At various concentrations of GEN (P/D = 0.25, 0.50, 0.75, 1.00 and 2.50) hyperchromicity with shift in the lambda(max) from 260-->263 nm and 260--> 270 nm is observed for DNA-GEN and RNA-GEN complexes respectively. The binding constant (from UV analysis) for GEN-nucleic acids complexes could not be obtained due to GEN absorbance overlap with that of nucleic acids at 260 nm. Nevertheless a detailed analysis with regard to the interaction of these drugs (RES/GEN) with DNA and RNA could feasibly be understood by FTIR.     

Evaluation of the binding effect and cytotoxicity assay of 2-Ethyl-5-(4-methylphenyl) pyramido pyrazole ophthalazine trione on calf thymus DNA: spectroscopic,calorimetric, and molecular dynamics approaches

With advances in new drug therapies, it is essential to understand the interactions between drugs and target molecules. In this study, we applied multiple spectroscopic techniques including absorbance, fluorescence, circular dichroism spectroscopy, viscosity, thermal melting, calorimetric, and molecular dynamics (MD) simulation to study the interaction between 2-Ethyl-5-(4-methylphenyl) pyramido pyrazole ophthalazine trione (PPF) and calf thymus DNA (ct DNA) in the absence or presence of histone H1. PPF exhibits a high binding affinity towards ct DNA in binary and ternary systems. In addition, the result for the binding constant was observed within the range 10⁴ M⁻¹ achieved through fluorescence quenching data, while the values for enthalpy and entropy changes for ct DNA–PPF and (ct DNA–H1) PPF complexes were measured to be −72.54 kJ.mol⁻¹, −161.14 J.mol⁻¹ K⁻¹, −85.34 kJ.mol⁻¹, and −19.023 J.mol⁻¹ K⁻¹, respectively. Furthermore, in accordance with circular dichroism spectra, the inducement of ct DNA structural changes was observed during binding of PPF and H1 in binary and ternary system forms. The essential roles of hydrogen bonding and van der Waals forces throughout the interaction were suggested using thermodynamic parameters. According to the obtained data, the interaction mode of ct DNA–PPF and (ct DNA–H1) PPF complexes was intercalation binding. Suggested by the MD simulation study, the ct DNA–H1 complex caused a reduction in the stability of the DNA structure in the presence or absence of ligand, which demonstrated that PPF as an intercalating agent can further distort the structure. The information achieved from this study will be very helpful in understanding the effects of PPF on the conformational state of ct DNA in the absence or presence of the H1 molecule, which seems to be quite significant for clarifying the mechanisms of action and its pharmacokinetics.