Fluorescence decay studies of the DNA-3,6-diaminoacridine complexes

The interaction of several 3,6-diaminoacridines with DNAs of various base composition has been studied by steady-state and transient fluorescence measurements. The acridine dyes employed are of the following two classes: class I - proflavine, acriflavine and 10-benzyl proflavine; class II - acridine yellow, 10-methyl acridine yellow and benzoflavine. It is found that the fluorescence decay kinetics follows a single-exponential decay law for free dye and the poly[d(A-T)]-dye complex, while that of the dye bound to DNA obeys a two-exponential decay law. The long lifetime (tau 1) for each complex is almost the same as the lifetime for the poly[d(A-T)]-dye complex, and the amplitude alpha 1 decreases with increasing GC content of DNA. The fluorescence quantum yields (phi F) of dye upon binding to DNA decrease with increasing GC content; the phi F values for class I are nearly zero when bound to poly(dG) X poly(dC), but those for class II are not zero. This is in harmony with the finding that GMP almost completely quenches the fluorescence for class I, whereas a weak fluorescence arises from the GMP-dye complex for class II. The fluorescence spectra of the DNA-dye complexes gradually shift toward longer wavelengths with increasing GC content. In this connection, the fluorescence decay parameters show a dependence on the emission wavelength; alpha 1 decreases with an increase in the emission wavelength. In view of these results, it is proposed that the decay behavior of the DNA-dye complexes has its origin in the heterogeneity of the emitting sites; the long lifetime tau 1 results from the dye bound to AT-AT sites, while the short lifetime tau 2 is attributable to the dye bound in the vicinity of GC pairs. Since GC pairs almost completely quench the fluorescence for class I, partly intercalated or externally bound dye molecules may play an important role in the component tau 2.     

Caffeine clusters as transmitters of actinomycin antibiotics to DNA in solutions

Using the screening model of hypochromism, we showed that caffeine forms regular clusters consisting of 8-12 molecules. Addition of 7-aminoactinomycin D (7AAMD, a fluorescent analogue of actinomycin D) to the clusters leads to its sorption on the cluster surface. Photoexcitation of 7AAMD leads to its desorption from the surface into the aqueous phase and emission of a quantum. Fluorescence of 7AAMD in the presence of caffeine clusters is quenched by dinitrophenol more weakly than without clusters (the quenching constants are approximately 85 and approximately 280 M(-1), respectively) due to decreased steric availability of the antibiotic to the quencher. Addition of 7AAMD-caffeine complexes to DNA leads to a long-wavelength shift in the excitation spectrum and an increase in the fluorescence intensity along with a shift of the fluorescence spectrum to the short-wavelength area. This fact reflects redistribution of the antibiotic from the caffeine surface to the hydrophobic areas inside DNA. The English version of the paper: Russian Journal of Bioorganic Chemistry, 2008, vol. 34, no. 2; see also http://www.maik.ru.     

DNA bifunctional intercalators. I. Synthesis and conformational properties of an ethidium homodimer and of an acridine ethidium heterodimer.

An ethidium homodimer and an acridine ethidium heterodimer have been synthesized. The ethidium and the acridine chromophore were introduced in such bifunctional intercalators in order to allow the fluorometric study of the interaction of such molecules with DNA, which is reported in the companion paper (Gaugain, B., Barbet, J., Capelle, N., Roques, B.P., & Le Pecq, J.B.(1978) Biochemistry 17 (following paper in this issue)). In the preparation of the acridine-ethidium dimer, we report the use of acetyl groups as new protecting agents in the phenanthridine series. Conformational studies of these molecules by visible absorption and NMR spectroscopy indicate that these dimers exist in equilibrium between folded and unfolded conformations and that this equilibrium is pH and temperature dependent. Models for the geometry of the folded forms are proposed.     

Influence of base stacking and hydrogen bonding on the fluorescence of 2-aminopurine and pyrrolocytosine in nucleic acids

Fluorescent nucleobase analogues are used extensively to probe the structure and dynamics of nucleic acids. The fluorescence of the adenine analogue 2-aminopurine and the cytosine analogue pyrrolocytosine is significantly quenched when the bases are located in regions of double-stranded nucleic acids. To allow more detailed structural information to be obtained from fluorescence studies using these bases, we have studied the excited-state properties of the bases at the CIS and TDB3LYP level in hydrogen-bonded and base-stacked complexes. The results reveal that the first excited state (the fluorescent state) of a hydrogen-bonded complex containing 2-aminopurine and thymine is just the first excited state of 2-aminopurine alone. However, the same cannot be said for structures in which 2-aminopurine is base stacked with other nucleobases. Stacking causes the molecular orbitals involved in the fluorescence transition to spread over more than one base. The predicted rate for the fluorescence transition is reduced, thus reducing the fluorescence quantum yield. The decrease in radiative rate varies with the stacking arrangement (e.g., A- or B-form DNA) and with the identity of the nucleobase with which 2-aminopurine is stacked. Stacking 2-aminopurine between two guanine moieties is shown to significantly decrease the energy gap between the first and second excited states. We do not find reliable evidence for a low-energy charge-transfer state in any of the systems that were studied. In the case of pyrrolocytosine, base stacking was found to reduce the oscillator strength for the fluorescence transition, but very little spreading of molecular orbitals across more than one base was observed.     

Polarized fluorescence studies of electrically oriented DNA-dye solutions

Transient changes have been recorded in each of the four polarized components of fluorescence, when dilute solutions of dye-tagged DNA are subjected to short electric pulses. The directions of the absorption and emission transition moments, and hence of the plane of the dye molecules, relative to the DNA geometry have been estimated for eleven dyes. Data obtained for ethidium bromide and five acridine derivatives are consistent with the intercalation model generally accepted for these dyes. In addition, it is shown that neutral red, acridine red and probably auramine O also bind with their molecular planes essentially perpendicular to the long helical axis. The remaining two, hydroxystilbamidine and the bibenzimidazole derivative Hoechst 33258, give rise to effects which indicate that these molecules bind in such a manner that the absorption and emission transitions are closely associated with the grooves of the DNA helix.     

Caffeine clusters as transmitters of actinomycin antibiotics to DNA in solution

Using the screening model of hypochromism, we showed that caffeine forms regular clusters consisting of 8–12 molecules. Addition of 7-aminoactinomycin D (7AAMD, a fluorescent analogue of actinomycin D) to the clusters leads to its sorption on the cluster surface. Photoexcitation of 7AAMD leads to its desorption from the surface into the aqueous phase and emission of a quantum. Fluorescence of 7AAMD in the presence of caffeine clusters is quenched by dinitrophenol more weakly than without clusters (the quenching constants are ～ 85 and ～280 M^?1, respectively) due to decreased steric availability of the antibiotic to the quencher. Addition of 7AAMD-caffeine complexes to DNA leads to a long-wavelength shift in the excitation spectrum and an increase in the fluorescence intensity along with a shift of the fluorescence spectrum to the short-wavelength area. This fact reflects redistribution of the antibiotic from the caffeine surface to the hydrophobic areas inside DNA.     

Binding and structural studies of the complexes of type 1 ribosome inactivating protein from Momordica balsamina with uracil and uridine

Ribosome inactivating protein (RIP) catalyzes the cleavage of glycosidic bond formed between adenine and ribose sugar of ribosomal RNA to inactivate ribosomes. Previous structural studies have shown that RNA bases, adenine, guanine, and cytosine tend to bind to RIP in the substrate binding site. However, the mode of binding of uracil with RIP was not yet known. Here, we report crystal structures of two complexes of type 1 RIP from Momordica balsamina (MbRIP1) with base, uracil and nucleoside, uridine. The binding studies of MbRIP1 with uracil and uridine as estimated using fluorescence spectroscopy showed that the equilibrium dissociation constants (K_D) were 1.2 × 10⁻⁶ M and 1.4 × 10⁻⁷ M respectively. The corresponding values obtained using surface plasmon resonance (SPR) were found to be 1.4 × 10⁻⁶ M and 1.1 × 10⁻⁷ M, respectively. Structures of the complexes of MbRIP1 with uracil (Structure-1) and uridine (Structure-2) were determined at 1.70 and 1.98 Å resolutions respectively. Structure-1 showed that uracil bound to MbRIP1 at the substrate binding site but its mode of binding was significantly different from those of adenine, guanine and cytosine. However, the mode of binding of uridine was found to be similar to those of cytidine. As a result of binding of uracil to MbRIP1 at the substrate binding site, three water molecules were expelled while eight water molecules were expelled when uridine bound to MbRIP1.     

Interaction of a copper(II)-Schiff base complexes with calf thymus DNA and their antimicrobial activity

The interaction of a copper complexes containing Schiff bases with calf thymus (CT) DNA was investigated by spectroscopic methods. UV-vis, fluorescence and CD spectroscopies were conducted to assess their binding ability with CT DNA. The binding constants K have been estimated from 0.8 to 9.1×10(4) M(-1). The percentage of hypochromism is found to be over 70% (from spectral titrations). The results showed that the copper(II) complexes could bind to DNA with an intercalative mode. Synergic action of Cu(II) complexes with ascorbic acid against Candida albicans induced the generation of free radicals and increased (more than 60 times) antimicrobial effect of these complexes.     

Direct measurement of interaction forces between a platinum dichloride complex and DNA molecules

The interaction forces between a platinum dichloride complex and DNA molecules have been studied using atomic force microscopy (AFM). The platinum dichloride complex, di-dimethylsulfoxide-dichloroplatinum (II) (Pt(DMSO)₂Cl₂), was immobilized on an AFM probe by coordinating the platinum to two amino groups to form a complex similar to Pt(en)Cl₂, which is structurally similar to cisplatin. The retraction forces were measured between the platinum complex and DNA molecules immobilized on mica plates using force curve measurements. The histogram of the retraction force for λ-DNA showed several peaks; the unit retraction force was estimated to be 130 pN for a pulling rate of 60 nm/s. The retraction forces were also measured separately for four single-base DNA oligomers (adenine, guanine, thymine, and cytosine). Retraction forces were frequently observed in the force curves for the DNA oligomers of guanine and adenine. For the guanine DNA oligomer, the most frequent retraction force was slightly lower than but very similar to the retraction force for λ-DNA. A higher retraction force was obtained for the adenine DNA oligomer than for the guanine oligomer. This result is consistent with a higher retraction activation energy of adenine with the Pt complex being than that of guanine because the kinetic rate constant for retraction correlates to exp(FΔx – ΔE) where ΔE is an activation energy, F is an applied force, and Δx is a displacement of distance.     

Adenine residue: A normal-coordinate analysis of the vibrational spectra

The frequencies observed for adenine in the Raman spectra of adenosine monophosphate (AMP) and biopolymers such as poly(A), DNA, and RNA are compared with those calculated for a model compound, 9-methyladenine, in which the methyl group is taken as a unit mass concentrated on the carbon. The force field used is a Urey-Bradley field already tested on polycrystalline adenine and its analogs D -substituted on the nitrogens, on the carbon at position 8, and on both. Assignments for adenine residue Raman bands are proposed and discussed on the basis of observed and calculated D-shifts. These assignments are examined, in particular, for bands common to both adenine and guanine residues by analysis of their behavior for Raman hypochromism.     

Distinguishing "looped-out" and "stacked-in" DNA bulge conformation using fluorescent 2-aminopurine replacing a purine base

The conformation of a bulged DNA base, whether looped-out of the DNA helix or stacked-in between the flanking bases, can be distinguished using fluorescence spectroscopy of an inserted fluorescent base. If 2-aminopurine, a structural analog of adenine and guanine, is placed in duplex DNA as the bulged base replacing an adenine or guanine, it loops out of the DNA helix into solution. This is determined by the decrease or increase of 2-aminopurine fluorescence during DNA thermomelting: if the 2-aminopurine base stacks into the helix, its fluorescence increases or remains about the same during DNA duplex melting, but if the 2-aminopurine base loops out of the helix, its fluorescence decreases upon melting of the DNA duplex.     

Crystal structure of the topoisomerase II poison 9-amino-[N-(2-dimethylamino)ethyl]acridine-4-carboxamide bound to the DNA hexanucleotide d(CGTACG)2.

The structure of the complex formed between d(CGTACG)(2) and the antitumor agent 9-amino-[N-(2-dimethylamino)ethyl]acridine-4-carboxamide has been solved to a resolution of 1.6 A using X-ray crystallography. The complex crystallized in space group P6(4) with unit cell dimensions a = b = 30.2 A and c = 39.7 A, alpha = beta = 90 degrees, gamma = 120 degrees. The asymmetric unit contains a single strand of DNA, 1. 5 drug molecules, and 29 water molecules. The final structure has an overall R factor of 19.3%. A drug molecule intercalates between each of the CpG dinucleotide steps with its side chain lying in the major groove, and the protonated dimethylamino group partially occupies positions close to ( approximately 3.0 A) the N7 and O6 atoms of guanine G2. A water molecule forms bridging hydrogen bonds between the 4-carboxamide NH and the phosphate group of the same guanine. Sugar rings adopt the C2'-endo conformation except for cytosine C1 which moves to C3'-endo, thereby preventing steric collision between its C2' methylene group and the intercalated acridine ring. The intercalation cavity is opened by rotations of the main chain torsion angles alpha and gamma at guanines G2 and G6. Intercalation perturbs helix winding throughout the hexanucleotide compared to B-DNA, steps 1 and 2 being unwound by 8 degrees and 12 degrees, respectively, whereas the central TpA step is overwound by 17 degrees. An additional drug molecule, lying with the 2-fold axis in the plane of the acridine ring, is located at the end of each DNA helix, linking it to the next duplex to form a continuously stacked structure. The protonated N,N-dimethylamino group of this "end-stacked" drug hydrogen bonds to the N7 atom of guanine G6. In both drug molecules, the 4-carboxamide group is internally hydrogen bonded to the protonated N-10 atom of the acridine ring. The structure of the intercalated complex enables a rationalization of the known structure-activity relationships for inhibition of topoisomerase II activity, cytotoxicity, and DNA-binding kinetics for 9-aminoacridine-4-carboxamides.     

Steady-state and time-resolved fluorescence studies indicate an unusual conformation of 2-aminopurine within ATAT and TATA duplex DNA sequences

2-Aminopurine (2-AP), a fluorescent analog of adenine, has been widely used as a probe for local DNA conformation, since excitation and emission characteristics and fluoresence lifetimes of 2-AP vary in a sequence-dependent manner within DNA. Using steady-state and time-resolved fluorescence techniques, we report that 2-AP appears to be unusually stacked in the internal positions of ATAT and TATA in duplex DNA. The excitation wavelength maxima for 2-AP within these contexts were red shifted, indicating reduced solvent exposure for the fluorophore. Furthermore, in these contexts, 2-AP fluorescence was resistant to acrylamide-dependent collisional quenching, suggesting that the fluorophore is protected by its stacked position within the duplex. This conclusion was further reinforced by the presence of a secondary peak at 275 nm in the fluorescence excitation spectra that is indicative of efficient excitation energy transfer from nearby non-fluorescent DNA bases. Fluorescence anisotropy decay and internal angular ‘wobbling’ motion measurements of 2-AP within these alternating AT contexts were also consistent with the fluorophore being highly constrained and immobile within the base stack. When these fluorescence characteristics are compared with those of 2-AP within other duplex DNA sequence contexts, they are unique.     

Poly(dA-dT) complexes with histone H1 and pancreatic ribonuclease: Specific base recognition evidenced by ultraviolet resonance Raman spectroscopy

The conformational changes of poly(dA-dT) from random coil to ordered structure with stacked bases produce important changes in the Raman line intensities (hypochromism) when the polymer is excited under the preresonance Raman conditions (λ excitation = 300 nm). Poly(dA-dT)–RNase and poly(dA-dT)–histone H1 interactions have been studied as models of mechanisms of destabilization and stabilization by proteins of the DNA secondary structure, respectively, following this intense preresonance Raman hypochromism. In addition, the specific variation of the intensity of the 1582-cm^?1 line of adenine is interpreted in terms of the interaction of the amino group with the RNase (thus involving the large groove). In the poly(dA-dT)–H1 complex, the intensity of the 1665-cm^?1 line of thymine increases. This increase appears to involve the C₂?O group of thymine, located in the narrow groove.     

Terbium as a solid-state probe for RNA

This paper continues previous work on the analysis of nucleic acid-terbium complexes in the solid state. The fluorescence excitation and emission spectra of the RNA-terbium(III) complex is reported. The fluorescence excitation and emission spectra of both the RNA-terbium(III) and DNA-terbium(III) complexes as trapped on millipore filters is reported. One hundred percent of the DNA combined with terbium was trapped on millipore filters. Deoxyribonucleic acid was recovered from DNA-terbium(III) complexes trapped on millipore filters using SDS-extraction. Energy transfer was shown to occur from the bases in nucleic acids to the terbium ion, whereas the actual binding of terbium to nucleic acids was due to phosphate groups. The relative fluorescence of homopolyribonucleotide-terbium complexes showed that the guanine moiety was responsible for most of the observed fluorescence. Binding studies showed an equal affinity of radioactive terbium for all the homopolyribonucleotides. The fluorescence of solid-state DNA and RNA terbium complexes was used to measure picomole quantities of DNA or RNA.     

DNA-directed aniline mustards based on 9-aminoacridine: interaction with DNA.

A series of 4-substituted aniline mustards ArNH(CH2)nOpC6H4N(CH2CH2Cl)2, where Ar is an acridine and n varies from 2 to 5, interact with DNA. Scatchard analysis shows the compounds bind tightly, with a binding site size similar to that of 9-aminoacridine. The rate of hydrolysis of the mustards, measured by HPLC, is essentially constant across the series. With increasing length of the polymethylene linker, non-covalent binding becomes less strong, but the rate of DNA alkylation increases. Viscometric helix extension measurements and electrophoretic analyses using closed circular supercoiled DNA show that all the compounds are DNA intercalating ligands. Despite these similarities, the compounds are known to have quite different patterns of DNA alkylation, switching from guanine to adenine alkylation as the chain length is extended.     

Binding studies of the anti‐retroviral drug,efavirenz to calf thymus DNA using spectroscopic and voltammetric techniques

Interactions between efavirenz (EFZ) with calf thymus DNA (CT‐DNA) were investigated in vitro under stimulated physiological conditions using multispectroscopic techniques, cyclic voltammetry viscosity measurement, and gel electrophoresis. Methylene blue and acridine orange dyes were used as spectral probes by fluorescence spectroscopy. Hypochromicity was observed in ultra‐violet (UV) absorption band of EFZ. Considerable fluorescence enhancement of EFZ was observed in the presence of increasing amounts of DNA solution and the binding constants (K_f) and corresponding numbers of binding sites (n) were calculated at different temperatures. Thermodynamic parameters including enthalpy change (ΔH) and entropy change (ΔS) were calculated to be –304.78 kJ mol^–1 and –924.52 J mol^–1 K^–1 according to the van ’t Hoff equation, which indicated that reaction is predominantly enthalpically driven. In addition, UV/vis absorption titration of DNA bases confirmed that EFZ interacted with guanine and cytosine preferentially. Gel electrophoresis of DNA with EFZ demonstrated that EFZ also has the ability to cleave supercoiled plasmid DNA. Circular dichroism study showed stabilization of the right‐handed B form of CT‐DNA. All results suggest that EFZ interacts with CT‐DNA via an intercalative mode of binding. Copyright © 2015 John Wiley & Sons, Ltd.     

Identification of the 9-aminoacridine/DNA complex responsible for photodynamic inactivation of P22

Acridine dyes bound to the condensed DNA within phage particles sensitize them to inactivation by visible light. The mechanism involves absorption of photons by an acridine/DNA complex, generating singlet oxygen, which covalently damages nearby proteins needed for DNA injection [Bryant, J., & King, J. (1985) J. Mol. Biol. 180, 837-863]. Acridines and related dyes interact with double-stranded DNA through a number of binding modes. To determine in condensed phage DNA the binding mode responsible for this inactivation, we have studied the formation of the DNA/acridine target complexes for photoinactivation. Analysis of the kinetics of 9-aminoacridine binding to Salmonella phage P22 particles revealed the formation of two binding species, one of which appeared more rapidly and was apparently an intermediate in the formation of the second. The rapidly forming species represented DNA sites with intercalated acridines, while the more slowly forming species represented the subsequent binding of additional acridine molecules to the DNA backbone of sites already containing intercalated dye. The rates of photoinactivation correlated with the rate of binding of 9-aminoacridine to the DNA backbone. This suggests that the most effective species for sensitizing phage to light-induced damage has acridine molecules stacked alongside the backbone of a region with intercalated molecules.     

Study of the interaction of DNA and acridine orange by various optical methods

The degree of binding of acridine orange to DNA, native or denatured, has been determined by equilibrium dialysis in 0.1M and 0.001M NaCl at 20°. The nature of the binding process has been investigated by studying various optical properties of the dye–DNA complexes and by relating them to the binding ratio. All these properties were found to vary quantitatively and qualitatively according to the successive stages of the process. These stages were assumed to be a strong binding of intercalated monomers followed by formation of bound dimers and finally by external binding of aggregates of native DNA. Absorption spectra of the complexes could be interpreted on that basis. Circular dichroism spectra were resolved into components: one band for intercalated monomers without interactions, two excition splittings for interacting monomers and bound dimers, respectively, weak bands and exciton splitting for external aggregates. The fluorescence intensity was greatly enhanced in intercallated monomers; its quenching at higher binding ratio was quantitatively related to dimer fixation. The value of the anisotropy of fluorescence at low binding ratio suggested a limited mobility of intercalated monomers; the decrease of polarization at higher binding was attributed to energy transfer between monomers. Electric dichroism displayed by the complexes in the dye absorption bands indicated an orientation of the bound molecules quite parallel to the base rings at low binding. In the range of fixation of dimers and external molecules, the dichroism was lower but still indicated an important degree of ordering.