DNA-4'-6-diamidine-2-phenylindole interactions: a comparative study employing fluorescence and ultraviolet spectroscopy

DAPI is a drug that interacts with double-stranded nucleic acids, binding preferentially to A + T base pairs. The interaction is not intercalative, therefore providing a useful model for mimicking the effect of functional molecules in modifying specific sites, namely, A + T segments, of significance in gene expression. Knowledge of the nature of such interaction has been enriched by additional information obtained from comparative analysis of the data acquired by uv spectroscopy and fluorescence. Two classes of binding sites, defined by different apparent affinity constants and numbers of binding sites, are evident. All types of interaction are dependent on the nucleic acid/dye ratio and on the ionic strength of the medium.     

Reagents specific for cell surface components.

Mercury, diazonium ions and dyes which bind nucleic acids were covalently linked to dextrans using methods that resulted in non-hydrolyzable reagent-dextran bonds without impairing the binding abilities of the reagents, i.e. these dextran derivatives reacted with thiols, phenols/imidazoles and nucleic acids respectively. Since these dextran derivatives cannot penetrate into cells and since dextran itself does not bind to cells, these compounds represent reagents specific for the cell surface. They may be used both to evaluate cell surface constituents of intact cells and to affect viable cells via an interaction with those constituents. Mercury-dextran was found to bind to cells; the amount of mercury thus attached to the cells was about ten times smaller than when an equivalent concentration of free mercury ions was used. Mercury-dextran, bound to cells after a 30-min exposure at room temperature, was localized on the surface of these cells, as sodium borohydride reduced this complex giving rise to the intact cells, elementary mercury and free dextran which was released into medium. When cells were constantly exposed to the mercury-dextran, its toxic effects were comparable to that of free mercury ions. Diazonium-dextran, which also binds tightly to the cell surface, was also considerably toxic. Dextrans substituted with dyes which bind to nucleic acids were less toxic than the parent dyes themselves; it was shown that the attachment of such a dye to dextran decreased the binding of dye to cells under detection limits.     

Interaction of the antineoplastic agent mitoxantrone with double-stranded nucleic acids

The binding of mitoxantrone with double-helical nucleic acids was investigated by the methods of isothermal microcalorimetry, circular dichroism and absorption at the ionic strength mu = 0.11 and 0.011 M NaCl at temperature region of 30 divided by 60 degrees C. The investigation shows, that at mu = 0.11 M NaCl mitoxantrone interacts with double-helical nucleic acids in one way only. For such conditions using spectrophotometric titration data Scatchard plots for the binding of mitoxantrone with double-helical nucleic acids were constructed. The calculations show that the saturation stoichiometry is one mitoxantrone molecule per 2 divided by 3 base pairs DNA and 6 divided by 8 base pairs RNA. The dependence of binding constant from GC-content is observed. It is shown that the binding enthalpy of mitoxantrone with DNA and RNA increases linearly and reaches -(3.0 +/- 0.5) kkal per 1 mol mitoxantrone. It is shown that a binding mitoxantrone with double-helical nucleic acids, besides the intercalation of rings, a determinate contribution in the binding is given also by electrostatic interaction of side chains mitoxantrone with nucleic acids.     

Denaturation of nucleic acids induced by intercalating agents. Biochemical and biophysical properties of acridine orange-DNA complexes

At high binding densities acridine orange (AO) forms complexes with ds DNA which are insoluble in aqueous media. These complexes are characterized by high red- and minimal green-luminescence, 1:1 (dye/P) stoichiometry and resemble complexes of AO with ss nucleic acids. Formation of these complexes can be conveniently monitored by light scatter measurements. Light scattering properties of these complexes are believed to result from the condensation of nucleic acids induced by the cationic, intercalating ligands. The spectral and thermodynamic data provide evidence that AO (and other intercalating agents) induces denaturation of ds nucleic acids; the driving force of the denaturation is high affinity and cooperativity of binding of these ligands to ss nucleic acids. The denaturing effects of AO, adriamycin and ellipticine were confirmed by biochemical studies on accessibility of DNA bases (in complexes with these ligands) to the external probes. The denaturing properties of AO vary depending on the primary structure (sugar- and base-composition) of nucleic acids.     

Evidence for a radical mechanism in biocatalytic degradation of synthetic dyes by fungal laccases mediated by violuric acid

The bleaching activity of the Pleurotus ostreatus POXC laccase isoenzyme has been tested against selected single textile acid dyes (two anthraquinonic and two azo dyes), as well as towards a solution mimicking a real acid dye waste-water for wool. The catalytic reaction of POXC has been investigated both in the presence and in the absence of the synthetic mediator violuric acid (VIO) (–NOH type of mediator). In all the cases tested, the presence of the mediator enhanced the reaction rate and the percentage of decolorization, apart from one of the dyes (Acid Blue 62), which is itself a good substrate for the laccase-catalyzed oxidation. Electron paramagnetic resonance (EPR) experiments, after the addition of an excess of VIO to the solution of laccase, showed the presence of a strong and stable radical signal that was assigned to a neutral radical form of VIO.     

Interactions of pyronin Y(G) with nucleic acids

Spectral properties of pyronin Y(PY) alone or in complexes with natural and synthetic nucleic acids of various base compositions have been studied in aqueous solution containing 10 or 150 mM NaCl and 5 mM Hepes at pH 7.0. The dimerization constant (KD = 6.27 X 10(3), M-1) and the absorption spectra of the dye in monomeric and dimeric form were established. The complexes of PY with single-stranded (ss) nucleic acids show a hypsochromic shift in absorption, and their fluorescence is quenched by over 90% compared to free dye. In contrast, complexes with double-stranded (ds) RNA or DNA (binding by intercalation) exhibit a bathochromic shift in their absorption (excitation) spectrum, and their fluorescence is correlated with the base composition of the binding site. Namely, guanine quenches fluorescence of PY by up to 90%, whereas A, C, I, T, and U bases exert a rather minor effect on the fluorescence quantum yield of the dye. The intrinsic association constant of the dye to ds RNA (Ki = 6.96 X 10(4), M-1) and to ds DNA (Ki = 1.74 X 10(4), M-1) was measured in 150 mM NaCl; the binding site size was 2-3 base pair for both polymers. Implications of these findings for qualitative and quantitative cytochemistry of nucleic acids are discussed.     

An Evaluation of Cresyl Echt Violet Acetate as a Nissl Stain

The new cresyl echt violet acetate, of which three different batches have been tested, proves to be a very useful Nissl stain. It is especially valuable for formalin-fixed, frozen-sectioned material. By using a buffered staining bath and controlled timing in dehydration it is possible, on paraffin embedded material, to use these dyes as progressive stains apparently specific for nucleic acids. With a saturated aqueous solution of the dye, especially when a mordant of lithium carbonate is used, it is possible to stain material that has been preserved in formalin for several years and also material from which nucleic acids have been removed. The dye is useful also for staining celloidin embedded material. With the buffered stain proposed, differentiation is much easier than with older methods which included a gross overstaining and a long destaining procedure.     

Nucleotide chloramines and neutrophil-mediated cytotoxicity.

Hypochlorite is a reactive oxidant formed as an end product of the respiratory burst in activated neutrophils. It is responsible for killing bacteria and has been implicated in neutrophil-mediated tissue injury associated with the inflammatory process. Although hypochlorite is a potent cytotoxic agent, the primary mechanism by which it exerts its effect is unclear. This review examines evidence that the primary event in hypochlorite cytotoxicity is the loss of adenine nucleotides from the target cell. This loss appears to be mediated by the formation of adenine nucleotide chloramines which are reactive intermediates with a free radical character and are capable of forming stable ligands with proteins and nucleic acids.     

Electrostatic contributions to the binding free energy of the lambdacI repressor to DNA.

A model based on the nonlinear Poisson-Boltzmann (NLPB) equation is used to study the electrostatic contribution to the binding free energy of the lambdacI repressor to its operator DNA. In particular, we use the Poisson-Boltzmann model to calculate the pKa shift of individual ionizable amino acids upon binding. We find that three residues on each monomer, Glu34, Glu83, and the amino terminus, have significant changes in their pKa and titrate between pH 4 and 9. This information is then used to calculate the pH dependence of the binding free energy. We find that the calculated pH dependence of binding accurately reproduces the available experimental data over a range of physiological pH values. The NLPB equation is then used to develop an overall picture of the electrostatics of the lambdacI repressor-operator interaction. We find that long-range Coulombic forces associated with the highly charged nucleic acid provide a strong driving force for the interaction of the protein with the DNA. These favorable electrostatic interactions are opposed, however, by unfavorable changes in the solvation of both the protein and the DNA upon binding. Specifically, the formation of a protein-DNA complex removes both charged and polar groups at the binding interface from solvent while it displaces salt from around the nucleic acid. As a result, the electrostatic contribution to the lambdacI repressor-operator interaction opposes binding by approximately 73 kcal/mol at physiological salt concentrations and neutral pH. A variety of entropic terms also oppose binding. The major force driving the binding process appears to be release of interfacial water from the protein and DNA surfaces upon complexation and, possibly, enhanced packing interactions between the protein and DNA in the interface. When the various nonelectrostatic terms are described with simple models that have been applied previously to other binding processes, a general picture of protein/DNA association emerges in which binding is driven by the nonpolar interactions, whereas specificity results from electrostatic interactions that weaken binding but are necessary components of any protein/DNA complex.     

Oligodeoxynucleotides covalently linked to intercalating dyes as base sequence-specific ligands. Influence of dye attachment site.

New molecules with high and specific affinity for nucleic acid base sequences have been synthesized. They involve an oligodeoxynucleotide covalently attached to an intercalating dye. Visible absorption spectroscopy and fluorescence have been used to investigate the binding of poly(rA) to octadeoxythymidylates substituted by a 9-aminoacridine derivative in different positions along the oligonucleotide chain. The 9-amino group of the acridine dye was linked through a polymethylene bridge to the 3''-phosphate, the 5''-phosphate, the fourth internucleotidic phosphate or to both the 3''- and 5''-phosphates. Different interactions of the acridine dye were exhibited by these different substituted oligodeoxynucleotides when they bind to poly(rA). The interaction was shown to be specific for adenine-containing polynucleotides. The stability of these complexes was compared with that of oligodeoxynucleotides substituted by an alkyl group on the 3''-phosphate. The increase in stability due to the presence of the intercalating dye has been determined from the comparison of melting temperatures. These results are discussed with respect to the strategy of synthesis of a new class of molecules with high affinity and high specificity for nucleic acid base sequences.     

The dNTPase enzyme activity is inhibited by nucleic acids and contains a heat-insensitive component

The dNTpase enzyme has previously been shown to specifically hydrolyse monodeoxyribonucleoside triphosphates (dNTPs). The remnant nucleotide resulting from this hydrolysis lacks the terminal phosphate and is covalently attached as part of a 3 kDa species, which we have termed the product nucleotide binding particle or "PNBP." PNBP is resistant to numerous nucleases and RNases, suggesting that it is not a nucleic acid polymer. Given that the exclusive specificity of dNTPase for dNTPs suggests some associative cellular role for the enzyme in polynucleotide maintenance, the interaction of dNTPase with various nucleic acids has now been examined. It is demonstrated that dNTPase activity is significantly inhibited by addition of single-stranded DNA or tRNA, but not rRNA. The data presented also suggest that thio-dATP can substitute for conventional phosphoester dATP in the enzymatic reaction. It is also demonstrated that the dNTPase enzyme comprises both heat/proteolysis/denaturant stable and heat/proteolysis/denaturant-sensitive components and we propose that this stable component may be the precursor to liganded PNBP.     

An eight-stranded helical fragment in RNA crystal structure: implications for tetraplex interaction

Multistranded helical structures in nucleic acids play various functions in biological processes. Here we report the crystal structure of a hexamer, rU(BrdG)r(AGGU),at 1.5 A resolution containing a structural complex of an alternating antiparallel eight-stranded helical fragment that is sandwiched in two tetraplexes. The octaplex is formed by groove binding interaction and base tetrad intercalation between two tetraplexes. Two different forms of octaplexes have been proposed, which display different properties in interaction with proteins and nucleic acids. Adenines form a base tetrad in the novel N6-H em leader N3 conformation and further interact with uridines to form an adenine-uridine octad in the reverse Hoogsteen pairing scheme. The conformational flexibility of adenine tetrad indicates that it can optimize its conformation in different interactions.     

Calorimetry of DNA-dye interactions in aqueous solution: I. Proflavine and ethidium bromide

The results of an investigation on the interaction of proflavine and of ethidium bromide with DNA (calf thymus) in dilute aqueous solution are reported. The binding of the two dyes by DNA has been studied by means of microcalorimetric and of equilibrium dialysis measurements. Data on the thermodynamics of dimerization of both proflavine and ethidium bromide in aqueous solution obtained on the basis of spectroscopic and/or calorimetric experiments are also reported.The enthalpy data show that dye-dimerization and dye “strong” interaction with DNA are energetically favourable and quite similar while only in the latter case the phenomenon is also entropy driven. This is taken as further evidence in support of the concept that “strong” interaction-of both proflavine and ethidium bromide with DNA means dye molecules intercalation into the native, double helical structure of the biopolymer.     

Interactions of acridine orange with double stranded nucleic acids. Spectral and affinity studies

Spectral properties of acridine orange (AO) alone or in complexes with natural and synthetic nucleic acids of various base composition have been studied in aqueous solutions by absorption and fluorescence spectroscopy. The dimerization constant and absorption spectra of the dye in monomeric and dimeric form were established; dimerization of AO resulted in quenching of its fluorescence. Complexes of the dye with synthetic nucleic acids differed in the degree of enhancement of fluorescence quantum yield, varying between 1.42 to 2.38 fold as compared to AO monomer; these differences, however, were not base-dependent. Affinity of the dye to natural and synthetic polymers was studied and analyzed using McGhee-von Hippel model of polymer-ligand interactions. Because the sterical requirement for intercalative binding assumes interaction of dye monomer, the correction for AO dimerization was made in all calculations. All studied DNAs (natural and synthetic ones, the latter being homopolymer pairs or alternating copolymers of A,T or G,C or I,C base composition) had similar intrinsic association constants (KI = 5 X 10(4) - 1 X 10(5), M-1) and binding site size (n = 2.0-2.4 b.p.). The exception was poly(dA).poly(dT), having KI = 1.2 X 10(4) and n = 19.3 b.p. The results of KI measurement for calf thymus DNA and AO in different sodium ion concentration were in good agreement with predictions of the counterion condensation theory. The intercalation of AO into DNA is discussed in view of recent theoretical models of DNA-ligand interactions.     

Interaction between 1,25-dihydroxyvitamin D3 receptors and intestinal nuclei. Binding to nuclear constituents in vitro

The molecular action of 1,25-dihydroxyvitamin D3 (1,25(OH)2D3) is thought to involve its localization within the nucleus of target cells, a process mediated by intracellular receptors. This report probes both the association between chick intestinal 1,25(OH)2D3 receptors and purified homologous nuclei and the interaction between this receptor and nucleic acids. 1,25(OH)2D3 receptors bound to purified nuclei in a apparently saturable manner (Kd = 2.2-4.8 X 10(-10) M) under conditions of intermediate ionic strength and constant protein concentration. Nuclear binding was hormone-dependent; whereas receptor-hormone complex (Rs) binds to nuclei under the ionic conditions employed here (greater than 70%), hormone-free (R0) receptors do not bind (less than 10%). Binding was localized to the nuclear chromatin fraction and was extremely sensitive to KCl concentration both in the incubation medium and during postincubation treatment of nuclei. The interaction appeared to be temperature-independent, suggesting the lack of a classic activation event characteristic of most steroid receptors. Partial digestion of intestinal nuclei with DNase I eliminated subsequent receptor binding by greater than 95%, pointing to the involvement of DNA in the binding interaction. In turn, receptors were found to bind to both DNA and RNA, a characteristic independent of receptor aggregation, but sensitive to disruption with increasing ionic strength buffers. Elution of both Rs and R0 from DNA appeared identical (0.28 M KCl), whereas the strength of interaction with RNA was much less (0.12 M KCl). Thus, while there appeared to be a fundamental difference between R0 and Rs, such that only the binding of receptor-hormone complex to nuclei was allowed under the conditions employed here, this characteristic was not observed during DNA binding. Nevertheless, the possibility exists that the in vivo interaction between 1,25(OH)2D3 receptor and nuclei involves DNA and that this nuclear constituent may be the ultimate site of action of this unique sterol hormone.     

Theoretical studies on protein-nucleic acid interactions. I. Interaction of positively charged amino acids with nucleic acid fragments

Coulombic interactions between the side chains of charged amino acids (Arg⁺, Lys⁺, and His⁺) and negatively charged phosphate groups of nucleic acid fragments have been studied theoretically. Diribose monophosphate and dideoxyribose monophosphate are chosen as model systems for single-stranded RNA and DNA, respectively. The interaction energies have been calculated by second-order perturbation theory using simplified formulas for individual terms. The interaction energy in this formalism is a sum of electrostatic, polarization, dispersion, and repulsive energies. Our results show that about 90% of the total interaction energy is contributed by the electrostatic term alone. Contribution from the repulsive term exceeds that from the dispersion term. Calculated interaction energies suggest that Lys⁺ and His⁺ form more stable complexes with RNA than with single-stranded DNA. On the other hand, Arg⁺ has a higher affinity for DNA than for RNA. The affinity of nucleic acids for the three amino acids is in the order Lys⁺ > His⁺ > Arg⁺. Further, the basic amino acid residues form more stable complexes with A-DNA than with B-DNA. The role of the Coulombic interactions in the specific recognition of nucleic acids by proteins is discussed.     

Stability decrease of RNA double helices by phenylalanine-, tyrosine- and tryptophane-amides. Analysis in terms of site binding and relation to melting proteins.

The amides of L-phenylalanine, L-tyrosine and L-tryptophane decrease the melting temperatures tm of poly(A)*poly(U) and poly(I)*poly(C) double helices at low concentrations (1 mM), whereas high concentrations finally lead to an increase of tm. This dependence of the tm-values upon the ligand concentration can be represented quantitatively by a simple site binding model, providing binding parameters for the interaction between the amides and the nucleic acids both in the double- and the single-stranded conformation. According to these data the affinity to the single strands is higher than that to the double strands and increases in the series Phe less than Tyr less than Trp. The binding constants decrease with increasing salt concentration as expected for an interaction driven by electrostatic attraction. However, part of the interaction is also due to stacking between the aromatic amides and the nucleic acid bases. The present results indicate a direct correlation between the presence of aromatic amino acids at the binding site of helix destabilising proteins and the properties of simple derivatives of these amino acids. Furthermore the results suggest that very simple peptides containing aromatic amino acids served as a starting point for the evolution of helix destabilising proteins.