Interaction of rat testis protein, TP, with nucleic acids in vitro. Fluorescence quenching, UV absorption, and thermal denaturation studies

The nucleic acid binding properties of the testis protein, TP, were studied with the help of physical techniques, namely, fluorescence quenching, UV difference absorption spectroscopy, and thermal melting. Results of quenching of tyrosine fluorescence of TP upon its binding to double-stranded and denatured rat liver nucleosome core DNA and poly(rA) suggest that the tyrosine residues of TP interact/intercalate with the bases of these nucleic acids. From the fluorescence quenching data, obtained at 50 mM NaCl concentration, the apparent association constants for binding of TP to native and denatured DNA and poly(rA) were calculated to be 4.4 X 10(3) M-1, 2.86 X 10(4) M-1, and 8.5 X 10(4) M-1, respectively. UV difference absorption spectra upon TP binding to poly(rA) and rat liver core DNA showed a TP-induced hyperchromicity at 260 nm which is suggestive of local melting of poly(rA) and DNA. The results from thermal melting studies of binding of TP to calf thymus DNA at 1 mM NaCl as well as 50 mM NaCl showed that although at 1 mM NaCl TP brings about a slight stabilization of the DNA against thermal melting, a destabilization of the DNA was observed at 50 mM NaCl. From these results it is concluded that TP, having a higher affinity for single-stranded nucleic acids, destabilizes double-stranded DNA, thus behaving like a DNA-melting protein.     

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.     

Application of pyronin Y(G) in cytochemistry of nucleic acids

Chinese hamster ovary (CHO) cells or isolated nuclei were stained with pyronin Y(PY) and analyzed by absorption or fluorescence microscopy, as well as by flow cytometry. Specificity of the staining reaction was assayed by testing sensitivity of the stainable material to RNase or DNase. The colored complexes detected by light absorption in fixed cells stained with PY are nonfluorescent and are most likely the products of condensation of single-stranded (ss) RNA by PY; the poly(rA) and poly(rA,rG) are the most sensitive to condensation. The products of PY interaction with double-stranded (ds) nucleic acids are fluorescent and can be detected in cells by cytofluorometry. PY used alone stains both DNA and RNA, and the staining capabilities of these nucleic acids vary depending upon the PY concentration at equilibrium; at a concentration above 330 microM, the RNA stainability decreases, perhaps due to its denaturation and condensation caused by the dye. In the presence of Hoechst 33342, PY can specifically stain RNA in fixed cells or isolated cell nuclei. Because only complexes of PY with ds RNA are fluorescent, this dye can be used as a probe of RNA conformation, e.g., to monitor denaturation of RNA in situ. The RNA stainability of mitotic cells is about 25% lower than that of cells in G2 phase, which indicates that during mitosis proportionately less cellular RNA is in the ds conformation. The advantages and limitations of the two cytochemical methods for DNA/RNA detection, one based on the use of Hoechst 33342 and PY, and another employing the metachromatic properties of acridine orange, are compared.     

Nucleic acid binding affinity of fd gene 5 protein in the cooperative binding mode

A sensitive ESR method which allows a direct quantitative determination of nucleic acid binding affinities of proteins under physiologically relevant conditions has been applied to the gene 5 protein of bacteriophage fd. This was achieved with two spin-labeled nucleic acids, (ldT, dT)n and (lA,A)n, which served as macro-molecular spin probes in ESR competition experiments. With the two different macromolecular spin probes, it was possible to determine the relative apparent affinity constants, Kapp, over a large affinity domain. In 20 mM Tris X HCl (pH 8.1), 1 mM sodium EDTA, 0.1 mM dithiothreitol, 10% (w/v) glycerol, 0.05% Triton, and 125 mM NaCl, the following affinity relationship was observed: K(dT)napp = 10(3) KfdDNAapp = 2 X 10(4) K(A)napp = 6.6 X 10(4) KrRNAapp = 1.5 X 10(5) KR17RNAapp. Increasing the [NaCl] from 125 to 200 mM caused considerably less tight binding of gene 5 protein to (lA,A)n, and a typical cooperative binding isotherm was observed, whereas at the lower [NaCl] used for the competition experiments, the binding was essentially stoichiometric. A computer fit of the experimental titration data at 200 mM NaCl gave an intrinsic binding constant, Kint, of 1300 M-1 and a cooperativity factor, omega, of 60 (Kint omega = Kapp) for (lA,A)n.     

The in vitro DNA-binding properties of purified nuclear lamin proteins and vimentin

The ability of purified nuclear lamin A, lamin B, lamin C, and vimentin from Ehrlich ascites tumor cells to bind nucleic acids was investigated in vitro via a quantitative filter binding assay. At low ionic strength, vimentin bound more nucleic acid than the nuclear lamins and showed a preference for G-containing nucleic acids. Nuclear lamins A and C were quite similar in their binding properties and bound G- and C-containing nucleic acids preferentially. The binding of poly(dT) by the lamins A and C was reduced in competition experiments by both poly(dG) and poly(dC), but not by poly(dA). Lamin B bound only oligo and poly(dG); no other nucleic acids tested were bound or could compete with the binding of oligo(dG). Vimentin, lamin A, and lamin C specifically bound a synthetic oligonucleotide human (vertebrate) telomere model. The Ka for vimentin (2.7 X 10(7) M-1) was approximately 10-fold higher than those for lamin A (2.8 X 10(6) M-1) and lamin C (2.9 X 10(6) M-1). Lamin B did not bind detectable amounts of the telomere model. Washing of lamin A- and lamin C-nucleic acid complexes, formed at low ionic strength, with solutions containing 150 mM KCl resulted in the elution of 30% of bound poly(dG)12-18 and 70% of bound synthetic oligonucleotide telomere model. These results, using purified individual proteins, are in good agreement with data from competition experiments with vimentin but are at odds with data obtained previously using a crude preparation of nuclear matrix proteins containing all three nuclear lamin proteins (Comings, D. E., and Wallack, A. S. (1978) J. Cell Sci. 34, 233-246). The nuclear lamins A and C and vimentin possess nucleic acid-binding properties that might permit their binding to specific base sequences and/or unique DNA structure, such as that observed for the binding of the telomere model. The significance of the higher affinity binding of nucleic acids by the cytoplasmic protein vimentin (compared with the nuclear lamins) remains to be elucidated.     

Structural effects in reactivity and adduct formation of polycyclic aromatic epoxide and diol epoxide derivatives with DNA: comparison between 1-oxiranylpyrene and benzo[a]pyrenediol epoxide

Reaction of 1-oxiranylpyrene (1-OP) with DNA and the structures of the covalent and noncovalent complexes formed were studied in aqueous media (5 mM phosphate buffer with 0.1 M NaCl, pH 7) by utilizing the techniques of absorption, fluorescence and linear dichroism spectroscopy in order to gain an understanding of possible structure-activity relationships for polycyclic aromatic hydrocarbon epoxides in tumorigenesis and carcinogenesis, and the results were compared with those obtained for the highly active benzo[a]pyrene diol epoxide (BaPDE). Like BaPDE, 1-OP undergoes acid-catalyzed hydrolysis with the pseudo-first-order rate constant k = 4.6 X 10(-4) s-1 in the absence of DNA, which is about 10 times slower than in the case of BaPDE. In DNA solutions, this hydrolysis is catalyzed by a rapid formation of a physically bound complex of 1-OP-DNA, which subsequently undergoes either (1) hydrolysis to a diol derivative or (2) formation of a covalent adduct of 1-OP-DNA. The same value of the noncovalent binding constant (K = 4000 M-1 is obtained for both 1-OP and for BaPDE, which suggests that the pi-electron interaction between the pyrenyl moiety and the nucleic acid bases is the dominant factor in the formation of the physical complexes and that the two extra OH groups in BaPDE do not play a significant role in determining the value of the physical binding constant.(ABSTRACT TRUNCATED AT 250 WORDS)     

Oxidative degradation of cationic metalloporphyrins in the presence of nucleic acids: a way to binding constants?

Mn(III) and Fe(III) complexes of meso-tetrakis(N-methylpyridinium-4-yl)porphyrin (M-TMePyP) and related hybrid molecules ("metalloporphyrin-ellipticine") were activated by potassium monopersulfate in the presence of variable calf thymus (CT) DNA and NaCl concentrations. Monitored by visible spectroscopy (Soret band), fast degradation of the free metalloprophyrin was observed while the DNA-bound form appeared protected. This direct quantitation of free versus bound metalloporphyrin ratios allowed determination of binding constants: Mn- and Fe-TMePyP respectively bind to CT DNA (5 mM phosphate buffer, 0.1 M NaCl, pH 7) with K = 3 X 10(4) and 1.2 X 10(4) M-1. Mn-TMePyP showed a greater affinity for poly[d(A-T)] (K = 1.2 X 10(5) M-1) than for poly[d(G-C)] (K = 0.2 X 10(4) M-1). This method allowed us access to the intrinsic DNA affinity of the metalloporphyrin moiety of the hybrid molecules "metalloporphyrin-ellipticine".     

Selective staining by 4'', 6-diamidine-2-phenylindole of nanogram quantities of DNA in the presence of RNA on gels.

4', 6-Diamidine-2-phenylindole.2HCl (DAPI) forms fluorescent complexes with double-stranded (ds) DNA but not with ds RNA as shown by fluorescence titration. The widely used dye ethidium bromide (EB) forms fluorescent complexes with both types of nucleic acids. Also, in contrast to EB, DAPI forms much weaker fluorescent complexes with single-stranded DNA than with ds DNA. These observations were utilized to develop staining procedures for the selective visualization of ds DNA on gels. The use of DAPI in addition to EB for staining makes possible the localization of ds DNA and other species of nucleic acids on a single gel.     

The binding mode of a mammalian (boar) protamine to DNA

The binding modes of mammalian and fish protamines to DNA were studied by reconstitution experiments from dansylated protamines and DNA, using fluorescence spectroscopy, thermal denaturation and sedimentation. Both boar and fish protamines showed strong positive cooperativity in binding to DNA. Binding parameters of the protamines were determined in 0.1 M NaCl, 50 mM Tricine-HCl, pH 7.4, at 37 degrees C: in the boar protamine, the cooperative binding constant (Kc) = 3.4 X 10(6) M-1 and the cooperative factor (q) = 667, in the fish protamine, Kc = 1.8 X 10(7) M-1 and q = 304. The boar protamines bound to DNA with two functional domains, but the fish protamines bound directly to DNA as a single linear molecule.     

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.     

Study of 2.5S RNA of 1,4-alpha-glucan branching enzyme by fluorescent methods using ethidium bromide

The fluorescence yield and lifetime of ethidium bromide complexes with 1,4-alpha-glucan branching enzyme and its free nucleic acid component 2.5S RNA were measured. Both fluorescence parameters showed a 10-fold increase in comparison with those characteristics for the free dye. This increase allows to suggest the existence of double-stranded regions in 2.5S RNA both in the free as well as in the protein bound state. The coefficients of fluorescence polarization were also determined for ethidium bromide complexed with free and protein bound 2.5S RNA. They proved to be 13 and 18% respectively. No concentration depolarization was observed in both types of ethidium bromide and ethidium bromide--enzyme--RNA complexes. This proves that the double-stranded regions are rather short and that two ethidium bromide molecules can't be bound to each of them. The binding isotherms were measured for ethidium bromide absorbed on 2.5S RNA and on the holoenzyme. Their parameters napp and rmax are identical in the cases of free and protein bound 2,5S RNA (rmax = 0.046 +/- 0.001). However the binding constants of ethidium bromide complexes with free and protein bound 2.5S RNA differ significantly (Kapp = 2.2 X 10(6) M-1 for free 2.5S RNA and Kapp = 1.6 X 10(6) M-1 for the holoenzyme). The quantity of nucleotides involved in the two double-stranded regions accessible for ethidium binding is estimated to be about 28%. Increasing of Mg2+ ion concentration up to 10(-3) results in a decrease of ethidium bromide binding with double stranded regions. It may be due to a more compact tertiary structure of 2.5S RNA in the presence of Mg2+ in the free as well as in protein bound state.     

The metallochromic indicator dye Arsenazo III forms 1:1 complexes with caffeine

The metallochromic indicator dye, Arsenazo III, forms a 1:1 complex with caffeine, a methylxanthine. Binding is accompanied by a wavelength-dependent shift in the absorption spectrum of the dye. The magnitude of the absorption change is significant at wavelengths typically used to monitor intracellular calcium ion. The equilibrium constant for the caffeine-dye reaction is approx. 20 mM. The complex has a differential molar extinction coefficient of -5.05 X 10(3) M-1 X cm-1 at 630 nm.     

Romanowsky dyes and Romanowsky-Giemsa effect. 2. Eosin Y, erythrosin B, tetrachlorofluorescein, spectroscopic characterization of pure dyes, association of eosin Y

Analytically pure samples of the Romanowsky dyes eosin y, erythrosin b and tetrachlorofluorescein are prepared. DC of the dye samples shows no contaminations. We measured the absorption spectra of the dye dianions in alkaline aqueous solution and of the dye acids in 95% ethanol at very low dye concentrations. The molar extinction coefficients of the long wavelength absorption of the monomeric dye species are determined (Table 1). The extinction coefficients may be used for standardisation of dye samples. The absorption spectra of eosin y in aqueous solution are dependent on concentration. Using a new very sensitive method it was possible to identify two association equilibria from the concentration dependency of the spectra. Dimers are formed even in very dilute solutions, at higher concentrations tetramers. The dissociation constant of the dimers D in monomers M at 293 K, pH = 12, is K21 = 2,9 X 10(-5) M; of the tetramers Q in dimers D K42 = 2,4 X 10(-3) M. From the experimental spectra of eosin solutions at various concentrations, pH = 12, and the equilibrium constants K21, K42 the absorption spectra of the pure monomers, dimers and tetramers are calculated. M has one long wavelength absorption band, VM = 19300 cm-1, epsilon M = 1,03 X 10(5) M-1 cm-1; D also one absorption band, VD = 19300 cm-1, epsilon D = 1,74 X 10(5) M-1 cm-1; Q two absorption bands, VQ1 = 19100, VQ2 = 20200 cm-1, epsilon Q1 = 1,65 X 10(5), epsilon Q2 = 1,96 X 10(5) M-1 cm-1. The absorption spectrum of the dimers is discussed by quantum mechanics.     

Steroid-binding site of human and rabbit sex steroid binding protein of plasma: fluorescence characterization with equilenin

The interaction of the estrogen d-3-hydroxy-1,3,5(10),6,8-estrapentaen-17-one (equilenin) with the human and rabbit sex steroid binding proteins (hSBP and rSBP, respectively) has been investigated by using fluorescence and absorption spectroscopy. Equilenin competes for the binding of 5 alpha-dihydrotestosterone. The calculated binding constant of equilenin for rSBP is 1.9 X 10(7) M-1 at 4 degrees C, which can be compared with the binding constant of 5.7 X 10(7) M-1 reported for hSBP [Ross, J.B.A., Torres, R., & Petra, P.H. (1982) FEBS Lett. 149, 240]. The results of fluorescence quenching experiments with the collisional quenchers KI and acrylamide indicate that the bound steroid has limited accessibility to the bulk solvent and that there are no anionic surface groups near the steroid-binding site. The fluorescence excitation spectra of SBP-equilenin complexes are similar to the absorption spectra of equilenin in low-dielectric solvents. The fluorescence emission of the SBP-equilenin complexes, however, exhibits wavelength shifts (red shifts) opposite to those of the steroid in low-dielectric solvents or complexed with beta-cyclodextrin (blue shifts) but similar to the red shift produced by addition of the proton acceptor triethylamine to equilenin in cyclohexane. These data indicate that the steroid-binding site of hSBP and rSBP is a nonpolar cavity containing a proton acceptor that participates in a specific interaction, possibly a hydrogen bond, with the 3'-hydroxyl group of the bound steroid.     

Two binding modes in Escherichia coli single strand binding protein-single stranded DNA complexes. Modulation by NaCl concentration

The binding properties of the Escherichia coli encoded single strand binding protein (SSB) to a variety of synthetic homopolynucleotides, as well as to single stranded M13 DNA, have been examined as a function of the NaCl concentration (25.0 degrees C, pH 8.1). Quenching of the intrinsic tryptophan fluorescence of the SSB protein by the nucleic acid is used to monitor binding. We find that the site size (n) for binding of SSB to all single stranded nucleic acids is quite dependent on the NaCl concentration. For SSB-poly(dT), n = 33 +/- 3 nucleotides/tetramer below 10 mM NaCl and 65 +/- 5 nucleotides/tetramer above 0.20 M NaCl (up to 5 M). Between 10 mM and 0.2 M NaCl, the apparent site size increases continuously with [NaCl]. The extent of quenching of the bound SSB fluorescence by poly(dT) also displays two-state behavior, 51 +/- 3% quenching below 10 mM NaCl and 83 +/- 3% quenching at high [NaCl] (greater than 01.-0.2 M NaCl), which correlates with the observed changes in the occluded site size. On the basis of these observations as well as the data of Krauss et al. (Krauss, G., Sindermann, H., Schomburg, U., and Maass, G. (1981) Biochemistry 20, 5346-5352) and Chrysogelos and Griffith (Chrysogelos, S., and Griffith, J. (1982) Proc. Natl. Acad. Sci. U. S. A. 79,5803-5807) we propose a model in which E. coli SSB binds to single stranded nucleic acids in two binding modes, a low salt mode (n = 33 +/- 3), referred to as (SSB)33, in which the nucleic acid interacts with only two protomers of the tetramer, and one at higher [NaCl], n = 65 +/- 5, (SSB)65, in which the nucleic acid interacts with all 4 protomers of the tetramer. At intermediate NaCl concentrations a mixture of these two binding modes exists which explains the variable site sizes and other apparent discrepancies previously reported for SSB binding. The transition between the two binding modes is reversible, although the kinetics are slow, and it is modulated by NaCl concentrations within the physiological range. We suggest that SSB may utilize both binding modes in its range of functions (replication, recombination, repair) and that in vivo changes in the ionic media may play a role in regulating some of these processes.     

Interaction of nucleolar phosphoprotein B23 with nucleic acids

The interaction of eukaryotic nucleolar phosphoprotein B23 with nucleic acids was examined by gel retardation and filter binding assays, by fluorescence techniques, and by circular dichroism. All studies utilized protein prepared under native conditions by a newly developed purification procedure. Electrophoretic gel mobility shift assays with phage M13 DNA suggested that protein B23 is a single-stranded nucleic acid binding protein. This was confirmed in competition binding assays with native or heat-denatured linearized plasmid pUC18 DNA where the protein showed a marked preference for the denatured form. In other competition assays, there was no apparent preference for single-stranded synthetic ribo- versus deoxyribonucleotides. Equilibrium binding with poly(riboethenoadenylic acid) indicated cooperative ligand binding with a protein binding site size of 11 nucleotides and an apparent binding constant (K omega) of 5 x 10(7) M-1 which includes an intrinsic binding constant (K) of 6.3 x 10(4) M-1 and a cooperativity factor (omega) of 800. In circular dichroism (CD) studies, protein B23, when combined with the single-stranded synthetic nucleic acids poly(rA) and poly(rC), effected a decrease in ellipticity and a shift of the positive peak at 260-270 nm toward higher wavelengths, indicating helix destabilizing activity. No CD changes were seen with double-stranded poly(dA.dT). The change in ellipticity of poly(rA) was sigmoidal upon addition of protein, confirming the cooperative behavior seen with fluorescence methods. These studies indicate that protein B23 binds cooperatively with high affinity for single-stranded nucleic acids and exhibits RNA helix destabilizing activity. These features may be related to its role in ribosome assembly.     

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.     

Binding of ellipticine base and ellipticinium cation to calf-thymus DNA. A thermodynamic and kinetic study

The acid-basic properties of ellipticine have been re-estimated. The apparent pK of protonation at 3 microM drug concentration is 7.4 +/- 0.1. The ellipticine free base (at pH 9, I = 25 mM) intercalates into calf-thymus DNA with an affinity constant of 3.3 +/- 0.2 X 10(5) M-1, and a number of binding sites per phosphate of 0.23. The ellipticinium cation (pH 5, I = 25 mM) binds also to DNA with a constant of 8.3 +/- 0.2 x 10(5) M-1 and at a number of binding sites (n = 0.19). It is postulated that the binding of the drug to DNA at pH 9 is driven by hydrophobic and/or dipolar effects. Even at pH 5, where ellipticine exists as a cation, it is thought that the hydrophobic interaction is the main contribution to binding. The neutral and cationic forms share common binding within DNA sites but yield to structurally different complexes. The free base has 0.04 additional specific binding sites per phosphate. As determined from temperature-jump experiments, the second-order rate constant of the binding of the free base (pH 9) is 3.4 x 10(7) M-1 s-1 and the residence time of the base within the DNA is 8 ms. The rate constant for the binding of the ellipticinium cation is 9.8 x 10(7) M-1 s-1 when it is assumed that drug attachment occurs via a pathway in which the formation of an intermediate ionic complex is not involved (competitive pathway).     

Salt-dependent binding of Escherichia coli initiation factor 3 to nucleic acids determined by sedimentation partition chromatography

The binding of 14CH3- initiation factor 3 (IF3) to polynucleotides is strongly dependent upon the concentration of added salt. The observed association constant, Kobs, increases by ca. a factor of 10(2) when the NaCl concentration is lowered from 200 to 100 mM for the binding of 14CH3-IF3 to all nucleic acids examined. This salt-dependent binding suggests that at physiological salt concentrations the formation of an IF3-polynucleotide complex is primarily driven by the release of cations from the nucleic acid, although anion effects are involved also. For single-stranded nucleic acids, nonelectrostatic interactions may contribute a factor of 10(2) to the value of Kobs, although accurate assessment of these interactions is complicated by anion effects. The binding of 14CH3-IF3 to the double helix, poly(A).poly(U), appears to be exclusively electrostatic. 14CH3-IF3 forms a maximum of 8 +/- 2 ion pairs with most single-stranded polynucleotides. The value of Kobs increases from ca. 10(3) to 10(5) M-1 when the NaCl concentration is lowered from 200 to 100 mM for the binding of 14CH3-IF3 to poly(A), poly(C), poly(U), and poly(A).poly(U). At physiological salt concentrations, IF3 shows no preference for any of these bases or for single or double-stranded structures. However, 14CH3-IF3 binds ca. 60 times greater to poly(A,G), at al NaCl concentrations examined, than to the other nucleic acids, indicating that IF3 has some preference for guanine-containing polynucleotides. The presence of 10 mM Mg2+ tends to reduce the value of Kobs at any given NaCl concentration, but to a smaller degree than predicted by simply a competition between Mg2+ and IF3 for the nucleic acid lattice.     

Denaturation of Nucleic Acids Induced by Intercalating Agents. Biochemical and Biophysical Properties of Acridine Orange-DNA Complexes

Abstract

At high binding denstities 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.