Binding of ethidium to the nucleosome core particle. 2. Internal and external binding modes

We have previously reported that the binding of ethidium bromide to the nucleosome core particle results in a stepwise dissociation of the structure which involves the initial release of one copy each of H2A and H2B (McMurray & van Holde, 1986). In this report, we have examined the absorbance and fluorescence properties of intercalated and outside bound forms of ethidium bromide. From these properties, we have measured the extent of external, electrostatic binding of the dye versus internal, intercalation binding to the core particle, free from contribution by linker DNA. We have established that dissociation is induced by the intercalation mode of binding to DNA within the core particle DNA, and not by binding to the histones or by nonintercalative binding to DNA. The covalent binding of [3H]-8-azidoethidium to the core particle clearly shows that less than 1.0 adduct is formed per histone octamer over a wide range of input ratios. Simultaneously, analyses of steady-state fluorescence enhancement and fluorescence lifetime data from bound ethidium complexes demonstrate extensive intercalation binding. Combined analyses from steady-state fluorescence intensity with equilibrium dialysis or fluorescence lifetime data revealed that dissociation began when approximately 14 ethidium molecules are bound by intercalation to each core particle and less than 1.0 nonintercalated ion pair was formed per core particle.     

Molecular determinants for DNA minor groove recognition: design of a bis-guanidinium derivative of ethidium that is highly selective for AT-rich DNA sequences

The phenanthridinium dye ethidium bromide is a prototypical DNA intercalating agent. For decades, this anti-trypanosomal agent has been known to intercalate into nucleic acids, with little preference for particular sequences. Only polydA-polydT tracts are relatively refractory to ethidium intercalation. In an effort to tune the sequence selectivity of known DNA binding agents, we report here the synthesis and detailed characterization of the mode of binding to DNA of a novel ethidium derivative possessing two guanidinium groups at positions 3 and 8. This compound, DB950, binds to DNA much more tightly than ethidium and exhibits distinct DNA-dependent absorption and fluorescence properties. The study of the mode of binding to DNA by means of circular and electric linear dichroism revealed that, unlike ethidium, DB950 forms minor groove complexes with AT sequences. Accurate quantification of binding affinities by surface plasmon resonance using A(n)T(n) hairpin oligomer indicated that the interaction of DB950 is over 10-50 times stronger than that of ethidium and comparable to that of the known minor groove binder furamidine. DB950 interacts weakly with GC sites by intercalation. DNase I footprinting experiments performed with different DNA fragments established that DB950 presents a pronounced selectivity for AT-rich sites, identical with that of furamidine. The replacement of the amino groups of ethidium with guanidinium groups has resulted in a marked gain of both affinity and sequence selectivity. DB950 provides protection against DNase I cleavage at AT-containing sites which frequently correspond to regions of enhanced cleavage in the presence of ethidium. Although DB950 maintains a planar phenanthridinium chromophore, the compound no longer intercalates at AT sites. The guanidinium groups of DB950, just like the amidinium group of furamidine (DB75), are the critical determinants for recognition of AT binding sites in DNA. The chemical modulation of the ethidium exocyclic amines is a profitable option to tune the nucleic acid recognition properties of phenylphenanthridinium dyes.     

The possible role of electron-transfer complexes in the antitumour action of amsacrine analogues

Amsacrine is a DNA intercalating agent which is active against a number of tumours in mice and is used for the treatment of leukaemia in humans. In its DNA-bound form, amsacrine efficiently quenches the fluorescence of ethidium. Fluorescence lifetime studies demonstrate two populations of DNA-bound ethidium. The first, whose fluorescence lifetime is constant at approx. 3 ns and whose proportion increases with increasing amsacrine binding ratio, may comprise molecules bound in close proximity to amsacrine. The second, whose fluorescence lifetime is longer and variable (10-24 ns) and whose proportion decreases with increasing amsacrine binding ratio, may comprise molecules three or more base-pairs away from ethidium. Studies with a number of derivatives of 9-anilinoacridine containing different anilino substituents suggest that the observed wide variation in quenching capacity is correlated with the magnitude of the substituent dipole moment in a particular direction. Consideration of the geometry of the DNA-binding complex indicates that the negative pole of a dipole established in the anilino ring is directed towards a positively charged site on the ethidium molecule. Quenching of ethidium fluorescence may therefore occur where an electron-transfer complex has formed between ethidium and amsacrine molecules. To ascertain whether electron-transfer complex formation is biologically important in the amsacrine series, ethidium quenching has been quantitated and compared with activity against a transplantable neoplasm in mice, the Lewis lung carcinoma. Compounds which strongly quench ethidium fluorescence are in general highly active antitumour agents. The results are discussed in terms of a model where amsacrine has both a DNA-binding and a protein-binding domain, the latter possibly interacting by formation of an electron-transfer complex. The most likely protein-binding domain is on the enzyme topoisomerase II, the target for its cytotoxic activity.     

Environment-induced changes in DNA conformation as probed by ethidium bromide fluorescence

The interaction of the ethidium cation with calf thymus DNA is investigated in solutions of different ionic strength and temperature by observation of the enhancement of fluorescence of ethidium upon intercalation in the duplex structure. The quantum yield of the fluorescence of the intercalated dye is found to increase either upon lowering the Na+ concentration or upon increasing the temperature. The existence of a correlation between the geometry of the intercalation complex and the features of the secondary structure of DNA is suggested. Binding isotherms under corresponding environmental conditions are also quantitated by fluorescence enhancement and interpreted in terms of the neighbor exclusion model. Large contributions from change in hydration to the thermodynamics of binding are demonstrated by the temperature dependences of the equilibrium constants. The neighbor exclusion range is found to be practically independent of the salt concentration but its value increases from an average of 2.4 around room temperature to 4-5 at 80 degrees C, as inferred from the binding curves in 0.15 and 0.5 M [Na+] or from the DNA hypochromism vs temperature profiles of complexes at 10(-3) M [Na+]. All the data point to a possible sequence-conformation specificity in the intercalation of ethidium which in heterogeneous DNA is mediated by environmental changes.     

Intercalative DNA binding of model compounds derived from metabolites of 7,12-dimethylbenz[a]anthracene

The DNA binding of nonreactive model compounds of metabolites of 7,12-dimethylbenz[a]-anthracene (DMBA)1 was studied in fluorescence quenching and fluorescence lifetime experiments. The model compounds examined were DMA and 8,9,10,11-tetrahydro-BA. DMA is a pi electron model of a highly carcinogenic bay region epoxide of DMBA, 8,9,10,11-tetrahydro-BA is a model compound of a less carcinogenic DMBA epoxide. The results indicate that the binding of DMA occurs primarily via intercalation. In 15% methanol the binding constant is 3.1 x 10(3) M-1. In 15% methanol and at DNA phosphate levels of 5.0 x 10(-4) M the intercalative binding of DMA is reduced by a factor of 6.2 when 5.0 x 10(-4) M Mg+2 is added. The DMA binding constant for intercalation is reduced by more than a factor of 4 when the methanol content of the solvent is increased from 0% to 20%. Finally DMA binding arising from pi interactions with the DNA bases is reduced more than 15 times when the DNA is denatured. For 8,9,10,11-tetrahydro-BA in 15% methanol the binding constant for intercalation is 6 times lower than that for DMA. These results along with previously reported binding data on other model compounds suggest that bay region metabolites of DMBA readily participate in physical pi stacking interactions with DNA.     

Pressure-jump study of the kinetics of ethidium bromide binding to DNA

Pressure-jump chemical relaxation has been used to investigate the kinetics of ethidium bromide binding to the synthetic double-stranded polymers poly[d(G-C)] and poly[d(A-T)] in 0.1 M NaCl, 10 mM tris(hydroxymethyl)aminomethane hydrochloride, and 1 mM ethylenediaminetetraacetic acid, pH 7.2, at 24 degrees C. The progress of the reaction was followed by monitoring the fluorescence of the intercalated ethidium at wavelengths greater than 610 nm upon excitation at 545 nm. The concentration of DNA was varied from 1 to 45 microM and the ethidium bromide concentration from 0.5 to 25 microM. The data for both polymers were consistent with a single-step bimolecular association of ethidium bromide with a DNA binding site. The necessity of a proper definition of the ethidium bromide binding site is discussed: it is shown that an account of the statistically excluded binding phenomenon must be included in any adequate representation of the kinetic data. For poly[d(A-T)], the bimolecular association rate constant is k1 = 17 X 10(6) M-1 s-1, and the dissociation rate constant is k-1 = 10 s-1; in the case of poly[d(G-C)], k1 = 13 X 10(6) M-1 s-1, and k-1 = 30 s-1. From the analysis of the kinetic amplitudes, the molar volume change, delta V0, of the intercalation was calculated. In the case of poly[d(A-T)], delta V0 = -15 mL/mol, and for poly[d(G-C)], delta V0 = -9 mL/mol; that is, for both polymers, intercalation is favored as the pressure is increased.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding of ethidium derivatives to natural DNA: a 300 MHz 1H NMR study.

The binding of three ethidium derivatives, ethidium (1), des-3-amino ethidium (2) and des-8-amino ethidium (3), to short (approximately 35 base pairs), random sequence DNA has been investigated using 300 MHz proton NMR. At 35 degrees C all three drugs cause upfield shifts of the resonances from the exchangeable imino protons, as expected for intercalative binding to DNA. However, the lineshapes vary significantly with the nature of the drug. The temperature dependence of the spectra of the DNA shows that differences between spectra observed at 35 degrees C with ethidium and with des-3-amino ethidium are primarily due to differences in the drug binding kinetics rather than to differences in mode of binding. Removal of the amino group at position 3, but not at position 8, on the parent ethidium shortens the lifetime of the intercalative state; this implies that the 3-NH2 group is involved in stabilization of the drug-DNA complex. Analysis of the drug-DNA spectra indicates that there is a preference for binding of the drugs adjacent to G.C base pairs.     

On the complex formation of acridine dyes with DNA. VII. Dependence of the binding on the dye structure

The binding constants for the complex formation of more than twenty ring nitrogen-and amino-substituted acridine derivatives with calf thymas DNA were measured by a fluorescence method. DNA quenches the fluorescence of the aminoacridine dyes so long as both amino hydrogens are not substituted. These dyes show an enhancement of their fluorescence intensity in the presence of DNA. Typical representatives of both are proflavine and acridine orange derivatives, respectively. A discussion of steric and electronic influences of various substituents attached to the ring nitrogen and amino groups on the binding led to the concept of different conformations for intercalated acridines without amino groups and the aminoacridines. The electrostatic binding site of the former seems to be the positively charged ring nitrogen, while the binding sites in the aminoacridines are so located that the amino groups are directed towards the negatively charged DNA phosphates.     

Characterization of PicoGreen interaction with dsDNA and the origin of its fluorescence enhancement upon binding

PicoGreen is a fluorescent probe that binds dsDNA and forms a highly luminescent complex when compared to the free dye in solution. This unique probe is widely used in DNA quantitation assays but has limited application in biophysical analysis of DNA and DNA-protein systems due to limited knowledge pertaining to its physical properties and characteristics of DNA binding. Here we have investigated PicoGreen binding to DNA to reveal the origin and mode of PicoGreen/DNA interactions, in particular the role of electrostatic and nonelectrostatic interactions in formation of the complex, as well as demonstrating minor groove binding specificity. Analysis of the fluorescence properties of free PicoGreen, the diffusion properties of PG/DNA complexes, and the excited-state lifetime changes upon DNA binding and change in solvent polarity, as well as the viscosity, reveal that quenching of PicoGreen in the free state results from its intramolecular dynamic fluctuations. On binding to DNA, intercalation and electrostatic interactions immobilize the dye molecule, resulting in a >1000-fold enhancement in its fluorescence. Based on the results of this study, a model of PicoGreen/DNA complex formation is proposed.     

Intercalative DNA Binding of Model Compounds Derived From Metabolites of 7, 12-Dimethylbenz[a]anthracene

Abstract

The DNA binding of nonreactive model compounds of metabolites of 7,12-dimethylbenz[a]-anthracene (DMBA)¹ was studied in fluorescence quenching and fluorescence lifetime experiments. The model compounds examined were DMA and 8,9,10,11-tetrahydro-BA. DMA is a π electron model of a highly carcinogenic bay region epoxide of DMBA. 8,9,10,11- tetrahydro-BA is a model compound of a less carcinogenic DMBA epoxide.

The results indicate that the binding of DMA occurs primarily via intercalation. In 15% methanol the binding constant is 3.1 × 10³M^?1. In 15% methanol and at DNA phosphate levels of 5.0 × ^?4 M the intercalative binding of DMA is reduced by a factor of 6.2 when 5.0 × 10^?4 M Mg⁺² is added. The DMA binding constant for intercalation is reduced by more than a factor of 4 when the methanol content of the solvent is increased from 0% to 20%. Finally DMA binding arising from π interactions with the DNA bases is reduced more than 15 times when the DNA is denatured. For 8,9,10,11-tetrahydro-BA in 15% methanol the binding constant for intercalation is 6 times lower than that for DMA.

These results along with previously reported binding data on other model compounds suggest that bay region metabolites of DMBA readily participate in physical π stacking interactions with DNA.     

A continuous kinetic assay for RNA-cleaving deoxyribozymes,exploiting ethidium bromide as an extrinsic fluorescent probe

We describe a rapid and inexpensive method to monitor the kinetics of small RNA-cleaving deoxyribozymes, based on the exogenous fluorophore ethidium bromide. Ethidium binds preferentially to double-stranded nucleic acids, and its fluorescence emission increases dramatically upon intercalation. Thus, ethidium can be used in single-turnover experiments to measure both annealing of the deoxyribozyme to its substrate and release of the products. Under conditions in which dissociation of the product is fast compared with cleavage, the apparent rate of product release reflects the cleavage step. The method was developed for characterizing the so-called 8-17 catalytic DNA, but its general applicability in the deoxyribozyme field was verified using the 10-23 RNA-cleaving construct. Catalysis by both deoxyribozymes was not inhibited in the presence of substoichiometric amounts of ethidium, and the rates obtained through the ethidium assay were virtually identical to the rates determined using radiolabeled substrates. In contrast, the assay cannot be applied to the large, structured ribozymes, and its use to study the kinetics of the small hammerhead ribozyme was hampered by the presence on the catalyst of at least one high-affinity ethidium binding site.     

Thermodynamic analysis of complex formation of ethidium bromide with DNA in water solutions

A thermodynamic analysis of two types of binding of ethidium bromide with DNA: intercalation and binding to the outer surface of a biopolymer has been performed by spectrophotometry. It has been shown that the dominant contribution to the energy of external binding of the ligand to DNA is made by hydrophobic interactions, which lead to less negative values of enthalpy and entropy and more severe negative changes in the heat capacity of complex formation as compared with the intercalation type of binding.     

Binding of ethidium bromide to a DNA triple helix. Evidence for intercalation

The interaction of ethidium, a DNA intercalator, with the poly(dA).poly(dT) duplex and the poly (dA).2poly(dT) triplex has been investigated by a variety of spectrophotometric and hydrodynamic techniques. The fluorescence of ethidium is increased when either the duplex or triplex form is present. Binding constants, determined from absorbance measurements, indicate that binding to the triple helical form is substantially stronger than to the duplex, with a larger binding site size (2.8 base triplets compared to 2.4 base pairs). Furthermore, while binding to poly(dA).poly(dT) shows strong positive cooperativity, binding to the triplex is noncooperative. Thermal denaturation experiments demonstrate that ethidium stabilizes the triple helix. Binding to either form induces a weak circular dichroism band in the visible wavelength region, while in the region around 310 nm, there is a band that is strongly dependent on the degree of saturation of the duplex, and which is positive for the duplex but negative for the triplex. Both fluorescence energy transfer and quenching studies provide evidence of intercalation of ethidium in both duplex and triplex complexes. Binding of ethidium leads to an initial decrease in viscosity for both the duplex and triplex structures, followed by an increase, which is greater for the duplex. Taken together, these results strongly suggest that ethidium binds to the poly (dA).2poly(dT) triple helix via an intercalative mechanism.     

Localization of noncovalently bound ethidium in free and methionyl-tRNA synthetase bound tRNAfMet by singlet-singlet energy transfer

Ethidium binds tRNAfMet with 17-fold enhancement in the emission intensity at 600 nm. Fluorescence titration of tRNAfMet with ethidium indicates a single high-affinity site in tRNAfMet with a dissociation constant of 5 microM. Ethidium is apparently rigidly bound to tRNAfMet and effectively shielded from solvent. tRNAfMet(8-13), tRNAfMet(3'-Flc), and tRNAfMet(D-PF) with fluorophores at thiouridine, the 3'-terminus, and dihydrouridine, respectively, are prepared, and the singlet-singlet energy-transfer efficiencies between these fluorophores and noncovalently bound ethidium are determined. The transfer efficiency between bound ethidium and the fluorophore in tRNAfMet(8-13) determined by donor quenching and sensitized emission is the same, strongly suggesting that there is only one bound ethidium per tRNAfMet molecule. The apparent distances between ethidium and various fluorophores including 3'-fluorescein, the 8-13 photo-cross-link, and D-proflavin are 41, 19, and 30 A, respectively, assuming random orientation between the donor and the acceptor. The results suggest that noncovalently bound ethidium is intercalated in the amino acid acceptor stem. In the complex of tRNAfMet and methionyl-tRNA synthetase, the transfer efficiencies for the tRNAfMet(8-13), tRNAfMet(3'-Flc), and tRNAfMet(D-PF) are reduced, enhanced, and little changed, respectively. These methionyl-tRNA synthetase induced changes suggest changes in the conformation of the 3'-terminal unpaired bases and the relative orientation or location between tRNAfMet and ethidium upon binding of methionyl-tRNA synthetase.     

Monoazido analog of ethidium as a chromatin probe: Binding to DNA

Two photoaffinity analogs of ethidium, 8-azido-3-amino, and 3-azido-8-amino-5-ethyl-6-phenylphenanthridinium chloride, have been used to probe the structure of mammalian chromatin and its interactions with the ethidium moiety. The monoazido analogs were established as suitable probes by comparing their interactions with chromatin and pure DNA prepared from chromatin to those of the parent ethidium bromide. Scatchard analysis of the binding data determined from spectrophotometric titrations showed that the analogs interacted with both nucleic acids in a manner similar to the parent compound. The effect of chromatin proteins on the interaction of the ethidium moiety with intact chromatin was investigated directly. By exposing the noncovalent complex to visible light, the monoazido analog was attached covalently in its interaction sites within chromatin, and the amount of drug bound covalently to DNA was determined for both protein-free DNA and chromatin. Using saturating concentrations of drug, DNA within intact chromatin was found to be associated with only half as much drug as DNA extracted from its protein prior to drug exposure. The distribution of drug bound within chromatin was determined following the attachment of the monoazido analog (by photoactivation) to chromatin that had undergone limited nuclease digestion. Several distinct populations isolated by size fractionation and quantitative measurements revealed that (1) both the core particles and the spacer-containing particles contained bound drug, reflecting high-affinity binding sites; and (2) chromatin particles containing 150 DNA base pairs (putatively nucleosome core structures) contained less total bound drug at high drug concentrations than those particles having intact spacer DNA.     

Efficient calf thymus DNA condensation upon binding with novel bile acid polyamine amides

Polyamine amides have been prepared from lithocholic and cholic acids (5beta-colanes) by acylation of tri-Boc-protected tetraamines spermine and thermine. These designed ligands for DNA are polyammonium ions at physiological pH. In NMR spectra, they display 14N-1H 1J = 51 Hz, 1:1:1 triplets, due to the symmetry of the R14NH(3)+ cations. The binding affinities of these conjugates for calf thymus DNA were determined using an ethidium bromide fluorescence quenching assay and compared with spermine and polylysine. DNA-binding affinities were dependent upon both salt concentration and the hydrophobicity or intermolecular bonding (facial effects) of the lipid moieties in these conjugates. Light scattering at 320 nm was used to determine DNA condensation and particle formation. The observed self-assembly phenomena are discussed with respect to DNA charge neutralization and DNA bending with loss of ethidium cation intercalation sites, ultimately leading to DNA condensation. These polyamine amides are models for lipoplex formation with respect to gene delivery (lipofection), a key first step in gene therapy.     

抗菌肽BuforinⅡ衍生物与大肠杆菌基因组DNA的作用机制

【目的】研究抗菌肽BuforinⅡ的衍生物BF2-A/B与大肠杆菌基因组DNA的作用机制。【方法】琼脂糖电泳检测肽对DNA的断裂作用,凝胶阻滞实验研究肽与DNA的结合作用,圆二色谱考察结合肽后DNA结构的变化,荧光光谱分析肽与溴化乙锭竞争性嵌入DNA以及磷酸根对肽与DNA相互作用的影响。【结果】BF2-A/B不断裂基因组DNA而是结合DNA,使DNA双螺旋结构变得松散,削弱碱基对间的堆积作用,并取代EB,使EB-DNA复合体系荧光减弱。而PO43-的加入减弱了肽对DNA-EB荧光的淬灭作用。【结论】衍生肽与DNA的结合方式是先靠静电引力吸附到DNA磷酸基团上,随即插入双螺旋沟槽,嵌入碱基对间。BF2-B有更多的正电荷,更强的插入沟槽和嵌入碱基对的能力,使得其结合DNA的能力比BF2-A强。     

Studies of the interaction of the fluorophores harmine and harmaline with calf thymus DNA.

The binding to calf thymus DNA of the hallucinogen harmine and one of its analogues harmaline was studied by absorption spectrophotometry and fluorescence quenching analysis. Viscosity measurements were also carried out. For both molecules, quenched and unquenched sites on DNA are present. For each type of binding site, the value of the product of the number of sites times the association constant was determined. Harmine is more strongly bound than harmaline. Viscosity measurements indicate intercalation in the case of harmine only.     

DNA-binding and cleavage studies of novel copper(II) complex with L-phenylalaninate and 1,4,8,9-tetra-aza-triphenylene ligands

DNA-binding properties of novel copper(II) complex [Cu(l-Phe)(TATP)(H(2)O)](+), where L-Phe=L-phenylalaninate and TATP=1,4,8,9-tetra-aza-triphenylene are investigated using electronic absorption spectroscopy, fluorescence spectroscopy, voltammetry and viscosity measurement. It is found that the presence of calf thymus DNA results in a hypochromism and red shift in the electronic absorption, a quenching effect on fluorescence nature of ethidium bromide-DNA system, an enhanced response on voltammograms of [Co(phen)(3)](3+/2+)-DNA system, and an obvious change in viscosity of DNA. From absorption titration, fluorescence analysis and voltammetric measurement, the binding constant of the complex with DNA is calculated. The latter two methods reveal the stronger binding of [Cu(l-Phe)(TATP)(H(2)O)](+) complex to double strand DNA by the moderate intercalation than [Co(phen)(3)](3+). Such a binding induces the cleavage of plasmid pBR322 DNA in the presence of H(2)O(2).     

Nonspecific interactions in dye binding to DNA. Influence of alcohols and amides

The binding of a few drugs (ethidium bromide, propidium diiodide, proflavine and actinomycin D) to DNA has been investigated in aqueous solutions to which cosolvents of different polarity have been added. It is found that both alcohols (less polar than water) and amides (more polar) lower the binding constant according to a linear relationship between the intercalation free energy and cosolvent concentration. The main action of cosolvents cannot be described in terms of electrostatic effects, since they predict much smaller changes in the binding constant than those observed. It appears instead that relevant solvation effects are responsible for the binding strength of the different dyes to DNA. As a general result, it is found that solvation effects largely contribute to the intercalation free energy, thereby weakening the influence of nonspecific interactions at the intercalation site.