Supercoils in human DNA.

The three-dimensional structure of a double-stranded DNA molecule may be described by distinguishing the helical turns of the DNA duplex from any superhelical turns that might be superimposed upon the duplex turns. There are characteristic changes in the hydrodynamic properties of superhelical DNA molecules when they interact with intercalating agents. The hydrodynamic properties of nuclear structures released by gently lysing human cells are changed by intercalating agents in this characteristic manner. The characteristic changes are abolished by irradiating the cells with gamma-rays but may be restored by incubating the cells at 37 degrees C after irradiation. These results are interpreted as showing that human DNA is supercoiled. A model for the structure of the chromosome is suggested.     

The helical repeat of underwound DNA in solution.

Closed circular DNA was relaxed with a topoisomerase in the presence of varying concentrations of the intercalating dye, ethidium bromide, to create underwound, planar DNA rings. We directly determined the helical repeat of these DNA molecules by the Gaussian center method and found that it varied as a simple predicted function of the degree of underwinding and the helical repeat of relaxed, dye-free DNA. We discuss these results in light of a recent mathematical treatment of DNA structure which predicts that the helical repeat of supercoiled DNA molecules in solution obeys the same function.     

Effect of ligand binding on the buoyant density of DNA in Nycodenz gradients.

The effect of ligand binding upon the buoyant density of DNA in Nycodenz gradients has been studied using DNAs of differing base compositions. The effect of both intercalating ligands (ethidium bromide and proflavin) and non-intercalating ligands (distamycin A, DAPI and netropsin) has been studied. The binding of intercalating ligands to DNA has essentially no effect on the buoyant density of DNA in Nycodenz gradients. The non-intercalating ligands were found to increase the buoyant density of DNA in a base specific manner. The increase in buoyant density can be interpreted in terms of disruption of the hydration shell of the DNA molecule caused by the binding of the ligand along the minor groove of the DNA helix.     

Ellipticine-induced protein-associated DNA breaks in isolated L1210 nuclei

DNA intercalating agents have been found to produce protein-associated DNA strand breaks in mammalian cells. As a first step towards a subcellular system for the study of this reaction, we demonstrate that the reaction can take place in isolated cell nuclei. Ellipticine induces in these nuclei DNA strand breaks and stable DNA-protein complexes. Complexes and breaks are present in equivalent amounts. DNA breaks are revealed only if protein-mediated DNA adsorption to filters is abolished. These findings make it unlikely that similar effects observed in cells in culture after treatment with intercalating agents are caused by metabolically activated drugs.     

Inhibition of estrogen-receptor-DNA interaction by intercalating drugs.

Ethidium bromide, an intercalating drug, was shown to inhibit the in vitro DNA binding of the uterine estradiol-receptor complex. The inhibition was reversible, dose dependent, complete for total saturation of DNA intercalating sites by the dye, and proportional to the extent of intercalated drug. The binding of the receptor to phosphocellulose and poly(adenylic acid)-cellulose was not decreased by this drug. Similar inhibition was also obtained with 9-hydroxyellipticine. Denatured DNA was more efficient at binding the estrogen receptor than phosphocellulose or poly(adenylic acid)-cellulose but less efficient than native DNA. We conclude that the DNA binding of the estrogen receptor cannot be simply interpreted in terms of electrostatic interactions but requires a particular double-helical structure of DNA.     

Low concentrations of acridine dimers inhibit micrococcus AP endonuclease through interaction with apurinic sites in DNA.

The effect of dimeric DNA intercalating compounds was assayed on a purified AP endonuclease from Microccoccus luteus using apurinic supercoiled PM2 DNA as a substrate. Binding on apurinic sites was estimated through the competition with the intercalating compound, 9-NH2-ellipticine, which displays great specificity for apurinic sites. An acridine dimer with a spermine linker is at 0.1 microM the best inhibitor of cleavage at the apurinic site induced either by the AP endonuclease or by 9-NH2-ellipticine. Bisintercalating agents are more effective inhibitors of AP endonuclease than monointercalating ones. Most effective inhibitors among dimers have acridine residues.     

Preparation of insolubilized-DNA film with three-dimensional network and removal of endocrine disruptors.

A water-insolubilized film was prepared by UV irradiation on a dried DNA film. When a UV-irradiated DNA was examined using a circular dichroism spectroscopy, a double stranded structure was observed as well as that of native DNA. The UV irradiated DNA film was also accumulated intercalating reagents. These results suggested that the double stranded structure was involved in the UV irradiated DNA film with a three-dimensional network. The thymine-thymine dimer formation was suggested to be involved in the cross-linking reactions by the polymerization analysis using poly(dA)-poly(dT) and poly(dG)-poly(dC). We also demonstrate the utilization of the UV-irradiated DNA film as a functional material for the accumulation of harmful DNA intercalating pollutants in aqueous solution. These results suggested that the UV-irradiated DNA film was applicable as a functional material for medical, engineering and environmental sciences.     

A Mechanism for the Entrapment of DNA at an Air-Water Interface

Addition of the intercalating dye quinacrine to a low ionic strength solution of DNA in quantities sufficient to saturate the high affinity sites in the DNA will result in the accumulation of the DNA at the solution interface. This entrapment of DNA at the air-water interface has been assayed by the adsorption of DNA to untreated carbon-coated electron microscope grids touched to the solution surface. Other intercalating dyes can also bring about this entrapment, if they possess a side arm large enough to occupy one of the DNA grooves when the dye is intercalated into the DNA. The extension and unwinding of the DNA helix brought about by the intercalating chromophore of the dye molecules are not requirements for the entrapment process. Spermidine, a simple polyamine that will bind to the DNA minor groove but that has no intercalating chromophore, was found to bring about this entrapment. Even simple mono- and divalent cations in the absence of the above ligands were found to promote a low level of surface entrapment. A model for the entrapment of DNA at the air-water interface is proposed in which one (or both) of the hydrophobic grooves of the DNA becomes a surface-active agent as a consequence of the association of various ligands and charge neutralization.     

Interaction of intercalating and non-intercalating agents with DNA: use of hydroxyapatite chromatography and S1 nuclease

We have used hydroxyapatite (HA) chromatography and S1 nuclease hydrolysis to study the modification in the secondary structure of DNA caused by certain intercalating and non-intercalating ligands. The principal conclusions of HA experiments were as follows: (1) when native DNA, complexed with drugs believed to bind to DNA by intercalation (ethidium bromide, acridine orange, actinomycin D and acriflavin), is chromatographed on HA a lower affinity of DNA for HA is observed; also, the DNA elutes from HA columns as a drug-DNA complex; (ii) ligands that are known to interact with DNA by surface interactions do not show these effects; (iii) it may be possible to quantitate the binding of the intercalating drug to DNA and to determine its degree of binding by HA chromatography. Possibly, intercalation causes a change in the configuration of the sugarphosphate backbone of DNA, resulting in an altered steric orientation or 'burial' of phosphate groups with reduced availability for surface interactions with HA. S1 nuclease was used to determine the thermal melting profiles of DNA complexed with ethidium bromide and acridine orange. The melting profile in both cases was found to be biphasic with considerably reduced denaturation even at 95 degrees C. This is accounted for by the property of intercalating agents of stabilizing the secondary structure of DNA and the reported preference in binding to G-C base pairs.     

Comparison of SYTO9 and SYBR Green I for real-time polymerase chain reaction and investigation of the effect of dye concentration on amplification and DNA melting curve analysis

Following the initial report of the use of SYBR Green I for real-time polymerase chain reaction (PCR) in 1997, little attention has been given to the development of alternative intercalating dyes for this application. This is surprising considering the reported limitations of SYBR Green I, which include limited dye stability, dye-dependent PCR inhibition, and selective detection of amplicons during DNA melting curve analysis of multiplex PCRs. We have tested an alternative to SYBR Green I and report the first detailed evaluation of the intercalating dye SYTO9. Our findings demonstrate that SYTO9 produces highly reproducible DNA melting curves over a broader range of dye concentrations than does SYBR Green I, is far less inhibitory to PCR than SYBR Green I, and does not appear to selectively detect particular amplicons. The low inhibition and high melting curve reproducibility of SYTO9 means that it can be readily incorporated into a conventional PCR at a broad range of concentrations, allowing closed tube analysis by DNA melting curve analysis. These features simplify the use of intercalating dyes in real-time PCR and the improved reproducibility of DNA melting curve analysis will make SYTO9 useful in a diagnostic context.     

Circular dichroism studies of ethidium bromide binding to the isolated nucleolus.

Circular dichroism in the 300-360 nm region and fluorescence induced by intercaltating binding of ethidum bromide to both DNA and RNA components were studied in isolated HeLa nucleoli. Both DNA and RNA compoents contribute to the induced dichroic elliticity. Digestion of nucleoli by RNase or DNase shows that most of the induced ellipticity comes from the DNA component. In nucleoli with an RNA/DNA = 0.8/1.0 the RNA component gives only 20% of the total ellipticity when measured at an ethidium bromide/DNA = 0.25. Spectro-fluorometric titration shows that ethidium bromide intercalates mostly into DNA in nucleoli. Both circular dichroism and fluorescence studies indicate that both DNA and RNA components in isolated nucleoli are less accessible to intercalating binding by ethidium bromide when compared to purified nucleolar DNA, DNA in chromatin or purified ribosomal RNA. Circular dichroic measurements of intercalating binding of ethidium bromide to to nucleoli may be used to study changes in nucleoli under different physiological or pathological conditions.     

Putative identification of functional interactions between DNA intercalating agents and topoisomerase II using the V79 in vitro micronucleus assay

Clastogenicity is frequently observed following treatment of mammalian cells with new chemical entities. This clastogenicity, unless proven otherwise, is assumed to result from the imperfect repair of DNA lesions produced from covalent chemical/DNA interaction. However, clastogenicity can also arise via other mechanisms such as non-covalent chemical intercalation into DNA resulting in poisoning of cellular DNA topoisomerase II (topo II) and stabilization of DNA double strand breaks. We have recently reported modifications to the V79 in vitro micronucleus assay which allow an indirect evaluation of both the intercalative and topoisomerase-interactive activities of chemical agents. In the present studies we have used these modified assays to further assess the validity of this approach in an evaluation of a number of intercalating and non-intercalating polycyclic compounds. It is shown that intercalating agents may be catalytic topo II inhibitors (e.g. chloroquine (CHL), tacrine (TAC), 9-aminoacridine (9AA), ethidium bromide (EB)) or topo II poisons (e.g. proflavine (PROF), auramine O (AUR) and curcumin (CURC)). Still other intercalators are shown to lack detectable topo II-interactions, (e.g. imipramine (IMP), quinacrine (QUIN), 2-aminoanthracene (AA), iminostilbene (IMN) and promethazine (PHE)). It is concluded that (1) the clastogenicity of three agents, PROF (a typical DNA intercalating agent), and AUR and CURC (both structurally atypical intercalating agents, with unknown clastogenic mechanisms), may be due to topo II poisoning; (2) other intercalating agents may either act as catalytic topo II inhibitors or exhibit no functional topo II interaction; (3) The use of these cell-based approaches may provide a logical first step in determining if unexpected clastogenicity associated with test article exposure is due to a topo II interaction.     

Binding of meso-tetra (4-N-methylpyridyl) porphine to DNA.

The porphyrin photosensitizer, meso-Tetra (4-N-methyl-pyridyl) porphine tetraperchlorate is shown to unwind supercoiled ColEI DNA at a somewhat lower concentration than ethidium bromide. In contrast to this, the Fe(III) chelate of T4MPyP cannot unwind supercoiled DNA. It is concluded that these results corroborate our previous findings that, despite its large bulk, T4MPyP is fully capable of intercalating in DNA.     

On the chemical basis of chromosome banding patterns.

A comparative study of the staining characteristics of four reagents for human chromosomes has been carried out. The four reagents are: (I) quinacrine mustard, as an alkylating agent, (II) the dihydroxy derivative of quinacrine mustard, (III) quinacrine, and (IV) 9-amino-6-chloro-2-methoxyacridine. The last reagent does not possess the amino substituted side chain even though it has the same intercalating nucleus. Comparison of the first three compounds in their staining and banding behavior suggested the initial step leading to banding may be the displacement of the nucleoprotein sites in hcromosomes. The Q and G banding could be blocked experimentally by treating the chromosome preparation with dimethylamine solution. This result may suggest that these sites have weaker basic proteins (nonhistone proteins?). The use of compound IV, which does not have the side chain in the molecule but does have the same intercalating chromophore, did not lead to banding and gives indirect support to this hypothesis. A combined use of compound IV and quinacrine may be useful for the determination of total DNA vs. banding DNA.     

Condensation of DNA in situ in metaphase chromosomes induced by intercalating ligands and its relationship to chromosome banding

Interactions of certain intercalating cationic ligands with nucleic acids result in the formation of products that undergo condensation and agglomeration; this transition in solution can be monitored by light-scatter measurements. In the present study, using such intercalators as the antitumor drug mitoxantrone or fluorochromes acridine orange and quinacrine, we induced condensation of DNA in situ in Chinese hamster chromosomes. The in situ products scattered light and could be detected by darkfield- or phase-contrast microscopy. In the darkfield the complexes had a characteristic granular appearance and often generated a banding pattern on the chromosomes. In contrast, condensation of DNA in situ by the nonintercalating polyvalent cations (Co3+, spermine4+), while enhancing the chromosome's image contrast, did not produce the granular products or the banding. The condensation of free DNA, single or double stranded, natural or synthetic, the latter of various base composition and configuration, was also measured in solution. The condensation in solution and in situ was observed at similar concentrations of the respective ligands. The intercalating dye ethidium bromide, which did not condense DNA in solutions of moderate and high ionic strength, also did not generate the granular products or banding on chromosomes. The data also show that both base composition and configuration are important factors in determining the sensitivity of DNA to condensation by particular intercalating ligands. The studies suggest that the phenomenon of DNA condensation by intercalating dyes, which shows a high degree of specificity with respect to primary and secondary structures of DNA, may be associated with mechanisms of chromosome banding induced by the intercalating thiazine dyes in Giemsa staining or by quinacrine. Observation of chromosome banding based on light-scatter detection in darkfield microscopy allows the study of interactions between DNA and the ligands that neither fluoresce nor generate colored products. This principle of chromosome "counter-staining" can be explored by flow cytometry.     

Photoaffinity labelling of atrial natriuretic factor (ANF)-R1 receptor by underivatized 125I-ANF. Involvement of lipid peroxidation.

A number of DNA intercalating and externally binding drugs have been found to inhibit nick sealing, cohesive and blunt end ligation, AMP-dependent DNA topoisomerization and EDTA-induced DNA nicking mediated by bacteriophage T4 DNA ligase. The inhibition seems to arise from drug-substrate interaction so that formation of active DNA-Mg2(+)-AMP-enzyme complex is impaired while assembled and active complexes are not disturbed by drug binding to the substrate.     

Intercalating fluorescence dye YOYO-1 prevents the folding transition in giant duplex DNA

Recently, it has become clear that with the addition of polyamines, giant DNA molecules of size greater than 10 kbp exhibit all-or-none switching between elongated coil and folded compact states. Here the effects of the intercalating fluorescent labeling dye, YOYO-1, and the minor-groove binding fluorescent labeling dye, DAPI, on the folding transition of single giant T4 DNA (166 kbp) induced by spermidine(3+) were examined, by use of the experimental technique of single molecular chain observation with fluorescence microscopy. It is found that the intercalating dye, YOYO-1, markedly prevents the folding transition, whereas the minor-groove binding dye, DAPI, exhibits negligible effect on the folding transition. This action of YOYO-1 is discussed in relation to the biological effect of intercalators.     

Interaction of novel tris-intercalators with DNA. Spectrofluorometric studies.

Novel DNA binding ligands (1 and its stereoisomer 2) which contain three potentially intercalating units in a linear molecular skeleton were prepared. From a study of the displacement of ethidium bromide from several natural and synthetic polynucleotides, both compounds 1 and 2 were found to show an AT base-pair preference in the interaction with DNAs with 2 a slightly higher affinity for DNA. This result is in sharp contrast to that for acridine and anthraquinone, because these two compounds exhibit a GC-preference.