Mechanism of interaction of DNA with fluorescent dye Hoechst 33258]

From the study of absorption and fluorescence spectra of the complex "Hoechst-33258"--DNA at different pH it is shown that AT--specific complex with DNA is formed by the neutral dye molecule, whereas the cationic state of the dye molecule forms the nonspecific complex. Possible formation of a specific complex in which the dye is bound to DNA in its major groove is discussed.     

Fluorescent analysis of irradiation-induced changes in chromatin state

A fluorescent technique with Hoechst-33258 and acridine orange staining was used to assess changes in chromatin state induced by radiation. Fluorochromes with different modes of binding to DNA were chosen. In T lymphocytes chronic irradiation caused a rearrangement of binding between nonhiston proteins and lipids accompanied by conformational changes in DNA, resulting in chromatin condensation. The decrease in fluorescence probably resulted from a reduction in the number of sites accessible for dye binding. After acute irradiation, the fluorescence intensity decreases predominantly due to double-strand breaks.     

Experimental and computational studies on the effects of valganciclovir as an antiviral drug on calf thymus DNA

DNA-binding properties of an antiviral drug, valganciclovir (valcyte) was studied by using emission, absorption, circular dichroism, viscosity, differential pulse voltammetry, fluorescence techniques, and computational studies. The drug bound to calf thymus DNA (ct-DNA) in a groove-binding mode. The calculated binding constant of UV-vis, K_a, is comparable to groove-binding drugs. Competitive fluorimetric studies with Hoechst 33258 showed that valcyte could displace the DNA-bound Hoechst 33258. The drug could not displace intercalated methylene blue from DNA double helix. Furthermore, the induced detectable changes in the CD spectrum of ct-DNA as well as changes in its viscosity confirm the groove-binding mode. In addition, an integrated molecular docking was employed to further investigate the binding interactions between valcyte and calf thymus DNA.     

Plasmodium species: flow cytometry and microfluorometry assessments of DNA content and synthesis

Fluorescence intensities were established by flow cytometry of different erythrocytic stages of Plasmodium berghei after staining of their DNA with Hoechst-33258 or Hoechst-33342. Parasites were obtained from highly synchronized infections or in vitro cultures. Most fluorescence measurements were performed using a low cost, clinical flow cytometer, equipped with a mercury arc lamp. Cells infected with P. berghei could be readily distinguished from uninfected cells on the basis of Hoechst-DNA fluorescence and single, double, and triple ring infected cells were separated clearly. The relative fluorescence intensities of different developmental stages (merozoites, ringforms, trophozoites, schizonts, and gametocytes) corresponded closely to the relative DNA contents of these stages as measured by microfluorometry. Flow cytometry appeared to be a sensitive and rapid method to measure DNA synthesis during asexual development; a C50 value of 5 microM of aphidicolin, a specific inhibitor of DNA synthesis, was established. Vital staining of parasites in culture was possible with both Hoechst dyes. After removal of Hoechst-33258, normal in vitro development of the stained parasites was observed. After Hoechst staining, the haploid ringforms of P. vivax showed slightly less fluorescence (15%) than ringforms of P. berghei and P. falciparum. No differences in fluorescence intensity were observed, however, by direct microfluorometry after Feulgen-pararosaniline staining, indicating that all three species have the same DNA content.     

Accurate determination of DNA content in single cell nuclei stained with Hoechst 33258 fluorochrome at high salt concentration

Summary In an attempt to achieve accurate quantification of DNA levels in cell nuclie, we studied the influence of salt concentration on the fluorescence of cell nuclei complexed with Hoechst-33258 (Hoe) fluorochrome. The fluorescence of cell nuclei was compared with that of extracted DNA as well as that of nucleosome core. Conformational changes in these complexes were examined by measuring both fluorescence anisotropy and fluorescence lifetime in the nanosecond region. The results showed that the fluorescence of DNA-Hoe was quenched by the nucleosomal structure, there being an associated increase in anisotropy and a decrease in the fluorescence lifetime; however, the fluorescence was restored to the orginal level by the addition of a high concentration of NaCl, CsCl, or LiCl. The reduction in fluorescence may have been due to loss of fluorescence energy caused by collision of the fluorophore with histones in the nucleosome. The addition of 1 M NaCl to the medium used for staining with Hoe greatly stabilized the fluorescence of DNA in cell nuclei. The DNA content of individual cell nuclei was determined by comparing the fluorescence of these nuclei with that of a standard DNA solution. For lymphocytes and liver ploidy cells, reasonably accurate values were obtained by applying the present method.     

Accurate determination of DNA content in single cell nuclei stained with Hoechst 33258 fluorochrome at high salt concentration

In an attempt to achieve accurate quantification of DNA levels in cell nuclei, we studied the influence of salt concentration on the fluorescence of cell nuclei complexed with Hoechst-33258 (Hoe) fluorochrome. The fluorescence of cell nuclei was compared with that of extracted DNA as well as that of nucleosome core. Conformational changes in these complexes were examined by measuring both fluorescence anisotropy and fluorescence lifetime in the nanosecond region. The results showed that the fluorescence of DNA-Hoe was quenched by the nucleosomal structure, there being an associated increase in anisotropy and a decrease in the fluorescence lifetime; however, the fluorescence was restored to the original level by the addition of a high concentration of NaCl, CsCl, or LiCl. The reduction in fluorescence may have been due to loss of fluorescence energy caused by collision of the fluorophore with histones in the nucleosome. The addition of 1 M NaCl to the medium used for staining with Hoe greatly stabilized the fluorescence of DNA in cell nuclei. The DNA content of individual cell nuclei was determined by comparing the fluorescence of these nuclei with that of a standard DNA solution. For lymphocytes and liver ploidy cells, reasonably accurate values were obtained by applying the present method.     

Decontamination of cell cultures by removing mycoplasmas: a comparison of 3 methods

Three different methods of decontamination of cell cultures from mycoplasma were compared: by macrophages in the presence of antibiotics, by ultraviolet radiation in the presence of 5-bromuridin and Hoechst-33258, by cloning of cells in the presence of antibiotics metacycline and doxicycline. Only the latter method was effective to decontaminate the cell cultures from mycoplasma. Twelve cell lines were decontaminated and tested for the presence of mycoplasma by microbiological method, by staining with the dye Hoechst-33258 and autoradiography. All the cell lines were free of mycoplasma.     

The effect of dimerization on the interaction of ibuprofen drug with calf thymus DNA: Molecularmodeling and spectroscopic investigation

The interaction between the dimer structure of ibuprofen drug (D-IB) and calf thymus DNA under simulative physiological conditions was investigated with the use of Hoechst 33258 and methylene blue dye as spectral probes by the methods of UV-visible absorption, fluorescence spectroscopy, circular dichroism spectroscopy and molecular modeling study.Using the Job's plot, a single class of binding sites for theD-IB on DNA was put in evidence. The Stern–Volmer analysis of fluorescence quenching data shows the presence of both the static and dynamic quenching mechanisms. The binding constants, K_b were calculated at different temperatures, and the thermodynamic parameters ?G^°, ?H^° and ?S^° were given. The experimental results showed that D-IB molecules could bind with DNA via groove binding mode as evidenced by: I. DNA binding constant from spectrophotometric studies of the interaction of D-IB with DNA is comparable to groove binding drugs. II. Competitive fluorimetric studies with Hoechst 33258 have shown that D-IB exhibits the ability of this complex to displace with DNA-bounded Hoechst, indicating that it binds to DNA in strong competition with Hoechst for the groove binding. III. There is no significantly change in the absorption of the MB-DNA system upon adding the D-IB, indicates that MB molecules are not released from the DNA helix after addition of the D-IB and are indicative of a non-intercalative mode of binding. IV. Small changes in DNA viscosity in the presence of D-IB, indicating weak link to DNA, which is consistent with DNA groove binding. As well as, induced CD spectral changes, and the docking results revealed that groove mechanism is followed by D-IB to bind with DNA.     

A microfluorometric assay for the measurement of de novo DNA synthesis in individual cells

A microfluorometric assay has been developed for the quantitation of de novo DNA synthesis. The assay reliably detects newly synthesized DNA in individual cells and provides a relative measure of the proportion of new DNA in each cell. When combined with microscopic techniques for cell identification, selected subpopulations can be examined in samples containing a complex mixture of interacting cell types. The assay employs the quenching of Hoechst-33258 fluorescence by bromodeoxyuridine incorporated into newly synthesized DNA. The ability of BUdR to quench H-33258 fluorescence is lost after a brief exposure of ultraviolet fluorescence excitation. Therefore, quenched and unquenched fluorescence intensity measurements from the same cell can be compared. Increases in fluorescence intensity occur only in cells that have synthesized DNA after the addition of BUdR. In addition the change in fluorescence intensity is proportional to the degree of BUdR substitution within the range of the assay and provides a relative measure of DNA synthesis.     

Effects of proflavin and photoactivated proflavin on the template function of single-stranded DNA

DNA context-specific effects of the association of proflavin, single-stranded DNA and DNA polymerase on DNA polymerization reactions were examined. Frameshift mutations induced by the presence of proflavin during in vitro DNA replication of a single-stranded DNA template by the Klenow fragment of Escherichia coli DNA polymerase I were sequenced. More than 80% of the frameshifts were one base-pair deletions opposite purine bases that were immediately 3' to pyrimidines. Purines (Pu) that were not adjacent to pyrimidines (Py) were not deletion sites. The remaining deletions were opposite template pyrimidines that were also immediately 3' to another pyrimidine. All pyrimidine site deletions occurred in the context 5' PyPyPu 3'. In additional experiments, the site-specific inhibition of processive DNA polymerization by proflavin was examined. A novel inhibition of polymerization was found opposite all pyrimidines in the template when proflavin-template complexes were exposed to ten seconds of white light. This inhibition of polymerization is reversible. Longer photoactivation led to an altered pattern of DNA sequence-specific inhibition that was not reversible. The role of DNA sequence-specific interactions of proflavin with DNA in proflavin mutagenesis is discussed.     

DNA binding studies of tartrazine food additive

The interaction of native calf thymus DNA with tartrazine in 10?mM Tris-HCl aqueous solution at neutral pH 7.4 was investigated. Tartrazine is a nitrous derivative and may cause allergic reactions, with a potential of toxicological risk. Also, tartrazine induces oxidative stress and DNA damage. Its DNA binding properties were studied by UV-vis and circular dichroism spectra, competitive binding with Hoechst 33258, and viscosity measurements. Tartrazine molecules bind to DNA via groove mode as illustrated by hyperchromism in the UV absorption band of tartrazine, decrease in Hoechst-DNA solution fluorescence, unchanged viscosity of DNA, and conformational changes such as conversion from B-like to C-like in the circular dichroism spectra of DNA. The binding constants (K(b)) of DNA with tartrazine were calculated at different temperatures. Enthalpy and entropy changes were calculated to be +37 and +213 kJ mol(-1), respectively, according to the Van't Hoff equation, which indicated that the reaction is predominantly entropically driven. Also, tartrazine does not cleave plasmid DNA. Tartrazine interacts with calf thymus DNA via a groove interaction mode with an intrinsic binding constant of 3.75?×?10(4) M(-1).     

Interaction of Hoechst 33258 and ethidium with histone1-DNA condensates

We report structural and dynamical aspects of DNAs from various sources including synthetic oligonucleotides in bulk buffer and as a complex with histone1 (H1). High-resolution transmission electron microscopic (HRTEM) studies reveal the structural change of the DNAs upon complexation with H1 leading to formation of compact-globular and hollow-toroidal particles. In order to explore the functionality of ligand binding of the DNAs and their complexes with H1, we have used two biologically common fluorescent probes Hoechst 33258 (H33258) and Ethidium (EB) as model ligands. Picosecond resolved fluorescence and polarization gated anisotropy studies examined that the minor groove binding of H33258 to the genomic DNA-H1 complex remains almost unaltered. However, the intercalative interaction of EB with the DNA in the complex is severely perturbed compared to that with the DNA in bulk buffer. Time-dependent solvochromic effect of the probe H33258 further elucidates the dynamical solvation, which is reflective of the overall environmental relaxation of the DNAs upon condensation by H1. We have also performed circular dichroism (CD) studies on the DNAs and their complexes with H1, which reveal the change in conformation of the DNAs in the complexes. Our studies in the ligand-binding mechanisms of the DNA-H1 complex are important to understand the mechanism of drug binding to linker DNA in condensed chromatin.     

Use of Electric Linear Dichroism and Competition Experiments with Intercalating Drugs to Investigate the Mode of Binding of Hoechst 33258, Berenil and DAPI to GC Sequences

Abstract

The drugs Hoechst 33258, berenil and DAPI bind preferentially to the minor groove of AT sequences in DNA Despite a strong selectivity for AT sites, they can interact with GC sequences by a mechanism which remains so far controversial. The 2-amino group of guanosine represents a steric hindrance to the entry of the drugs in the minor groove of GC sequences. Intercalation and major groove binding to GC sites of GC-rich DNA and polynucleotides have been proposed for these drugs. To investigate further the mode of binding of Hoechst 33258, berenil and DAPI to GC sequences, we studied by electric linear dichroism the mutual interference in the DNA binding reaction between these compounds and a classical intercalator, proflavine, or a DNA-threading intercalating drug, the amsacrine-4-carboxamide derivative SN16713. The results of the competition experiments show that the two acridine intercalators markedly affect the binding of Hoechst 33258, berenil and DAPI to GC polynucleotides but not to DNA containing AT/GC mixed sequences such as calf thymus DNA Proflavine and SN16713 exert dissimilar effects on the binding of Hoechst 33258, berenil and DAPI to GC sites. The structural changes in DNA induced upon intercalation of the acridine drugs into GC sites are not identically perceived by the test compounds. The electric linear dichroism data support the hypothesis that Hoechst 33258, berenil and DAPI interact with GC sites via a non-classical intercalation process.     

A-like guanine-guanine stacking in the aqueous DNA duplex of d(GGGGCCCC)

We have used CD spectroscopy, NMR spectroscopy and unrestrained molecular dynamics to study conformational properties of a DNA duplex formed by the self-complementary octamer d(GGGGCCCC). Its unusual CD spectrum contains features indicating A-like stacking of half of the bases, whereas the other half stack in a B-like fashion. Unrestrained molecular dynamics simulations converged to a stable B-like double-helix of d(GGGGCCCC). However, the double-helix contained a central hole whose size was half of that occurring in structure A. In the canonical structure B, the hole does not exist at all because the base-pairs cross the double-helix centre. The cytosine bases were stacked in the duplex of d(GGGGCCCC) as in structure B, while stacking of the guanine bases displayed features characteristic for structure A. NMR spectroscopy revealed that the A-like guanine-guanine stacking was accompanied by an increased tendency of the deoxyribose rings attached to the guanine bases to be puckered in an A-like fashion. Otherwise, the duplex of d(GGGGCCCC) showed no clash, no bend and no other significant deviation from structure B. The present analysis demonstrates a remarkable propensity of the guanine runs to stack in an A-like fashion even within the B-DNA framework. This property explains why the oligo(dG). oligo(dC) tracts switch into structure A so easily. Secondly, this property may influence replication, because structure A is replicated more faithfully than structure B. Thirdly, the oligo(dG) runs might have played an important role in early evolution, when DNA took on functions that originally evolved on RNA. Fourthly, the present study extends the vocabulary of DNA secondary structures by the heteronomous duplex of d(GGGGCCCC) in which the B-like strand of oligo(dC) is bound to the A-like strand of oligo(dG).     

Nitric oxide prevents anoxia-induced apoptosis in colonic HT29 cells.

Apoptosis is a critical determinant of tissue mass homeostasis and may play a role in carcinogenesis. The aim of the present study was to investigate anoxia-induced cell death in colon-derived HT29 cells and the effect of nitric oxide on this phenomenon. It was found that HT29 cells subjected to anoxia undergo apoptosis in a time dependent manner, as determined by DNA fragmentation and Hoechst-33258 dye staining. Cytochrome c release from mitochondria to cytosol is a key step in this process and this release precedes DNA fragmentation. NO inhibits anoxia induced apoptosis in these cells by inhibiting the release of cytochrome c and thus may play a role in modulating the apoptotic cell death of colon-derived epithelial cells.     

Effects of Ethidium Bromide and Several Acridine Dyes on the Kinetoplast DNA of Leishmania tropica*†

Whole cell DNA from Leishmania tropica has 2 peaks when banded by CsCl equilibrium density centrifugation. The main band has a buoyant density of 1.721 and the satellite band a buoyant density of 1.705, with Clostridium perfringens DNA (ρ= 1.6915) used as a reference. The satellite band has been identified as the kinetoplast DNA by purifying DNA from isolated kinetoplasts. L. tropica has the highest G + C content of both nuclear and kinetoplastic DNA thus far reported for trypanosomatids. The effects of ethidium bromide, acriflavin, proflavin, and 5-aminoacridine on the kinetoplast of L. tropica have been compared. Ethidium bromide and acriflavin, but not proflavin or 5-aminoacridine, induce dyskinetoplasty. L. tropica is one of the most sensitive trypanosomatids to ethidium bromide and acriflavin. Examination of the DNA from drug-treated cells in CsCl gradients revealed a loss of the satellite band after ethidium bromide or acriflavin treatment, but not after proflavin or 5-aminoacridine treatment. Cell division was required to produce these effects on the kinetoplast.     

Role of topoisomerases in cytotoxicity induced by DNA ligand Hoechst-33342 and UV-C in a glioma cell line

DNA ligand Hoechst-33342 significantly enhances UV induced cytotoxicity in human glioma cell lines (BMG-1 & U-87) with supra additive increase in cell death, cytogenetic damage, cell cycle delay, apoptosis and inhibition of PLDR. Cytotoxicity of Hoechst-33342 arises due to its interference in the breakage-rejoining reaction of DNA topoisomerases by stabilization of cleavable complexes. Since topoisomerases have also been implicated in the generation of potentially lethal DNA breaks by interaction with various types of DNA damage including UV induced DNA lesions, we investigated in present studies the role of functional topoisomerases in the synergistic cytotoxicity of Hoechst-33342 and UV in a human glioma cell line (BMG-1). Topoisomerase I activity analyzed by the plasmid relaxation assay, was significantly enhanced upon UV irradiation, implying a possible role of this enzyme in the processing of UV induced lesions. However, this increase in the activity was reduced by >50% in cells incubated with Hoechst-33342 for 1 hr prior to irradiation. Imunoflowcytometric analysis of the chromatin bound topoisomerases I and II levels (cleavable complex) using topoisomerases I and II anti-antibodies showed a good correlation between the induction of apoptosis by Hoechst-33342 and UV and enhancement in the level of topoisomerase II mediated cleavable complexes. Induction of apoptosis was associated with a decline in the level of Bcl2. Taken together, these studies show that supra additive cytotoxic effects of UV-C and Hoechst-33342 in BMG-1 cells are consequences of enhanced stabilization of topo II mediated cleavable complexes and alterations in specific signal transduction pathways of apoptosis, besides the inhibition of topoisomerase mediated repair processes.     

A Structural Model For Sequence-Specific Proflavin-DNA Interactions During In Vitro Frameshift Mutagenesis

Abstract

Molecular models describing intermediates that may lead to proflavin-induced 1 bp deletions during in vitro polymerization by E. coli DNA polymerase I Klenow fragment are proposed. The models provide structural explanations for the fact that the induced frameshifts always occur opposite template bases that are adjacent to 5′ pyrimidines and are based on the underlying hypothesis that the deletions arise because the polymerase passes by a template base without copying it. Because the most frequent mutations are opposite Pu in the template sequence 5′ Py Pu 3′, a single-strand loop-out model was constructed for this sequence and proflavin was added, using structures found in crystalline oligonucleotides and their complexes with proflavin. The model seeks to rationalize the roles of the 5′ pyrimidine and proflavin in facilitating the bypass. Four potential roles for proflavin in mutagenesis are described: 1) stacking on the looped-out base; 2) stacking on the base pair immediately preceding the site of mutation; 3) hydrogen bonding with the 5′ pyrimidine; 4) hydrogen bonding with the phosphate backbone. These models point to the possibility that a number of proflavin-DNA interactions may be involved. In contrast, modeling does not suggest a role for classically intercalated proflavin in frameshift mutagenesis arising during in vitro DNA polymerization.     

A structural model for sequence-specific proflavin-DNA interactions during in vitro frameshift mutagenesis.

Molecular models describing intermediates that may lead to proflavin-induced 1 bp deletions during in vitro polymerization by E. coli DNA polymerase I Klenow fragment are proposed. The models provide structural explanations for the fact that the induced frameshifts always occur opposite template bases that are adjacent to 5' pyrimidines and are based on the underlying hypothesis that the deletions arise because the polymerase passes by a template base without copying it. Because the most frequent mutations are opposite Pu in the template sequence 5' Py Pu 3', a single-strand loop-out model was constructed for this sequence and proflavin was added, using structures found in crystalline oligonucleotides and their complexes with proflavin. The model seeks to rationalize the roles of the 5' pyrimidine and proflavin in facilitating the bypass. Four potential roles for proflavin in mutagenesis are described: 1) stacking on the looped-out base; 2) stacking on the base pair immediately preceding the site of mutation; 3) hydrogen bonding with the 5' pyrimidine; 4) hydrogen bonding with the phosphate backbone. These models point to the possibility that a number of proflavin-DNA interactions may be involved. In contrast, modeling does not suggest a role for classically intercalated proflavin in frameshift mutagenesis arising during in vitro DNA polymerization.