The circular dichroism of complexes of 2,7-di-tertiary-butyl proflavine with DNA

The binding isotherm of 2, 7-di-tert-butyl proflavine on calf thymus DNA has been measured by dialysis equilibrium. The CD spectra of complexes of the dye and DNA have been measured, and the variation of the induced circular dichroism of the dye with the amount of dye bound (r) has been found. The results show that di-tert-butyl proflavine binds to DNA in a completely different manner from proflavine itself, since both the visible and ultraviolet CD spectra of complexes of the two dyes with DNA differ markedly. The conformation of the nucleic acid is not affected by the binding of di-tert-butyl proflavine. It is possible that these results may allow determination, by using CD spectroscopy, of whether molecules intercalate into DNA.     

Comparisons between hog intestinal peroxidase and bovine lactoperoxidase-compound I formation and inhibition by benzhydroxamic acid.

The bihelical polydeoxyribonucleotides DNA and poly (deoxyadenylate-deoxythymidylate form at least two distinct complexes with the dye Hoechst 33258. The nonfluorescent complex formed at low polymer/dye ratios is replaced at high polymer/dye ratios by an intensely fluorescent complex. The transition is accompanied by pronounced changes in circular dichroism and absorption spectra and may be interpreted in terms of a noncooperative replacement of dye molecules bound in proximity by isolated molecules of bound dye. In the case of the bihelical polyribonucleotides the transition exhibits positive cooperativity and major differences from the deoxyribose polymers exist in the circular dichroism spectra, suggesting a different geometry for the complex species.     

A comparison of the interactions of proflavine with DNA and with deoxyribonucleohistone using circular dichroism spectroscopy

Complexes of proflavine with DNA and deoxyribonucleohistone from calf thymus show different optical activity in the visible and the ultraviolet. Although the visible CD spectra of both complexes arise from interactions of dye molecules, the variation in the optical activity with the amount of dye bound suggests that a lesser conformational mobility exists in DNH. This is confirmed by the ultraviolet CD spectra of the complexes, and it is suggested that the conformation of DNA within nucleohistone is altered by separation of the base pairs by a greater extent than occurs in DNA in free solution. Even if the protein is unequally distributed along the DNA, the conformation of all of the DNA is altered by its incorporation into the nucleoprotein complex, since no evidence could be detected to show that DNA in a “free” conformation existed.     

Fluorescence anisotropy of DNA/DAPI complex: torsional dynamics and geometry of the complex.

Fluorescence depolarization of synthetic polydeoxynucleotide/4'-6-diamidino-2-phenylindole dihydrochloride complexes has been investigated as a function of dye/polymer coverage. At low coverage, fluorescence depolarization is due to local torsional motions of the DNA segment where the dye resides. At relatively high coverage, fluorescence depolarization is dominated by energy transfer to other dye molecules along the DNA. The extent of the observed depolarization due to torsional motion depends on the angle the dye molecule forms with the DNA helical axis. A large torsional motion and a small angle produce the same depolarization as a small torsional motion and a large projection angle. Furthermore, the extent of transfer critically depends on the relative orientation of dye molecules along the DNA. The effect of multiple transfer is examined using a Monte Carlo approach. The measurement of depolarization with transfer, at high coverage, allows determination of the dye orientation about the DNA helical axis. The value of the torsional spring constant is then determined, at very low coverage, for few selected polydeoxynucleotides.     

Fluorescence spectra of Hoechst 33258 bound to chromatin

Fluorescence spectra of Hoechst 33258 bound to rat thymocytes were measured by flow cytometry. At low dye concentrations (less than or equal to 2 micrograms/ml) the fluorescence maximum was situated at 460 nm irrespective of solvent composition. With higher dye concentrations the fluorescence maximum was shifted upwards, the intensity decreased and the width of the fluorescence peak increased. Linear combinations of a spectrum obtained at a low dye concentration (0.5 microgram/ml, type 1 binding) and one obtained at a high dye concentration (42.4 micrograms/ml, type 2 binding) failed to reproduce spectra measured at intermediate dye concentrations (0.15 M NaCl). Hence, Hoechst 33258 forms at least three different fluorescing complexes with DNA in chromatin. The shift in the fluorescence maximum of the Hoechst 33258/chromatin complex towards higher wavelengths decreased with ionic strength. 25% ethanol in the 0.15 M NaCl staining buffer reduced the wavelength shift at high dye concentrations, indicating that the strength of type 2 binding depends on DNA conformation in addition to ionic strength. The fluorescence spectrum was independent of whether DNA in chromatin was complexed with histones or not. However, histone-depleted thymocytes fluoresced more intensely than cells in which DNA was complexed with histones, the difference being greater at low concentrations of Hoechst 33258. Hence, type 2 binding to DNA in chromatin appears to be less restricted by histones than type 1 binding.     

Analysis of calorimetric data for the binding of monomeric bis-benzimidazole,an analog of the Hoechst 33258 dye,to poly(dA) · poly(dT)

Monomeric bis-benzimidazole (MB) is an analog of the Hoechst 33258 dye. The enthalpy and entropy of MB binding were evaluated by analyzing the calorimetric data on MB reverse titration with poly(dA) · poly(dT). A mathematical model was developed to estimate the thermodynamic parameters of binding on the basis of calorimetric data. The results agree well with spectrophotometric data on the binding of analogous compounds. The model was used to estimate the parameters of binding with poly(dA) · poly(dT) for dimeric bis-benzimidazole (DB), which consists of two bis-benzimidazole monomers linked via a flexible chain. The ligand was assumed to produce different types of complexes with the polymer.     

Optimizing the cationic conjugated polymer-sensitized fluorescent signal of dye labeled oligonucleotide for biosensor applications

Methods for real time, highly selective and sensitive polynucleotide detection are of vast scientific and economic importance. Fluorescence resonance energy transfer (FRET)-based assays which take advantage of the collective response of water-soluble conjugated polymers (CPs) and the self-assembly characteristic of aqueous polyelectrolytes have been widely used for the detection of DNA, RNA, protein and small molecules. The detection sensitivity of CP-based biosensor is dependent on the signal amplification of dye emission upon excitation of CP relative to that upon direct excitation of the dye. Using cationic polyfluorene derivatives and chromophore (fluorescein or Texas Red) labeled single-stranded DNA molecules (ssDNA-C*) as donor/acceptor pairs, we show that in addition to the spectral overlap, orientation and distance between the donor and the acceptor, the energy levels and fluorescence quenching of the donor/acceptor within the polymer/DNA-C* complexes are also important factors that affect the signal output of dye emission.     

Fluorescence spectra of cells stained with a DNA-specific dye, measured by flow cytometry

Fluorescence spectra of ethanol-fixed rat thymocytes stained with the DNA-specific dye Hoechst 33258 have been measured in an arc lamp-based flow cytometer including a grating monochromator in front of the fluorescence detector. Spectral resolution was 5-10 nm. Increasing dye concentration was found to yield an increasing shift of the fluorescence spectrum toward longer wavelengths, thus supporting previous work on soluble DNA that indicated several different binding modes of this dye. The results show that similar data may be obtained for all commonly used DNA-specific dyes. It appears that this type of spectral information may be used to probe the structure of cell chromatin.     

Induced circular dichroism of DNA-dye complexes

The binding of methylene blue, proflavine, and ethidium bromide with DNA has been studied by spectrophotometric titration. Methylene blue and proflavine or methylene blue and ethidium bromide were simultaneously titrated by DNA. The results indicate that all of these dyes compete for the same bindine sites. The binding properties are discussed in terms of symmetry. The optical properties of the dye–DNA complexes have been studied as a function of DNA/dye ratio. The induced circular dichriosm due to dye–dye interaction was measured at low dye/DNA ratios for cases involving both the same dye and different dyes. A positive Cotton effect for DNA–proflavine complex may be induced at 465 mμ by eithr proflavine or ethidium bromide, whereas a netgative Cotton effect at 465 mμ may be induced by methylene blue. The limiting circular dichroism, with no dye–dye interaction, and the induced circular dichroism spectra are discussed in terms of symmetry rules.     

Double bands in DNA gel electrophoresis caused by bis-intercalating dyes.

Many bis-intercalating dyes used for fluorescence detection of DNA in electrophoresis have been reported to give band-splitting and band-broadening, which results in poor resolution and a decreased detection sensitivity. We have studied the dimeric dye YOYO-1, and to some extent also TOTO-1 and EthD-1, and found that in complex with DNA these dyes give rise to two components with different electrophoretic mobilities. Electrophoresis experiments and spectroscopic measurements on the two components show that they differ in that the DNA molecules have different amounts of dye bound. Our results exclude that the extra bands are caused by intermolecular cross-linking. Incubation of the samples for increasing times before electrophoresis makes the bands move closer and closer to each other as the dye molecules become more homogeneously distributed among the DNA molecules. Finally, the two bands merge into one at an intermediate position. This equilibration process is extremely slow at room temperature (days), and is therefore not a practical method to eliminate band-splitting in routine analysis. However, we find that if the temperature is raised to 50 degrees C, the dye-DNA complexes equilibrate completely in only 2 h.     

Fluorescence-determined preferential binding of quinacrine to DNA.

Quinacrine complexes with native DNA (Calf thymus, Micrococcus lysodeikticus, Escherichia coli, Bacillus subtilis, and Colstridium perfringens) and synthetic polynucleotides (poly(dA) . poly(dT), poly[d(A-T)] . poly[d(A-T)], poly(dG) . poly(dC) and poly[d(G-C)] . poly[d(G-C)]) has been investigated in solution at 0.1 M NaCl, 0.05 M Tris HCl, 0.001 M EDTA, pH 7.5, at 20 degrees C. Fluorescence excitation spectra of complexes with dye concentration D = 5-30 microM and DNA phosphate concentration P = 400 microM have been examined from 300 to 500 nm, while collecting the emission above 520 nm. The amounts of free and bound quinacrine in the dye-DNA complexes have been determined by means of equilibrium dialysis experiments. Different affinities have been found for the various DNAs and their values have been examined with a model that assumes that the binding constants associated with alternating purine and pyrimidine sequences are larger than those relative to nonalternating ones. Among the alternating nearest neighbor base sequences, the Pyr(3'-5')Pur sequences, i.e., C-G, T-G, C-A and T-A seem to bind quinacrine stronger than the remaining sequences. In particular the three sites, where a G . C base pair is involved, are found to display higher affinities. Good agreement is found with recent calculations on the energetics of intercalation sites in DNA. The analysis of the equilibrium shows also that the strength of the excitation spectrum of bound dye depends strongly upon the ratio of bound quinacrine to DNA. This effect can be attributed to dye-dye energy transfer along DNA.     

Pigment organization of the B800–850 antenna complex of Rhodopseudomonas sphaeroides

The B800–850 antenna complex of Rhodopseudomonas sphaeroides was studied by comparing the spectral properties of several different types of complexes, isolated from chromatophores by means of the detergents lithium dodecyl sulfate (LDS) or lauryl dimethylamine N-oxide (LDAO). Fluorescence polarization spectra of the BChl 800 emission at 4 K indicated that rapid energy transfer between at least two BChl 800 molecules occurs with a rate constant of energy transfer k_ET > 3 · 10¹² s^?1. The maximal dipole-dipole distance between the two BChl 800 molecules was calculated to be 18–19 Å. The porphyrin rings of the BChl 800 molecules are oriented parallel to each other, while their Q_y transition moments are mutually perpendicular. The energy-transfer efficiency from carotenoid to bacteriochlorophyll measured in different complexes showed that two functionally different carotenoids are present associated with, respectively, BChl 800 and BChl 850. Fluorescence polarization and linear dichroism spectra revealed that these carotenoids have different absorption spectra and a different orientation with respect to the membrane. The carotenoid associated with BChl 800 absorbs some nanometers more to the red and its orientation is approximately parallel to the membrane, while the carotenoid associated with BChl 850 is oriented more or less perpendicular to the membrane. The fluorescence polarization of BChl 850 was the same for the different complexes. This indicates that the observed polarization of the fluorescence is determined by the smallest complex obtained which contains 8–10 BChl 850 molecules. The B800–850 complex isolated with LDAO thus must consist of a highly ordered array of smaller structures. On basis of these results a minimal model is proposed for the basic unit consisting of four BChl 850 and two BChl 800 and three carotenoid molecules.     

Interaction of ethidium bromide with DNA. Optical and electrooptical study

The binding of ethidium bromide to DNA has been studied by various optical methods. From fluorescence polarization studies, and film, electric linear dichroism, and circular dichroism spectra, we propose assignments of the absorption bands of the dye, which are discussed in connection with wave-mechanical calculations recently reported. The optical activity induced in the dye absorption bands upon binding to DNA was attributed to various origins depending on the electronic transition considered. The visible absorption band displayed a circular dichroism due to the asymmetry of the binding site and independent of the amount of binding. The transition identified at 378 nm from the circular dichroism and electric dichroism observations was thought to be due to a magnetic-dipole transition. It remained constant with increasing amounts of dye bound. The main ultraviolet band showed circular dichroism characteristics corresponding to exciton interactions between dye molecules bound to neighboring sites. The electric dichroism observed for the strongly bound dye molecules indicated that the phenanthridinium ring of ethidium bromide was probably not perfectly parallel to the DNA base planes. When the amount of dye bound to DNA exceeded the maximum amount compatible with the exclusion of adjacent binding sites, the electric dichroism decreased owing to the appearance of externally bound dye molecules with no contribution to the dichroism. Sonicated DNA was used to study the lengthening of the DNA molecule upon complexation. Although the viscosity of the complexes increased with the amount of binding, the rotational diffusion coefficient measured by the electric birefringence relaxation was not detectably affected. The absence of variation in the electric birefringence with the binding indicated that the DNA base stacking remained unaltered.     

Nature of the fluorescence spectra of the DNA-specific dye "Hoechst 33258" in solvents and in DNA complexes]

Fluorescence spectra of the DNA-specific dye Hoehst 33258 are obtained in a number of solvents. These spectra are interpreted as superpositions of monomeric and dimeric fluorescence bands of this compound. We show that abnormal Stokes' shift in the Hoehst fluorescence occurs only for the dimer form of this dye. It is suggested that formation of the A--T-specific complex is realized by dimers of the Hoehst 33258 located in the narrow groove of DNA.     

New investigations on hematoxylin, hematein, and hematein-aluminium complexes. II. Hematein-aluminium complexes and hemalum staining.

The absorption spectra of hematein-aluminium solutions have been recorded at various concentrations and pH values; the solutions were prepared using analytically pure hematein and potassium alum as aluminium source. In aqueous solution, four different hematein-aluminium complexes could be distinguished by absorption spectroscopy. In weakly acidic media we observed the violet 1:1 and 1:2 complexes HmAl (VII) and HmAl2(3) (VIII), and in strongly acidic solution the red 1:1 complex HmAl2 (IX). Whereas, in weakly alkaline solution the blue 1:1 complex HmAl0 (X) was detected. By change of the pH value the complexes were mutual interconverted. The dye complexes were characterized by their absorption spectra and molar extinction coefficients. We have stained HeLa cells with the complex solutions under different experimental conditions. In all cases the nuclear staining was intense whereas the staining of the cytoplasm was weak. The microspectra of the stained nuclei were recorded and compared with the absorption spectra of the complexes in solution. Thus it was possible to identify the bound dye species. After staining in acidic media, the cells were red to red-violet depending on the reaction conditions. The three cationic dye species VII, VIII, and IX were bound in varying amounts. After blueing in weakly acidic media or in water, only the violet dye complex VII was detected whereas, after blueing in weakly alkaline media, only the blue complex X has been observed. Enzymatic digestion experiments have shown that the dye complexes in the nuclei were bound to DNA while those in the cytoplasm and nucleoli were bound to RNA. The binding between the dye complexes and the nucleic acids is discussed.     

Modification of the radiation sensitivity of human tumour cells by a bis-benzimidazole derivative

A comparison was made of the ability of either X-radiation or a DNA-specific ligand (the vital bis-benzimidazole dye; Hoechst 33342) to induce: cell killing, inhibition of de novo DNA synthesis, DNA strand breakage and the delay of cell division in human colon adenocarcinoma cells in vitro. Unlike radiation-induced cell killing, ligand-induced cytotoxicity appeared to be positively correlated with the extent of inhibition of de novo DNA synthesis--a feature consistent with the persistent binding of ligand molecules to nuclear DNA. Ligand-induced DNA strand-breaks disappeared slowly although ligand-treated cells retained apparently normal capacities to repair discrete radiogenic DNA strand-breaks. Pre-treatment of cells with Hoechst 33342 resulted in a dose-modifying enhancement of radiation resistance not associated with altered dosimetry for strand-break induction. However, radioresistance was accompanied by the protracted retention of cells in the G2 phase of the cell cycle. We suggest that the results provide direct evidence that the retention of cells in G2 phase is a sparing phenomenon and is triggered by the responses of chromatin domains to the presence of DNA damage. Our results have implications for the use of DNA-interactive agents in combined modalities for tumour therapy, and indicate a possible basis for the sparing of some tumour cells in dividing populations.     

Study of the interaction of DNA and acridine orange by various optical methods

The degree of binding of acridine orange to DNA, native or denatured, has been determined by equilibrium dialysis in 0.1M and 0.001M NaCl at 20°. The nature of the binding process has been investigated by studying various optical properties of the dye–DNA complexes and by relating them to the binding ratio. All these properties were found to vary quantitatively and qualitatively according to the successive stages of the process. These stages were assumed to be a strong binding of intercalated monomers followed by formation of bound dimers and finally by external binding of aggregates of native DNA. Absorption spectra of the complexes could be interpreted on that basis. Circular dichroism spectra were resolved into components: one band for intercalated monomers without interactions, two excition splittings for interacting monomers and bound dimers, respectively, weak bands and exciton splitting for external aggregates. The fluorescence intensity was greatly enhanced in intercallated monomers; its quenching at higher binding ratio was quantitatively related to dimer fixation. The value of the anisotropy of fluorescence at low binding ratio suggested a limited mobility of intercalated monomers; the decrease of polarization at higher binding was attributed to energy transfer between monomers. Electric dichroism displayed by the complexes in the dye absorption bands indicated an orientation of the bound molecules quite parallel to the base rings at low binding. In the range of fixation of dimers and external molecules, the dichroism was lower but still indicated an important degree of ordering.     

Dielectric behavior of DNA-proflavine complex

The dielectric relaxation of namtive DNA and DNA–proflavine complexes at different DNA phosphate (P) to dye (D) ratios, were investigated in the frequency range 100 c/sec to 100 Kc/sec. The proflavine molecules were found to have a profound effect on the static dielectric constant and the relaxation time of the polymers. The static dielectric constant was oberserved to decrese with increasing level of added proflavine. At P/D = 1, the variation of dielectric constant with frequency was small. Relaxation time (τ) was greater for the DNA–proflavine complexes compared to that for free DNA, Maximum value of the relaxation time was obtained at P/D = 10. The increase in the relaxation time and decrease in the static dielectric constant were attributed to the increase in length and meutralization of surface charges of the DNA molecules, respectively, as aresult of proflavine binding.     

Study of the interaction of proflavin with deoxytetraribonucleoside triphosphate 5'-d(ApGpCpT) in aqueous solution by uni- and two-dimensional 1H-spectroscopy]

Complex formation between acridine dye proflavine and self-complementary deoxytetraribonucleoside triphosphate 5'-d(ApGpCpT) in water-salt solution was studied by the method of one- and two-dimensional 1H-NMR spectroscopy (500 MHz). Two-dimensional homonuclear 1H-NMR spectroscopy (2D-COSY and 2D-NOESY) was used for complete assignments of proton signals of molecules in solution and for qualitative analysis of the nature of interactions between proflavine and tetranucleotide. Concentration dependences of proton chemical shifts of the molecules were measured at 293 K. Equilibrium reaction constants and limiting chemical shifts of dye protons in the complexes were determined using suggested schemes of complex formation. Based on the obtained data possible types of complexes were considered. Analysis of relative content of different types of complexes was made and special features of dynamic equilibrium were revealed as a function of correlation of dye and tetranucleotide concentrations. The most favourable structure of 1:2 complex of dye with tetranucleotide was constructed using the calculated values of induced chemical shifts of proflavine protons and 2D-NOESY spectra.     

Fluorescence, absorption and electron spin resonance study of bacteriochlorin a incorporation into membrane models.

Analysis of the bacteriochlorin a absorption spectra suggests the existence of a monomer-dimer equilibrium, particularly intense in phosphate buffer and favored by a decrease of the pH. The dye in methanolic solution is predominantly in monomeric form. Fluorescence and electron spin resonance nitroxide spin labeling measurements indicate that incorporation into the lipid phase of dimyristoyl-L-alpha-phosphatidylcholine liposomes induces dye monomerization. Moreover, the molecules are bound in the external surface of the vesicles and a complete incorporation is ensured by a lipid-to-dye ratio greater than 125.