Combination of BUdR-quenched Hoechst fluorescence with DNA-specific ethidium bromide fluorescence for cell cycle analysis with a two-parameter flow cytometer

Stimulated or asynchronous L-cells were grown in a BUdR-medium, harvested and stained with a combination of 33258 Hoechst and ethidium bromide for analysis in a FACS II cell sorter. The u.v. laser line served as a light source for exciting the Hoechst fluorescence, the ethidium bromide fluorescence being excited mainly by energy transfer from the Hoechst dye. The quenched Hoechst fluorescence was analysed between 410 nm and 480 nm, the DNA specific EB fluorescence at beyond 630 nm. Thus, not only the actual location of each cell in the cycle could be determined, but also its initial location at time 0 of the experiment, together with its moment of division (BUdR-quenched Hoechst fluorescence). This method could become a powerful tool in many investigations dealing with cell cycle perturbations in culture.     

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.     

Combination of Budr-Quenched Hoechst Fluorescence With Dna-Specific Ethidium Bromide Fluorescence For Cell Cycle Analysis With A Two-Parametrical Flow Cytometer

Stimulated or asynchronous L-cells were grown in a BUdR-medium, harvested and stained with a combination of 33258 Hoechst and ethidium bromide for analysis in a FACS II cell sorter. the u.v. laser line served as a light source for exciting the Hoechst fluorescence, the ethidium bromide fluorescence being excited mainly by energy transfer from the Hoechst dye. the quenched Hoechst fluorescence was analysed between 410 nm and 480 nm, the DNA specific EB fluorescence at beyond 630 nm. Thus, not only the actual location of each cell in the cycle could be determined, but also its initial location at time 0 of the experiment, together with its moment of division (BUdR-quenched Hoechst fluorescence). This method could become a powerful tool in many investigations dealing with cell cycle perturbations in culture.     

Thermal denaturation of the DNA-ethidium complex. Redistribution of the intercalated dye during melting.

The temperature dependence of the circular dichroism of the DNA-ethidium bromide complex at elevated temperatures provides evidence that the optical activity of the complex near 307 nm originates from interactions between intercalated dye molecules while the optical activity near 515 nm results from singly intercalated ethidium bromide molecules. The behavior of the circular dichroism of the complex at elevated temperatures also explains the higher ellipticities near 307 nm which characterize complexes formed between ethidium bromide and denaturated DNA. Finally the circular dichroism data indicate that the melting of the complex takes place in a stepwise manner with some DNA regions, probably AT-rich regions, dissociating first. The implications of these findings regarding the inhibiting effect of ethidium bromide on the function of DNA polymerase are examined.     

Measurements of DNA and RNA in mammary gland homogenates by the ethidium bromide technique.

A rapid method of determining simultaneously DNA and RNA in mammary gland homogenates using the ethidium bromide technique is discussed. The method utilizes a quantitative extraction of DNA and RNA with 2.0m sodium chloride, SDS, and EDTA at pH 8.0. Assays of mammary gland RNA and DNA using previously published methods were compared with determinations using the ethidium bromide technique. While the fluorescence method gave lower values for RNA when compared to those obtained using the orcinol or absorbancy ratio (OD 260nm/280nm), DNA measurements agreed well with the values determined by the diphenylamine technique. Extinction coefficient data for total mammary gland RNA isolated using a modified phenol extraction procedure are also presented.     

In Pseudomonas aeruginosa ethidium bromide does not induce its own degradation or the assembly of pumps involved in its efflux

Xu et al. [Biochem. Biophys. Res. Commun. 305 (2003) 941] reported that, when a mutant strain of Pseudomonas aeruginosa lacking its major multidrug efflux pump complex, MexAB-OprM, was incubated with 100 μM ethidium bromide, the fluorescence, caused by its binding to DNA following its entry into cells, decreased gradually. The authors concluded that the intracellular ethidium bromide “induced” either its degradation or its efflux through the assembly of unknown efflux pumps. We found, through quantitation of ethidium bromide by absorption spectroscopy, that the total amount of ethidium bromide in the system remained constant under these conditions, indicating the absence of its degradation. Furthermore, intracellular ethidium bromide kept increasing during the experiment, showing that the decrease of fluorescence was due to self-quenching, and that ethidium bromide is not pumped out by a newly assembled efflux system.     

A study of the peripheral quaternary ligand binding site of cholinesterase with the use of ethidium bromide

The peripheral binding site of horse serum cholinesterase (EC 3.1.1.7) for quaternary ligands was investigated by fluorescent probing with the use of ethidium bromide. Spectral evidence for the participation of the tryptophan indole group of the peripheral site of horse serum cholinesterase in the formation of a cholinesterase complex with ethidium bromide is presented. The mechanism of cholinesterase effect on ethidium bromide fluorescence is proposed.     

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)     

Quantitation of DNA and RNA in crude tissue extracts by flow injection analysis.

An automated two-dye flow injection analysis system to quantitate DNA and RNA in crude extracts of tissues is described. The method uses the fluorochrome dyes ethidium bromide and Hoechst 33258. DNA concentration is determined directly from its fluorescence in Hoechst dye. RNA is estimated from fluorescence in ethidium bromide after subtraction of the fluorescence due to DNA. This method has several advantages: a simple extraction procedure, a low detection limit (0.01 micrograms DNA and 0.10 micrograms RNA), automation, and a high sample throughput.     

Multiparametric flow cytometric analysis of radiation-induced micronuclei in mammalian cell cultures.

A new flow cytometric method is presented that quantifies the frequency of radiation-induced micronuclei in mammalian cell cultures with high precision. After preparing a suspension of main nuclei and micronuclei stained with ethidium bromide and Hoechst 33258, both types of particles are measured simultaneously in a flow cytometer using forward light scatter and three fluorescence emission intensities excited by UV, 488 nm, and by energy transfer from Hoechst 33258 to ethidium bromide. Nonspecific debris overlapping the micronucleus distribution especially in the low fluorescence intensity region was discriminated from micronuclei by calculating ratios of the different fluorescences. The frequencies of radiation-induced micronuclei measured with this new technique agreed well with results obtained by conventional microscopy. The lower limit of the DNA content of micronuclei identified by this technique was found to be about 0.5%-0.75% of the DNA content of G1-phase nuclei. Dose effect curves and the time-dependent induction of micronuclei were measured for two different mouse cell lines.     

The use of fluorescence anisotropy decay of poly d(A-T) ethidium bromide complex to estimate the unwinding angle of the double helix.

We measured the fluorescence decay under polarized light, of ethidium bromide bound to the poly d(A-T) isolated from Cancer Pagurus. The decay of the whole fluorescence is a single exponential function revealing a good homogeneity of the binding sites. The anisotropy decay due to energy transfers between the ethidium bromide molecules bound to a same poly d(A-T) molecule has been analysed, with a Monte Carlo calculation. We found the dye unwinds the poly d(A-T) duplex by an angle of 17 degrees plus or minus 2 degrees. This result is in agreement with the value previously found in the case of calf thymus DNA-ethidium bromide complex, although the base compositions of the two nucleic acids are different.     

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

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

Intercalation of ethidium bromide into a triple-stranded oligonucleotide.

We have examined the ability of a cationic planar chromophore, ethidium bromide, to intercalate into a short, defined triple helix. Using UV absorption, fluorescence spectroscopy and a gel retardation assay we demonstrate that ethidium bromide is able to bind to a triple helix with a lower affinity than to the corresponding duplex. Energy transfer from base triplets to ethidium shows that ethidium is intercalated into the triple helix. The spectroscopic characteristics of ethidium intercalated into a triplex are similar to those observed for intercalation into duplex DNA.     

A flow cytometric approach for characterization and differentiation of bacteria during microbial processes

The analysis of growing or resting bacterial populations by flow cytometry offers several advantages over traditional methods for determining mean-value parameters. This method has been applied here to measure both the distribution of single-cell fluorescence intensity and the light-scatter behaviour of the methylotrophical strains of Methylobacterium rhodesianum MB126 and Methylocystis GB25 as well as Pseudomonas fluorescens and a strain isolated from the soil. The four different bacterial populations were analysed concerning the DNA and the poly-3-hydroxybutyrate (PHB) content. A new cell-preservation method is presented. Optimized staining methods for each strain were developed in detail, in two cases DNA had to be dehybridized before staining with a mixture of mithramycin/ethidium bromide. Nile red is used for detecting PHB. Both stains were excited by an argonion laser at 488 nm; fluorescence emission for mithramycin/ethidium bromide was measured from 520 nm and for Nile red from 600 nm onwards. It is shown that changes in the DNA content and in the forward-light-scattering behaviour of the bacterial strains chosen were measurable. These changes could be related to different cultivation conditions and correlated, in the case of strains that accumulate PHB, with alterations of that biopolymer content. In addition it was found that these methods provide a contribution to the differentiation of mixed bacterial populations.     

Ethidium bromide resistance in a rat liver epithelial cell line: Association with enhanced drug efflux

Ethidium bromide-resistant cell strains were obtained by continuous selection of an adult rat liver-derived cell line (ARL6T) grown in the continuous presence of 200 ngl ml ethidium bromide. Comparison of resistant strains and parental (sensitive) cells was made for uptake and binding of ethidium bromide, visualized as fluorescent ethidium bromide-nucleic acid complexes. Although uptake of ethidium bromide was similar in parental and resistant cells, efflux kinetics were markedly different. Over a three-hour period, parental (sensitive) cells maintained fluorescence following a short ethidium bromide pulse (100 g/ ml ethidium bromide). In contrast, ethidium bromide-resistant cell lines eliminated photographically detectable fluorescent complexes within three hours following pulse exposure to ethidium bromide. The rapid elimination of ethidium bromide fluorescent complexes in all (5) resistant cell strains examined supports an efflux mechanism as contributing to the resistance of ethidium bromide cytotoxicity in these cells.Abbreviations EtBr ethidium bromide - HBSS Hanks' balanced salt solution     

Fiuorimetric assessment of Pseudomonas fluorescens viability after freeze-thawing using ethidium bromide

E.O. PUCHKOV AND A.N. MELKOZERNOV. 1995. The relationship between impairment of the Pseudomonas fluorescens cell envelope's permeability barrier for ethidium cation, the fluorescent moiety of ethidium bromide, and viability after freeze-thawing was investigated. Ethidium fluorescence in the suspension of intact bacteria did not change. Disruption of the bacterial permeability barrier by cetyltrimethylammonium bromide (CTAB) led to ethidium fluorescence increase due to interaction of the fluorochrome with intracellular nucleic acids. In the suspension of freeze-thawed cells, ethidium fluorescence increased and the subsequent treatment by CTAB resulted in further fluorescence increase up to the final level corresponding to that in CTAB-treated intact bacteria. For bacteria exposed to different freeze-thawing regimes, the relative ethidium fluorescence increase closely correlated with the relative number of fluorescing cells revealed microscopically. In the suspension of freeze-thawed cells, the relative additional ethidium fluorescence increase after CTAB treatment closely correlated with viability evaluated by plate counts. It is concluded that the fluorimetric approach may be used as a means of rapidly evaluating bacterial viability after freeze-thawing.     

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.     

An assay for proteinases and their inhibitors based on DNA/ethidium bromide fluorescence

Proteinases and their inhibitors have become the subject of intense research interest recently, since they control a multitude of very important biological processes, from the development of lambda phage to hypertension in humans. We have developed a simple and sensitive assay for detecting the activity of proteinases and of their proteinase inhibitors. The assay is based on ethidium bromide fluorescence, according to the following principles: (i) Ethidium bromide increases its fluorescence by 25-fold when it intercalates between base pairs of double-stranded DNA. (ii) Histones prevent this large increase in fluorescence by binding with high affinity to DNA thus blocking ethidium bromide intercalation. (iii) A proteinase that digests histones will make more DNA available for ethidium bromide intercalation, thereby producing an increase of fluorescence. Proteinase activity can easily be determined, in the presence of a DNA/histone complex, from the rate of ethidium fluorescence increase. In contrast, activity of a proteinase inhibitor is quantitated by the inhibition of fluorescence gain in the presence of a known amount of proteinase. This assay is rapid, simple, inexpensive, and, at the same time, accurate and sensitive enough to allow quantitation of nanogram amounts of various broad-specificity proteinases and their inhibitors. We show some possible applications of the assay (i) in testing column fractions during protein purifications, (ii) quantitation of alpha 1-antitrypsin in human serum, and (iii) detection of proteinase activity in cell extracts.     

Determination of plasmid copy number by fluorescence densitometry

A simple and reliable method for the determination of plasmid copy numbers by direct fluorescence densitometry of ethidium bromide-stained electrophoretic gels was developed. In developing the method, the following parameters were evaluated and controlled: plasmid DNA trapping in the linear chromosomal DNA, staining-destaining kinetics for ethidium bromide, linearity of the fluorescence response, and the effect of the molecular topology of DNA on ethidium bromide binding to DNA in agarose.     

Fluorometric determination of DNA and RNA in Chlamydomonas using ethidium bromide

By using the fluorescence enhancement of ethidium bromide bound to nuclei acid, a very rapid, simple and sensitive assay of DNA in the green alga Chlamydomonas has been devised. Total fluorescence (DNA + RNA) was determined by complex formation with ethidium bromide in a cell lysate made by mixing cell samples with lauroyl sarcosinate, EDTA and NaOH and incubating the mixture for 5 min at room temperature followed by neutralization. For determination of DNA the RNA was digested by incubating the cell sample in te alkaline lysis solution for 45 min at 60 degrees C followed by neutralization, and complex formation with ethidium bromide. Quenching of the fluorescence due to cellular pigments was corrected for using an internal DNA standard.