Increase in acridine orange (AO) fluorescence intensity of monocytes cultured in plastic tissue culture plates as measured by flow cytometry.

Although the green-red fluorescence of AO is an accepted measure of DNA-RNA content, respectively, it is actually a measure of the fluorescence of dye bound to nucleic acids, and may vary with changes in accessibility to the dye. It has been shown for example that extraction of nuclear proteins results in a marked increase in DNA stainability. Moreover, in certain cell systems the binding of fluorochromes correlates with structural modifications in chromatin that accompany cell differentiation. We report here that changes in green & red fluorescence intensity also occur in long-term monocyte cultures. The increased red fluorescence intensity observed in cultured monocytes may reflect ribosomal RNA synthesis and the increased green fluorescence enhanced AO accessibility to DNA due to changes in chromatin organization. We compared cultured monocytes from bladder cancer patients and healthy donors. The results indicate a small but statistically significantly greater increase in mean green & red fluorescence of cultured monocytes from the cancer patients. These fluorescence variations may indicate differences in the immunologic status of cancer patients and/or be related to disease state.     

Denaturation and condensation of DNA in situ induced by acridine orange in relation to chromatin changes during growth and differentiation of Friend erythroleukemia cells

DNA in situ is progressively denatured when the cells or nuclei are treated with increasing concentration of acridine orange (AO). This transition can be monitored by flow cytometry as a decrease in green fluorescence. The complexes of denatured DNA and AO undergo immediate condensation and aggregation; this step is manifested by appearance of red luminescence and formation of precipitates that can be detected by electron microscopy. The precipitates form preferentially in heterochromatin as well as in ribosomes and polysomes. Their formation and further aggregation affects cellular light scatter properties in both the forward and right-angle direction. The AO-induced DNA denaturation and condensation was studied in nuclei of Friend erythroleukemia cells from exponentially growing, differentiated or quiescent cells. The DNA in nuclei of quiescent cells, from plateau-phase cultures, was the most sensitive to denaturation; it denatured (measured by changes in luminescence) at an AO concentration between 50 and 80 microM with the midpoint of the transition (Cd) at 70 microM. DNA in nuclei of differentiated cells (dimethyl-sulfoxide-induced erythroid differentiation) was more resistant (Cd = 77-83 microM), whereas DNA in exponentially growing cells was the most resistant (Cd = 86 microM). Extraction of proteins with 0.1 M HCl at 0 degree C abolished the differences between the cells and shifted the transition to a lower AO concentration (Cd = 46 microM). For comparison, the midpoint transitions representing condensation of free, nucleic acids measured as light scatter changes occurred at 13, 22, 31 and 53 microM of AO, for rRNA, tRNA, and denatured and native-calf thymus DNA, respectively. Denaturation and condensation of DNA, which can be induced by AO either in isolated nuclei or viable permeabilized or fixed cells provides a new approach to discriminate cell subpopulations with different chromatin structure by flow cytometry. The molecular mechanisms of this phenomenon are discussed.     

Acridine orange-induced precipitation of mouse testicular sperm cell DNA reveals new patterns of chromatin structure

Precipitate resulting from interaction between certain intercalators, such as acridine orange (AO), and nucleic acids can be detected by electron microscopy. Formation of precipitate in nuclei of live cells is modulated by chromatin structure. Susceptibility of in situ DNA to precipitation was studied in mouse testicular germ cells during various stages of sperm maturation. DNA in round spermatid chromatin, similar to somatic cell euchromatin, was rather resistant to precipitation; the electron-dense precipitate was granular and randomly distributed. DNA in elongated spermatids was more susceptible to precipitation; the products were in the form of fibers. At early stages of spermatid maturation these fibers were distributed uniformly throughout the entire nucleus. At later stages, the products appeared as approximately 25-nm-thick fibers arranged longitudinally in arrays within the nucleus. With further cell maturation, fibers in the anterior portion of the nucleus appeared to fuse, forming homogeneously dense product. These fibrous products likely represent AO interactions with DNA in chromatin in which transition proteins had replaced histones. Changing patterns of these precipitated fibers likely reflect progressive stages of chromatin condensation, which starts at the center and anterior portion of the nucleus where the fibers coalesce. Mature sperm cell DNA, known to be complexed with protamines, was more resistant to AO-induced precipitation. The data suggest that precipitation induced by AO and monitored by electron microscopy may be a useful probe of nuclear chromatin structure.     

Unstainable DNA in cell nuclei. Comparison of ten different fluorochromes

Ten fluorochromes with specificity for DNA were used to compare the stainability of nuclei of exponentially growing, nondifferentiated Friend leukemia (FL) cells with that of dimethylsulfoxide-induced, fully differentiated FL cell nuclei. Decreased accessibility of DNA to several dyes, particularly pronounced in the case of some intercalators, was observed in differentiated cells. Dye binding was also compared for both sets of nuclei following extraction of nuclear proteins, mostly histones, with 0.1-N HCl. Acid extraction of nuclear proteins increased the accessibility of DNA to varying degrees, depending upon the fluorochrome. In most cases, the differences in fluorescence between differentiated and nondifferentiated nuclei stained with most intercalating dyes was abolished by acid treatment. The results are discussed in terms of the mode of interaction between DNA and the various fluorochromes and the factors associated with chromatin structure, which may affect or be associated with different degrees of proliferative activity.     

Nuclear chromatin changes during erythroid differentiation of friend virus induced leukemic cells

Friend leukemia (FL) cells grown in the presence of dimethylsulfoxide (DMSO) undergo erythroid differentiation. Acridine orange (AO) binding to DNA and thermal denaturation of DNA in situ were studied in differentiated and non-differentiated FL cells using flow-through cytofluorometry. The differentiated cells bind less AO than do the non-differentiated ones. The difference in AO binding is higher in the spectrum of emission characteristic for AO intercalation (at 530 nm) than for AO stacking (>600 nm) and depends on AO concentration. The difference is abolished after extraction of acid-soluble macromolecules from cells. During stepwise extraction by lowering pH, there is a progressive increase of AO binding to DNA. Most of the increase in AO binding of the non-differentiated cells occurs at pH 2.5-2.0; of the differentiated cells at pH 1.75-1.50. There are differences in sensitivity of DNA in situ to heat-denaturation between differentiated and non-differentiated cells, as evidenced by the variation in height and in position of the melting bands on derivative melting profiles. The changes described suggest that a profound modulation of chromatin structure, perhaps involving altered DNA-histone interactions, occurs during the DMSO-induced erythroid differentiation of FL cells.     

Increased accessibility of bases in DNA upon binding of acridine orange.

Acridine orange (AO) forms 1:1 complexes with dsDNA which are insoluble in aqueous media, exhibit red luminescence, have minimal green luminescence and resemble complexes of AO with ss nucleic acids. During formation and/or dissociation of these complexes, accessibility of DNA bases to two conformational probes, formaldehyde and diethyl pyrocarbonate is increased, suggesting that the base pairing is destroyed and DNA at least partially denatured. Adriamycin and Ellipticine, but not Ethidium Bromide exert similar destabilizing effects. The results confirm our earlier predictions based on thermodynamic calculations that the double helix undergoes destabilization upon binding an intercalator characterized by high cooperativity in interaction with ss nucleic acids. Thus, the highly cooperative ligand binding to ss sections during the "breathing" of the polymer may progressively destabilize the adjacent ds structure.     

Denaturation of nucleic acids induced by intercalating agents. Biochemical and biophysical properties of acridine orange-DNA complexes

At high binding densities acridine orange (AO) forms complexes with ds DNA which are insoluble in aqueous media. These complexes are characterized by high red- and minimal green-luminescence, 1:1 (dye/P) stoichiometry and resemble complexes of AO with ss nucleic acids. Formation of these complexes can be conveniently monitored by light scatter measurements. Light scattering properties of these complexes are believed to result from the condensation of nucleic acids induced by the cationic, intercalating ligands. The spectral and thermodynamic data provide evidence that AO (and other intercalating agents) induces denaturation of ds nucleic acids; the driving force of the denaturation is high affinity and cooperativity of binding of these ligands to ss nucleic acids. The denaturing effects of AO, adriamycin and ellipticine were confirmed by biochemical studies on accessibility of DNA bases (in complexes with these ligands) to the external probes. The denaturing properties of AO vary depending on the primary structure (sugar- and base-composition) of nucleic acids.     

Accessibility of DNA in situ to various fluorochromes: relationship to chromatin changes during erythroid differentiation of Friend leukemia cells

Friend leukemia cells from exponentially growing or differentiated (DMSO-induced) cultures were permeabilized and their DNA was stained with 4'6-diamidino-2-phenylindole (DAPI), Hoechst 33342, acridine orange, ethidium bromide, propidium iodide, quinacrine, 7-amino-actinomycin D, mithramycin, or chromomycin A3. Accessibility of DNA to each of the above fluorochromes was compared in differentiated and nondifferentiated cells before and after nuclear proteins, mostly histones, were extracted with 0.1N HCl. A decrease in the accessibility of DNA to several dyes, especially pronounced in the case of some intercalators, was observed in differentiated cells. After extraction of nuclear proteins with HCl there was an increase in DNA accessibility, of varying degree depending on the fluorochrome and the difference between differentiated and nondifferentiated cells was abolished for most of the intercalating dyes. The increase was the lowest for DAPI (45%), the highest for 7-amino-actinomycin D (13-fold), and in general was higher for the intercalating dyes that unwind DNA than for dyes binding externally to the double helix. The results are discussed in terms of the mode of interactions between DNA and the fluorochromes and factors associated with chromatin structure that may affect accessibility of DNA in situ in exponentially growing and differentiated cells.     

Caffeine increases sensitivity of DNA to denaturation in chromatin of L1210 cells.

Exposure of exponentially growing L1210 cells to 5 mM and higher concentrations of caffeine perturbs their progression through the cell cycle and results in increased sensitivity of DNA in situ to denaturation. The latter is detected by the increased metachromatic stainability of DNA with acridine orange (AO) and sensitivity to S1 nuclease, measured by flow cytometry. Decreased DNA stability is generally characteristic of chromatin condensation and in untreated cells is observed in mitosis or quiescence (G0). The caffeine-induced decrease in DNA stability affects the interphase cells regardless of their position in the cycle and the changes are stochastic, concentration- and time-dependent. Populations of cells responding to caffeine are very heterogenous with respect to the degree of destabilization of DNA; sensitivity of DNA to denaturation of the maximally affected cells is similar to that of untreated cells in mitosis. The present method allows one to quantitatively express effects of caffeine on nuclear chromatin in individual cells of large cell populations and may be employed in studies correlating chromatin changes induced by this agent with its effects in modulation of cell sensitivity to radiation or antitumour drugs.     

Changes in cell nuclei during S phase: progressive chromatin condensation and altered expression of the proliferation-associated nuclear proteins Ki-67, cyclin (PCNA), p105, and p34.

Using multiparameter flow cytometry we have measured the nuclear DNA content of exponentially growing HL-60 cells in conjunction with protein content, nuclear forward light scatter, DNA in situ sensitivity to denaturation, DNA accessibility to 7-aminoactinomycin D (7-AMD), and content of the proliferation-associated proteins: cyclin (PCNA), p105, p34, and Ki-67. Multivariate analysis of the data made it possible to correlate changes in each parameter with the degree of cell advancement through S phase (amount of replicated DNA). A decrease of the protein/DNA ratio, lowered DNA accessibility to 7-AMD, increased sensitivity of DNA to denaturation, and increased ability of isolated nuclei to scatter light all paralleled cell progression through S phase. These changes indicate that during S phase chromatin progressively condenses and suggest that the condensation is associated with the efflux of nonhistone proteins from the nucleus. The increase in the content of the antigen detected by the Ki-67 antibody was observed to exceed the increase in DNA content during S phase and the rate of the Ki-67/DNA increase was higher during the second half of S phase. Thus, this protein appears to be primarily synthesized during S, especially late in S phase, and is degraded in G1. The ratio of cyclin (PCNA)/DNA remained rather constant whereas the contents of p105 and p34 proteins, when expressed per unit of DNA, both decreased during S phase. The data indicate that significant changes in structure and composition of chromatin take place during S phase and suggest that the composition of chromatin associated with the nonreplicated DNA is different compared to chromatin associated with the newly replicated DNA.     

Cytofluorometric and cytochemical comparisons of normal and abnormal human cells from the female genital tract.

Acridine orange staining of exfoliated cells from epithelial tissues facilitates discrimination between normal and abnormal cells: abnormal cells develop highly elevated nuclear fluorescence. Comparisons of acridine orange (AO) staining with propidium iodide (PI) or Feulgen staining have shown that: (a) PI staining also provides highly elevated nuclear fluorescence from abnormal cells; (b) the distributions of nuclear fluorescence following AO or PI staining were usually not significantly different as judged by the Kolmogorov-Smirnov test; (c) fluorescence emission spectra from AO and PI stained cells are consistent with the hypothesis that both fluorochromes bind to DNA within cell nuclei; (d) DNAse treatment of AO stained normal cells eliminates the nuclear fluorescence peak from slit-scan contours; RNAse treatment has no effect on nuclear fluorescence; (e) the distribution of abnormal cell nuclear fluorescence after AO staining is usually, but not always, significantly different from the distribution of abnormal cell nuclear absorbance after Feulgen staining, with relative nuclear fluorescence being greater than relative nuclear absorbance. The hypothesis currently most consistent with these results is that elevated Feulgen DNA content can account for only part of the discrimination provided by AO staining, and that the chromatin within abnormal cells is altered so as to increase accessibility of DNA to intercalating dyes.     

Mechanics of chromatin template activation. Physical evidence for destabilization of nucleoproteins by polyanions.

Thermal denaturation profiles were used to quantitate the destabilizing activity of five classes of polyanions in an effort to explain previously reported differences in activity among apparently similar polymers. This physical assay for polyanion action on chromatin is free of the biochemical complications associated with template assay systems. Most polyanions tested caused a thermal destabilization of the normal nucleohistone complexes of rat thymus chromatin and exposed free or weakly complexed DNA. Polyphosphates dissociated chromatin even when their net charge was as low as 6, and activity per unit of weight increased with chain length only for polymers containing less than about 20 phosphate units; pyrophosphate was inactive. Two polymers which had no influence on chromatin had a low negative charge density. Some, such as polycytidlate and denatured DNA, possessed a high charge but caused only minor changes in the shape of denaturation profiles and exposed little or no free DNA. The highly active nucleic acids, ribosomal RNA and polyguanylate, were distinguishable from inactive nucleic acids by having more secondary structure and potentially less steric hindrance for anionic interaction with chromatin. There was evidence that some polyanions dissociate certain histones before others. Although data obtained show that some histones may be redistributed from chromatin onto added double-stranded DNA in a medium containing urea, this does not appear to interfere significantly with the interpretation of typical thermal denaturation profiles of chromatin.     

Fluorescence image cytometry of nuclear DNA content versus chromatin pattern: a comparative study of ten fluorochromes.

This study is intended to be the first step of an in situ exploration of the intranuclear DNA distribution by image cytometry (SAMBA) with several fluorochromes. The nuclear DNA content and the chromatin pattern, revealed by ten fluorochromes (HO, DAPI, MA, CMA3, OM, QM, AO, EB, PI, and 7-AMD), were analyzed on mouse hepatocytes fixed by the Boehm-Sprenger procedure optimal for preserving the chromatin pattern. The question was whether fluorochromes specific to DNA make it possible to accurately quantitate the total nuclear DNA content when the chromatin pattern is preserved. Only HO and MA were found to provide satisfactory quantitation of nuclear DNA content, as assumed by both a small CV and a 4c to 2c ratio equal to 2. PI, EB, 7-AMD, and OM provided higher CV values, although the 4c to 2 c ratio was still equal to 2. QM, AO, CMA3, and DAPI provided non-reproducible and non-stoichiometric nuclear DNA content measurements under the fixation conditions used. The intranuclear and the internuclear SD of the fluorescence intensities describing the fluorescence pattern of the 2c hepatocytes proved to vary according to both the basepair specificity and the binding mode of the fluorochromes. The results reported here argue in favor of an external binding of 7-AMD to DNA and an increased quantum yield of QM when bound to AT-rich DNA. For PI, EB, 7-AMD, and OM, the measured DNA content increased with the fluorescence distribution heterogeneity. This correlation was not observed with other fluorochromes and is suggested to result from decreased fluorochrome accessibility to DNA when the chromatin is condensed. This study demonstrates that under conditions that preserve chromatin organization, only HO for AT-rich DNA and MA for GC-rich DNA can be used, alone or in combination, to measure nuclear DNA content. With other fluorochromes, either the measured DNA content or the chromatin pattern is assessed in suboptimal conditions when fluorescent image cytometry is used.     

Caffeine increases sensitivity of DNA to denaturation in chromatin of L1210 cells

Abstract.
Exposure of exponentially growing L1210 cells to 5 mM and higher concentrations of caffeine perturbs their progression through the cell cycle and results in increased sensitivity of DNA in situ to denaturation. The latter is detected by the increased metachromatic stainability of DNA with acridine orange (AO) and sensitivity to S₁ nuclease, measured by flow cytometry. Decreased DNA stability is generally characteristic of chromatin condensation and in untreated cells is observed in mitosis or quiescence (G₀). The caffeine-induced decrease in DNA stability affects the interphase cells regardless of their position in the cycle and the changes are stochastic, concentration- and time-dependent. Populations of cells responding to caffeine are very heterogenous with respect to the degree of destabilization of DNA; sensitivity of DNA to denaturation of the maximally affected cells is similar to that of untreated cells in mitosis. The present method allows one to quantitatively express effects of caffeine on nuclear chromatin in individual cells of large cell populations and may be employed in studies correlating chromatin changes induced by this agent with its effects in modulation of cell sensitivity to radiation or antitumour drugs.     

Electron spectroscopic imaging of chromatin.

The analytical electron microscope technique called electron spectroscopic imaging (ESI) has a number of applications in the study of DNA:protein complexes. The method offers an intermediate level of spatial resolution for in vitro structural studies of complexes that may be too large or heterogeneous to study by crystallography or magnetic resonance spectroscopy. An advantage of ESI is that the distribution of nucleic acids can be resolved in a nucleoprotein complex by mapping the element phosphorus, present at high levels in nucleic acid compared to protein. Measurements of phosphorus content together with mass determination allows estimates to be made of stoichiometric relationships of protein and nucleic acids in these complexes. ESI is also suited to in situ studies of nuclear structure. Mass-sensitive images combined with nitrogen and phosphorus maps can be used to distinguish nucleic acid components from nuclear structures that are predominantly protein based. Interactions between chromatin on the periphery of interchromatin granule clusters (IGC) with the protein substructure that connects the exterior of the IGC to its core can be studied with this technique. The method also avoids the use of heavy atom stains, agents required in conventional electron microscopy, that preclude the distinguishing of structures on the basis of their biochemical composition. The principles of ESI and technical aspects of the method are discussed.     

Different sensitivity of chromatin to acid denaturation in quiescent and cycling cells as revealed by flow cytometry.

The properties of DNA in situ as reflected by its staining with acridine orange are different in quiescent nonstimulated lymphocytes as compared with interphase lymphocytes that have entered the cell cycle after stimulation by mitogens. The difference is seen after cell treatment with buffers at pH 1.5 (1.3-1.9 range) followed by staining with acridine orange at pH 2.6 (2.3-2.9). Under these conditions the red metachromatic fluorescence of the acridine orange-DNA complex is higher in quiescent cells than in the cycling lymphocytes while the orthochromatic green fluorescence is higher in the cycling, interphase cells. The results suggest that DNA in condensed chromatin of quiescent lymphocytes (as in metaphase chromosomes) is more sensitive to acid-denaturation than DNA in dispersed chromatin of the cycling interphase cells. The phenomenon is used for flow cytometric differentiation between G0 and G1 cells and between G2 and M cells. In contrast to normal lymphocytes the method applied to neoplastic cells indicates the presence of cell subpopulations with condensed chromatin but with DNA content characteristic not only of G1 but also of S and G2 cells. The possibility that these cells represent quiescent (resting) subpopulations, arrested in G1, S and/or G2, is discussed.     

The use of propidium iodide in cytochemical studies of interphase chromatin structure

Different cytochemical conditions of using Propidium Iodide, a phenanthridinic fluorochrome specific for double-stranded nucleic acids, have been considered to study some structural aspects of the interphasic chromatin. Some molecular properties of the dye allow to define the structure of chromatin fibre (degree of condensation) by means of thermal denaturation of DNA, fluorochromization after extraction of different chromatin components and fluorochromization in condition of low dye-substrate molar ratio (relative unsaturation of DNA). Different biological situations such as cell specialization, neoplastic transformation and life cycles have been examined choosing some typical models (hepatocytes, nucleated erythrocytes, lymphocytes, endometrial cells).     

Unbiased chromatin accessibility profiling by RED-seq uncovers unique features of nucleosome variants in vivo

Background

Differential accessibility of DNA to nuclear proteins underlies the regulation of numerous cellular processes. Although DNA accessibility is primarily determined by the presence or absence of nucleosomes, differences in nucleosome composition or dynamics may also regulate accessibility. Methods for mapping nucleosome positions and occupancies genome-wide (MNase-seq) have uncovered the nucleosome landscapes of many different cell types and organisms. Conversely, methods specialized for the detection of large nucleosome-free regions of chromatin (DNase-seq, FAIRE-seq) have uncovered numerous gene regulatory elements. However, these methods are less successful in measuring the accessibility of DNA sequences within nucelosome arrays.

Results

Here we probe the genome-wide accessibility of multiple cell types in an unbiased manner using restriction endonuclease digestion of chromatin coupled to deep sequencing (RED-seq). Using this method, we identified differences in chromatin accessibility between populations of cells, not only in nucleosome-depleted regions of the genome (e.g., enhancers and promoters), but also within the majority of the genome that is packaged into nucleosome arrays. Furthermore, we identified both large differences in chromatin accessibility in distinct cell lineages and subtle but significant changes during differentiation of mouse embryonic stem cells (ESCs). Most significantly, using RED-seq, we identified differences in accessibility among nucleosomes harboring well-studied histone variants, and show that these differences depend on factors required for their deposition.

Conclusions

Using an unbiased method to probe chromatin accessibility genome-wide, we uncover unique features of chromatin structure that are not observed using more widely-utilized methods. We demonstrate that different types of nucleosomes within mammalian cells exhibit different degrees of accessibility. These findings provide significant insight into the regulation of DNA accessibility.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-1104) contains supplementary material, which is available to authorized users.     

Structural topography of simian virus 40 DNA replication.

Applying an in situ cell fractionation procedure, we analyzed structural systems of the cell nucleus for the presence of mature and replicating simian virus 40 (SV40) DNA. Replicating SV40 DNA intermediates were tightly and quantitatively associated with the nuclear matrix, indicating that elongation processes of SV40 DNA replication proceed at this structure. Isolated nuclei as well as nuclear matrices were able to continue SV40 DNA elongation under replication conditions in situ, arguing for a coordinated and functional association of SV40 DNA and large T molecules at nuclear structures. SV40 DNA replication also was terminated at the nuclear matrix. While the bulk of newly synthesized, mature SV40 DNA molecules then remained at this structure, some left the nuclear matrix and accumulated at the chromatin.