DNA stainability in aneuploid breast tumors: comparison of four DNA fluorochromes differing in binding properties.

The aim of this study was to evaluate whether or not the differences in chromatin structure between diploid stromal cells or lymphocytes, which are often used as DNA ploidy standard, and aneuploid breast tumor cells can significantly affect the estimates of the DNA index of these tumors. To this end, the DNA content estimates of 34 aneuploid breast tumors, differing in size, degree of differentiation, and presence or absence of estrogen and progesterone receptors and metastases, were compared using four common DNA fluorochromes: DAPI, Hoechst 33342, propidium iodide, and acridine orange. These dyes differ in their mode of interaction with DNA (binding to minor groove or intercalation) and for each of them binding to DNA is restricted to a different degree by nuclear proteins. It was expected, therefore, that if differences in chromatin structure play a role in DNA content estimates, the DNA index of the measured tumors may vary depending on the dye. The cell nuclei were isolated from the tumors using a detergent-based procedure and stained with each of the dyes and the DNA index was estimated using peripheral blood lymphocytes as a DNA content standard. For each of the tumors, the DNA index estimates with all four dyes correlated very well. When the results obtained with individual dyes were compared in pairs, the correlation coefficients (r) of DNA indices were all above 0.96 (correlation at p less than 0.001). The best concordance was seen between specimens stained with Hoechst 33342 and DAPI (r = 0.99), and the least between those stained with Hoechst 33342 and propidium iodide (r = 0.96). The data indicate that DNA content analysis of unfixed nuclei, utilizing the above fluorochromes, is not significantly biased by differences in chromatin structure of the measured cells.     

The radial positioning of chromatin is not inherited through mitosis but is established de novo in early G1

The organization of chromatin in the nucleus is nonrandom. Different genomic regions tend to reside in preferred nuclear locations, relative to radial position and nuclear compartments. Several lines of evidence support a role for chromatin localization in the regulation of gene expression. Therefore, a key problem is how the organization of chromatin is established and maintained in dividing cell populations. There is controversy about the extent to which chromatin organization is inherited from mother to daughter nucleus. We have used time-lapse microscopy to track specific human loci after exit from mitosis. In comparison to later stages of interphase, we detect increased chromatin mobility during the first 2 hr of G1, and during this period association of loci with nuclear compartments is both gained and lost. Although chromatin in daughter nuclei has a rough symmetry in its spatial distribution, we show, for the first time, that the association of loci with nuclear compartments displays significant asymmetry between daughter nuclei and therefore cannot be inherited from the mother nucleus. We conclude that the organization of chromatin in the nucleus is not passed down precisely from one cell to its descendents but is more plastic and becomes refined during early G1.     

Partial characterization of nuclear binding sites for retinol delivered by cellular retinol binding protein

Retinol (vitamin A alcohol), which plays an important role in the differentiation of epithelia, can be transferred to chromatin in vitro. Rat liver chromatin can accept retinol in a specific and saturable manner only when the retinol is presented as a complex with cellular retinol-binding protein (CRBP). A partial characterization of the nuclear components responsible for accepting retinol is reported here. A preparation of solubilized chromatin isolated from liver nuclei was able to accept retinol from its complex with CRBP as described previously for nuclei and chromatin. The binding of retinol to chromatin was noncovalent. However, chromatin prepared from nuclei which were incubated with DNase I or micrococcal nuclease did not accept retinol specifically. Chromatin in the form of mono and dinucleosomes also did not accept retinol. However, treatment of nuclei with RNase did not affect the specific binding of retinol. Furthermore, it has been found that retinol was not transferred to purified double or single stranded DNA. These results are interpreted to indicate that the transfer of retinol to specific nuclear binding sites requires a higher order of chromatin structure than that occurring in nucleosome preparations.     

Chromatin structure at the replication origins and transcription-initiation regions of the ribosomal RNA genes of Tetrahymena

The chromatin structure of regulatory regions of the extrachromosomal rRNA genes of Tetrahymena thermophila was probed by nuclease treatment of isolated nuclei. The chromatin near the origins of replication contains hypersensitive sites for micrococcal nuclease, DNAase I, and DNAase II. These sites persist in starved cells, consistent with the origins' being maintained in an altered chromatin structure independent of DNA replication. The region between the two origins of replication is organized into a phased array of seven nucleosomes, the fourth of which is centered at the axis of symmetry of the palindromic rDNA. The entire transcribed region and 150 bp upstream from the initiation site are generally accessible to nucleases; any histone proteins associated with these regions are clearly not in a highly organized nucleosomal array as seen in the central region. Comparison of the chromatin structures of the central spacer of T. thermophila and T. pyriformis rDNA reveals that deletion or insertion of DNA has occurred in increments of 200 bp. This is taken to imply that there are constraints on the evolution of spacer DNA sequences at the level of the nucleosome.     

Interaction of the retinol/cellular retinol-binding protein complex with isolated nuclei and nuclear components

Retinol (vitamin A alcohol) is involved in the proper differentiation of epithelia. The mechanism of this involvement is unknown. We have previously reported that purified cellular retinol-binding (CRBP) will mediate specific binding of retinol to nuclei isolated from rat liver. We now report that pure CRBP delivers retinol to the specific nuclear binding sites without itself remaining bound. Triton X-100-treated nuclei retain the majority of these binding sites. CRBP is also capable of delivering retinol specifically to isolated chromatin with no apparent loss of binding sites, as compared to whole nuclei. CRBP again does not remain bound after transferring retinol to the chromatin binding sites. When isolated nuclei are incubated with [3H]retinol- CRBP, sectioned, and autoradiographed, specifically bound retinol is found distributed throughout the nuclei. Thus, CRBP delivers retinol to the interior of the nucleus, to specific binding sites which are primarily, if not solely, on the chromatin. The binding of retinol to these sites may affect gene expression.     

In vitro interaction of 63-nickel(II) with chromatin and DNA from rat kidney and liver nuclei

The interaction of nickel(II) with chromatin was studied in vitro and in isolated nuclei from rat liver and kidney. Nickel(II) bound to chromatin, polynucleosomes (DNA + histone octamer protein complex), and to deproteinized DNA both in intact nuclei and in vitro. The amount of nickel(II) bound depended on the concentration of nickel(II), the presence of chromosomal proteins and the binding sites on DNA which provide a stable coordination environment for nickel(II). The binding of nickel(II) to chromatin and to DNA in whole nuclei was much slower than in vitro indicating that assessibility of the DNA binding sites was influenced by the presence of the nuclear membrane, nuclear matrix and nuclear proteins and/or by the condensed nuclear structure of chromatin. Since DNA containing bound nickel(II) was isolated from chromatin, nickel(II) directly interacted with stable binding sites on the DNA molecule in chromatin. Nickel(II) was associated with the histone and non-histone nuclear proteins as well as the DNA in rat liver and kidney chromatin. Nickel(II) was found to bind to calf thymus histones in vitro. Nickel(II)-nuclear protein and -DNA interactions were investigated by gel electrophoretic analysis of in vitro incubation products. Although nickel-histone and nickel-non-histone protein interactions were completely disrupted by the electrophoretic conditions, fluorography revealed the presence of inert nickel(II)-DNA and/or nickel(II)-DNA-protein complexes.     

Cleavage preferences of the apoptotic endonuclease DFF40 (caspase-activated DNase or nuclease) on naked DNA and chromatin substrates

Here we report the co-factor requirements for DNA fragmentation factor (DFF) endonuclease and characterize its cleavage sites on naked DNA and chromatin substrates. The endonuclease exhibits a pH optimum of 7.5, requires Mg(2+), not Ca(2+), and is inhibited by Zn(2+). The enzyme generates blunt ends or ends with 1-base 5'-overhangs possessing 5'-phosphate and 3'-hydroxyl groups and is specific for double- and not single-stranded DNA or RNA. DFF endonuclease has a moderately greater sequence preference than micrococcal nuclease or DNase I, and the sites attacked possess a dyad axis of symmetry with respect to purine and pyrimidine content. Using HeLa cell nuclei or chromatin reconstituted on a 5 S rRNA gene tandem array, we prove that the enzyme attacks chromatin in the internucleosomal linker, generating oligonucleosomal DNA ladders sharper than those created by micrococcal nuclease. Histone H1, high mobility group-1, and topoisomerase II activate DFF endonuclease activity on naked DNA substrates but much less so on chromatin substrates. We conclude that DFF is a useful reagent for chromatin research.     

Three-dimensional distribution of DNase I-sensitive chromatin regions in interphase nuclei of embryonal carcinoma cells

In situ nick-translation allows the visualization of nuclease-sensitive chromatin regions in interphase nuclei. We have analyzed the three-dimensional (3-D) distribution of DNase I-sensitive regions of chromatin in nuclei from mouse P19 embryonal carcinoma cells by making optical sections using confocal scanning laser microscopy. In undifferentiated as well as embryonal carcinoma cells differentiated in vitro, DNase I-sensitive regions of chromatin are observed as discrete spots in the nucleus. These spots represent clusters of DNase I-sensitive sites. By optical sectioning, we show that these spots are preferentially, but not exclusively, localized at the nuclear periphery. No differences were observed in the spatial distribution of DNase I-sensitive sites in P19 EC cells or the differentiated P19 END-2 cells. Furthermore, we did not observe differences in the distribution of DNase I-sensitive chromatin regions during the cell cycle. These findings indicate, at least for P19 mouse embryonal carcinoma cells and their differentiated derivative END-2, that the compartmentalization of DNase I-sensitive chromatin regions is a general characteristic of the nucleus, independent of cell cycle stage or differentiation state. Since evidence has been presented that DNase I-sensitive sites are associated with actively transcribed chromatin, our results indicate that active transcribing chromatin is compartmentalized, preferentially in the periphery of the nucleus.     

The study of chromatin and chromosome structure on preparations of interphase nucleus derivatives resulting from nuclear wall removal.III Structural heterogeneity of chromatin and argyrophilic zone of the nucleolus in stretched membrane-free nuclei and chromatin bodies from human peripheral lymphocytes

Viewed by light microscopy, the majority of lymphocytes in smears of human peripheral blood display a deep staining (with any chromatin- or DNA-specific dye) of the nucleus consisting of densely aggregated chromatin in addition to one or several small nucleoli with a dot- or spot-like argyrophilic zone. Amembraneous nuclei and "free chromatin" structures were isolated from intact lymphocytes gently treated with Triton X-100. Surface stretching of both these nuclei and structures, shortly fixed in methanol--glacial acetic acid (3:1), resulted in spatial separation of thin and thick chromatin or argyrophilic fibres, nucleoli, intranuclear bodies, polymorphous aggregations of chromatin or argyrophilic fibres and incidentally observed splitted or beaded thick chromatin fibres and the chromocenter. The light microscopic pattern of chromatin fibres of stretched amembraneous nuclei, isolated from peripheral lymphocytes, well compares with that of deconvolved images of intact lymphocyte nucleus obtained with optical tomography.     

Specificity of cellular retinol-binding protein in the transfer of retinol to nuclei and chromatin

We have reported previously that cellular retinol-binding protein (CRBP) is able to transfer retinol to specific binding sites in nuclei and chromatin. In this report, we have examined the specificity of the interaction of the protein moiety of retinol-CRBP (R-CRBP) with chromatin and nuclei in the transfer process. We first determined the ability of apo-CRBP, apo-serum retinol-binding protein (RBP), and apo beta-lactoglobulin (BLG), all capable of retinol binding, to compete with R-CRBP in the transfer of retinol to chromatin and nuclei. Apo-CRBP was an effective competitor but apo-RBP and apo-BLG showed no competitive ability. On the other hand, cellular retinol-binding protein type II (CRBP(II], whose amino acid sequence shows a considerable similarity to CRBP, did compete for the transfer of retinol from the R-CRBP complex, but less effectively than CRBP. These results demonstrate that the interaction of the protein moiety of the R-CRBP complex with nuclei and chromatin is quite specific.     

An ectopic copy of the Drosophila ftz associated SAR neither reorganizes local chromatin structure nor hinders elution of a chromatin fragment from isolated nuclei.

In vitro assays using detergent extracted nuclei allow the operational definition of SARs--specific sequences in the chromosome which are thought to interact with a structural matrix or scaffold. This interaction results in the formation of large stable protein-DNA complexes. We have used P-element transformation to introduce a characterized SAR into the Drosophila genome. The standard assay, which uses detergent extracted nuclei, shows that the ectopic SAR is indeed bound to the scaffold. However, in unextracted nuclei, a chromatin fragment containing the SAR sequence is eluted from the nucleus as readily as a fragment which lacks an SAR. Furthermore, an analysis of the accessibility of the neighbouring chromosomal restriction sites in unextracted nuclei indicates that the introduction of this ectopic SAR does not influence the local structure of chromatin. We conclude that the ectopic SAR site is not attached to a nuclear scaffold or matrix in vivo.     

DNase I digestion reveals alternating asymmetrical protection of the nucleosome by the higher order chromatin structure

DNase I was used to probe the higher order chromatin structure in whole nuclei. The digestion profiles obtained were the result of single-stranded cuts and were independent of pH, type of divalent ion and chromatin repeat length. Furthermore, the protection from digestion of the DNA at the entry/exit points on the nucleosome was found to be caused not by the H1/H5 histone tails, but by the compact structure that these proteins support. In order to resolve symmetry ambiguities, DNase I digestion fragments over several nucleosome repeat lengths were analysed quantitatively and compared with computer simulations using combinations of the experimentally obtained rate constants (some of which were converted to 0 to simulate steric protection from DNase I digestion). A clear picture of precisely defined, alternating, asymmetrically protected nucleosomes emerged. The linker DNA is inside the fibre, while the nucleosomes are positioned above and below a helical path and/or with alternating orientation towards the dyad axis. The dinucleosomal modulation of the digestion patterns comes from alternate protection of cutting sites inside the nucleosome and not from alternating exposure to the enzyme of the linker DNA.     

The effect of aflatoxin B1 on normal and cortisol-stimulated rat liver ribonucleic acid synthesis

1. Aflatoxin B(1), administered in vivo, inhibits the incorporation of [(14)C]orotic acid in vivo into rat liver nuclei, and also inhibits both Mg(2+)- and Mn(2+)-dependent RNA polymerase activities in nuclei assayed in vitro. 2. Aflatoxin B(1) inhibits the cortisol-induced increase in incorporation of [(14)C]leucine in vivo, but does not affect the control value of this activity. 3. Aflatoxin B(1) administered in vivo inhibits the increase in nuclear Mg(2+)-dependent RNA polymerase activity, assayed in vitro, which results from the treatment with cortisol. 4. Adrenalectomy causes a decrease in Mg(2+)-dependent RNA polymerase activity. The effect on this enzymic activity of adrenalectomy plus treatment with aflatoxin B(1) is no greater than that of treatment with aflatoxin B(1) alone. 5. These results suggest that the inhibition of cortisol-stimulated biochemical pathways by aflatoxin B(1) is due to an inhibition of cortisol-stimulated RNA synthesis. 6. The cytoplasmic action of aflatoxin is thought to be due to a competition for receptor sites on the endoplasmic reticulum between steroid hormones and aflatoxin B(1). No evidence was obtained for a similar competition for nuclear receptor sites between [(3)H]cortisol and aflatoxin B(1). 7. No differences were observed between the activities of RNA polymerase preparations solubilized from control or aflatoxin-inhibited nuclei. 8. No differences in ;melting' profiles were observed between DNA and chromatin preparations isolated from control nuclei or from aflatoxin-inhibited nuclei. 9. It is suggested that aflatoxin B(1) exerts its effect on RNA polymerase by decreasing the template capacity of the chromatin and that the aflatoxin ;target' area of the chromatin includes that region which is stimulated by cortisol. This process, however, does not involve inhibiting the movement of cortisol from the outside of the hepatic cell to the nuclear chromatin.     

Influence of Distamycin,Chromomycin, and UV-irradiation on Extraction of Histone H1 from Rat Liver Nuclei by Polyglutamic Acid

Rat liver nucleus histone H1 was fractionated by polyglutamic acid (PG) in the presence of distamycin A (DM) or chromomycin A3 (CM). In the absence of the antibiotics, PG extracts from the nuclei about half of the nuclear H1. DM or CM added to the nuclei in saturating concentrations weakens the binding potential of most of H1. Titration of nuclei with DM shows that the number of binding sites for DM in the nuclei is less than in isolated DNA by only 20-25%, and this dif- ference disappears after treatment of nuclei with PG. The lower CD value of DM complexes with nuclei compared to that of DM complexes with free DNA is evidence of a change in the DM-DNA binding mode in nuclear chromatin. About 25% of total histone H1 is sensitive only to DM and s~5% is sensitive only to CM. Half of the DM-sensitive H1 fraction seems to have a different binding mode in condensed compared relaxed chromatin. A small part of H1 (s~3%) remains tightly bound to the nuclear chromatin independent of the presence of the antibiotics. Subfraction H1A is more DM-sensitive and H1B is more CM-sensitive. UV irradiation of nuclei results in dose-dependent cross-linking of up to 50% of total H1, which is neither acid-extractable nor recovered during SDS electrophoresis. PG with DM extracts only about 3% of H1 from UV- stabilized chromatin. DM treatment of the nuclei before UV irradiation results in extraction of the whole DM-sensitive H1 fraction (s~25%), which in this case is not stabilized in the nucleus. A hypothesis on possible roles of the found H1 fractions in chromatin structural organization is discussed.     

Preferential sites of early DNA cleavage in apoptosis and the pathway of nuclear damage

 We have tested the specific hypothesis that the pathway of nuclear collapse in apoptosis is governed by the early attack on active chromatin at spatially restricted nuclear sites. Cell death in PC12 pheochromocytoma cells deprived of serum growth factors, in HL-60 leukemic cells treated with inhibitors of protein or RNA biosynthesis, and in U937 histiocytic lymphoma cells exposed to the cytokine tumor necrosis factor alpha showed a common mechanism in the targeting of DNA for degradation. An incorporation assay with labeled nucleotide revealed an early selective nicking in peripheral nuclear chromatin with concomitant diminution in the amount of immunoreactive lamin B protein. This was followed by a phase of more extensive cleavages, continued nuclear protein loss, chromatin collapse, and fragmentation of nuclei. The spatial restriction of early cleavages is similar to the nicking obtained by the application of exogenous DNase I to fixed nuclei of normal cells and to that obtained in the activation of the endogenous endonuclease of liver nuclei by Ca²⁺. These similarities suggest that, in apoptosis, activation of an endonuclease preferentially recognizing a specific chromatin configuration, such as that of active (DNase I-sensitive) genes, underlies the early spatial demarcation of cleavages. Accepted: 12 October 1998     

Chromatin organization during spermiogenesis in Octopus vulgaris. I: Morphological structures

In the process of the chromatin remodeling that occurs during spermiogenesis in some animal species, it is possible to distinguish between two separate aspects: the chromatin condensation pattern itself (granular, fibrillar, or lamellar), and the architecture of this pattern, that is to say, its arrangement within the nucleus. In the cephalopod Octopus vulgaris these two aspects are clearly differentiated. The condensation pattern develops from 25 nm fibers to fibers with a tubular aspect and with a progressively increasing diameter (40-60 nm and then to 80 nm), to end finally in the form of very thin fibers (3-5 nm) product of the coalescence and dissolution of the major fibers. The main directive force that governs this process lies in the global change that occurs in the proteins that interact with all (or the major part) of the genomic DNA. The condensation pattern by itself in this species does not present a fixed order: most of the fibers appear without any predominant spatial direction in the spermiogenic nuclei. However, as the nuclei elongate, the chromatin fibers arrange in parallel following the elongation axis. This parallel disposition of the chromatin fibers appears to be mediated by two specific areas, each of which we call a "polar nuclear matrix" (PNM). These matrices differentiate in the basal and apical nuclear poles adjacent to the centriolar implantation fosse and the acrosome, respectively. The areas that constitute the PNM have the following characteristics: (a) they are the only areas where DNA is found anchored to the nuclear membrane; (b) they are the zones from which the chromatin condensation pattern (fibers/tubules) begins; and (c) they are most probably the points through which the mechanical forces originating from nuclear elongation are transmitted to chromatin, causing the chromatin fibers/tubules to adopt an almost perfectly parallel disposition. Finally, we discuss the importance of the architecture of the chromatin condensation pattern, as it is one of the determining factors of the spatial organization of the mature sperm genome and chromosome positioning.     

Four fluorochromes for the demonstration and microfluorometric estimation of RNA

Microfluorometric estimates of total RNA were made in selected test material stained with berberine sulfate, acridine orange, and Hoechst 33258. These measurements were compared with those obtained with propidium iodide, which is known to interact only with double-stranded nucleic acids. It was observed that all of the fluorochromes, including propidium iodide, yielded very similar patterns of fluorescence in the various types of material tested. In isolated thymocyte and hepatocyte nuclei stained with either propidium iodide or Hoechst 33258 at pH 2, it was evident that RNA could be estimated only indirectly by measuring the amount of fluorescence before and after extraction with RNase. It was apparent that the total fluorescence of small thymocyte nuclei was affected much less by RNase extraction than that of 2c hepatocyte nuclei. Attempts to obtain direct estimates of RNA by exposing the preparations to DNase were not successful: the fluorescence of thymocyte nuclei dropped almost to zero, and hepatocyte nuclei could no longer be assigned to distinct ploidy classes. In addition, since the highly condensed chromatin of thymocyte nuclei was stained much more prominently than the looser chromatin of hepatocyte nuclei with Hoechst 33258, it was apparent that this fluorochrome - when used at pH 2 - has potential usefulness as a "probe" of organizational differences in chromatin.