Condensation of interphase chromatin in nuclei of synchronized chinese hamster ovary (CHO-K1) cells

Reversibly permeabilized cells have been used to visualize interphase chromatin structures in the presence and absence of biotinylated nucleotides. By reversing permeabilization, it was possible to confirm the existence of a flexible chromatin folding pattern through a series of transient geometric forms such as supercoiled, circular forms, chromatin bodies, thin and thick fibers, and elongated chromosomes. Our results show that the incorporation of biotin-11-dUTP interferes with chromatin condensation, leading to the accumulation of decondensed chromatin structures. Chromatin condensation without nucleotide incorporation was also studied in cell populations synchronized by centrifugal elutriation. After reversal of permeabilization, nuclei were isolated and chromatin structures were visualized after DAPI staining by fluorescent microscopy. Decondensed veil-like structures were observed in the early S phase (at an average C-value of 2.21), supercoiled chromatin later in the early S (2, 55 C), fibrous structures in the early mid S phase (2, 76 C), ribboned structures in the mid-S phase (2, 98 C), continuous chromatin strings later in the mid-S phase (3,28), elongated prechromosomes in the late S-phase (3, 72 C), precondensed chromosomes at the end and after the S phase (3, 99 C). Fluorescent microscopy revealed that neither interphase nor metaphase chromosomes are separate entities but form a linear array arranged in a semicircle. Linear arrangement was confirmed by computer image analysis.     

Gamma irradiation-induced apoptosis in murine pre-B cells prevents the condensation of fibrillar chromatin in early S phase

Local changes in chromatin structure leading to temporally distinct geometric forms were characterized in nuclei of reversibly permeabilized cells. Reversal of permeabilization was tested by 3H-thymidine incorporation and trypan blue dye exclusion. Apoptotic changes were visualized in a cell cycle dependent manner at the chromatin level by fluorescent microscopy in non-irradiated cells and after 400 rad Co60 irradiation. Fluorescent microscopy of chromatin structures belonging mainly to the interphase of the cell cycle confirmed the existence of specific geometric forms in nuclei of non-irradiated cells. In this control population, the following main transitory forms of condensing chromatin were distinguished: decondensed veil-like structures and fibrous structures in early and mid S phase (2.0-2.5 average C-value), chromatin bodies, semicircles later in mid S phase (3.0-3.5 C), precondensed chromosomes in late S (3.5-3.7 C) and metaphase chromosomes at the end and after S phase (3.7-4.0 C). Our results show that upon gamma-irradiation (a) the cellular and nuclear sizes were increased, (b) the DNA content was lower in each elutriated subpopulation of cells, (c) the progression of the cell cycle was arrested in the early S phase at 2.4 C value, (d) the chromatin condensation was blocked between the fibrillar chromatin and precondensed elongated chromosomal forms, and (e) the number and size of apoptotic bodies were inversely correlated with the progression of the cell cycle, with many small apoptotic bodies in early S phase and less and larger apoptotic bodies in late S phase.     

Common pathway of chromosome condensation in Mammalian cells

Chromatin folding in the interphase nucleus is not known. We compared the pattern of chromatin condensation in Indian muntjac, Chinese hamster ovary, murine pre B, and K562 human erythroleukemia cells during the cell cycle. Fluorescent microscopy showed that chromosome condensation follows a general pathway. Synchronized cells were reversibly permeabilized and used to isolate interphase chromatin structures. Based on their structures two major categories of intermediates were distinguished: (1) decondensed chromatin and (2) condensed chromosomal forms. (1) Chromatin forms were found between the G1 and mid-S phase involving veil-like, supercoiled, fibrous, ribboned structures; (2) condensing chromosomal forms appeared in the late-S, G2, and M phase, including strings, chromatin bodies, elongated pre-chromosomes, pre-condensed chromosomes, and metaphase chromosomes. Results demonstrate that interphase chromosomes are clustered in domains; condensing interphase chromosomes are linearly arranged. Our results raise questions related to telomer sequences and to the chemical nature of chromosome connectivity.     

Structure of interphase chromosomes in the nuclei of Drosophila cells

Fluorescent images of interphase chromatin structures and chromosome structures isolated from reversibly permeable Drosophila cells were analyzed. Decondensed chromatin in early S phase (2.0-2.5 C-value) consisted of a veil-like fibrillary network. Fibrillar chromatin formed rodlets later in the early S phase (2.5-2.75 C). Drosophila chromosomes contain several smaller subunits called rodlets. Fibrillar chromatin turned to chromatin ribbon and the early mid-S-phase globular chromosomes (2.75-3.0 C), then to opened fibrous globular forms later in the mid-S-phase (3.0-3.25 C), to late-S-phase supercoiled ribbons (3.25-3.5 C), end-S-phase elongated prechromosomes (3.5-3.75 C), bent and linear chromosomes (3.75-4.0 C). Early-S phase chromatin fibrils in the nuclei of Drosophila cells are thinner than the veil-like structures in mammalian cells. The connectivity of chromosomes shows linear arrangement (3, 1, 2, 4), with larger chromosomes (1 and 2) inside and smaller chromosomes (3, 4) at the two ends in the chromosomal chain.     

Linear connection of condensing chromosomes in nuclei of synchronized CHO cells

Reversibly permeabilized cells allowed the analysis of intermediates of large-scale chomatin condensation in a cell cycle-dependent manner. This paper summarizes major intermediates of chromatin condensation and visualizes connectivity between different forms of chromosomes. At the early S phase the veil-like fibrillary chromatin is supercoiled to form chromatin bodies representing the earliest visible chromosomes. Supercoiling results in a chromatin fiber, which turns to rope (thick fiber) forming loops and chromatin ribbon. The elongated shape of prechromosomes indicates that they are arranged head to tail. Bent forms (loop, c-, and v-shaped structures) of interphase chromosomes open at the end of S phase. Linear arrangement of chromosomes was observed to the end of the condensation process, suggesting that connectivity of chromosomes is maintained throughout the cell cycle.     

Chemically induced carcinogenesis affecting chromatin structure in rat hepatocarcinoma cells

A new, chemically induced animal tumor cell line (HeDe) was established and characterized by its property of causing aggressively growing tumors in specific strain of rats and changes in the chromatin structure. Results show that (1) the nuclear material in nuclei of normal resting (G0) hepatocytes consists mainly of decondensed veil-like chromatin, chromosomes being clustered in six lobular domains; (2) nuclei of HeDe cells contain primarily supercoiled chromatin; or (3) the nuclear material of tumor cells undergoes apoptosis seen as apoptotic bodies. Heterogeneity of chromatin structures was expressed as contour/area ratio and was nine times higher in apoptotic cells and two times higher in tumor cells compared to resting cells.     

Transition from chromatin bodies to linear chromosomes in nuclei of murine PreB cells synchronized in S phase

Chromatin structures and individual interphase chromosomes escaping nuclei of reversibly permeabilized cells were analyzed in a cell cycle-dependent manner. Cells were synchronized by counterflow centrifugal elutriation. Individual interphase chromosomes became visible as distinct fibrous chromatin bodies from mid-S-phase, turning to elongated chromosomes by the end of S phase. Major interphase chromosomal forms include (1) mid-S-phase chromatin bodies at 3.0 C-value, (2) elongated chromatin bodies later in mid-S-phase (3.25 C-value), (3) chromatin bodies with head and leg portions later in S phase (3.5 C-value), (4) supercoiled ribbons later in S phase seen as twisted prechromosomes (3.7 C-value), and (5) end-S-phase elongated, bent prechromosomal structures (3.9 C-value). The first karyotype analysis of the earliest forms of chromosomes referred to as chromatin bodies was performed.     

Gamma irradiation induced apoptotic changes in the chromatin structure of human erythroleukemia K562 cells

Exponentially growing human erythroleukemia K562 cells were synchronized by centrifugal elutriation prior to and after Co⁶⁰ γ-irradiation (4 Gy). Forward scatter flow cytometry used for size analysis revealed the increase of an early apoptotic cell population ranging from lower (0.05 C-value) to higher DNA content (∼1 C) as the cells progressed through the S phase. The increase in cellular DNA content expressed in C-values correlated with apoptotic chromatin changes manifested as many small apoptotic bodies in early S phase and larger but less numerous disintegrated apoptotic bodies in late S phase. Most significant changes after exposure to γ-irradiation took place in early S phase resulting in an increase of nuclear size by more than 50%. Cell fractions containing irradiated cells showed enhanced growth arrest at 2.4 C-value, which was accompanied by apoptosis. Apoptotic cell cycle arrest near to the G₁/G₀ checkpoint and apoptotic changes indicate that the radiation resistance of K562 cells is related to the bypass of the early stage of the p53 apoptotic pathway. Apoptotic changes in chromatin structure induced by γ-irradiation indicate that these injury-specific changes can be identified and distinguished from chromatin changes induced by UV radiation or heavy metals.     

Aspects of Interaction of Putative Anchorosomal Protein p68 with the Nuclear Envelope during the Cell Cycle

In the interphase nucleus, the chromatin associated with the nuclear envelope is represented by a layer of anchorosomes, granules with a diameter of 20–25 nm. Biochemically, the fraction of chromatin directly associated with the nuclear envelope is characterized by resistance against decondensing influences, a low level of DNA methylation, and presence of specific acid-soluble proteins. However, the mechanisms lying at the base of chromatin-nuclear envelope interaction have been insufficiently studied. Specifically, it is unknown whether anchorosomes are constant structures or subject to reversible disassembly, when the contacts between chromatin and nuclear envelope are destroyed. We obtained immune serum recognizing a 68 kDa protein from the nuclear envelopes fraction and studied the localization of this protein in interphase and mitotic cells. We show that this protein, present in the NE/anchorosomal fraction, does not remain bound with chromosomes during mitosis. It dissociates from chromosomes at the beginning of the prophase and then can be identified again at the periphery of the newly forming nuclei in the telophase.     

Topography of genetic loci in the nuclei of cells of colorectal carcinoma and adjacent tissue of colonic epithelium

To determine the influence of increased gene expression and amplification in colorectal carcinoma on chromatin structure, the nuclear distances between pairs of bacterial artificial chromosome (BAC) clones with genomic separation from 800 to 29,000 kb were measured and compared between the tumor and parallel epithelial cells of six patients. The nuclear distances were measured between the loci in chromosomal bands 7p22.3–7p21.3; 7q35–7q36.3; 11p15.5–11p15.4; 20p13; 20p12.2; 20q11.21 and 20q12 where increased expression had been found in all types of colorectal carcinoma. The loci were visualized by three-dimensional fluorescence in situ hybridization using 22 BAC clones. Our results show that for short genomic separations, mean nuclear distance increases linearly with increased genomic separation. The results for some pairs of loci fell outside this linear slope, indicating the existence of different levels of chromatin folding. For the same genomic separations the nuclear distances were frequently shorter for tumor as compared with epithelial cells. Above the initial growing phase of the nuclear distances, a plateau phase was observed in both cell types where the increase in genomic separation was not accompanied by an increase in nuclear distance. The ratio of the mean nuclear distances between the corresponding loci in tumor and epithelium cells decreases with increasing amplification of loci. Our results further show that the large-scale chromatin folding might differ for specific regions of chromosomes and that it is basically preserved in tumor cells in spite of the amplification of many loci.Communicated by T. Hassold     

Condensed chromatin and its underreplication during root differentiation in leguminosae

Interphase nuclear structure was studied in 15 leguminous species. Eleven species showed chromocentric interphase nuclei while the remaining 4 had reticulate nuclei. The number of chromocenters appeared to be dependent on the number of chromosomes (2n). The total proportion of condensed chromatin as determined by planimetry was found to vary from 11–24% in chromocentric nuclei and 29–62% in reticulate nuclei. The condensed chromatin amount showed a direct correlation with the nuclear DNA content (2C). Though the interphase nuclear structure remained same in differentiated cells, the amount of condensed chromatin was considerably less than that in the meristematic cells, indicating underreplication of heterochromatin during differentiation. HCl-Giemsa method seems to be the simplest method for detection of underreplication in plants.1. NCL Communication No. 35942. To whom all the correspondence should be addressed     

Immunoelectron microscopical distribution of poly(ADP-ribose)polymerase in the mammalian cell nucleus

The ultrastructural distribution of poly(ADP-ribose)polymerase has been studied using a specific antibody and immunocytochemistry with immunogold markers. In situ localization in synchronized Chinese hamster ovary cells reveals the antibody associated with mitotic chromosomes, and later with condensed chromatin and perichromatin regions in G1 phase. During S and G2, the label occurs mostly on perichromatin regions where perichromatin fibrils are also observed. In the nucleolus, the label appears especially on the dense fibrillar component and to a minor extent on the granular component. Immunolabeled spread active chromatin preparations from exponentially growing cultured mouse P815 cells indicate preferential association of the antibody with nascent nonribosomal RNP fibrils compared to inactive chromatin. The results, suggesting a relationship between the poly(ADP-ribose)polymerase occurrence and RNA (or RNP) formation, are discussed in view of the present knowledge about possible relations between poly(ADP-ribosylation) and synthesis of RNA and DNA.     

Nuclear translocation of stress protein Hsc70 during S phase in rat C6 glioma cells

The expression and the nuclear translocation of the constitutive heat shock protein 70 (Hsc70) were determined during the cell cycle in synchronized rat astrocytomic C6 glioma cells. Cells were first shifted to the GO by serum starvation. Twelve hours after a subsequent growth stimulation by transfer to 20% newborn calf serum, about 50% of the cells entered S phase. Western blot analysis with different monoclonal antibodies showed that only the constitutively expressed and moderately stress-activated Hsc70 is induced during serum stimulation. Maximal cellular Hsc70 content (170% of the control) was observed in early to mid S phase followed by a drastic decline while cells pass through G2/M (20% of the control). Hsp70, the major heat-inducible heat shock protein in C6 cells, is not detected in either asynchronously proliferating, serum-starved or in serum-stimulated C6 cells. Analysis of the nuclear and cytoplasmic protein fractions showed a significant increase of Hsc70 translocation into the nucleus during early S phase. These results indicate a role for Hsc70 but not for Hsp70 in the process of S phase entry and/or progression in C6 cells under physiological conditions.     

Cell culture density dependent toxicity and chromatin changes upon cadmium treatment in murine pre-B-cells

Murine pre-B-cells grown in the presence of lower (1 μM) or higher (5 μM) concentration of cadmium chloride were separated into 13 fractions by centrifugal elutriation. The rate of DNA synthesis after cadmium treatment determined in permeable cells was dependent on cell culture density during cadmium treatment. Cell cycle analysis revealed a shift in the profile of DNA synthesis from replicative to repair DNA synthesis upon cadmium treatment. The study of the relationship between cell culture density and cell diameter at lower and higher cell densities in the presence of 1 μM cadmium chloride concentration showed that a. at 5×10⁵ cell/ml or lower densities cells were shrinking indicating apoptotic changes, b. at higher cell culture densities the average cell size increased, c. the treatment of cells with low CdCl₂ concentration (1 μM) at higher cell culture density (>5×10⁵ cell/ml) did not change significantly the average cell diameter. At 5 μM cadmium concentration and higher cell culture densities (>5×10⁵ cell/ml) the average cell size decreased in each elutriated fraction. Most significant inhibition of cell growth took place in early S phase (2.0–2.5 C value). Apoptotic chromatin changes in chromatin structure after cadmium treatment were seen as large extensive disruptions, holes in the nuclear membrane and stickiness of incompletely folded chromosomes.     

The position of chromosomes at metaphase in human fibroblasts and their DNA synthesis behaviour

The peripheral location of H³-thymidine labelled chromosomes in spreads of colcemid blocked metaphases from human fibroblasts has been investigated in several karyotypes. Chromosomes show non-random distribution in relation to the periphery of the plate. Longer chromosomes are significantly more peripheral than smaller chromosomes. Those chromosomes which contain large amounts of late-synthesising DNA (Y, 18 and 13) are significantly more peripheral than early synthesising chromosomes of similar length (21–22, 19–20 and 14–15). These locations are compared with those from peripheral leucocytes obtained by other workers. When location and grain number of homologues of nos. 1, 2, 3, 16 and late-X are compared it was found that in late-S labelled cells, the more peripheral of each pair was significantly more heavily labelled; in early-S labelled cells the reverse was the case. Location and patterns of labelling between late-X homologues of XXXXY cells showed that peripheral location was related to more delay in DNA synthesis. These results are discussed in terms of peripheral and central interphase distribution of condensed chromatin. It is concluded that the apparent asynchrony of replication of homologues is principally the result of different degrees of condensation of the chromatin in the late-S phase at the time of synthesis, and these differences are related to the proximity to the nuclear membrane.     

Perichromatin fibrils and chromatin ultrastructural pattern

The relationship between the synthesis of acidic nuclear proteins, phosphoproteins, RNA and chromatin ultrastructural pattern was studied in regenerating rat hepatocytes after partial hepatectomy. α-Amanitin induced, as early as 30 min after injection, a reduction of RNA synthesis to about 50% of the control level; the degree of inhibition had remained the same at 2 h after poisoning. No change was detected either in acidic nuclear protein synthesis or in phosphorylation for the whole time examined. The DNA-containing structures, demonstrated by the Gautier staining procedure, were in a dispersed pattern either in untreated regenerating hepatocytes or 30 min after α-amanitin administration to rats; but they did appear in a condensed form 1 h and more especially 2 h after toxin injection. In untreated regenerating hepatocytes, the regressive EDTA staining method for RNP revealed a large quantity of perichromatin fibrils which remained unchanged 30 min after α-amanitin treatment and were diminished at 1 h and strongly reduced 2 h thereafter.Cycloheximide treatment promptly reduced the synthesis of nuclear acidic proteins while leaving unchanged the synthesis of RNA; the quantity of perichromatin fibrils and the loosened appearance of DNA-containing structures were the same as in the control rat nuclei.Our results showed that the ultrastructural pattern of chromatin was not directly related either to the synthesis of RNA or to acidic nuclear proteins or to the phosphorylation of phosphoproteins; on the contrary, a strict relationship with the quantity of perichromatin fibrils was demonstrated. The possible interaction of perichromatin fibrils with other chromatin components was discussed as a possible regulatory mechanism of chromatin pattern.     

Incomplete chromatin condensation in enlarged rat myelocytic leukemia cells

The distinguishable morphologic features of nuclei of acute myelogenous leukemia cells with enlarged size and finely distributed nuclear chromatin indicate incomplete chromosome condensation that can be related to elevated gene expression. To confirm this, interphase chromosome structures were studied in exponentially growing rat myelomonocytic leukemia 1 cells isolated at the University of Debrecen (My1/De cells). This cell line was established from primary rat leukemia chemically induced by 7,12-dimethylbenz[a]anthracene treatment. The enlarged nuclei of My1/De cells allowed improved fluorescent visualization of chromosomal structures. Increased resolution revealed major interphase intermediates consisting of (1) veil-like chromatin, (2) chromatin ribbon, (3) chromatin funnel, (4) chromatin bodies, (5) elongated prechromosomes, (6) seal-ring, spiral shaped, and circular chromosomal subunits, (7) elongated, bent, u- and v-shaped prechromosomes, and (8) metaphase chromosomes. Results confirmed the existence of the chromatin funnel, the first visible interphase chromosome generated by the supercoiling of the chromatin ribbon. Other intermediates not seen previously included the spiral subunits that are involved in the chromonemic folding of metaphase chromosomes. The existence of spiral subunits favors the helical coil model of chromosome condensation. Incomplete chromatin condensation in leukemia cells throughout the cell cycle is an indication of euchromatization contributing to enhanced gene expression and is regarded as a leukemic factor.     

Determination of the RNA-content in samples of isolated chromatin by circular dichroism measurements

A method is presented to determine the RNA content in isolated chromatin. An increased elipticity at 260nm–290nm in the circular dichroism spectrum of chromatin is due to RNA released together with chromatin from the cell nuclei. Mixtures of chicken erythrocyte chromatin and pure 5s-RNA were used to reconstruct such spectra. From the obtained data an RNA content higher than 3–5% in samples of isolated chromatin can be determined.