CHO cells were grown in the presence of 1 mu M CdCl(2) and subjected to ATP-dependent replicative DNA synthesis after permeabilization. By decreasing the density of the cell culture replicative DNA synthesis was diminishing. At higher than 2 x 10(6) cell/ml concentration Cd had virtually no effect on the rate of DNA replication. Growth at higher cell concentrations could be suppressed by increasing Cd concentration. After Cd treatment cells were synchronized by counterflow centrifugal elutriation. Cadmium toxicity on cell growth in early and mid S phase led to the accumulation of enlarged cells in late S phase. Flow cytometry showed increased cellular and nuclear sizes after Cd treatment. As the cells progressed through the S phase, 11 subpopulations of nuclear sizes were distinguished. Apoptotic chromatin changes were visualized by fluorescent microscopy in a cell cycle dependent manner. In the control untreated cells the main transitory forms of chromatin corresponded to those we have published earlier (veil-like, supercoiled chromatin, fibrous, ribboned structures, chromatin strings, elongated prechromosomes, precondensed chromosomes). Cadmium treatment caused: (a) the absence of decondensed veil-like structures and premature chromatin condensation in the form of apoptotic bodies in early S phase (2.2-2.4 average C-value), (b) the absence of fibrous structures, the lack of supercoiled chromatin, the appearance of uncoiled ribboned chromatin and perichromatin semicircles, in early mid S phase (2.5-2.9 C), (c) the presence of perichromatin fibrils and chromatin bodies in mid S phase (2.9-3.2 C), (d) early intra-nuclear inclusions, elongated forms of premature chromosomes, the extrusion and rupture of nuclear membrane later in mid S phase (3.3-3.4 C), (e) the exclusion of chromatin bodies and the formation of clusters of large-sized perichromatin granules in late S phase (3.5-3.8 C) and (f) large extensive disruptions and holes in the nuclear membrane and the clumping of incompletely folded chromosomes (3.8-4. C).
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.
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.
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