Nuclear Organization and Chromosome Segregation (original) (raw)
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Experimental Cell Research, 1983
Chinese hamster cells (M3-1 line) in S phase were laser-UV-microirradiated (I, 257 nm) at a small site of the nucleus. Cells were fixed either immediately thereafter or in subsequent stages of the cell cycle, including prophase and metaphase. The microirradiated chromatin was visualized by indirect immunofluorescence microscopy using antibodies specific for UV-irradiated DNA. During the whole post-incubation period (4-15 h) immunofluorescent labelling was restricted to a small part of the nucleus (f, 4.5% of the total nuclear area). In mitotic cells segments of a few chromosomes only were labelled. Following microirradiation of chromosome segments in anaphase, immunofluorescent labelling was observed over a small part of the resulting interphase nucleus. A territorial organization of interphase chromosomes, i.e. interphase chromosomes occupying distinct domains, has previously been demonstrated by our group for the nucleus of Chinese hamster cells in Gl. Our present findings provide evidence that this organization pattern is maintained during the entire cell cycle.
Condensation of Interphase Chromatin in Nuclei of Synchronized Chinese Hamster Ovary (CHO-K1) Cells
DNA and Cell Biology, 2005
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.
Experimental Cell Research
Chinese hamster cells (M3-1 line) in S phase were laser-UV-microirradiated (I, 257 nm) at a small site of the nucleus. Cells were fixed either immediately thereafter or in subsequent stages of the cell cycle, including prophase and metaphase. The microirradiated chromatin was visualized by indirect immunofluorescence microscopy using antibodies specific for UV-irradiated DNA. During the whole post-incubation period (4-15 h) immunofluorescent labelling was restricted to a small part of the nucleus (f, 4.5% of the total nuclear area). In mitotic cells segments of a few chromosomes only were labelled. Following microirradiation of chromosome segments in anaphase, immunofluorescent labelling was observed over a small part of the resulting interphase nucleus. A territorial organization of interphase chromosomes, i.e. interphase chromosomes occupying distinct domains, has previously been demonstrated by our group for the nucleus of Chinese hamster cells in Gl. Our present findings provide evidence that this organization pattern is maintained during the entire cell cycle.
Influence of Cell Fixation on Chromatin Topography
Analytical Biochemistry, 2000
Using in situ hybridization techniques, a fixation step must precede denaturation to prevent disintegration of the chromosomes. The analysis of nuclei fixed by paraformaldehyde, preserving the native structure (three-dimensional or 3D fixation and analysis) has become possible with the development of confocal microscopy; however, the analysis of those fixed by methanol and acetic acid, dehydrating the nuclei (two-dimensional or 2D fixation and analysis), remains a very valuable tool for practical use in diagnostics and also in many cases for research. We compared both types of fixation and analyses using different cell lines and different DNA probes. Fixation of cells by methanol and acetic acid leads to the enlargement of contact of nuclei with the slide surface, resulting in a substantial increase of nuclear diameter, flattening of the nucleus, and consequently to a distortion of gene topology. Our results indicate that chromatin structures located in the outer parts of the nuclear volume (e.g., heterochromatin of some centromeres) are relatively shifted to the membrane of these nuclei, keeping the absolute centromere-membrane distance constant. On the other hand, euchromatin located in the inner parts of the nuclear volume is not shifted outside proportionally to the increase of molecular dimensions; consequently, the relative distances for the center of nucleus to gene are smaller after methanol-acetic acid fixation. The limitations of the analysis of dehydrated preparations for practical use and in research are discussed.
The Topography of Chromosomes and Genes in the Nucleus
Experimental Cell Research, 1996
of nucleosomes packed into a spiral or solenoid [2 -4]. At present several lines of evidence indicate that the However, more recent in situ analysis of cryopreserved nucleus is functionally compartmentalized into dis-nuclei reveals a more disorded structure made of ribcrete structures with defined properties. For instance, bons of zigzagging nucleosomes and not solenoids [5]; it is well established that the molecular machines inadditionally, 30-nm chromatin fibers have been seen volved in replication, transcription, and RNA proin transcriptionally inactive nuclei [6], but not in active cessing assemble into morphological entities but it renuclei [7], suggesting that chromatin in the nucleus mains unclear whether these correspond to autonomay switch from a condensed and ordered configuramous ''organelles'' or rather represent temporary tion to a more extended and disordered structure deaccumulations of either active factors recruited onto pending on transcriptional activity.
Chromosomes exhibit preferential positioning in nuclei of quiescent human cells
Journal of cell …, 1999
The relative spatial positioning of chromosomes 7, 8, 16, X and Y was examined in nuclei of quiescent (noncycling) diploid and triploid human fibroblasts using fluorescence in situ hybridization (FISH) with chromosome-specific DNA probes and digital imaging. In quiescent diploid cells, interhomolog distances and chromosome homolog position maps revealed a nonrandom, preferential topology for chromosomes 7, 8 and 16, whereas chromosome X approximated a more random distribution. Variations in the orientation of nuclei on the culture substratum tended to hinder detection of an ordered chromosome topology at interphase by biasing homolog position maps towards random distributions. Using two chromosome X homologs as reference points in triploid cells (karyotype = 69, XXY), the intranuclear location of chromosome Y was found to be predictable within remarkably narrow spatial limits. Dual-FISH with various combinations of chromosome-specific DNA probes and contrasting fluorochromes was used to identify adjacent chromosomes in mitotic rosettes and test whether they are similarly positioned in interphase nuclei. From among the combinations tested, chromosomes 8 and 11 were found to be closely apposed in most mitotic rosettes and interphase nuclei. Overall, results suggest the existence of an ordered interphase chromosome topology in quiescent human cells in which at least some chromosome homologs exhibit a preferred relative intranuclear location that may correspond to the observed spatial order of chromosomes in rosettes of mitotic cells.