Analysis of chromosome positions in the interphase nucleus of Chinese hamster cells by laser-UV-microirradiation experiments

Summary Unsynchronized cells of an essentially diploid strain of female Chinese hamster cells derived from lung tissue (CHL) were laser-UV-microirradiated (=257 nm) in the nucleus either at its central part or at its periphery. After 7–9 h postincubation with 0.5 mM caffeine, chromosome preparations were made in situ. Twenty-one and 29 metaphase spreads, respectively, with partial chromosome shattering (PCS) obtained after micro-irradiation at these two nuclear sites, were Q-banded and analyzed in detail. A positive correlation was observed between the frequency of damage of chromosomes and both their DNA content and length at metaphase. No significant difference was observed between the frequencies of damage obtained for individual chromosomes at either site of microirradiation. The frequency of joint damage of homologous chromosomes was low as compared to nonhomologous ones. Considerable variation was noted in different cells in the combinations of jointly shattered chromosomes. Evidence which justifies an interpretation of these data in terms of an interphase arrangement of chromosome territories is discussed. Our data strongly argue against somatic pairing as a regular event, and suggest a considerable variability of chromosome positions in different nuclei. However, present data do not exclude the possibility of certain non-random chromosomal arrangements in CHL-nuclei. The interphase chromosome distribution revealed by these experiments is compared with centromere-centromere, centromere-center and angle analyses of metaphase spreads and the relationship between interphase and metaphase arrangements of chromosomes is discussed.     

Fusion between interphase and mitotic plant protoplasts : Induction of premature chromosome condensation

Morphological changes in interphase nuclei were cytologically studied in heterophasic dinucleate cells formed by the fusion of mitotic and interphase plant protoplasts. Mitotic protoplasts were isolated from a partially synchronized suspension culture of wheat (Triticum monococcum). The mitotic cells were accumulated by colchicine after release of hydroxyurea block. Treatment of protoplast populations with polyethylene glycol-dimethyl sulphoxide solution resulted in metaphase-interphase fusion. Three hours after fusion, the appearance of chromosomes with single chromatid as well as of fragmented, pulverized chromatin in heterophasic cells indicated the induction of premature chromosome condensation (PCC) in somatic wheat cells. Condensation in interphase nuclei of mitotically inactive rice protoplasts was also detected after fusion with mitotic wheat protoplasts.     

Premature chromosome condensation. I. Visualization of x-ray-induced chromosome damage in interphase cells

A new method is described to visualize chromosome damage in interphase cells immediately after exposure to mutagenic agents. This method involves the fusion of treated interphase cells with untreated mitotic cells which results in the induction of premature chromosome condensation (PCC). Chinese hamster ovary (CHO) cells were treated with X-rays and chromosome aberrations were scored in G2-PCC and the mitotic chromosomes. The incidence of aberrations was significantly higher in PCC than that observed in the mitotic chromosomes of the treated cells. Post-irradiation incubation for I h before fusion allowed the repair of some of the chromosome damage. Data are also presented which indicate that the extent of radiation damage visualized in PCC is inversely proportional to the degree of chromosome condensation. These results indicate that the PCC method has a greater senstivity in the detection of induced chromosome damage than the standard method of scoring metaphase chromosomes.     

Chromatin condensation dynamics and implications of induced premature chromosome condensation

Somatic cell cycle is a dynamic process with sequential events that culminate in cell division. Several physiological activities occur in the cytoplasm and nucleus during each of the cell cycle phases which help in doubling of genetic content, organized arrangement of the duplicated genetic material and perfect mechanism for its equal distribution to the two daughter cells formed. Also, the cell cycle checkpoints ensure that the genetic material is devoid of damages thus ensuring unaltered transmission of genetic information. Two important phenomena occurring during the cell cycle are the DNA condensation and decondensation cycles in the nucleus along with the cyclic expression and functioning of certain specific proteins that help in the same. Several protein families including Cyclins, cyclin dependent kinases, condensins, cohesins and surivins ensure error free, stage specific DNA condensation and decondensation by their highly specific, controlled orchestrated presence and action. Understanding the molecular mechanisms of chromatin compaction towards formation of the structural units, the chromosomes, give us valuable insights into the cellular physiology and also direct us to techniques such as premature chromosome condensation. The techniques of inducing ‘prophasing’ of interphase cells are undergoing rapid advances which have multidimensional applications for basic research and direct applications.     

Analysis of proteins associated with chromosome condensation in baby hamster kidney cells

To identify proteins concerned with chromosome condensation processes, we used a temperature-sensitive mutant, tsBN2 derived from BHK21, in which premature chromosome condensation occurred at high temperature. When the proteins synthesized in tsBN2 during the induction of premature chromosome condensation were analyzed by two-dimensional gel electrophoresis, we found that an acidic protein with a molecular weight of 35,000 was specifically associated with chromosome condensation. In the normal cell cycle, this protein was synthesized from the G2 through the M phase. The protein was located mainly in the chromosome fraction and was phosphorylated.     

Relationship between histone phosphorylation and premature chromosome condensation

The relationship between histone phosphorylation and chromosome condensation was investigated by determining changes in phosphorylation levels of histones H1 and H3 following fusion between mitotic and interphase cells and subsequent premature chromosome condensation. We detected significant increases in the levels of phosphorylation of H1 and H3 from interphase chromatin in which a majority of nuclei had undergone premature chromosome condensation. In addition, we noted significant decreases in the phosphate content of the highly phosphorylated mitotic H1 and H3, presumably resulting from phosphatase activity contributed by the interphase component of mitotic/interphase fused cells. These observations further strengthen the correlation between histone phosphorylation and the changes in chromosome condensation associated with the initiation of mitosis. This study also suggests that maintenance of the mitotic chromosomes in a highly condensed state does not require the continued presence of histones in a highly phosphorylated form.     

Induction by H2O2 of DNA and interphase chromosome damage in plateau-phase Chinese hamster ovary cells.

The induction by H2O2 of DNA breaks, DNA double-strand breaks (DSBs), and interphase chromatin damage and their relationship to cytotoxicity were studied in plateau-phase Chinese hamster ovary (CHO) cells. Damage in interphase chromatin was assayed by means of premature chromosome condensation (PCC); DNA DSBs were assayed by nondenaturing filter elution (pH 9.6), and DNA breaks by hydroxyapatite chromatography. Cells were treated with H2O2 in suspension at 0 degrees C for 30 min and treatment was terminated by the addition of catalase. Concentrations of H2O2 lower than 1 mM were not cytotoxic, whereas concentrations of 40 and 60 mM reduced cell survival to 0.1 and 0.004, respectively. An induction of DNA breaks that was dependent on H2O2 concentration was observed at low H2O2 concentrations that reached a maximum at approximately 1 mM; at higher H2O2 concentrations induction of DNA breaks either remained unchanged or decreased. Damage at the chromosome level was not evenly distributed among the cells, when compared to that expected based on a Poisson distribution. Three categories of cells were identified after exposure to H2O2: cells with intact, control-like chromosomes, cells showing chromosome fragmentation similar to that observed in cells exposed to ionizing radiation, and cells showing a loss in the ability of their chromatin to condense into chromosomes under the PCC reaction. The fraction of cells with fragmented chromosomes, as well as the number of excess chromosomes per cell, showed a dose response similar to that of DNA DSBs, reaching a maximum at 1 mM and decreasing at higher concentrations. The results indicate that induction of DNA and chromosome damage by H2O2 follows a complex dependence probably resulting from a depletion of reducing equivalents in the vicinity of the DNA. Reducing equivalents are required to recycle the transition metal ions that are needed to maintain a Fenton-type reaction. The absence of cell killing at H2O2 concentrations that yielded the maximum amount of DNA and chromosome damage suggests that this damage is nonlethal and repairable. It is suggested that lethal DNA and chromosome damage is induced at higher concentrations of H2O2 where cell killing is observed by an unidentified mechanism.     

Histone H1 and H3 phosphorylation during premature chromosome condensation in a temperature-sensitive mutant (tsBN2) of baby hamster kidney cells

The histone phosphorylations of temperature-sensitive mutant cells (tsBN2) were investigated during the induction of premature chromosome condensation (PCC). At the permissive temperature (33.5 degrees C), the histones of the cells were phosphorylated typically as in any other mammalian cell. However, at the nonpermissive temperature (40.5 degrees C), both histone H1 and H3 were phosphorylated extensively as in mitotic cells, and the increase in these phosphorylations throughout S to G2 phase was closely correlated to the frequency of cells showing PCC. The pattern of H1 subtype phosphorylations was quite similar, and the sites of H1 phosphorylation from PCC were the same as those from mitotic cells. Although the degree of phosphorylation was low, H1 and H3 phosphorylations were observed even in G1 phase at the nonpermissive temperature. The effects of metabolic inhibitors on the induction of PCC were parallel in H1 and H3 phosphorylations; actinomycin D failed to inhibit either PCC induction or these phosphorylations, whereas cyclohexamide did, completely inhibiting H3 phosphorylation.     

Reversible chromosome condensation induced in Drosophila embryos by anoxia: visualization of interphase nuclear organization

We have studied the morphology of nuclei in Drosophila embryos during the syncytial blastoderm stages. Nuclei in living embryos were viewed with differential interference-contrast optics; in addition, both isolated nuclei and fixed preparations of whole embryos were examined after staining with a DNA-specific fluorescent dye. We find that: (a) The nuclear volumes increase dramatically during interphase and then decrease during prophase of each nuclear cycle, with the magnitude of the nuclear volume increase being greatest for those cycles with the shortest interphase. (b) Oxygen deprivation of embryos produces a rapid developmental arrest that is reversible upon reaeration. During this arrest, interphase chromosomes condense against the nuclear envelope and the nuclear volumes increase dramatically. In these nuclei, individual chromosomes are clearly visible, and each condensed chromosome can be seen to adhere along its entire length to the inner surface of the swollen nuclear envelope, leaving the lumen of the nucleus devoid of DNA. (c) In each interphase nucleus the chromosomes are oriented in the "telophase configuration," with all centromeres and all telomeres at opposite poles of the nucleus; all nuclei at the embryo periphery (with the exception of the pole cell nuclei) are oriented with their centromeric poles pointing to the embryo exterior.     

Chromatin fiber structure and plectonemic model of chromosome condensation in Drosophila cells

Reversible permeable cells have been used to isolate chromatin structures during the process of chromosome condensation. Analysis of individual structures slipping out from nuclei after reversal of permeabilization revealed that chromosomes of Drosophila cells consist of small units called rodlets. The fluorescent images of chromatin fibers were subjected to computer analysis allowing the computer-aided visualization of chromatin fibers. The zig-zag array of fibers consisting of 12-15 nucleosomes with a length of 270-330 nm (average 300 nm) showed decondensed extended strings, condensed loops, and coiled condensed loops. Theoretical considerations leading to the plectonemic model of chromatin condensation are based on experimental data, and give an explanation how the 30 chromatin fibers are formed and further condensed to the 300 nm chromatin loops in Drosophila cells.     

Ultrastructural changes associated with the induction of premature chromosome condensation in Vicia faba root meristem cells

Key message

PCC induction is regulated by several signaling pathways, and all observed effects associated with PCC induction are strongly dependent on the mechanism of action of each PCC inducer used.

Abstract

Electron microscopic observations of cells with symptoms of premature chromosome condensation (PCC) showed that the interphase chromatin and mitotic chromosomes differed with respect to a chemical compound inducing PCC. Induction of this process under the influence of hydroxyurea and caffeine as well as hydroxyurea and sodium metavanadate led to a slight decrease in interphase chromatin condensation and the formation of chromosomes with a considerably loosened structure in comparison with the control. Incubation in the mixture of hydroxyurea and 2-aminopurine brought about clear chromatin dispersion in interphase and very strong mitotic chromosome condensation. Electron microscopic examinations also revealed the characteristic features of the structural organization of cytoplasm of Vicia faba root meristems, which seemed to be dependent on the type of the PCC inducer used. The presence of the following was observed: (i) large plastids filled with starch grains (caffeine), (ii) mitochondria and plastids of electron dense matrix with dilated invaginations of their internal membranes (2-aminopurine), and (iii) large mitochondria of electron clear matrix and plastids containing protein crystals in their interior (sodium metavanadate). Moreover, since caffeine causes either the most effective loosening of chromatin fibrils (within the prematurely condensed chromosomes) or induction of starch formation (in the plastids surrounding the nuclei), this may be a proof that demonstrates the existence of a link between physical accessibility to chromatin and the effectiveness of cellular signaling (e.g., phosphothreonine-connected).     

Optimization of calyculin A-induced premature chromosome condensation assay for chromosome aberration studies

Calyculin A-induced premature chromosome condensation (PCC) assay is a simple and useful method to assess structural and numerical chromosome aberrations in cells. Our hypothesis in this study is that suboptimum calyculin A induction of PCC resulting in fuzzy compactness and/or shortened length chromosomes would decrease the detection sensitivity of numerical and structural chromosome aberrations such as small PCC rings and small excess fragments. In this study, an optimization of calyculin A exposure on chromosome morphology and PCC induction frequency was investigated using a human peripheral blood lymphocyte (PBL) ex vivo irradiation ((60) Co-γ rays; ～0.6 Gy/min; 0-30 Gy) model. Treatment with calyculin A (50 nM) for 15 and 30 min resulted in 11.3 ± 2.7 and 9.9 ± 1.6-fold increases in the frequency of G(2) /M-PCC cells with extended length chromosomes compared with the 60-min treated group over a broad dose range (0 to 20 Gy), respectively. The G(2) /M-PCC scoring index per PCC in 15- and 30-min treated groups was increased by 1.9 ± 0.2 (P = 0.001) and 1.8 ± 0.2 (P = 0.001) compared with the 60-min treated group over 0-20 Gy, respectively. The G(2) /M-PCC efficiency of 30-min treated group was highest in the three conditions (i.e., 15-, 30-, and 60-min treatment) of calyculin A exposure. Calyculin A (50 nM) treatment for 30 min before the 48-h harvest of mitogen-stimulated human PBL is optimum for the formation of suitable chromosome morphology necessary to assess structural chromosome aberrations induced by exposure to radiation using the chemical induced-PCC assay. Published 2011 Wiley Periodicals, Inc.     

Effect of arabinofuranosyladenine on radiation-induced chromosome damage in plateau-phase CHO cells measured by premature chromosome condensation: implications for repair and fixation of alpha-PLD

The effect of the DNA polymerase inhibitor beta-arabinofuranosyladenine (araA) on radiation-induced damage was studied at the cell survival and chromosome level in unfed plateau-phase cultures of Chinese hamster ovary cells. At the cell survival level postirradiation treatment with araA fixed a form of radiation-induced potentially lethal damage, termed alpha-PLD. In the absence of araA treatment, repair of PLD resulted in the formation of the survival curve shoulder in immediately plated cells and in the increase in survival observed after delayed plating. The repair kinetics observed after delayed plating of plateau-phase cells or after delayed administration of 500 microM araA were similar, suggesting that both protocols assay similar lesions. AraA-mediated fixation reached a plateau at concentrations higher than 500 microM, indicating complete fixation of alpha-PLD. At the cytogenetic level, postirradiation treatment with araA at concentrations higher than 500 microM caused a complete inhibition of chromosome repair, as scored by premature chromosome condensation. In the absence of araA, the linearity of the dose-effect relationship for chromosome fragmentation obtained immediately after irradiation was preserved even after long repair times. The repair kinetics of chromosome damage measured in cells held postirradiation in the plateau phase were the mirror image of the repair kinetics for alpha-PLD. The half-time was 1 h in both cases and repair reached a plateau after about 4-6 h. AraA-mediated repair inhibition of chromosome damage was reversible, and a decrease in residual chromosome damage was observed after post-treatment incubation in araA-free conditioned medium. This persistent chromosome damage increased with increasing araA concentration and, as with PLD fixation, reached a plateau at about 500 microM. These results suggest that repair and araA-mediated fixation of alpha-PLD have their counterparts at the chromosome level as indicated by the similar repair kinetics and inhibition/fixation characteristics obtained for alpha-PLD and chromosome damage. This relationship implies a correlation between repair at the DNA and the chromosome level and suggests that DNA polymerization is required for the repair of chromosome damage.     

Analysis of X-ray induced aberrations in mammalian chromosomes by electrofusion induced premature chromosome condensation

Summary Premature chromosome condensation (PCC) was induced by electrofusion of metaphase cells of an Ehrlich ascites tumor cell line with interphase cells of a Muntjac cell line or of a Chinese Hamster subline. Electrofusion was performed by cell alignment in a weakly inhomogeneous a.c. field of 200 V/cm amplitude (peak-to-peak value) and of 1.7 MHz frequency, followed by the application of a series of breakdown (fusion) pulses of 5 kV/cm strength and 15 µs duration. Most of the PCC's were of the G2 type despite the large proportion of G1 and S cells in the suspension. The number of chromatid aberrations observed in electrofused cells which had not been subjected to irradiation was not significantly above the spontaneous level. This indicates that electrofusion, at least as used here, did not lead to lesions expressed as structural aberrations. When interphase cells were irradiated by X-ray doses below 3 Gy before electrofusion PCC analysis showed chromosome damage consisting mainly of breaks and gaps. The frequency of aberrations recorded by PCC was 6 to 40 fold larger than that seen in conventional metaphase analysis. This large increase probably arose because of an effective suppression of the G2 repair of chromosomal lesions by the fast condensation process which took place within about 30 min. This assumption was supported by PCC experiments in which the time between X-irradiation and fusion with subsequent chromosome condensation was varied. The results demonstrated that G2 repair of chromosomal lesions was not detectable until 20 min after fusion with a half-time of the repair kinetics of about 1.5 h. The selectivity of premature chromosome condensation in G2 cells is discussed in terms of the differences between electrofusion and chemically or virally induced fusion. It is assumed that the concentration and the transfer rate of the chromosome condensation factor from the metaphase to the interphase cell are the limiting factors in achieving PCC. This is because the localised permeabilisation of the membrane and the dominance of two-cell fusions are characteristic of electrofusion.     

Changes in the proliferation of human lymphocytes induced by several cytostatics and revealed by the premature chromosome condensation technique

Premature chromosome condensation was induced by cell fusion in stimulated human lymphocytes treated with different cytostatics. Changes in the proportion of the cell-cycle stages were investigated after 72 h of culture. Although it has been reported that some agents which induce severe DNA damage accumulate cells in G2, our results have shown some differences in the modes of action of the different tested chemicals. These variations could be due to several factors like mechanisms of action of the drugs, sensitivity of lymphocyte subpopulations to the cytostatics, inter- and intra-individual variability in the response of donors.     

Occurrence of premature chromosome condensation in mouse spermatogonia treated with busulfan

Busulfan induction of premature chromosome condensation (PCC) was examined in mouse spermatogonia. Adult (C3H X SWV) F1 male mice were injected intraperitoneally with busulfan at 10 or 30 mg/kg of body weight and killed 18-72 h later. Polyploid-like mitoses were frequent (ca. 1/4 of all spermatogonial mitoses examined) in both the untreated and treated groups. Most of these were considered to have been derived from normal spermatogonia. In busulfan-treated mice, polyploid-like mitoses with PCC were seen. The frequency of PCC-containing mitoses increased with increasing dose and exposure time. A possible interpretation for PCC induction in mouse spermatogonia is discussed.     

The kinetics of postirradiation chromatin restitution as revealed by chromosome aberrations detected by premature chromosome condensation and fluorescence in situ hybridization

In a study of X-ray-induced chromosome aberrations in human G(0) lymphocytes irradiated with 4 Gy using premature chromosome condensation (PCC) and fluorescence in situ hybridization (FISH), the time-dependent pattern of chromosome fragments and interchromosomal exchanges involving chromosome 4 was recorded after postirradiation incubation times varying from 0.5 to 46.5 h. Unattached acentric fragments and incomplete interchromosomal exchanges have high initial yields, followed by an exponential decrease, while complete interchromosomal exchanges have almost zero initial yield with a subsequent increase in their number. Plateau values of all yields are reached after about 25 h. This temporal variation of aberration yields can consistently be explained by the competition of disruptive PCC stress with the progress of postirradiation structural restitution at the sites of radiation-induced chromatin instabilities. Details of the temporal pattern of incomplete exchanges reflect the different kinetics of the alpha and beta components of the yield of aberrations. The observed large difference between late-PCC and metaphase yields of unattached acentric fragments and the almost perfect conversion from incomplete prematurely condensed chromosomes into complete metaphase exchanges are explained by a difference in the magnitude of chromosome condensation stress between PCC and mitotic conditions. Chromatin sites prone to fragmentation and incompleteness under conditions of PCC can therefore persist as genetic instabilities hidden during mitosis.     

Premature chromosome condensation is induced by a point mutation in the hamster RCC1 gene.

At the nonpermissive temperature, premature chromosome condensation (PCC) occurs in tsBN2 cells derived from the BHK cell line, which can be converted to the Ts+ phenotype by the human RCC1 gene. To prove that the RCC1 gene is the mutant gene in tsBN2 cells, which have RCC1 mRNA and protein of the same sizes as those of BHK cells, RCC1 cDNAs were isolated from BHK and tsBN2 cells and sequenced to search for mutations. The hamster (BHK) RCC1 cDNA encodes a protein of 421 amino acids homologous to the human RCC1 protein. In a comparison of the base sequences of BHK and BN2 RCC1 cDNAs, a single base change, cytosine to thymine (serine to phenylalanine), was found in the 256th codon of BN2 RCC1 cDNA. The same transition was verified in the RCC1 genomic DNA by the polymerase chain reaction method. BHK RCC1 cDNA, but not tsBN2 RCC1 cDNA, complemented the tsBN2 mutation, although both have the same amino acid sequence except for one amino acid at the 256th codon. This amino acid change, serine to phenylalanine, was estimated to cause a profound structural change in the RCC1 protein.