DNA stable pentaploid H1 (ES) cells obtained from an octaploid cell induced from tetraploid cells polyploidized using demecolcine

Pentaploid H1 (ES) cells (5H1 cells) were accidentally obtained through one‐cell cloning of octaploid H1 (ES) cells (8H1 cells) that were established from tetraploid H1 (ES) cells (4H1 cells) polyploidized using demecolcine. The number of chromosomes of 5H1 cells was 100, unlike the 40 of diploid H1 (ES) cells (2H1 cells), 80 of 4H1, and 160 of 8H1 cells. The durations of G₁, S, and G₂/M phases of 5H1 cells were 3, 7, and 6 h, respectively, almost the same as those of 2H1, 4H1, and 8H1 cells. The cell volume of 5H1 cells was half of that of 8H1 cells, suggesting that 5H1 cells were created through abnormal cell divisions of 8H1 cells. The morphology of growing 5H1 cells was a spherical cluster similar to that of 2H1 cells and differing from the flagstone‐like shape of 4H1 and 8H1 cells. Pentaploid solid tumors were formed from 5H1 cells after interperitoneal injection into the mouse abdomen, and they contained endodermal, mesodermal, and ectodermal cells as well as undifferentiated cells, suggesting both that the DNA content of 5H1 cells was retained during tumor formation and that the 5H1 cells were pluripotent. The DNA content of 5H1 cells was stable in long‐term culturing as 2H1 cells, meaning that 5H1 and 2H1 cells shared similarities in DNA structure. The excellent stability of the DNA content of 5H1 cells was explained using a hypothesis for the DNA structure of polyploid cells because the pairing of homologous chromosomes in 5H1 cells is spatially forbidden. J. Cell. Physiol. 223: 369–375, 2010. © 2010 Wiley‐Liss, Inc.     

DNA-unstable decaploid mouse H1 (ES) cells established from DNA-stable pentaploid H1 (ES) cells polyploidized using demecolcine

Objectives: DNA content of diploid H1 (ES) cells (2H1 cells) has been shown to be stable in long‐term culture; however, tetraploid and octaploid H1 (ES) cells (4H1 and 8H1 cells, respectively) were DNA‐unstable. Pentaploid H1 (ES) cells (5H1 cells) established recently have been found to be DNA‐stable; how, then is cell DNA stability determined? To discuss ploidy stability, decaploid H1 (ES) cells (10H1 cells) were established from 5H1 cells and examined for DNA stability. Materials and methods: 5H1 cells were polyploidized using demecolcine (DC) and 10H1 cells were obtained by one‐cell cloning. Results: Number of chromosomes of 10H1 cells was 180 and durations of their G₁, S, and G₂/M phases were 3, 7 and 6 h respectively. Volume of 10H1 cells was double that of 5H1 cells and morphology of 10H1 cells was flagstone‐like in shape. 10H1 cells exhibited alkaline phosphatase activity and their DNA content decayed in 91 days of culture. 10H1 cells injected into mouse abdomen formed solid tumours that contained several kinds of differentiated cells with lower DNA content, suggesting that 10H1 cells were pluripotent and DNA‐unstable. Loss of DNA stability was explained using a hypothesis concerning DNA structure of polyploid cells as DNA reconstructed through ploidy doubling was arranged in mirror symmetry in a new configuration. Conclusion: In the pentaploid–decaploid transition of H1 cells, cell cycle parameters and pluripotency were retained, but morphology and DNA stability were altered.     

Haploid unit-ploidy transition of tetraploid and octaploid H1 (ES) cells in long-term culturing

Haploid unit-ploidy transition in tetraploid and octaploid mouse H1 (ES) cells (4H1 and 8H1 cells, respectively) during long-term culturing was observed using flow cytometry. The DNA content of 4H1 cells was elevated from 3.5C to 4.5C, and that of 8H1 cells was degraded from 6.5C to 5.5C, in addition to gradual DNA loss (C: complement). The timing of the transition was not predetermined. Cell cycle parameters, doubling time and phase durations, were essentially the same before and after the transition, suggesting that most cells in a cell population were induced to undergo the ploidy transition at the same time. Cellular morphology was altered before and after the transition, suggesting that the ploidy shift changed cellular characteristics; however, pluripotency was maintained irrespective of DNA content. Cell volume correlated with DNA content during the final stage of culturing. Diploid and hexaploid H1 (ES) cells--2H1 and 6H1 cells, respectively--were used as control cells in which the ploidy was maintained for about 300 days of culturing. The haploid unit-ploidy transition was explained using a hypothesis concerning the DNA structure of polyploid cells: closing homologous chromosomes causes inhomogeneous cell division accompanying a haploid DNA set, suggesting the existence of a coupling apparatus connecting DNA fibers with a single haploid DNA set.     

Effects of etoposide on the proliferation of hexaploid H1 (ES) cells

Etoposide is a specific inhibitor of topoisomerase II, which is an enzyme that enables double-stranded DNA to pass through another double-stranded DNA. Topoisomerase II is a major constituent of chromosome scaffold, existing at appreciable amounts in cells. To examine the effects of etoposide on the cell cycle, hexaploid H1 (ES) cells (6H1 cells) were used with diploid H1 (ES) cells (2H1 cells) as a control. Exponentially growing 2H1 and 6H1 cells were exposed to etoposide at various concentrations, and cultured for about 60 days in L15F10 medium with leukemia inhibitory factor. With a high concentration of etoposide (1 μM), the DNA histograms showed G(2)/M accumulation, suggesting that etoposide arrested the cell cycle at the G(2)/M phase. With a low concentration of etoposide (50 nM), the cell proliferation was suppressed with a doubling time of 98.4 h for 2H1 cells and 51.6 h for 6H1 cells, and without significant alteration in DNA histograms. Time-lapse videography revealed that 6H1 cells survived in the medium containing 50 nM etoposide had a cell cycle time of 18.8 h, which was equivalent to 19.2 h of the doubling time for the 6H1 cell population in drug-free medium, suggesting that a part of the cell population died and was excluded from the cell system. It was concluded that etoposide affected the cell cycle at a wide range of concentrations.     

Synthesis of H1 histones by BHK cells in G1

The synthesis of histones and DNA was examined in BHK cells arrested in G1 by isoleucine starvation and in cells progressing into the S phase upon isoleucine refeeding. Approximately 2–3% of the cells were not arrested in G1 and synthesized DNA. The rate of synthesis of DNA and nucleosomal histones observed in cells starved for isoleucine could be accounted for by the presence of these asynchronous cells. Synthesis of H1 histones by cells in G1, however, was 3 times that of the nucleosomal histones and approximately 15% of the rate of H1 histone synthesis in mid-S. Upon entry into S, the histones were synthesized in the same molar ratio in which they are present in chromatin. The possible biological significance of H1 histone synthesis in G1 cells and its implications for the regulatory mechanisms controlling histone synthesis are discussed.     

Initiation of DNA synthesis in the prematurely condensed chromosomes of G1 cells

The objective of this study was to investigate whether G1 cells could enter S phase after premature chromosome condensation resulting from fusion with mitotic cells. HeLa cell synchronized in early G1, mid-G1, late G1, and G2 and human diploid fibroblasts synchronized in G0 and G1 phases were separately fused by use of UV-inactivated Sendai virus with mitotic HeLa cells. After cell fusion and premature chromosome condensation, the fused cells were incubated in culture medium containing Colcemid (0.05 micrograms/ml) and [3H]thymidine ([3H]ThdR) (0.5 microCi/ml; sp act, 6.7 Ci/mM). At 0, 2, 4, and 6 h after fusion, cell samples were taken to determine the initation of DNA synthesis in the prematurely condensed chromosomes (PCC) on the basis of their morphology and labeling index. The results of this study indicate that PCC from G0, G1, and G2 cells reach the maximum degree of compaction or condensation at 2 h after PCC induction. In addition, the G1-PCC from normal and transformed cells initiated DNA synthesis, as indicated by their "pulverized" appearance and incorporation of [3H]ThdR. Further, the initiation of DNA synthesis in G1-PCC occurred significantly earlier than in the mononucleate G1 cells. Neither pulverization nor incorporation of label was observed in the PCC of G0 and G2 cells. These findings suggest that chromosome decondensation, although not controlling the timing of a cell's entry into S phase, is an important step for the initiation of DNA synthesis. These data also suggest that the entry of a S phase may be regulated by cell cycle phase-specific changes in the permeability of the nuclear envelope to the inducers of DNA synthesis present in the cytoplasm.     

Cell cycle regulation of histone H1O in CHO cells: a flow cytofluorimetric study after double staining of the cells

The regulation of histone H1O content throughout the cell cycle of non-synchronized Chinese hamster ovary (CHO) cells has been studied using double fluorescent staining and flow cytofluorometry. In exponentially growing cells, the amount of H1O was found to be proportional to the DNA content of the cells, indicating that the protein is synthesized throughout the cell cycle. However, when cells were arrested in G1 at saturation density the amount of H1O was greater than that found in G1 cells of the exponentially growing population. In contrast, the levels of H1-1 were the same for G1 cells of both populations. These results show that the regulation of H1O accumulation differs from that of other histones.     

Time-dependent changes in H1 content, H1 turnover, DNA elongation, and the survival of cells blocked in early S phase by hydroxyurea, aphidicolin, or 5-fluorodeoxyuridine

Cells were synchronized in G1 by isoleucine deprivation and then released into medium containing 1 mM hydroxyurea (HU), 5 micrograms mL-1 aphidicolin (APC), or 1 microgram mL-1 5-fluorodeoxyuridine (fl5dU). Coulter volume, content of histone H1 per unit DNA, turnover of histone H1, the extent of DNA elongation, and the survival of cells were measured as functions of time after release into the presence of the drugs. At the concentrations used in the experiments, the drug differ in their toxicity (fl5dU greater than HU greater than APC), induction of unbalanced cell growth, and the distribution of new DNA fragment sizes allowed during block, but they all (1) allow cells to enter S phase, (2) cause similar time-dependent losses of histone H1 per unit DNA, which begin as synchronized G1 cells begin to enter S phase, (3) retard DNA elongation beyond replicon size, and (4) retard the turnover of histone H1. The results indicate that loss of histone H1, inhibition of histone turnover, the retarded ligation of newly replicated DNA into bulk chromatin, and chromatin structural changes may be part of the cell's general response to inhibition of DNA replication. Since transient S phase block increases the frequencies of gene amplification [Mariani, B. D., & Schimke, R. T. (1984) J. Biol. Chem. 259, 1901-1910] and sister chromatid exchanges (SCE) [Rainaldi, G., Sessa, M. R., & Mariani, T. (1984) Chromosoma 90, 46-49], the observed changes in H1 content and chromatin organization may also be essential features of gene amplification and SCE.     

Dodecaploid H1 embryonic stem cells abolished pluripotency in L15F10 medium both with and without leukemia inhibitory factor

Two lines of dodecaploid H1 embryonic stem cells, 12H1 and 12H1(?) cells (mouse-originated cells), were established through polyploidization of two hexaploid H1 cells, 6H1 and 6H1(?) cells, which were cultured in L15F10 (7:3) medium with and without leukemia inhibitory factor (LIF), respectively. The G₁, S, and G₂/M phase fractions of 12H1 and 12H1(?) cells were almost the same as those of 6H1 and 6H1(?) cells, respectively, but the doubling time of cell proliferation was prolonged, suggesting that cell death occurred in 12H1 and 12H1(?)cells. The cell volumes of 12H1 and 12H1(?) cells were about double those of 6H1 and 6H1(?) cells, respectively. 12H1 and 12H1(?) cells showed near-negative activity of alkaline phosphatase and no ability to form teratocarcinomas in mouse abdomen, suggesting that 12H1 and 12H1(?) cells lost pluripotency. The DNA contents of 12H1 and 12H1(?) cells decayed in long-term culturing, suggesting that 12H1 and 12H1(?) cells were DNA-unstable. Possible explanations for the lost pluripotency and for the DNA decay in 12H1 and 12H1(?) cells are presented.     

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.     

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.     

Nuclease S1 sensitive sites in parental deoxyribonucleic acid of cold-and temperature-sensitive mammalian cells

Temperature-sensitive mutants of 3T3 cells (H6-15) express the transformed phenotype at 33 degrees C and the normal phenotype at 39 degrees C. Cold-sensitive mutants of Chinese hamster ovary cells (cs4-D3) express the transformed phenotype at 39 degrees C and the normal phenotype, along with a G1 block, at 33 degrees C. When either cell type is under conditions such that it is normal and in a G0 state, the number of S1-sensitive sites in purified DNA, labeled in parental chains only, is zero. When the normal cells are stimulated by 10% serum, the number of S1 sites per 10(5) base pairs increases slightly, to 0.7 in cs4-D3 and 1.1 in H6-15. Under conditions permitting the expression of the transformed phenotype, but not proliferation, the maximum number of S1 sites per 10(5) base pairs is 5 in cs4-D3 and 44 in H6-15. When the stationary transformed cells are stimulated by 10% serum, the number of S1 sites per 10(5) base pairs increases to 6 in cs4-D3 and 43 in H6-15. Furthermore, the DNA from the stimulated transformed H6-15 cells contains at least twice as many S1 sites as the total number of breaks (nicks plus gaps), raising the possibility of the acquisition of stable looped or cruciform structures as the cells are stimulated.     

Cell cycle-dependent expression of phosphorylated histone H2AX: reduced expression in unirradiated but not X-irradiated G1-phase cells

Exposure of cells to ionizing radiation causes phosphorylation of histone H2AX at sites flanking DNA double-strand breaks. Detection of phosphorylated H2AX (gammaH2AX) by antibody binding has been used as a method to identify double-strand breaks. Although generally performed by observing microscopic foci within cells, flow cytometry offers the advantage of measuring changes in gammaH2AX intensity in relation to cell cycle position. The importance of cell cycle position on the levels of endogenous and radiation-induced gammaH2AX was examined in cell lines that varied in DNA content, cell cycle distribution, and kinase activity. Bivariate analysis of gammaH2AX expression relative to DNA content and synchronization by centrifugal elutriation were used to measure cell cycle-specific expression of gammaH2AX. With the exception of xrs5 cells, gammaH2AX level was approximately 3 times lower in unirradiated G(1)-phase cells than S- and G(2)-phase cells, and the slope of the G(1)-phase dose-response curve was 2.8 times larger than the slope for S-phase cells. Cell cycle differences were confirmed using immunoblotting, indicating that reduced antibody accessibility in intact cells was not responsible for the reduced antibody binding in G(1)-phase cells. Early apoptotic cells could be easily identified on flow histograms as a population with 5-10-fold higher levels of gammaH2AX, although high expression was not maintained in apoptotic cells by 24 h. We conclude that expression of gammaH2AX is associated with DNA replication in unirradiated cells and that this reduces the sensitivity for detecting radiation-induced double-strand breaks in S- and G(2)-phase cells.     

Acetylation and deacetylation of histone H4 continue through metaphase with depletion of more-acetylated isoforms and altered site usage

Antibodies specific for acetylated isoforms of histone H4 have been used to compare acetylation of this histone in interphase and metaphase cells. Two rabbit antisera (R5 and R6) were used, each specific for H4 molecules acetylated at one of the four possible acetylation sites, namely Lys-5 (R6) and Lys-12 (R5). Both antisera bound preferentially to the more-acetylated H4 isoforms (H4Ac2-4). To test for continued H4 acetylation in metaphase chromosomes. Chinese hamster ovary cells were blocked in metaphase and treated for one hour with the deacetylase inhibitor sodium butyrate. Isolated chromosomes were assayed for H4 acetylation by antibody labeling and flow cytometry. H4 acetylation was increased several fold by this brief butyrate treatment. The increase was in direct proportion to DNA content, with no evidence for exceptionally high- or low-labeling chromosomes. The results demonstrate that a cycle of H4 acetylation and deacetylation continues within metaphase chromosomes. Immunofluorescence microscopy showed labeling to be distributed throughout the chromosome, but with variable intensity. Western blotting and immunostaining with R5 and R6 showed a net reduction in labeling of H4 from metaphase cells, with major reductions in the more-acetylated isoforms H4Ac3-4. In contrast, labeling of H4Ac1 was reduced to a lesser extent (R6) or increased (R5). This increase indicates more frequent use of the acetylation site at lysine 12 in H4Ac1 from metaphase cells.     

Release of H2O2 and phosphorylation of 30 kilodalton proteins as early responses of cell cycle-dependent inhibition of DNA synthesis by transforming growth factor beta 1.

Transforming growth factor beta 1 (TGF-beta 1) and H2O2 both inhibited DNA synthesis of mouse osteoblastic (MC3T3) cells in the late G1 phase of the cell cycle. TGF-beta 1 stimulated cells to release H2O2 in the late G1 phase, but not in the G0 phase, even though TGF-beta 1 receptors were present in both phases. The inhibition of DNA synthesis caused by TGF-beta 1 was partly decreased by the addition of catalase. TGF-beta 1 and H2O2 increased the phosphorylation of the same proteins with a molecular weight of 30,000 in cells in the late G1 phase, and the increase by TGF-beta 1 was abolished at least partly by catalase. The results suggest that H2O2 is one of the mediators of inhibition of DNA synthesis by TGF-beta 1.     

Changes in H1 content, nucleosome repeat lengths and DNA elongation under conditions of hydroxyurea treatment that reportedly facilitate gene amplification

Depletion of histone H1, changes in nucleosome repeat lengths, and extents of DNA elongation were investigated in synchronized Chinese hamster (line CHO) cells using the general conditions of hydroxyurea treatment that appear to increase the frequency of gene amplification, i.e., synchronized cultures of G1 cells were allowed to begin to enter S phase before treatment with hydroxyurea was effected to retard DNA synthesis (Mariani, B.D. and Schimke, R.T. (1984) J. Biol. Chem. 259, 1901-1910). During the time that synchronized G1 cells begin to enter S phase, there occur considerable synchrony decay and accumulation of new DNA that increase with time before treatment with hydroxyurea is initiated. During exposure to hydroxyurea, there occur depletion of histone H1 and shortened repeat lengths for the DNA synthesized in the presence of hydroxyurea. In contrast, DNA synthesized in S phase before exposure to hydroxyurea has essentially the same repeat lengths as bulk chromatin at both the time that hydroxyurea treatment is effected and after 6 h in its presence. Sedimentation measurements indicate that the early replicating DNA undergoes considerable elongation both before and during 6 h of exposure to 0.3 mM hydroxyurea. Thus, nearly all of the early replicating DNA is elongated to greater than average replicon size under those conditions of hydroxyurea treatment that appear to favor gene amplification. Because the extents of DNA synthesis and cell cycle progression vary as functions of drug concentration, treatment times, and unknown factors (from experiment to experiment), it would appear that the parameters must be carefully monitored in each experiment if biochemical results are to be related to the position of cells in the growth cycle.     

H1 variant synthesis in proliferating and quiescent human cells

The synthesis of histone H1 isoprotein species in human cells of several different types and in several different physiological states was studied. Up to five H1 and two H1 degrees isoprotein species could be resolved by two-dimensional electrophoresis. All five H1 isoprotein species were synthesized in exponentially growing cultures of IMR-90 human fibroblasts; in quiescent IMR-90 cells the synthesis of three H1 isoprotein species was greatly decreased while the synthesis of two others was much less affected. When DNA synthesis in exponentially growing cultures of IMR-90 was inhibited, the pattern of H1 isoprotein synthesis became similar to that found in quiescent cultures. Other human cells, isolated from blood, yielded similar results. These results suggest that the pattern of H1 synthesis is the same for cells in non-S phases of the cell cycle and in quiescent cells. Thus for histone H1 in human cells the relationship of the variant synthesis pattern to the growth state and DNA replication is similar to that of the core histone H3 but not that of H2A.     

Alteration and preservation of cellular characteristics in long-term culture of tetraploid H-1 (ES) cells

To examine the alteration in cellular characteristics of polyploid ES cells during long-term culturing, tetraploid H-1 (ES) cells were continuously cultured for 180 days. Cellular DNA content of the tetraploid cells decreased and reached a plateau of 3.3 C, where C represents the complement of haploid chromosomes. The chromosome number also decreased, indicating that the DNA loss was induced by chromosome loss. Cell volume was maintained, suggesting that the DNA loss did not involve cytoplasmic loss. The cell cycle parameters were almost the same during the DNA decay process, indicating that cell cycle progression was independent of the quantity of homologous chromosomes. Hypotetraploid cells showed alkaline phosphatase activity and formed teratocarcinomas in mouse abdomens, suggesting that the pluripotent potential was maintained. Cellular morphology was also retained, suggesting that the gene expression specifying morphological characteristics was conserved. We conclude that these initial cellular characteristics of tetraploid H1 (ES) cells were preserved in long-term culture, irrespective of chromosome loss.