Early chromosome condensation without cell fusion. I. Preliminary results with allogeneic and xenogeneic cells.

Early chromatin condensation in interphase cells (G1) of human peripheral blood lymphocytes has been induced without virus or cell fusion by exposure to allogeneic or xenogeneic mitotic cells. The event, although similar in some ways to the phenomenon described as "premature chromosome condensation," "chromosome pulverization," and "prophasing," differs in that it does not require the presence of viruses and cell fusion before mitosis proceeds in the G1 cell. Early chromatin condensation in interphase cells induced by mitotic cells only, consists of chromatids in the early or late G1 phase of the cell cycle that are not pulverized or fragmented at mitosis. Some of the chromosomes are twice as long as the metaphase chromosomes and exhibit natural bands. Almost twice as many of these bands are produced as by trypsin treatment of metaphase chromosomes. The nuclear membrane is intact and nucleoli are present, to which some chromosomes are attached. The DNA content of the precocious chromosomes in G1 is half the amount of the metaphase complement.     

Premature chromosome condensation and cell cycle analysis.

The application of the phenomenon of premature chromosome condensation for cell cycle analysis in HeLa and CHO cells has been examined. Random populations of HeLa and CHO cells pulse labelled with H3-TdR were separately fused with mitotic HeLa cells using U.V. inactivated Sendai virus. The resulting prematurely condensed chromosomes (PCC) were scored and classified into G1, S and G2-PCC on the basis of both morphological and autoradiographic data, The results of this study indicated that the G1, S and G2 phase cells are equally susceptible to virus-induced fusion with mitotic cells and subsequent induction into PCC. Hence the PCC method for cell cycle analysis is both practical and accurate. This study also revealed that the process of chromosome decondensation initiated during the telophase of mitosis continues throughout the G1 period reaching an ultimate state of decondensation by the end of G1, at which point the fusion of such cells with those in mitosis yield PCC with the most diffused morphology instead of the discrete single stranded structures characteristic of early G1-PCC. Thus, the decondensation of chromatin during G1 appears to be a prerequisite for the subsequent initiation of DNA synthesis.     

Chromatin structure during the prereplicative phases in the life cycle of mammalian cells

The object of this study was to determine the kinetics of chromosome decondensation during the G1 period of the HeLa cell cycle. HeLa cells synchronized in the G1 period following the reversal of mitotic block were fused with Colcemid-arrested mitotic HeLa cells at 1.5, 3, 5, and 7 h after the reversal of N2O block. The resulting prematurely condensed chromosomes (PCC) were classified into six categories depending on the degree of their condensation. The frequency of occurrence of each category was plotted as a function of time after mitosis. The results of this study indicate that the process of chromosome decondensation, initiated during the telophase of mitosis continues throughout the G1 period without any interruption, thus the chromatin reaches an ultimate state of decondensation by the end of G1 period, when DNA synthesis is initiated.     

Chromosome architecture can dictate site-specific initiation of DNA replication in Xenopus egg extracts

Xenopus egg extracts initiate DNA replication specifically at the dihydrofolate reductase (DHFR) origin locus with intact nuclei from late G1-phase CHO cells as a substrate, but at nonspecific sites when purified DNA is assembled by the extract into an embryonic nuclear structure. Here we show that late G1-phase CHO nuclei can be cycled through an in vitro Xenopus egg mitosis, resulting in the assembly of an embryonic nuclear envelope around G1-phase chromatin. Surprisingly, replication within these chimeric nuclei initiated at a novel specific site in the 5' region of the DHFR structural gene that does not function as an origin in cultured CHO cells. Preferential initiation at this unusual site required topoisomerase II-mediated chromosome condensation during mitosis. Nuclear envelope breakdown and reassembly in the absence of chromosome condensation resulted in nonspecific initiation. Introduction of condensed chromosomes from metaphase- arrested CHO cells directly into Xenopus egg extracts was sufficient to elicit assembly of chimeric nuclei and preferential initiation at this same site. These results demonstrate clearly that chromosome architecture can determine the sites of initiation of replication in Xenopus egg extracts, supporting the hypothesis that patterns of initiation in vertebrate cells are established by higher order features of chromosome structure.     

Measurement of bioreduction rates of cells with distinct responses to ionizing radiation and cisplatin.

A low frequency electron paramagnetic resonance (EPR) spectrometer has been used to measure the bioreduction rate of an exogenously added nitroxide free radical species. Measurements have been made in a well controlled, in vitro system using an X-ray and cisplatin sensitive Chinese hamster ovary (CHO) cell line, xrs-5, and partial revertants which display wild-type levels of sensitivity to X-rays but retain xrs-5 levels of cisplatin sensitivity. The xrs-5 cells reduce this radical species at a rate which is approx. 50% that of the wild-type CHO cell line, K1. The partial revertants maintain this defect in bioreduction despite their decrease in radiosensitivity. However, the bioreduction rate observed in these cells correlates with their sensitivity to the chemotherapeutic drug cisplatin. Low frequency EPR allows measurements and imaging of living tissue and may be of value as a predictive assay of human tumor response to chemotherapy.     

Evidence for the presence of inhibitors of mitotic factors during G1 period in mammalian cells

Our earlier studies indicated that the mitotic factors, which induce germinal vesicle breakdown and chromosome condensation when injected into fully grown Xenopus oocytes, are preferentially associated with metaphase chromosomes and that they bind to chromatin as soon as they are synthesized during the G2 phase. In this study, we attempted to determine the fate of these factors as the cell completes mitosis and enters G1. Extracts from HeLa cells at different points during G1, S, and G2 periods were mixed with mitotic extracts in various proportions, incubated, and then injected into Xenopus oocytes to determine their maturation-promoting activity. The maturation-promoting activity of the mitotic extracts was neutralized by extracts of G1 cells during all stages of G1 but not by those of late S and G2 phase cells. Extracts of quiescent (G0) human diploid fibroblasts exhibited very little inhibitory activity. However, UV irradiation of G0 cells, which is known to cause decondensation of chromatin, significantly enhanced the inhibitory activity of extracts of these cells. These factors are termed inhibitors of mitotic factors (IMF). They seem to be activated, rather than newly synthesized, as the cell enters telophase when chromosomes begin to decondense. The IMF are nondialyzable, nonhistone proteins with a molecular weight of greater than 12,000. Since mitotic factors are known to induce chromosome condensation, it is possible that IMF, which are antagonistic to mitotic factors, may serve the reverse function of the mitotic factors, i.e., regulation of chromosome decondensation.     

Histone hyperacetylation in mitosis prevents sister chromatid separation and produces chromosome segregation defects

Posttranslational modifications of core histones contribute to driving changes in chromatin conformation and compaction. Herein, we investigated the role of histone deacetylation on the mitotic process by inhibiting histone deacetylases shortly before mitosis in human primary fibroblasts. Cells entering mitosis with hyperacetylated histones displayed altered chromatin conformation associated with decreased reactivity to the anti-Ser 10 phospho H3 antibody, increased recruitment of protein phosphatase 1-delta on mitotic chromosomes, and depletion of heterochromatin protein 1 from the centromeric heterochromatin. Inhibition of histone deacetylation before mitosis produced defective chromosome condensation and impaired mitotic progression in living cells, suggesting that improper chromosome condensation may induce mitotic checkpoint activation. In situ hybridization analysis on anaphase cells demonstrated the presence of chromatin bridges, which were caused by persisting cohesion along sister chromatid arms after centromere separation. Thus, the presence of hyperacetylated chromatin during mitosis impairs proper chromosome condensation during the pre-anaphase stages, resulting in poor sister chromatid resolution. Lagging chromosomes consisting of single or paired sisters were also induced by the presence of hyperacetylated histones, indicating that the less constrained centromeric organization associated with heterochromatin protein 1 depletion may promote the attachment of kinetochores to microtubules coming from both poles.     

Response of X-ray-sensitive CHO mutant cells to gamma radiation. I. Effects of low dose rates and the process of repair of potentially lethal damage in G1 phase

X-ray-sensitive CHO mutants (xrs-5 and xrs-6) were exposed to isoleucine-deficient (IL-) medium for 24-36 h to accumulate G1-phase cells. Cells exposed to IL- medium for up to 5 days did not show significant changes in plating efficiency when returned to normal medium. Nearly confluent cultures of IL- -treated cells were irradiated with either 60Co gamma rays (75 cGy/min) or 137Cs gamma rays (2.7, 6.0, or 15.3 cGy/h). A significant reduction (approximately 2.5-fold) in the radiation sensitivity of the parental CHO K-1 cells was observed for chronic low-dose-rate radiation exposure compared to the results obtained for acute high-dose-rate exposure. However, no noticeable differences were observed in the survival curves of either xrs-5 or xrs-6 cells when low-dose-rate and acute exposures were compared. CHO K-1 cells exhibited potentially lethal damage repair while held in IL- medium after gamma irradiation, whereas no repair was observed in either of the radiation-sensitive mutant lines examined at similar survival levels.     

Cell cycle variations in chromatin structure detected by DNase I

We have recently developed a reproducible method for the use of DNase I as a sensitive probe of chromatin structure (Prentice, D A & Gurley, L R, Biochim biophys acta 740 (1983) 134) [12] and have used this probe to investigate chromatin structure during the interphase of the cell cycle. Chinese hamster cells (line CHO) were synchronized by: (1) mitotic detachment, to obtain M-phase cells; (2) isoleucine deprivation, to obtain G1-phase cells; and (3) sequential use of isoleucine deprivation followed by release into the presence of hydroxyurea, to obtain cells blocked at the start of S phase. The cells were released from the various blocking schemes and nuclei were isolated and digested with DNase I at various times. The digestion kinetics were monitored to detect possible changes in chromatin condensation through the cell cycle. The chromatin was much more accessible to DNase I in G1 phase than in S or G2 phase, with only small variations in structure detected in late G1 and very early S phase. From early S phase up to mitosis, the chromatin became increasingly condensed and inaccessible to DNase I action. These results support the concept of a chromatin condensation cycle during interphase as well as during mitosis.     

Mechanism of radiosensitization by halogenated pyrimidines: effect of BrdU on cell killing and interphase chromosome breakage in radiation-sensitive cells

The effect of BrdU incorporation on cell radiosensitivity as well as on the induction of chromosome damage by radiation was studied in plateau-phase xrs-5 cells using the premature chromosome condensation (PCC) method. It is well known that xrs-5 cells are sensitive to ionizing radiation and defective in the repair of radiation-induced DNA double-strand breaks, chromosome damage, and potentially lethal damage (PLD). Compared to repair-proficient CHO 10B cells, a reduction was observed in the overall BrdU-mediated radiosensitization in plateau-phase xrs-5 cells for the same degree of thymidine replacement. This finding is interpreted with a model for BrdU-induced radiosensitization advanced previously, in which two distinct components act to produce the overall radiosensitization observed. One component involves processes associated with the increase in initial damage (DNA and chromosome) production per unit absorbed dose and causes an increase in the slope of the survival curve, while the second component involves enhanced fixation of radiation-induced damage (PLD) and causes a reduction in the width of the shoulder of the survival curve. It is suggested that in plateau-phase xrs-5 cells, the deficiency in the repair of radiation-induced damage compromises BrdU-mediated radiosensitization by leaving active only the radiosensitization component that is associated with an increase in damage induction. Enhancement of cell killing by BrdU in plateau-phase xrs-5 cells resulted in a decrease in D0, the relative value of which was similar to the relative increase in the production of chromosome damage as measured by the PCC method. The relative values for the change in D0 and the production of chromosome aberrations were similar in plateau-phase CHO 10B and xrs-5 cells, suggesting that the physicochemical and/or biochemical processes associated with this phenomenon are the same in the two cell lines. Radiosensitization of a magnitude similar to that observed in exponentially growing CHO 10B cells was induced by BrdU in exponentially growing xrs-5 cells. This effect is attributed to a partial expression of the repair gene (transiently during S phase in all cells, or throughout the cycle in a fraction of cells) that permits some repair of radiation-induced damage and which is compromised by BrdU.     

Changes in the nuclear structure in the radiation-sensitive CHO mutant cell, xrs-5

The structural organization of the cell nucleus was investigated by transmission electron microscopy in the radiosensitive Chinese hamster ovary (CHO) cell mutant, xrs-5 (D0 = 45 cGy), relative to parental K1 cells (D0 = 200 cGy). In 99% of all xrs-5 cells, the outer layer of the nuclear envelope was separated from the inner layer, while 96% of K1 cells had closely apposed layers. This separation of the inner and outer layers of the nuclear envelope in xrs-5 cells was not explained by an increased susceptibility of xrs-5 cells to osmotically induced changes because (1) xrs-5 cells retained the altered nuclear periphery even when several different fixation protocols were used and (2) xrs-5 cells were not more susceptible to cell lysis as measured by trypan blue dye exclusion or by the extracellular presence of lactate dehydrogenase. The difference in the morphological organization in the nuclear periphery of xrs-5 cells correlated with the radiation sensitivity of the cells; xrs-5 cells which spontaneously reverted to a radiation sensitivity similar to that of K1 cells also reverted to a nuclear morphology similar to that of K1 cells. The inner and outer layers of the nuclear envelope were retained in nuclear scaffolds isolated from K1 and xrs-5 cells, indicating that components of the nuclear periphery are part of the nuclear scaffold. These data show that xrs-5 cells have an altered nuclear periphery which correlates with the radiation sensitivity of the cells. The separation of the layers of the nuclear envelope may represent an altered template for repair of DNA damage at the nuclear scaffold and thus may play a role in the defective repair of X-ray-induced DNA double-strand breaks in xrs-5 cells.     

Polycomb group protein-associated chromatin is reproduced in post-mitotic G1 phase and is required for S phase progression

Polycomb group (PcG) proteins form two distinct complexes, PRC1 and PRC2, to regulate developmental target genes by maintaining the epigenetic state in cells. PRC2 methylates histone H3 at lysine 27 (H3K27), and PRC1 then recognizes methyl-H3K27 to form repressive chromatin. However, it remains unknown how PcG proteins maintain stable and plastic chromatin during cell division. Here we report that PcG-associated chromatin is reproduced in the G(1) phase in post-mitotic cells and is required for subsequent S phase progression. In dividing cells, H3K27 trimethylation (H3K27Me(3)) marked mitotic chromosome arms where PRC2 (Suz12 and Ezh2) co-existed, whereas PRC1 (Bmi1 and Pc2) appeared in distinct foci in the pericentromeric regions. As each PRC complex was increasingly assembled from mitosis to G(1) phase, PRC1 formed H3K27Me(3)-based chromatin intensively during middle and late G(1) phase; this chromatin was highly resistant to in situ nuclease treatment. Thus, the transition from mitosis to G(1) phase is crucial for PcG-mediated chromatin inheritance. Knockdown of Suz12 markedly reduced the amount of H3K27Me(3) on mitotic chromosomes, and as a consequence, PRC1 foci were not fully transmitted to post-mitotic daughter cells. S phase progression was markedly delayed in these Suz12-knockdown cells. The fact that PcG-associated chromatin is reproduced during post-mitotic G(1) phase suggests the possibility that PcG proteins enable their target chromatin to be remodeled in response to stimuli in the G(1) phase.     

Premature chromosome condensation. II. The nature of chromosome gaps produced by alkylating agents and ultraviolet light

Chinese hamster ovary (CHO) cells were treated with ultraviolet radiation or the alkylating agents, nitrogen mustard or trenimon, and chromosome damage to G2 phase cells were scored by the premature chromosome condensation (PCC) method or the metotic chromosome method. Treatment with these agents produced gaps but not chromatid breaks or exchanges. After UV treatment, the gap frequency observed in G2-PCC was higher than in the mitotic chromosomes, while the reverse trend was observed after treatment with nitrogen mustard or trenimon. These results suggest that two types of chromosome gaps exist, both of which are observable in mitotic chromosomes while only one type is observable in PCC due to differences in the stages of condensation between PCC and mitotic chromosomes.     

Changes in the organization of chromosomes during the cell cycle: response to ultraviolet light.

Fusion between mitotic and interphase cells results in the premature condensation of the interphase chromosomes into a morphology related to the position in the cell cycle at the time of fusion. These prematurely condensed chromosomes (PCC) have been used in conjunction with u.v. irradiation to examine the interphase chromosome condensation cycle of HeLa cells. The following observations have been made: (I) There is a progressive decondensation of the chromosomes during G1 which is accentuated by u.v. irradiation: (2) The chromosomes become more resistant to u.v.-induced decondensation during G2 and mitosis. (3) There is a close correlation between the degree of chromosome decondensation and the amount of unscheduled DNA synthesis induced by u.v. irradiation during G1 and mitosis: (4) Hydroxyurea enhances the ability of u.v. irradiation to promote the decondensation of chromosomes during G1, G2 and mitosis. Hydroxyurea also potentiates the lethal action of u.v. irradiation during mitosis and G1. These data are discussed in relation to the suggestion that chromosomes undergo a progressive decondensation during G1 and condensation during G2.     

Antibodies specific for mitotic human chromosomes

The induction of premature chromosome condensation in an interphase cell immediately following fusion with a mitotic cell suggests the presence of factors in the mitotic cell that are responsible for the transformation of an interphase nucleus into prematurely condensed chromosomes (PCC). Several lines of evidence suggest that these factors are proteins present in the cytoplasm of mitotic cells. The objective of this study was to raise antibodies to the factors responsible for PCC. Cytosol from synchronized mitotic HeLa cells was injected into rabbits in order to obtain antiserum. The IgG fraction from this antiserum reacted with 98% of mitotic HeLa cells when tested by indirect immunofluorescence. Most of the fluorescence was localized on the chromosomes. About 5% of the interphase nuclei also reacted with the antiserum, but 50% of these cells were in early G1. Antigenic reactivity was induced in the condensing interphase chromatin in 31% of the interphase nuclei found in mitotic-interphase fused cells. Rodent cells did not react with the antibody by indirect immunofluorescence. Mitotic HeLa cells were able to induce antigenic reactivity in 23 % of interphase Chinese hamster ovary (CHO) cell nuclei in fused binucleate cells, whereas the converse was not true of mitotic CHO cells. Enzyme digestion and incubation with denaturing agents suggested that antigenic reactivity depended on a DNA-non-histone protein complex.     

Caffeine overcomes a restriction point associated with DNA replication, but does not accelerate mitosis

Mitotic chromosome condensation is normally dependent on the previous completion of replication. Caffeine spectacularly deranges cell cycle controls after DNA polymerase inhibition or DNA damage; it induces the condensation, in cells that have not completed replication, of fragmented nuclear structures, analogous to the S-phase prematurely condensed chromosomes seen when replicating cells are fused with mitotic cells. Caffeine has been reported to induce S-phase condensation in cells where replication is arrested, by accelerating cell cycle progression as well as by uncoupling it from replication; for, in BHK or CHO hamster cells arrested in early S-phase and given caffeine, condensed chromosomes appear well before the normal time at which mitosis occurs in cells released from arrest. However, we have found that this apparent acceleration depends on the technique of synchrony and cell line employed. In other cells, and in synchronized hamster cells where the cycle has not been subjected to prolonged continual arrest, condensation in replication-arrested cells given caffeine occurs at the same time as normal mitosis in parallel populations where replication is allowed to proceed. This caffeine-induced condensation is therefore "premature" with respect to the chromatin structure of the S-phase nucleus, but not with respect to the timing of the normal cycle. Caffeine in replication-arrested cells thus overcomes the restriction on the formation of mitotic condensing factors that is normally imposed during DNA replication, but does not accelerate the timing of condensation unless cycle controls have previously been disturbed by synchronization procedures.     

Disturbance in function and expression of condensin affects chromosome compaction in HeLa cells

Condensin, a major non-histone protein complex on chromosomes, is responsible for the formation of rod-shaped chromosome in mitosis. A heterodimer composed of SMC2 (structural maintenance of chromosomes) and SMC4 subunits constitutes the core part of condensin. Although extensive studies have been done in yeast, fruit fly and Xenopus to uncover the mechanisms and molecular nature of SMC proteins, little is known about the complex in mammalian cells. We have conducted a series of experiments to unveil the nature of condensin complex in human chromosome formation. The results show that overexpression of the C-terminal domain of SMC subunits disturbs chromosome condensation, leading to formation of swollen chromosomes, while knockdown of SMC subunits severely disturbs mitotic chromosome formation, resulting in chromatin bridges between daughter cells and multiple nuclei in single cells. The salt extraction assay indicates that a fraction of the condensin complex is bound to chromatin in interphase, but most of the condensin bind to chromatin at the onset of mitosis. Thus, disturbance in condensin function or expression affects chromosome condensation and influences mitotic progression.     

The enhancement of histone H4 and H2A serine 1 phosphorylation during mitosis and S-phase is evolutionarily conserved

Histone phosphorylation has long been associated with condensed mitotic chromatin; however, the functional roles of these modifications are not yet understood. Histones H1 and H3 are highly phosphorylated from late G2 through telophase in many organisms, and have been implicated in chromatin condensation and sister chromatid segregation. However, mutational analyses in yeast and biochemical experiments with Xenopus extracts have demonstrated that phosphorylation of H1 and H3 is not essential for such processes. In this study, we investigated additional histone phosphorylation events that may have redundant functions to H1 and H3 phosphorylation during mitosis. We developed an antibody to H4 and H2A that are phosphorylated at their respective serine 1 (S1) residues and found that H4S1/H2AS1 are highly phosphorylated in the mitotic chromatin of worm, fly, and mammals. Mitotic H4/H2A phosphorylation has similar timing and localization as H3 phosphorylation, and closely correlates with the chromatin condensation events during mitosis. We also detected a lower level of H4/H2A phosphorylation in 5-bromo-2-deoxyuridine-positive S-phase cells, which corroborates earlier studies that identified H4S1 phosphorylation on newly synthesized histones during S-phase. The evolutionarily conserved phosphorylation of H4/H2A during the cell cycle suggests that they may have a dual purpose in chromatin condensation during mitosis and histone deposition during S-phase.Electronic Supplementary Material Supplementary material is available in the online version of this article at http://dx.doi.org/10.1007/s00412-004-0281-9Communicated by G. Almouzni     

Monoclonal antibody with specificity to mitotic chromosomes of primates

Fusion of a cell in mitosis with a cell in interphase results in the condensation of chromatin in the interphase nucleus into chromosomes. Premature chromosome condensation is caused by certain proteins, called mitotic factors, that are present in the mitotic cell and are localized on chromosomes. Extracts from mitotic cells were used to immunize mice to produce monoclonal antibodies specific for cells in mitosis. Among the antibodies obtained, the MPM-4 antibody defines a 125-kD polypeptide antigen located on mitotic chromosomes by indirect immunofluorescence. Although the polypeptide antigen is present in approximately equal concentrations in extracts of interphase cells and mitotic cells, as revealed by immunoblots, it cannot be detected cytologically in the former. Cell fractionation experiments showed that the 125-kD antigen is found in the cytoplasm of interphase cells and metaphase cells, but is concentrated in fractions containing metaphase chromosomes, although not detectable in interphase nuclei. Even though the antigen is apparently primate-specific, it binds to mitotic chromosomes and prematurely condensed chromosomes in human-rodent cell hybrids without regard to the species of origin of the mitotic inducer. The presence of the antigen in the cytoplasm of interphase cells and the chromosomes of mitotic cells suggests a relationship between the presence of the antigen on chromosomes and the process of chromosome condensation and decondensation.