Cell cycle progression after cleavage failure: mammalian somatic cells do not possess a "tetraploidy checkpoint"

Failure of cells to cleave at the end of mitosis is dangerous to the organism because it immediately produces tetraploidy and centrosome amplification, which is thought to produce genetic imbalances. Using normal human and rat cells, we reexamined the basis for the attractive and increasingly accepted proposal that normal mammalian cells have a "tetraploidy checkpoint" that arrests binucleate cells in G1, thereby preventing their propagation. Using 10 microM cytochalasin to block cleavage, we confirm that most binucleate cells arrest in G1. However, when we use lower concentrations of cytochalasin, we find that binucleate cells undergo DNA synthesis and later proceed through mitosis in >80% of the cases for the hTERT-RPE1 human cell line, primary human fibroblasts, and the REF52 cell line. These observations provide a functional demonstration that the tetraploidy checkpoint does not exist in normal mammalian somatic cells.     

Mammalian cell fusion. VI. Regulation of mitosis in binucleate HeLa cells.

In two different cell fusion experiments a synchronized population of HeLa cells, prelabeled with ³H-TdR, was fused with an unlabeled one using inactivated Sendai virus. In the first experiment, HeLa cells in early G2 phase which were exposed to either 4 °C, cycloheximide, actinomycin D or X-irradiation were fused separately with untreated and more advanced G2 cells. A comparison of the rates of mitotic accumulation (in the presence of Colcemid) for the various classes of mono- and binucleate cells revealed that the hybrid (binucleate) cells were intermediate between those of the advanced and the retarded parental types indicating that the chromosome condensing factors of the advanced component were diluted as a result of such fusion. The manner in which the retarding effects of actinomycin D and cycloheximide were reversed in the hybrid cells suggested that proteins had a major role as chromosome condensing factors in the G2 mitotic transition. In the second experiment, when S phase HeLa cells were fused with those in G2, the resulting heterophasic (S/G2) binucleate cells reached mitosis at about the same time as the homophasic (S/S) cells of the lagging parent indicating a complete dominance of the S over the G2 with regard to their progress towards mitosis. However, the addition of Mg²⁺ (2 × 10^?2 M of MgCl₂) to the medium helped the G2 nuclei to enter mitosis asynchronously, which consequently induced premature chromosome condensation (PCC) in the S phase component. These data suggested that in the heterophasic (S/G2) binucleate cells the S phase component caused decondensation of the G2 chromatin thus blocking it from entering into mitosis. This effect which did not appear to be dose-dependent could be neutralized and the G2 nuclei relieved from this repression by an external supply of Mg²⁺ ions.     

Polyploidization in rat liver: the role of binucleate cells.

Liver cells were isolated from rats undergoing active formation of tetraploid cells and prelabelled in their DNA with 14C thymidine. Autoradiography of the isolated cells showed that binucleate diploid cells, a major component of the parenchymal cell population at this time, are also active in DNA synthesis. These cells probably pass through mitosis and generate mononucleate tetraploid cells, the dominant cell type of mature rat liver, since the frequency of binucleate tetraploid cells is very low at this stage in rat liver development. The biological significance of liver polyploidy is discussed and it is suggested that this lies in enhanced resistance to mutagenesis.     

Human hepatocyte polyploidization kinetics in the course of life cycle

The processes of polyploidization in normal human liver parenchyma from 155 individuals aged between 1 day and 92 years were investigated by Feulgen-DNA cytophotometry. It was shown that polyploid hepatocytes appear in individuals from 1 to 5 years old. Up to the age of 50 years the accumulation rate of binucleate and polyploid cells is very slow, but subsequently hepatocyte polyploidization is intensified, and in patients aged 86–92 years the relative number of cells with polyploid nuclei is about 27%. Only a few hepatocytes in the normal human liver reach 16C and 8C×2 ploidy levels for mononucleate and binucleate cells respectively. Using a mathematical modeling method, it was shown that during postnatal liver growth the polyploidization process in human liver is similar to that in the rat, and that polyploid cells are formed mainly from binucleate cells. As in rats, prior to an increase in ploidy level, diploid human hepatocytes can pass several times through the usual mitotic cycles maintaining their initial ploidy level. After birth, only one in ten hepatocytes starting DNA synthesis enters the polyploidization process. At maturity about 60% of 2C-hepatocytes starting DNA synthesis divide by conventional mitosis, the rest dividing by acytokinetic mitosis leading to the formation of binucleate cells. During ageing the probability of hepatocyte polyploidization increases and in this period there are two polyploid or binucleate cells for every diploid dividing by conventional mitosis.     

Cell cycle duration and time of DNA synthesis in binucleate cells induced inV. faba meristems by caffeine or isobutyl-methylxanthine

Summary Lateral roots ofVicia faba were treated with a solution of 5-aminouracil (3.93×10^–3M) for 6 hours. After 15 hours roots were recovering from the temporary inhibition of mitosis induced by 5-AU and were approaching peak mitotic indices; they were then treated with 0.1% caffeine or 0.1% isobutylmethylxanthine (IBMX) for 1 hour. Treatment with methylxanthines when the mitotic index was high gave relatively high yields of binucleate cells, 3.8 to 7.5%. DNA synthesis, cell cycle duration and nuclear growth were determined for binucleate cells. Caffeine induced binucleate cells underwent a marked reduction in nuclear volume, from 1,074 m³ at 1+1 hours to 534 m³ at 1+14 hours. Only 15% of these binucleates entered S phase; those that did so were in mitosis or had divided by 1+14 hours. We conclude that 85% of the binucleate cells are so inhibited by caffeine that their G₁ is extended to>14 hours or that they are no longer proliferating cells. IBMX-induced binucleate cells, by contrast, did enter S phase and many of them also divided. Though in IBMX-induced binucleate cells there was also a decrease in nuclear volume up to 1+10 hours, subsequently mean nuclear volume increased e.g. at 1+16 and 1+18 hours. Both caffeine and IBMX treatments resulted in decreases in mean volume of prophase nuclei of mononucleate cells; this is further evidence that both methylxanthines inhibit the macromolecular synthesis required to sustain nuclear growth. It also suggests that nuclear division can be initiated at considerably lower nuclear volumes than those of untreated cells. We suggest that caffeine may act as a mimic of the normal mechanism that regulates the switch from a proliferating to a non-proliferative condition.     

Origin of mono- and binucleate cells with heterochromatic chromosomes in the malpighian tubules of the european elm scale,Gossyparia spuria (Coccoidea: Homoptera)

Males of the European elm scale, Gossyparia spuria (Erioccoccidae) have two Malphigian tubules, each made up of mononucleate and binucleate cells. Both types of cells may contain heterochromatic (H) chromosomes which form an H body. The cells with H bodies (H cells) usually appeared singly anywhere along the tubule. However, when two or more H cells were present they tended to be closer to each other than would be expected by chance. The possible origin of this tendency is discussed. Following squashing, the nuclei of the binucleate cells were much larger than those of most other somatic cells, suggesting that they were highly endopolyploid. However, the H bodies of the cells of the tubules were of about the same size as those of the other cells. These observations suggested that the H chromosomes of the binucleate cells did not replicate while the euchromatic chromosomes of these cells replicated several times. The great majority of the nuclei of the H cells contained a single H body per nucleus. An analysis of the number of H bodies in binucleate cells indicated that when two H bodies were present in the same nucleus they usually did not fuse. Thus, they were believed also not to fuse in the mononucleate cells. Since almost all the mononucleate H cells had only a single H body (rather than 2) it was concluded that they did not originate from binucleate cells by nuclear fusion.     

Chromosome nondisjunction and instabilities in tapetal cells are affected by B chromosomes in maize

Abnormal mitosis occurs in maize tapetum, producing binucleate cells that later disintegrate, following a pattern of programmed cell death. FISH allowed us to observe chromosome nondisjunction and micronucleus formation in binucleate cells, using DNA probes specific to B chromosomes (B's), knobbed chromosomes, and the chromosome 6 (NOR) of maize. All chromosome types seem to be involved in micronucleus formation, but the B's form more micronuclei than do knobbed chromosomes and knobbed chromosomes form more than do chromosomes without knobs. Micronuclei were more frequent in 1B plants and in a genotype selected for low B transmission rate. Nondisjunction was observed in all types of FISH-labeled chromosomes. In addition, unlabeled bridges and delayed chromatids were observed in the last telophase before binucleate cell formation, suggesting that nondisjunction might occur in all chromosomes of the maize complement. B nondisjunction is known to occur in the second pollen mitosis and in the endosperm, but it was not previously reported in other tissues. This is also a new report of nondisjunction of chromosomes of the normal set (A's) in tapetal cells. Our results support the conclusion that nondisjunction and micronucleus formation are regular events in the process of the tapetal cell death program, but B's strongly increase A chromosome instability.     

Variable pathways for developmental changes of mitosis and cytokinesis in Physarum polycephalum

The development of a uninucleate ameba into a multinucleate, syncytial plasmodium in myxomycetes involves a change from the open, astral mitosis of the ameba to the intranuclear, anastral mitosis of the plasmodium, and the omission of cytokinesis from the cell cycle. We describe immunofluorescence microscopic studies of the amebal-plasmodial transition (APT) in Physarum polycephalum. We demonstrate that the reorganization of mitotic spindles commences in uninucleate cells after commitment to plasmodium formation, is completed by the binucleate stage, and occurs via different routes in individual developing cells. Most uninucleate developing cells formed mitotic spindles characteristic either of amebae or of plasmodia. However, chimeric mitotic figures exhibiting features of both amebal and plasmodial mitoses, and a novel star microtubular array were also observed. The loss of the ameba-specific alpha 3-tubulin and the accumulation of the plasmodium-specific beta 2-tubulin isotypes during development were not sufficient to explain the changes in the organization of mitotic spindles. The majority of uninucleate developing cells undergoing astral mitoses (amebal and chimeric) exhibited cytokinetic furrows, whereas cells with the anastral plasmodial mitosis exhibited no furrows. Thus, the transition from astral to anastral mitosis during the APT could be sufficient for the omission of cytokinesis from the cell cycle. However, astral mitosis may not ensure cytokinesis: some cells undergoing amebal or chimeric mitosis contained unilateral cytokinetic furrows or no furrow at all. These cells would, most probably, fail to divide. We suggest that a uninucleate committed cell undergoing amebal or chimeric mitosis can either divide or else form a binucleate cell. In contrast, a uninucleate cell with a mitotic spindle of the plasmodial type gives rise only to a binucleate cells. Further, the decision to enter mitosis after commitment to the APT is independent of the developmental changes in the organization of the mitotic spindle and cytokinesis.     

Light and electron microscopic radioautographic studies on macromolecular synthesis in amitotic hepatocytes of aging mice.

The problem on cell divisions whether cells proliferate by mitosis or amitosis has been the heated controversy among many biologists since the late 19th century. We confirmed by extensive experiments since the mid 20th century that all the cells proliferated by mitosis not by amitosis but that amitosis actually existed in some glandular cells such as hepatocytes or pancreatic acinar cells which showed only amitotic nuclear divisions without cytoplasmic division producing binucleate cells in several kinds of experimental animals. We further verified that such amitotic cells did not synthesize macromolecular compounds incorporating macromolecular precursors such as 3H-thymidine for DNA, 3H-uridine for RNA or 3H-leucine for proteins. Recent experiments at the end of 20th century using many groups of aging mice, from fetal day 19 to postnatal month 24, injected with such precursors, amitotic cells and resulting binucleate cells in the hepatocytes were detected by electron microscopic radioautography and compared to mononucleate cells. The results demonstrated that only a few hepatocytes showing amitotic nuclear division were found labelled with the 3 precursors demonstrating DNA, RNA and protein synthesis. However, the numbers of silver grains showing incorporations of labelled precursors in respective amitotic cells were very few. It was clarified that the amitotic cells did not synthesize such macromolecules as mononucleate hepatocytes did. On the other hand, more binucleate cells were found than the amitotic cells. DNA synthesis of mononucleate and binucleate hepatocyte nuclei was observed at perinatal stage and disappeared at adult stage. The labeling index of mononucleate hepatocytes was greater than that of binucleate hepatocytes. RNA and protein syntheses in karyoplasm and cytoplasm in both mononucleate and binucleate cells increased from perinatal stage, reaching the maxima at adult stage then decreased to senescent stage. Grain counts revealed that synthesized RNA and proteins were more in binucleate cells than mononucleate cells at respective aging stages.     

Arrangement of spindle apparatus in mitoses of different ploidy

In non-hypotonically treated mitoses from tissue cultures of Microtus agrestis, both the constitutive heterochromatin of the sex chromosomes and the spindle apparatus were stained by the Giemsa C-banding technique. By means of counting the heterochromatic chromosomes, we determined the cell ploidy and studied the number of centrioles and the spindle arrangement of diploid, triploid, tetraploid and octoploid mitoses. Diploid and triploid prophases contained 2 centrioles in most cases, tetraploid prophases 4, binucleate cells with 2 diploid nuclei likewise 4 and binucleate cells with 2 tetraploid nuclei 8 centrioles. Nearly 99% of diploid and triploid metaphases were bipolar. Of the tetraploid metaphases only 45% were bipolar, 29.5% tripolar, 7.5% quadripolar and 18% formed as a parallel mitosis. In all examined binucleate cells that had had an asynchronous DNA synthesis, a multipolar mitosis was found.     

Membrane dynamics during migration of placental cells through trophectodermal tight junctions in sheep and goats

Binucleate cells in ruminant trophectodermal epithelium are unique in that they form part of the tight junction as they migrate across it, maintaining the ionic barrier seal to the internal milieu of the fetus. Such participation imposes considerable constraints on the cell migration because membrane cannot flow through a tight junction. We report quantitative ultrastructural immunocytochemical evidence for vesicle membrane insertion into the binucleate cell plasmalemma which allows the cells to form a pseudopodium past the tight junction. This pseudopodium increases continuously in area by vesicle insertion and develops a close apposition to the plasmalemma of the fetomaternal syncytium which constitutes the fetomaternal boundary in the placenta of the sheep and goat. Enventually the apposed membranes of the binucleate cell pseudopodium and the syncytium fuse by vesiculation and the cytoplasm and nuclei of the binucleate cell merge into the fetomaternal syncytium. The binucleate cell plasmalemma remaining on the trophectodermal side of the tight junction is blebbed off into, and phagocytosed by, the uninucleate trophectodermal cells between which the binucleate cell passed. This process permits the delivery of the binucleate cell granules to the maternal side of the placenta but none of the fetal molecules expressed on the plasma membrane of the binucleate cells are exposed to potential maternal immunological rejection.     

On the triggering of mitosis and the division cycle of polynucleate cells

In binucleate 2n-2n and 4n-4n, trinucleate 2n-4n-2n and tetra nucleate cells 2n-2n-2n-2n which had been experimentally induced by means of caffeine (0.1% in tap water) in root-tip cells of onion bulbs (Allium cepa) division cycle time increases sligthly (about 15%) when the DNA content increases from 2n to 8n chromosomes per cell. The interphase time is not significantly modified, whereas the mitosis time increases (about 50%) in the tetranucleate cells in relation to the diploid mononucleate cells.The unsynchronized initiation of prophase and the subsequent synchronization of the nuclei in the polynucleate cells suggest an inhibiting mechanism regulating initiation of the mitosis via cytoplasm.     

Growth and development in relation to the cell cycle inPhysarum polycephalum

Summary In strain CL ofPhysarum polycephalum, multinucleate, haploid plasmodia form within clones of uninucleate, haploid amoebae. Analysis of plasmodium development, using time-lapse cinematography, shows that binucleate cells arise from uninucleate cells, by mitosis without cytokinesis. Either one or both daughter cells, from an apparently normal amoebal division, can enter an extended cell cycle (28.7 hours compared to the 11.8 hours for vegetative amoebae) that ends in the formation of a binucleate cell. This long cycle is accompanied by extra growth; cells that become binucleate are twice as big as amoebae at the time of mitosis. Nuclear size also increases during the extended cell cycle: flow cytometric analysis indicates that this is not associated with an increase over the haploid DNA content. During the extended cell cycle uninucleate cells lose the ability to transform into flagellated cells and also become irreversibly committed to plasmodium development. It is shown that commitment occurs a maximum of 13.5 hours before binucleate cell formation and that loss of ability to flagellate precedes commitment by 3–5 hours. Plasmodia develop from binucleate cells by cell fusions and synchronous mitoses without cytokinesis.Abbreviations CL Colonia Leicester - DSDM Dilute semi-defined medium - FKB Formalin killed bacterial suspension - IMT Intermitotic time - LIA Liver infusion agar - SBS Standard bacterial suspension - SDM Semi-defined medium     

Cell division in caffeine-induced binucleate protonemal cells ofAdiantum. II. Formation of the preprophase band and cell division in centrifuged and non-centrifuged cells

Organization of microtubules (MTs) in relation to the behavior of nuclei was examined in dividing binucleate cells ofAdiantum capillus-veneris L. To induce binucleate cells, caffeine, an inhibitor of formation of the cell plate, was applied at 4 mM to synchronously dividing protonemal cells during cytokinesis (Murata and Wada 1993). Formation of the preprophase band (PPB) during the next cell cycle was examined in non-centrifuged and centrifuged cells. The two nuclei were separated or associated with one another in both non-centrifuged and centrifuged cells, although the location of the nuclei in the cylindrical protonemal cells was different (Murata and Wada 1993). Irrespective of centrifugation, a single PPB was formed around the nuclei in cells with associated nuclei. Two PPBs were formed in cells with separated nuclei in centrifuged cells. Patterns of mitosis and cytokinesis varied, depending on the location of the PPB and the distribution of the nuclei. The role of the nucleus in formation of the PPB is discussed.     

The DNA damage checkpoint signal in budding yeast is nuclear limited

The nature of the DNA damage-induced checkpoint signal that causes the arrest of cells prior to mitosis is unknown. To determine if this signal is transmitted through the cytoplasm or is confined to the nucleus, we created binucleate heterokaryon yeast cells in which one nucleus suffered an unrepairable double-strand break, and the second nucleus was undamaged. In most of these binucleate cells, the damaged nucleus arrested prior to spindle elongation, while the undamaged nucleus completed mitosis, even when the strength of the damage signal was increased. The arrest of the damaged nucleus was dependent upon the function of the RAD9 checkpoint gene. Thus, the DNA damage checkpoint causing G2/M arrest is regulated by a signal that is nuclear limited.     

Differential behaviour of sister nuclei in methylxanthine-induced binucleate cells

Binucleate cells were induced by treatment with methylxanthines. Nuclear volume increased rapidly in the early part of G1 but the increases were unequal in most pairs of sister nuclei. Treatment with 5-amino-uracil results in increases in nuclear volume; when cells with large nuclei divided they were induced to become binucleate. The sister nuclei of these binucleate cells also showed increases in mean volume and in the mean difference between their volumes. Even though they share the same cytoplasm, sister nuclei behave autonomously in terms of changes in volume.     

The positional control of mitosis and cytokinesis in higher-plant cells

The present work establishes a correlation between cell length and patterns of mitotic microtubular assemblies in Allium cepa L. root meristems. Binucleate cells were formed by a short caffeine treatment which aborted the formation of the phragmoplast during telophase. The largest binucleate cells (about 50 μm in length) behaved as two contiguous mononucleate cells in their next mitosis: they developed two preprophase bands (PPBs), one around each nucleus, where two spindles and two phragmoplasts were subsequently formed. On the other hand, the shortest binucleate cells (about 36 μm in length) formed a single PPB at the site of the aborted phragmoplast and, in the medium-sized cells (about 44 μm) in which the single PPB formed around the nucleus possessing the largest cytoplasmic environment, the two mitotic spindles and the new phragmoplasts moved to, or were assembled in the position of the phragmoplast that had been aborted one cycle earlier. Some rules derive from these observations. First of all, the aborted phragmoplast left a signal for microtubule positioning which was still operative one cycle later, in two-thirds of the bimitoses. Also, that formation of the PPB is dispensable. Moreover, its development does not always predict the future division plane, because of the presence of competing old signals which are stronger than those shed by the PPB in the same mitosis, but which fade away with distance. Finally, the positional signals were reinforced when the ratio of monomeric to fibrillar actin was increased by cytochalasin D during their shedding. When this drug was given simultaneously with caffeine, the frequency of bimitoses which, one cycle later, developed spindles and phragmoplasts in the positions of the old phragmoplast increased. On the other hand, those frequencies dropped in relation to control when the cytochalasin D treatment took place during bimitosis, indicating that at this time the treatment reinforced the signals produced in bimitosis itself. Received: 3 February 1997 / Accepted: 4 June 1997     

The mode of nuclear DNA synthesis in experimentally induced binucleate cells of root meristems

The synthesis of DNA does not proceed in a perfectly synchronous way in about 20% of the binucleate cells induced in Allium sativum L. root meristems by treatment with methyl 3 hydroxy 6 (1 H, 3 H) quinazoline dione, 2.4 (an inhibitor of cytokinesis). — Nuclear labelling after tritiated thymidine incorporation and the measurement of nuclear DNA by cytophotometry both establish that the beginning of the S phase as well as its duration may be different in the two nuclei included in a single cytoplasm. Yet the nuclear synchronism progressively asserts itself as the cell cycle goes on and, following this asynchronous synthesis, the beginning of mitosis is synchronous. The restoration of such a coordination points to the existence in the cytoplasm of separable factors inducing DNA synthesis and mitosis.     

Cellular events during sexual development from amoeba to plasmodium in the slime mould Physarum polycephalum

Time-lapse cinematography and immunofluorescence microscopy were used to study cellular events during amoebal fusions and sexual plasmodium development in Physarum polycephalum. Amoebal fusions occurred frequently in mixtures of strains heteroallelic or homoallelic for the mating-type locus matA, but plasmodia developed only in the matA-heteroallelic cultures. These observations confirmed that matA controls development of fusion cells rather than cell fusion. Analysis of cell pedigrees showed that, in both types of culture, amoebae fused at any stage of the cell cycle except mitosis. In matA-heteroallelic fusion cells, nuclear fusion occurred in interphase about 2 h after cell fusion; interphase nuclear fusion did not occur in matA-homoallelic fusion cells. The diploid zygote, formed by nuclear fusion in matA-heteroallelic fusion cells, entered an extended period of cell growth which ended in the formation of a binucleate plasmodium by mitosis without cytokinesis. In contrast, no extension to the cell cycle was observed in matA-homoallelic fusion cells and mitosis was always accompanied by cytokinesis. In matA-homoallelic cultures, many of the binucleate fusion cells split apart without mitosis, regenerating pairs of uninucleate amoebae; in the remaining fusion cells, the nuclei entered mitosis synchronously and spindle fusion sometimes occurred, giving rise to a variety of products. Immunofluorescence microscopy showed that matA-heteroallelic fusion cells possessed two amoebal microtubule organizing centres, and that most zygotes possessed only one; amoebal microtubule organization was lost gradually over several cell cycles. In matA-homoallelic cultures, all the cells retained amoebal microtubule organization.     

Cell Displacement Through the Columella of the Root Cap of Zea mays L

Exposing roots of Zea mays to a solution of caffeine for 1 hinduces a small population of binucleate cells in the meristem.The progress of the binucleate cell population was then followed,in time, as it was displaced along the length of the cap columella.Since this method of marking cells seems to have no effect onthe subsequent pattern of cell proliferation in the cap meristem,the movement of the binucleate cells through the cap is inferredto be similar to the movement of cells in an undisturbed cap.The binculeate cells that persist in the cap are believed tobe cells that were engaged in their final mitosis at the timeof the caffeine treatment, so the time that it takes for themto appear at the edge of the cap is a measure of the periodfor which a cell is contained in the non–dividing portionof the tissue before being lost from the cap surface. In rootsof Zea grown at 22 °C cells take about 7 days to reach thetip of the cap columella and about 2 to 3 days to reach theflanks of the cap following their displacement from the capmeristem. Zea mays, root cap, cell displacement, binucleate cells