A role for cyclin D3 in the endomitotic cell cycle.

Platelets, essential for thrombosis and hemostasis, develop from polyploid megakaryocytes which undergo endomitosis. During this cell cycle, cells experience abrogated mitosis and reenter a phase of DNA synthesis, thus leading to endomitosis. In the search for regulators of the endomitotic cell cycle, we have identified cyclin D3 as an important regulatory factor. Of the D-type cyclins, cyclin D3 is present at high levels in megakaryocytes undergoing endomitosis and is markedly upregulated following exposure to the proliferation-, maturation-, and ploidy-promoting factor, Mpl ligand. Transgenic mice in which cyclin D3 is overexpressed in the platelet lineage display a striking increase in endomitosis, similar to changes seen following Mpl ligand administration to normal mice. Electron microscopy analysis revealed that unlike such treated mice, however, D3 transgenic mice show a poor development of demarcation membranes, from which platelets are believed to fragment, and no increase in platelets. Thus, while our model supports a key role for cyclin D3 in the endomitotic cell cycle, it also points to the unique role of Mpl ligand in priming megakaryocytes towards platelet fragmentation. The role of cyclin D3 in promoting endomitosis in other lineages programmed to abrogate mitosis will need further exploration.     

Endomitosis: A reappraisal

Summary The concept and role of endomitosis is reevaluated in the light of observations on three organisms. Endomitosis which morphologically agrees with Geitler's (1939) classical definition is compared in tapetal cells of the liliaceous plant Eremurus, in the septal cells of the testicular follicles of the grasshopper Melanoplus, and in human cells from normal and molar trophoblasts and cervical cancer. These observations, together with those of Kidnadze and Istomina (1980), show that functionally at least two fundamentally different types of endomitosis exist, although morphologically the stages resemble each other in the three organisms. In the first type, exemplified by Eremurus, each endomitosis leads to a chromosome constitution which represents one level higher ploidy, a course that has been assumed to be characteristic of endomitosis in general. The second type, observed in its most characteristic form in the grasshopper, seems to be stationary: no DNA synthesis occurs, but an intensive RNA synthesis takes place. Presumably such cells have reached a final state in their development and are specialized in manufacturing one or more gene products. Endomitosis in normal placenta comes near this type, although DNA synthesis takes place in occasional cells. However, similar endomitotic nuclei in the hydatiform moles are in the process of DNA synthesis. When endomitosis is analyzed in different organisms and tissues, the observation that this process is not one entity should be kept in mind.     

Mitotic catastrophe and endomitosis in tumour cells: an evolutionary key to a molecular solution

Following genotoxic insult, p53 mutated tumour cells undergo mitotic catastrophe. This is characterised by a switch from mitosis to the endocycle. The essential difference between mitosis and the endocycle is that in the latter, DNA synthesis is uncoupled from cell division, which leads to the formation of endopolyploid cells. Recent data suggests that a return from the endocycle into mitosis is also possible. Furthermore, our observations indicate that a particular type of endocycle known as endomitosis may be involved in this return. Here we review the role of endomitosis in the somatic reduction of polyploidy during development and its postulated role in the evolution of meiosis. Finally, we incorporate these evolutionary data to help interpret our most recent observations in the tumour cell system, which indicate a role for endomitosis and meiotic regulators, in particular p39mos in the segregation of genomes (somatic reduction) of these endopolyploid cells.     

ENDOMITOSIS IN TAPETAL CELLS OF EREMURUS (LILIACEAE)

True endomitosis in the anther tapetum of the liliaceous plant Eremurus is described. The nuclear membrane does not disappear, but during metaphase the chromosomes are condensed, often considerably more than in normal mitosis. When the pollen mother cells (PMCs) go through the last premeiotic mitosis, the tapetal cells have one diploid nucleus which divides while the cell remains undivided. The two diploid nuclei may undergo an endomitosis and the resulting tetraploid nuclei a second endomitosis. An alternative pathway is an ordinary mitosis—again without cell division—instead of one of the endomitotic cycles. The cytological picture in the tapetum is further complicated by restitution in anaphase and fusion of metaphase and anaphase groups during mitosis, processes which could give rise to cells with one, two, or three nuclei, instead of the expected two or four. No sign of the so-called “inhibited” mitosis is seen in these tapetal cells. When the PMCs are in leptotene-zygotene, very few tapetal nuclei are in endomitosis. When the PMCs have reached diplotene, almost 100% of cells which are not in interphase show an endomitotic stage.     

Presence of a defect in karyokinesis during megakaryocyte endomitosis

Megakaryocyte is the naturally polyploid cell that gives rise to platelets. Polyploidization occurs by endomitosis, a process corresponding to a late failure of cytokinesis with a backward movement of the daughter cells. Generally, a pure defect in cytokinesis produces a multinucleated cell, but megakaryocytes are characterized by a single polylobulated nucleus with a 2^N ploidy. Here, we show the existence of a defect in karyokinesis during the endomitotic process. From late telophase until the reversal of cytokinesis, some dipolar mitosis/endomitosis and most multipolar endomitosis present a thin DNA link between the segregated chromosomes surrounded by an incomplete nuclear membrane formation, which implies that sister chromatid separation is not complete. This observation may explain why polyploid megakaryocytes display a single polylobulated nucleus along with an increase in ploidy.     

Novel alterations in CDK1/cyclin B1 kinase complex formation occur during the acquisition of a polyploid DNA content.

The pathways that regulate the S-phase events associated with the control of DNA replication are poorly understood. The bone marrow megakaryocytes are unique in that they leave the diploid (2C) state to differentiate, synthesizing 4 to 64 times the normal DNA content within a single nucleus, a process known as endomitosis. Human erythroleukemia (HEL) cells model this process, becoming polyploid during phorbol diester-induced megakaryocyte differentiation. The mitotic arrest occurring in these polyploid cells involves novel alterations in the cdk1/cyclin B1 complex: a marked reduction in cdk1 protein levels, and an elevated and sustained expression of cyclin B1. Endomitotic cells thus lack cdk1/cyclin B1-associated H1-histone kinase activity. Constitutive over-expression of cdk1 in endomitotic cells failed to re-initiate normal mitotic events even though cdk1 was present in a 10-fold excess. This was due to an inability of cyclin-B1 to physically associate with cdk1. Nonetheless, endomitotic cyclin B1 possesses immunoprecipitable H1-histone kinase activity, and specifically translocates to the nucleus. We conclude that mitosis is abrogated during endomitosis due to the absence of cdk1 and the failure to form M-phase promoting factor, resulting in a disassociation of mitosis from the completion of S-phase. Further studies on cyclin and its interacting proteins should be informative in understanding endomitosis and cell cycle control.     

Roles of GIG1 and UVI4 in genome duplication in Arabidopsis thaliana

Endomitosis and endoreplication are atypical modes of cell cycle that results in genome duplication in single nucleus. Because the cell size of given cell type is generally proportional to the nuclear DNA content, endoreplication and endomitosis are effective strategy of cell growth, which are widespread in multicellular organisms, especially those in plant kingdom. We found that these processes might be differently regulated by GIGAS CELL1 (GIG1) and its paralog UV-INSENSITIVE4 (UVI4) in Arabidopsis thaliana. GIG1 and UVI4 may negatively regulate activities of anaphase-promoting complex or cyclosome (APC/C) ubiquitin ligase that acts as an important mitotic regulator. The gig1 mutation induced ectopic occurrence of endomitosis during somatic cell division, while it has been reported that uvi4 mutation resulted in premature occurrence of endoreplication during organ development. Overexpression of GIG1 and UVI4 dramatically increased the amount of mitotic cyclin, CYCB1;1, a well-known substrate of APC/C. Ectopic endomitosis in gig1 was enhanced by mutation in CYCB2;2 and suppressed by downregulation of APC10 encoding a core subunit of APC/C. Overexpression of CDC20.1, an activator protein of APC/C, further promoted the ectopic endomitosis in gig1. These findings suggest that endomitosis and endoreplication are regulated by similar molecular mechanisms, in which two related proteins, GIG1 and UVI4, may inhibit APC/C in different ways.     

GIGAS CELL1, a novel negative regulator of the anaphase-promoting complex/cyclosome, is required for proper mitotic progression and cell fate determination in Arabidopsis

Increased cellular ploidy is widespread during developmental processes of multicellular organisms, especially in plants. Elevated ploidy levels are typically achieved either by endoreplication or endomitosis, which are often regarded as modified cell cycles that lack an M phase either entirely or partially. We identified GIGAS CELL1 (GIG1)/OMISSION OF SECOND DIVISION1 (OSD1) and established that mutation of this gene triggered ectopic endomitosis. On the other hand, it has been reported that a paralog of GIG1/OSD1, UV-INSENSITIVE4 (UVI4), negatively regulates endoreplication onset in Arabidopsis thaliana. We showed that GIG1/OSD1 and UVI4 encode novel plant-specific inhibitors of the anaphase-promoting complex/cyclosome (APC/C) ubiquitin ligase. These proteins physically interact with APC/C activators, CDC20/FZY and CDH1/FZR, in yeast two-hybrid assays. Overexpression of CDC20.1 and CCS52B/FZR3 differentially promoted ectopic endomitosis in gig1/osd1 and premature occurrence of endoreplication in uvi4. Our data suggest that GIG1/OSD1 and UVI4 may prevent an unscheduled increase in cellular ploidy by preferentially inhibiting APC/C(CDC20) and APC/C(FZR), respectively. Generation of cells with a mixed identity in gig1/osd1 further suggested that the APC/C may have an unexpected role for cell fate determination in addition to its role for proper mitotic progression.     

Underreplication of repetitive DNA in polyploid cells of Pisum sativum.

Earlier reported results of a difference in the amount of DNA between 2C meristematic plumula cells and 2C cortex cells of the epicotyls are confirmed by fluorometric Feulgen-DNA determinations. Renaturation experiments of isolated DNA suggest that this difference in DNA is probably correlated with an underreplication of some highly repetitive DNA sequences in cells preparing endomitosis.     

脊椎动物孤雌生殖杂交起源的研究进展

脊椎动物行孤雌生殖的物种中,绝大多数都是杂交起源的。本文从孤雌生殖物种的外部形态特点、同工酶分析、核酸分子标记、染色体涂染法等方面,综述了脊椎动物中孤雌生殖杂交起源的研究进展,分析了其核内有丝分裂模式的细胞学机制。     

Endomitosis in human trophoblast

Summary Endopolyploidy, which arises through the duplication of DNA without accompanying nuclear division, occurs in large numbers of lower and higher plants and animals, including the best known, the salivary gland nuclei of Drosophila. Endomitosis is one of the processes leading to endopolyploidy, in which the stages of mitosis (prophase, metaphase, anaphase) take place inside the nuclear membrane and without spindle formation. In mammals, endomitosis has been observed in the trophoblast of the placenta of the mouse, rat and rabbit. This is the first report of endomitosis in a normal human tissue, the trophoblast of first trimester human placenta.This research was supported in part by the Foundation for Reproductive Research and Education, Inc., Northwestern University, Department of Obstetrics and Gynecology.     

Endomitotic Megakaryocytes that Form a Bipolar Spindle Exhibit Cleavage Furrow Ingression Followed by Furrow Regression

Megakaryocyte (MK) differentiation is marked by the development of progressive polyploidy, due to repeated incomplete cell cycles in which mitosis is aborted during anaphase, a process termed endomitosis. We have postulated that anaphase in endomitotic MKs diverges from diploid mitosis at a point distal to the assembly of the midzone, possibly involving impaired cleavage furrow progression. To define the extent of furrow initiation and ingression in endomitosis, we performed time-lapse imaging of MKs expressing yellow fluorescent protein (YFP)-tubulin and monitored shape change as they progressed through anaphase. We found that in early endomitotic cells that have a bipolar spindle, cleavage furrows form that can undergo significant ingression, but furrows regress to produce polyploid cells. Compared to cells that divide, cells that exhibit furrow regression have a slower rate of furrow ingression and do not furrow as deeply. More highly polyploid MKs undergoing additional endomitotic cycles also show measurable furrowing that is followed by regression, but the magnitude of the shape change is less than seen in the early MKs. This suggests that in the earliest endomitotic cycles when there is formation of a bipolar spindle, the failure of cytokinesis occurs late, following assembly and initial constriction of the actin/myosin ring, whereas in endomitotic MKs that are already polyploid there is secondary inhibition of furrow progression. This behavior of furrow ingression followed by regression may explain why midbody remnants are occasionally observed in polyploid MKs. This finding has important implications for the potential mechanisms for cytokinesis failure in endomitosis.     

Endomitosis in the mealy bug,Planococcus citri (Homoptera: Coccoidea)

Endomitosis in the Malpighian tubules of the mealy bug Planococcus citri (Risso) is described. The stages are identified on the basis of the length of the chromosomes and the distance between the sister chromatids or chromosomes. The appearance of the chromosomes in the various stages of endomitosis is compared to that in other hemipteran insects. During anaphase and telophase of endomitosis the ends of the sister chromatids and chromosomes tend to stay together longer than the other parts. It is suggested that in holokinetic chromosomes special regions for holding the chromatids together are concentrated near the ends of the chromosomes.Supported by grant GB1585 from the National Science Foundation, Washington, D.C.     

Endomitotic Megakaryocytes form a Midzone in Anaphase but Have a Deficiency in Cleavage Furrow Formation

Megakaryocyte differentiation is marked by development of progressive polyploidy and accumulation of large nuclear mass and cytoplasmic volume. During differentiation, megakaryocytes undergo repeated incomplete cell cycles in which mitosis is aborted in late anaphase with failure of cytokinesis, termed endomitosis. Recent studies have postulated that failure of Aurora-B kinase to localize to the spindle midzone is responsible for endomitosis in megakaryocytes. In diploid cells, the translocation of Aurora-B kinase is critical for positioning of the cleavage furrow, in part through its phosphorylation of the Rho family GTPase activating protein MgcRacGAP which in turn alters activity of RhoA. However, we have previously demonstrated that Aurora-B kinase localizes to centromeres and is functional in endomitotic megakaryocytes. Here, we show that endomitotic megakaryocytes form midzone structures that recruit Aurora-B kinase and its substrate MgcRacGAP. Although many cells with polyploid anaphases showed cortical localization of Aurora-B kinase, we did not observe accumulation of RhoA in furrows or formation of an actin ring. When mitotic exit was induced by inhibition of cdk1, diploid control cells formed furrows exhibiting cortical RhoA but megakaryocytes exited endomitosis without evidence of furrowing. Therefore, localization of Aurora-B kinase to the midzone is normal in endomitotic megakaryocytes but furrowing is abnormal. These data suggest that endomitotic MKs fail to complete cytokinesis due to aberrant regulation of furrowing at a step subsequent to the localization of Aurora-B kinase, possibly involving the activation or localization of RhoA. This work explores the mechanism of a normally occurring furrowing defect in a non-malignant primary cell.     

DNA replication events during larval silk gland development in the silkworm, Bombyx mori

The silk gland is an important organ in silkworm as it synthesizes silk proteins and is critical to spinning. The genomic DNA content of silk gland cells dramatically increases 200-400 thousand times for the larval life span through the process of endomitosis. Using in vitro culture, DNA synthesis was measured using BrdU labeling during the larval molt and intermolt periods. We found that the cell cycle of endomitosis was activated during the intermolt and was inhibited during the molt phase. The anterior silk gland, middle silk gland, and posterior silk gland cells asynchronously exit the endomitotic cycle after day 6 in 5th instar larvae, which correlated with the reduced expression of the cell cycle-related cdt1, pcna, cyclin E, cdk2 and cdk1 mRNAs in the wandering phase. Additional starvation had no effect on the initiation of silk gland DNA synthesis of the freshly ecdysed larvae.     

Polyploid megakaryocytes can complete cytokinesis

Megakaryocytes (MK) undergo polyploidization through endomitosis, a mitotic process that ends prematurely due to aborted cytokinesis. To better understand this and other events associated with MK differentiation, we performed long-term and large-field live cell imaging of human MKs derived in cord blood (CB) and bone marrow (BM) CD34+ cell cultures. Polyploid level of imaged cells was evaluated using three complementary approaches; cell history, cell size and ploidy correlation and nuclei staining. This system and strategy enabled the direct observation of the development of a large number of MKs (n=4865) and to quantify their fates. The most significant finding of this study is that a considerable proportion of polyploid MKs could complete cytokinesis. This unexpected process gave rise to polyploid daughter cell(s) with normal fates and contributed significantly to the expansion of polyploid MKs. Further analyses revealed that the proliferation rate amongst polyploid MKs was inversely correlated to their ploidy level, and that this phenomenon was much more frequent in CB- than BM-derived MKs. Accordingly, endomitosis was identified as the dominant fate of polyploid BM-MKs, while this was less accentuated for polyploid CB-MKs. These findings explain partially why CB-derived MKs remain in lower ploidy class. In conclusion, this study demonstrates that the development of polyploid MK results from the failure and/or success of cytokinesis and brings a new paradigm to the field of megakaryopoiesis.     

Calcium- and integrin-binding protein 1 regulates endomitosis and its interaction with Polo-like kinase 3 is enhanced in endomitotic Dami cells

Endomitosis is a form of mitosis in which both karyokinesis and cytokinesis are interrupted and is a hallmark of megakaryocyte differentiation. Very little is known about how such a dramatic alteration of the cell cycle in a physiological setting is achieved. Thrombopoietin-induced signaling is essential for induction of endomitosis. Here we show that calcium- and integrin-binding protein 1 (CIB1), a known regulator of platelet integrin α(IIb)β(3) outside-in signaling, regulates endomitosis. We observed that CIB1 expression is increased in primary mouse megakaryocytes compared to mononuclear bone marrow cells as determined by Western blot analysis. Following PMA treatment of Dami cells, a megakaryoblastic cell line, we found that CIB1 protein expression increased concomitant with cell ploidy. Overexpression of CIB1 in Dami cells resulted in multilobated nuclei and led to increased time for a cell to complete cytokinesis as well as increased incidence of furrow regression as observed by time-lapse microscopy. Additionally, we found that surface expression of integrin α(IIb)β(3,) an important megakaryocyte marker, was enhanced in CIB1 overexpressing cells as determined by flow cytometry. Furthermore, PMA treatment of CIB1 overexpressing cells led to increased ploidy compared to PMA treated control cells. Interestingly, expression of Polo-like kinase 3 (Plk3), an established CIB1-interacting protein and a key regulator of the mitotic process, decreased upon PMA treatment of Dami cells. Furthermore, PMA treatment augmented the interaction between CIB1 and Plk3, which depended on the duration of treatment. These data suggest that CIB1 is involved in regulating endomitosis, perhaps through its interaction with Plk3.     

Mutagenicity testing of amniotic fluid from smokers and non-smokers at 16 weeks of pregnancy

The effect of saccharin on the occurrence of meiotic diploid and disomic products in Saccharomyces cerevisiae was investigated. It was found that this substance inhibits the sporulation process in a dose-dependent manner, is ineffectual on recombination frequency, and slightly increases the occurrence of diploid and disomic meiotic products. It is demonstrated that the formation of diploid meiotic products is a consequence of random nuclear fusions at the end of the meiotic process or of endomitosis preceding meiosis.