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.     

Molecular Cytogenetic Analysis of Polyploidization in the Anther Tapetum of Diploid and Autotetraploid Arabidopsis thaliana Plants

Like those of most angiosperms, vegetative tissues of Arabidopsisthaliana undergo high levels of endopolyploidization. One suchtissue is the anther tapetum which plays a role in male sporo-and gametogenesis. The degree of polyploidization of the tapetumvaries from species to species. Although the role of this processis not yet fully understood, it may be linked to functioningof the tapetum, increasing the copy number of genes needed forthe synthesis of specific factors required by developing pollenmother cells (PMCs) and pollen grains. The present study focusedon polyploidization during the development of the tapetum ofArabidopsis thaliana. The aim was to outline the mode of tapetumpolyploidization in this model plant species and to establishan efficient method for analysing ploidy levels in differentiatedcells. The course and degree of tapetum polyploidization inArabidopsis was analysed in interphase nuclei using fluorescencein situ hybridization (FISH) with repetitive DNA (45S rDNA).The stages of development of the tapetum were analysed alongsidemeiosis in PMCs. The majority of tapetal cells undergo two,maximally three, rounds of divisions. Tapetal nuclei have usuallydivided by metaphase I of meiosis of PMCs. The pattern of tapetumpolyploidization was similar in diploid and autotetraploid plantsand is thus not affected by increasing amounts of maternal plantDNA. The tapetum of autotetraploid plants exhibits a higherfrequency of additional division than seen in diploid plants.Copyright 2001 Annals of Botany Company Arabidopsis thaliana, autotetraploid, FISH, rDNA polyploidization, tapetum     

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.     

Meiotic restitution in wheat-barley hybrids

Meiotic restitution occurs in pollen mother cells (PMCs) of reciprocal F₁ hybrids between wheat and barley. In occasional PMCs, all or most of the 28 chromosomes assemble at the equatorial plate at metaphase I, but instead of undergoing anaphase I separation they reform into a mass of chromatin to form a restitution nucleus. Some of these restituted nuclei undergo a regular second division and dyads are produced among other non-restituted cells which have reached the tetrad stage of division. Other restituted nuclei fail to undergo a second division and then the PMCs appear as monads among neighbouring tetrads. Both the monads and dyads are expected to produce microsporocytes with the diploid complement of chromosomes. Chromosomes which fail to become included in the restituted nucleus form separate micronuclei and, depending on whether they undergo a regular second division or not, the PMCs containing them eventually appear as tetrads, triads or dyads. These partially restituted nuclei are expected to produce unreduced gametes, deficient for one or more chromosomes. It is postulated from these observations that restitution in wheatbarley F₁ hybrids depends on a high frequency of univalent accumulation at the equatorial plate at metaphase I and the subsequent failure of the chromosomes to undergo anaphase I separation.     

POLLEN AND TAPETUM DEVELOPMENT IN DESMODIUM GLUTINOSUM AND D. ILLINOENSE (PAPILIONOIDEAE; LEGUMINOSAE)

Each of the four microsporangia has three or four wall layers, a uninucleate tapetum of various cell shapes with nuclei that remain in prophase, and 12-24 pollen mother cells (PMCs). A sterile transverse septum sometimes bisects the microsporangium. PMCs secrete callose but not uniformly, and contact among them continues through meiosis. Simultaneous cytokinesis by furrowing isolates each microspore in callose, which later disperses. The separated microspores become vacuolate, undergo mitosis to become pollen, and later become filled with food reserves. Endothecial wall thickening and tapetal dissolution occur after pollen engorgement. Calcium oxalate crystals form in tapetal cells during the sporogenous stage, reach maximum size during early meiosis, and remain prominent until tapetal dissolution.     

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.     

Stathmin Prevents the Transition from a Normal to an Endomitotic Cell Cycle during Megakaryocytic Differentiation

Physiological polyploidy is a characteristic of several cell types including themegakaryocytes (MK) that give rise to circulating blood platelets. MK achieve polyploidy byswitching from a normal to an endomitotic cell cycle characterized by the absence of late mitoticstages. During an endomitotic cycle, the cells enter into mitosis and proceed normally throughmetaphase and early anaphase. However, late anaphase, telophase and cytokinesis are aborted. Thisabortive mitosis is associated with atypical multipolar mitotic spindles and limited chromosomesegregation. Stathmin is a microtubule-depolymerizing protein that is important for the regulation ofthe mitotic spindle and interfering with its expression disrupts the normal mitotic spindle and leadsto aberrant mitotic exit. As cells enter mitosis, the microtubule depolymerizing-activity of stathminis switched-off, allowing microtubules to polymerize and assemble into a mitotic spindle.Reactivation of stathmin in the later stages of mitosis is necessary for the disassembly of the mitoticspindle and the exit from mitosis. Previous studies had shown that stathmin expression isdownregulated as MK become polyploid and inhibition of its expression in K562 cells increasestheir propensity to become polyploid. In this report, we describe our studies of the mechanism bywhich stathmin plays its role in MK polyploidization. We show that stathmin overexpressionprevents the transition from a mitotic cycle to an endomitotic cycle as determined by a decrease inthe number of multipolar mitotic spindles. These observations support a model in whichdownregulation of stathmin expression in megakaryocytes and other polyploid cells may be acritically important factor in endomitosis and polyploidy.     

Arrest of Micronuclear DNA Replication during Genomic Exclusion in Tetrahymena Produces Haploid Strains

Diploid cells of Tetrahymena thermophila were crossed to strain A*V, whose micronucleus is defective, to induce the unilateral transfer of gametic nuclei from the diploid cells to the A*V cells (round I of genomic exclusion). These haploid nuclei presumably undergo one endomitotic cycle and then become diploid with a G1 (2C) DNA content. However, further DNA replication from 2C to 4C was transiently arrested until the pairs separated. When endomitosis was blocked by treatment with cycloheximide during 6-8 hours of conjugation, the exconjugants of round I of genomic exclusion remained haploid. Competence for diploidization is apparently limited to some period of time after nuclear transfer. Blocking of diploidization during round I of genomic exclusion can be used as an efficient way to induce haploid strains in Tetrahymena.     

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.     

Development and karyology of the tapetal layer of anthers in sweet pepper (Capsicum annuum L.)

The tapetal layer of anthers inCapsicum annuum L. is differentiated from the archesporial complex during the early development stage of the anthers. Further development of tapetum proceeds according to the scheme of the cellular polynuclear type. The high rate of polyploidy is characteristic of the whole layer (from 4n to 8n). Cytokinesis does not follow karyokinesis which conditions the inception of two or three-nuclear cells. The majority of the mononuclear cells show the typical plant endomitosis without the chromosome spiralization, accompanied by the structural nuclear change-over. In other cells chromosome spiralization in the prophase and, after passing through the metaphase, restitution of the cell nuclei were observed. The tapetum development has been studied in 12 cultivars of sweet pepper which did not differ in the course of the karyological processes. The subtle differences during the temporal course of degeneration of the whole layer in the postmeiotic period of development were observed.     

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.     

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.     

Somatic polyploidy in neurons of the gastropod mollusca. III. Mitosis and endomitosis in the postnatal development of neurons in the Succinea snail central nervous system

General morphology of chromatin, the number of chromosomes and chromocenters in normal condition and at the increase of bivalent cation (Ca2+, Mg2+) concentration were studied with the purpose to reveal mechanisms of polyploidization of neuron nuclei in the snail Succinea lauta (Gastropoda, Pulmonata). The morphology of nuclei was studied on squashed preparations. Normal diploid mitoses are described in the cerebral ganglia. A possibility is supposed that part of neurons or neuroblasts in the central nervous system (CNS) of succineid snail may divide mitotically. It has been shown that the basic mechanism of neuron postnatal growth is endomitotic polyploidization of nuclei. The transition from ordinary mitosis to polyploid cycles occurs via restitutional (polyploidizing) mitosis (4c2n-->4c4n). The next endocycles are carried out by means of classic endomitosis up to reaching the highest ploidy levels--4096n--16,384n. The study of general morphology of chromatin and chromocenters at normal condition and at artificial compactization enabled us to exclude any probability of polyteny in the CNS of lauta.     

MICROSPOROGENESIS AND TAPETAL DEVELOPMENT IN NORMAL AND MALE-STERILE CARROTS (DAUCUS CAROTA)

Zenkteler , Maciej . (U. Adam Mickiewicz, ul. Stalingradzka 14, Poznan, Poland.) Microsporogenesis and tapetal development in normal and male-sterile carrots (Daucus carota). Amer. Jour. Bot. 49(4): 341–348. Illus. 1962.—Meiosis and anther development proceed normally in fertile plants. Nine pairs of chromosomes are present at diakinesis and at metaphase I. The mature pollen grains possess 2 male gametes at the time of shedding; 80–92% of the pollen appears normal. A cross-shaped configuration at pachytene characteristic of a reciprocal translocation is present in the completely pollen-sterile plants indicating that one of the parents is homozygous for an interchange between 2 members of the chromosome complex. Chromosome bridges with fragments at anaphase I and anaphase II lead to aberrant chromosome distribution during meiosis. Complete microspore abortion is associated with a periplasmodium formation of the tapetum and anther wall deterioration.     

A comparative light and electron microscopic analysis of microspore and tapetum development in fertile and cytoplasmic male sterile radish

To gain further insight into the abortive stages and ultrastructural changes leading to pollen degeneration of a novel cytoplasmic male sterile radish 805A, we compared differences of cellular and subcellular structure of sterile anther with fertile anther by light and electron microscopy analysis. Two types of locule degeneration in sterile anther were detected, of which the time of degeneration occurred and completed was different. In type I, abnormality of pollen mother cells (PMCs) and tapetal cells, including condensation of cytoplasm and large vacuoles within tapetal cells, was shown at PMC stage. In type II, meiosis and early tetrad stage progressed normally except for large vacuoles that appeared in tapetal cells. Ultrastructural alterations of the cellular organization were observed in the type II locules, such as chromatin condensation at the periphery of the nucleus and degeneration of the karyotheca, compared with normal pollen development. The results suggested that the cytoplasmic male sterility anther degeneration was probably caused by dysfunctions of tapetum and vacuolation of tapetum, PMCs, and microspores. Thus, the identical factors, which induced CMS in the same cytoplasmic and nuclear genetic background, might affect development of tapetum and microspore at different stages during the cytoplasmic male sterile 805A anther development.     

The B-chromosome system of Hypochoeris maculata

The meiotic process in PMCs of Hypochoeris maculata is progressively disrupted in the presence of two or more B-chromosomes. Bivalent formation and chiasma conditions are unaffected by up to 3Bs although some univalence occurs with higher numbers. Spindle behaviour, however, is inefficient at both first and second division in the presence of two or more Bs. At metaphase I, regular equatorial alignment breaks down and A-bivalents sometimes show amphitelic or monosyntelic orientation. Anaphase I is characterised by irregular segregation, equatorial laggards and centric division products. The proportion of normal anaphase segregations declines by 20% for every B more than one. A-chromosome laggards, but not Bs, can induce nuclear restitution at telophase I. Following centric division at anaphase II poleward movement can fail leading to further nuclear restitution. Telophase II nuclei thus can be approximately haploid, diploid or tetraploid with aneuploid variation around the haploid and diploid levels. The frequency of numerical mutants in the offspring indicates that EMC meiosis is much less susceptible to the presence of Bs than PMC meiosis: only 4- and 5B^t plants have an enhanced frequency of numerically-aberrant offspring. The deleterious effects of Bs on meiotic efficiency will contribute to setting an upper limit on B-numbers in natural populations of this species.     

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.     

Formation and division of binucleated cells in kidney cell cultures of microtus agrestis

Summary Epithelial kidney cell cultures of Microtus agrestis contain 10 to 25% binucleated cells. Observations of living cells under the phase contrast microscope showed that binucleated cells can arise by nuclear mitosis without cytoplasmic division. When binucleated cells divide the two nuclei are highly synchronized as they enter mitosis. In mitosis the chromosomes of both nuclei combine to a common metaphase plate leading to polyploid cells. In one case a tripolar spindle was seen after formation of a metaphase by the chromosomes of the two nuclei of a binucleated cell. This tripolar mitosis resulted in one binucleated and one mononucleated cell. The DNA-content (Feulgen photometry) and the distribution of heterochromatic bodies of the nuclei were corresponding to a tetraploid, a triploid and a haploid chromosome set. This suggests the possibility of somatic segregation of complete haploid sets.Supported by the Deutsche Forschungsgemeinschaft.     

玉兰减数分裂观察及染色体构型分析

采用去壁低渗方法,观察研究了玉兰Magnolia denudata有丝分裂和减数分裂的细胞学特征。实验结果证实玉兰存在两种染色体倍性,即2n=4x=76和2n=6x=114。通常,在木兰属甚至整个木兰科每个物种只具有一种染色体数目。玉兰有丝分裂间期核为复杂染色中心型,其中期染色体较小。玉兰在减数分裂中期I的构型表现出多样性,其中最主要的特点是比同源多倍体预期的二价体出现的频率更高些,其次是在减数分裂中期I可以观察到1或2个环状和（或）链状六价体。这些特征与同源异源六倍体或部分的异源六倍体种北美红杉Sequ     

Development and Histochemical Observations of Tapetum and Peritapetal Membrane in Anther of Pulsatilla chinensis

Tapetum of Pulsatilla chinensis is of secretory type. Its development proceeds rapidly in following sequence: (1) The stage of initiation-differentiation. At this stage cytological and histochemical features have been described in detail in this paper. (2) The stage of growth- synthesis: This stage appears to be the most important anabolic phase during the development of the tapetum. The salient features are that the tapetal cells become relatively enlarged and form two polyploid nuclei or aberrent polyploid nuclei resulting in synthetizing maximum proteins, fluorescing substances and maximum fluorescent Pro-Ubisch bodies in the tapetal cytoplasm. (3) The stage of secretion-disorganization: After the disintegration of the tapetal wall the enlarged naked cells appear at once. This is an important secretion period in which Pro-Ubisch bodies as well as all other fluorescing substances, carbohydrate or some enzymes are released into anther loculus. The naked cell layer becomes disorgnized until the beginning divition of the pollen grains into two ceils. As to peritapetal membrane of P. chinensis, mainly based on the membrane being on the outer side of the tapetum enclosing both the pollen, tapetal cytoplasm and Ubisch bodies, and the cellular configurations facing the pollen, Authors postulate that peritapetal membrane might be survival of the cytoplasmic membrane of tapetal cells. However, the peritapetal membrane of P. chinensis is similar to that of plasmodial, tapetum reported in certain Compositae and that of secretory tapetum reported in Pinus banksiana. Heslop-Harrison and Gupta et al. had conceded that the tapetal and peritapetal membrane belong to the general class of sporopollenin. On the contrary in P. chinensis the sporopollenin property of peritapetal membrane is only confined to its inner surface. But the thin mem- brane itself with the reticulate sporopollenin attched on its inner side appears negative staining reactions for sporopollenin though it has an ability to resist the acetolysis as well. In P. chinensis the Ubisch body is short necked flask shaped and their size is very similar. Ubisch body is either single or 2–5 in a group, resulting in compound bodies. When the Pro-Ubisch body is still within the tapetal cell it shows positive fluorescent reaction, while it eomletely unstains with Teluidine blue O. So Authors infer that the sporopollenin precur- sors may have permeated through Pro-Ubisch bodies. Finally, How sporopollenin precursor is synthesized in the tapetal cells, transported to pollen locula and polymerized into the sporopollenin on pollen, Ubisch body and peritapetal membrane? Future works along these problems may yield fruitful results.