Remodelling of thymocyte nuclei in activated mouse oocytes: an ultrastructural study

Oocyte-thymocyte mouse cell hybrids were produced using polyethylene glycol (PEG) and examined at the ultrastructural level. Fusion was accomplished either before or after activation of metaphase II oocytes. In both experimental variants thymocyte nuclei undergo remodelling which comprises the following sequence of events: nuclear envelope breakdown, initial chromatin condensation, and subsequent decondensation, nuclear envelope reformation and formation of nucleoli. In hybrids produced before oocyte activation but activated within a short time and cultured for several hours the thymocyte nuclei become identical to the female pronucleus. In the second variant (fusion with activated oocytes) the degree of remodeling of thymocyte nuclei is variable. Our observations demonstrate that between metaphase II, telophase of meiosis and early female pronuclear stages the mouse oocyte contains all "factors" necessary for remodelling of differentiated somatic nuclei and their development as if they were pronuclei.     

Caenorhabditis elegans polo-like kinase PLK-1 is required for merging parental genomes into a single nucleus

Before the first zygotic division, the nuclear envelopes of the maternal and paternal pronuclei disassemble, allowing both sets of chromosomes to be incorporated into a single nucleus in daughter cells after mitosis. We found that in Caenorhabditis elegans, partial inactivation of the polo-like kinase PLK-1 causes the formation of two nuclei, containing either the maternal or paternal chromosomes, in each daughter cell. These two nuclei gave rise to paired nuclei in all subsequent cell divisions. The paired-nuclei phenotype was caused by a defect in forming a gap in the nuclear envelopes at the interface between the two pronuclei during the first mitotic division. This was accompanied by defects in chromosome congression and alignment of the maternal and paternal metaphase plates relative to each other. Perturbing chromosome congression by other means also resulted in failure to disassemble the nuclear envelope between the two pronuclei. Our data further show that PLK-1 is needed for nuclear envelope breakdown during early embryogenesis. We propose that during the first zygotic division, PLK-1–dependent chromosome congression and metaphase plate alignment are necessary for the disassembly of the nuclear envelope between the two pronuclei, ultimately allowing intermingling of the maternal and paternal chromosomes.     

INDUCTION OF NUCLEAR ENVELOPES AROUND METAPHASE CHROMOSOMES AFTER FUSION WITH INTERPHASE CELLS

The process of cellular fusion induced by Sendai virus in Chinese hamster cells (Don line) afforded us the opportunity to study nuclear envelope formation around metaphase sets in the presence of interphase nuclei, when chromosome pulverization failed to occur in such multinucleate cells. Morphologically, the enveloped metaphase chromosomes resembled a normal telophase nucleus, though minor differences prompted us to call it telophase-like. Electron microscopic observations demonstrated that the membranes enveloping the chromosomes appeared to be identical with a normal nuclear envelope. The longer the cells were incubated with Colcemid before fusion, the higher was the number of cells with telophase-like nuclei and the lower the percentage of cells with pulverizations. Furthermore, the number of pulverizations bore a somewhat direct relationship to the ratio of metaphase to interphase nuclei in multinucleate cells, and the number of telophase-like nuclei was inversely proportional to this ratio. A hypothesis is advanced in which a balance between the activities of a chromosome pulverization factor and a nuclear envelope formation factor, the former in metaphase cells and the latter in interphase cells, is decisive as to the nature of morphologic events observed in virus-induced fused cells.     

Cytological events leading to the cleavage of golden hamster zygotes.

Fertilized golden hamster eggs were examined between 6 and 20 hours post-ovulation to determine the events leading to the two-cell stage. Following their migration the pronuclei remain in the central region of the zygote for approximately ten hours. The morphologically, indistinguishable male and female pronuclei remain relatively unchanged during this period, i.e., they do not interdigitate or fuse with one another as described for the zygotes of other organisms. Following this period and at the time of pronuclear breakdown elongate vesicles appear along the nucleoplasmic surface of the pronuclear envelopes. Later the pronuclear envelopes fragment into elongate cisternae; these and the vesicles formed along the inner lamina of the pronuclear envelopes remain closely associated and constitute quadrilaminar structures. The chromosomes which condense prior to and during pronuclear envelope breakdown, migrate to the equatorial plate of the forming cleavage spindle. After cytokinesis the chromosomes in the blastomere nuclei disperse. Increase in the nuclear envelope to accommodate this dispersion may involve the addition of membrane from the quandrilaminar structures.     

Interactions between metaphase and interphase factors in heterokaryons produced by fusion of mouse oocytes and zygotes

The cytoplasmic factor responsible for chromosome condensation was introduced into mouse zygotes at different times after fertilization by fusion of the zygotes with metaphase I oocytes. In 72% of heterokaryons obtained after fusion of early zygotes (14-18 hr post-human chorionic gonadotrophin (HCG) with oocytes, the male and female pronuclei of the zygote decondensed. At the same time, the oocyte chromosomes became enclosed in a nuclear envelope and decondensed to an interphase state. However, in the rest of the heterokaryons, the chromatin of the pronuclei condensed to metaphase chromosomes, thus resulting in three sets of chromosomes. Fusion of zygotes that had begun DNA synthesis (20-22 hr post-HCG) with oocytes induced chromosome condensation of the pronuclei in 76% of the cases. In some heterokaryons, however, the oocyte chromosome decondensed to an interphase state similar to the zygote pronuclei. Fusion between late zygotes (27-29 hr post-HCG) with oocytes resulted in chromosome condensation of the pronuclei in all heterokaryons. On the basis of these results, the formation of the pronuclei and their progression toward mitosis in the zygote may be explained by changing levels of a metaphase factor in the cell, or by a balance between interphase and metaphase factors.     

THE FUSION OF SEXUAL NUCLEI

A classification scheme is proposed for the types of sexual nuclear fusion that occur in eukaryotes. The two main classes are envelope fusion and envelope vesiculation and each is further divided into subclasses. The formation of sexual nuclei (pronuclei) has been detailed in representatives from various phyla, but is best understood in animals, in which the development of male and female pronuclei differs in some respects. The only characterized cytoplasmic mediator of pronuclear movement are microtubules. Groups of eukaryotes can be classified according to the type of nuclear fusion they reveal. Envelope fusion occurs in animals whose eggs are fertilized at the pronuclear stage, and in all plants, fungi, protozoa and algae studied to date. Ultrastructural details of envelope fusion have shown variations that are classified in our scheme as direct and indirect, the latter being restricted to the plant kingdom. Envelope vesiculation only occurs in animals, in which it is the most common means of nuclear fusion. Four subclasses can be defined according to the timing of the vesiculation of the nuclear envelopes, and the extent of envelope surface projections prior to fusion. The amount of work reported on the controlling mechanisms of nuclear fusion has been limited, but some evidence of genetic control has been provided, particularly in fungi. Evidence is presented to indicate that the control of the fusion competence of nuclei is a negative one. This review of the information available on nuclear fusion points out the need for extensive future comparative studies if this important process is to be better understood.     

Nuclear envelope breakdown is under nuclear not cytoplasmic control in sea urchin zygotes

Nuclear envelope breakdown (NEB) and entry into mitosis are though to be driven by the activation of the p34cdc2-cyclin B kinase complex or mitosis promoting factor (MPF). Checkpoint control mechanisms that monitor essential preparatory events for mitosis, such as DNA replication, are thought to prevent entry into mitosis by downregulating MPF activation until these events are completed. Thus, we were surprised to find that when pronuclear fusion in sea urchin zygotes is blocked with Colcemid, the female pronucleus consistently breaks down before the male pronucleus. This is not due to regional differences in the time of MPF activation, because pronuclei touching each other break down asynchronously to the same extent. To test whether NEB is controlled at the nuclear or cytoplasmic level, we activated the checkpoint for the completion of DNA synthesis separately in female and male pronuclei by treating either eggs or sperm before fertilization with psoralen to covalently cross-link base-paired strands of DNA. When only the maternal DNA is cross-linked, the male pronucleus breaks down first. When the sperm DNA is cross-linked, male pronuclear breakdown is substantially delayed relative to female pronuclear breakdown and sometimes does not occur. Inactivation of the Colcemid after female NEB in such zygotes with touching pronuclei yields a functional spindle composed of maternal chromosomes and paternal centrosomes. The intact male pronucleus remains located at one aster throughout mitosis. In other experiments, when psoralen-treated sperm nuclei, over 90% of the zygote nuclei do not break down for at least 2 h after the controls even though H1 histone kinase activity gradually rises close to, or higher than, control mitotic levels. The same is true for normal zygotes treated with aphidicolin to block DNA synthesis. From these results, we conclude that NEB in sea urchin zygotes is controlled at the nuclear, not cytoplasmic, level, and that mitotic levels of cytoplasmic MPF activity are not sufficient to drive NEB for a nucleus that is under checkpoint control. Our results also demonstrate that the checkpoint for the completion of DNA synthesis inhibits NEB by acting primarily within the nucleus, not by downregulating the activity of cytoplasmic MPF.     

Electron microscopic observations of karyogamy in the fish egg

In the initial step of pronuclear association in fertilized fish eggs, the female and male pronuclei (containing large nucleolus-like bodies) were juxtaposed in the center of the blastodisc and formed nucleoplasmic projections along adjacent surfaces. After contact of the pronuclei, small internuclear bridges joining them were formed by fusion at several regions of the nuclear envelope projections. No specific site of fusion or breakdown of nuclear envelopes was recognized in the pronuclei during karyogamy. In the advanced stage, clumps of condensing chromatin appeared in the nucleoplasm of the newly fused pronuclei. The number and diameter of the internuclear bridges increased gradually by progressive fusion in many regions, finally yielding a spherical zygote nucleus. Following complete formation of the zygote nucleus, the pronuclear envelope began to break down concomitantly with shrinkage of the nucleoplasm, which was highly convoluted around the entire nuclear surface. The nucleoplasm containing chromosomes then mingled with the perinuclear cytoplasm.     

Action of colcemid in sea urchin eggs

The effects of Colcemid, the deacetyl-N-methyl derivative of colchicine, on the eggs of Arbacia punctulata were investigated. Colcemid in concentrations of 2.7 x 10^-5 M or greater blocks syngamy (the fusion of the pronuclei) in these eggs. Although a tenfold decrease in concentration of Colcemid usually permits the pronuclei to fuse, the subsequent division is blocked. In the sea urchin egg, the duration of presyngamy is about 15 min during which time there is no DNA synthesis. However, DNA synthesis is recorded in Colcemid-blocked cells prior to syngamy. Radioautographs of Colcemid-blocked cells which were immersed into thymidine-³H exhibited silver grains above each of the pronuclei. The action of Colcemid on Arbacia eggs is reversible. Nevertheless, exposures to 2.7 x 10^-5 M Colcemid for only 3 min, initiated 5 min after insemination, caused delays of 70 min in subsequent division. In general, cells are more sensitive to Colcemid prior to the time when the mitotic spindle is being assembled than at presyngamy stages. The results are discussed in terms of Colcemid action on pronuclear fusion and cell division.     

Transformations of sperm nuclei incorporated into sea urchin (Arbacia punctulata) embryos at different stages of the cell cycle

In order to test the hypothesis that regulators of male pronuclear development may have a more general role, sharing some relation to factors involved with the cell cycle, Arbacia zygotes and 2- to 8-cell stage embryos were inseminated during different phases of the cell cycle and examined by light and electron microscopy. Differences in the development and morphology of fertilization cones and sperm asters were observed in embryos inseminated during different stages of the cell cycle. Extremely large fertilization cones, approximately four times the length of those found in fertilized eggs, formed in embryos inseminated during metaphase to telophase. Sperm asters developed only in embryos inseminated during prophase to anaphase. These variations are believed to reflect changes in the status of the cortex and cytoskeletal system of the embryo. Although sperm nuclei underwent morphological changes subsequent to incorporation, in general, they failed to develop into male pronuclei. There was a consistent correlation in sperm nuclear transformations and the cell cycle which was expressed in two patterns of morphogenesis: (1) sperm nuclei incorporated into embryos just prior to prophase and at telophase failed, for the most part, to disperse and transformed into aggregations of chromatin granules approximately 40 nm in diameter; and (2) sperm nuclei incorporated into prometaphase-anaphase embryos dispersed and then condensed into chromatin masses, morphologically similar to chromosomes of the embryo. Evidence is discussed which indicates that following the normal period of fertilization changes occur in the zygote, rendering it unable to fully support the transformation of sperm nuclei into male pronuclei.     

Pronuclear formation in starfish eggs inseminated at different stages of meiotic maturation: correlation of sperm nuclear transformations and activity of the maternal chromatin

Changes in sperm nuclei incorporated into starfish, Asterina miniata, eggs inseminated at different stages of meiosis have been correlated with the progression of meiotic maturation. A single, uniform rate of sperm expansion characterized eggs inseminated at the completion of meiosis. In oocytes inseminated at metaphase I and II the sperm nucleus underwent an initial expansion at a rate comparable to that seen in eggs inseminated at the pronuclear stage. However, in oocytes inseminated at metaphase I, the sperm nucleus ceased expanding by meiosis II and condensed into chromosomes which persisted until the completion of meiotic maturation. Concomitant with the formation and expansion of the female pronucleus, sperm chromatin of oocytes inseminated at metaphase I enlarged and developed into male pronuclei. Condensation of the initially expanded sperm nucleus in oocytes inseminated at metaphase II was not observed. Instead, the enlarged sperm nucleus underwent a dramatic increase in expansion commensurate with that taking place with the maternal chromatin to form a female pronucleus. Fusion of the relatively large female pronucleus and a much smaller male pronucleus was observed in eggs fertilized at the completion of meiotic maturation. In oocytes inseminated at metaphase I and II, the male and female pronuclei, which were similar in size, migrated into juxtaposition, and as separate structures underwent prophase. The chromosomes in each pronucleus condensed, intermixed, and became aligned on the metaphase palate of the mitotic spindle in preparation for the first cleavage division. These observations demonstrate that the time of insemination with respect to the stage of meiotic maturation has a significant effect on sperm nuclear transformations and pronuclear morphogenesis.     

Development of human male pronucleus: Ultrastructure and timing

The process of human male pronuclear formation was studied using an experimental model based on in vitro inseminated human zona-free eggs prepared from oocytes that failed to fertilize in a clinical in vitro fertilization program. The main ultrastructural changes in penetrated sperm nuclei transforming into pronuclei were used to define four stages of pronuclear development. The first two stages, representing partial (Stage 1) and total (Stage 2) sperm chromatin decondensation, appeared as early as 1 hr after mixing of gametes. This rapid initial phase was followed by a more lengthy array of events leading to transformation of decondensed sperm nuclei into fully developed male pronuclei (Stages 3 and 4). Stage 3 was characterized by reformation of the nuclear envelope, reorganization of chromatin, and the assembly of nuclcolar precursors. It was not completed until 12 hr after in vitro insemination when fully developed male pronuclei (Stage 4) were first observed. In some eggs pronuclei did not reach Stage 4 at all. The results of this study provide a morphological background for further research into molecular aspects of human male pronuclear development and its regulation.     

Kinetochore appearance during meiosis,fertilization and mitosis in mouse oocytes and zygotes

The events of mammalian fertilization overlap with the completion of meiosis and first mitosis; the pronuclei never fuse, instead the parental genomes first intermix at the mitotic spindle equator at metaphase. Since kinetochores are essential for the attachment of chromosomes to spindle microtubules, this study explores their appearance and behavior in mouse oocytes, zygotes and embryos undergoing the completion of meiosis, fertilization and mitoses. Kinetochores are traced with immunofluorescence microscopy using autoimmune sera from patients with CREST (CREST = calcinosis, Raynaud's phenomenon, esophageal dysmotility, sclerodactyly, telangiectasia) scleroderma. These sera cross-react with the 17 kDa centromere protein (CENP-A) and the 80 kDa centromere protein (CENP-B) found at the kinetochores in human cell cultures. The unfertilized oocyte is ovulated arrested at second meiotic metaphase and kinetochores are detectable as paired structures aligned at the spindle equator. At meiotic anaphase, the kinetochores separate and remain aligned at the distal sides of the chromosomes until telophase, when their alignment perpendicular to the spindle axis is lost. The female pronucleus and the second polar body nucleus each receive a detectable complement of kinetochores. Mature sperm have neither detectable centrosomes nor detectable kinetochores, and shortly after sperm incorporation kinetochores become detectable in the decondensing male pronucleus. In pronuclei, the kinetochores are initially distributed randomly and later found in apposition with nucleoli. At mitosis, the kinetochores behave in a pattern similar to that observed at meiosis or mitosis in somatic cells: irregular distribution at prophase, alignment at metaphase, separation at anaphase and redistribution at telophase. They are also detectable in later stage embryos. Colcemid treatment disrupts the meiotic spindle and results in the dispersion of the meiotic chromosomes along the oocyte cortex; the chromosomes remain condensed with detectable kinetochores. Fertilization of Colcemid-treated oocytes results in the incorporation of a sperm which is unable to decondense into a male pronucleus. Remarkably kinetochores become detectable at 5 h post-insemination, suggesting that the emergence of the paternal kinetochores is not strictly dependent on male pronuclear decondensation.     

Sequential transformations of human sperm nucleus in human egg

In-vitro insemination of human zona-free oocytes prepared from oocytes that failed to fertilize in an in-vitro fertilization programme was used as an experimental model to study the time course and morphological events during the development of sperm nuclei into male pronuclei. At 30 min after insemination, 22 eggs were cultured in a CO2 incubator for further 3.5 h and 17 eggs were placed individually between a slide and coverslip for randomly repeated microscopical observations in a controlled environment for at least 3.5 h. Simultaneous arrest of maternal meiosis and sperm nuclear development occurred in 36.4% (8/22) eggs cultured in the CO2 incubator and 47.1% (8/17) of those cultured between a slide and coverslip. Sequential transformation of the human sperm nucleus in human eggs was studied in 6 eggs that showed continuous development of sperm nuclei into male pronuclei during at least 3.5 h after insemination. The early sperm nuclear development in human egg ooplasm can be divided into three phases: the sperm nucleus first decondenses (phase 1) then partly recondenses (phase 2) before expanding again to form an early male pronucleus (phase 3). The prepronuclear stages (phases 1 and 2) took about 60 min each and the pronuclear formation (phase 3) began between 120 and 170 min after insemination. Early pronuclear formation was associated with the occurrence of dense outline material, probably a precursor of the future pronuclear membrane, around the recondensed nucleus in re-expansion (phase 3). Between 30 and 60 min after the beginning of phase 3, numerous (greater than 20) dense grains, considered as nucleolar precursors, were clearly visible inside the growing male pronucleus. Moreover, we have examined sperm nuclear changes in some eggs in which the progression of late meiosis was abnormal. Meiotic arrest of maternal chromatin was always associated with arrest of sperm head development. In 75% (6/8) of the eggs arrested in the metaphase II stages and in 87.5% (7/8) of the eggs arrested in late anaphase II, sperm nuclear development was stopped at the decondensed and recondensed stages, respectively. We have always observed male pronuclei when a maternal pronucleus was present in the egg. These observations suggested that maternal chromatin and sperm nuclear development are probably regulated by common factor(s).     

Ultrastructural changes in hamster spermatogenic cell nuclei after incorporation into homologous oocytes by electrofusion

Isolated hamster spermatogenic cells at various stages of spermatogenesis were examined by thin‐sectioning techniques after electrofusion with activated homologous oocytes. The nuclei and attached organelles of the cells remained almost unchanged within the ooplasm three to five hours after the fusion pulse, by which time the oocytes had developed to the pronuclear stage. Only the spherical nuclei of primary spermatocytes and early spermatids in the Golgi and cap phases underwent modifications in their fine structures. They gained the morphological characteristics of well‐developed mammalian pronuclei; e.g., electron‐dense round nucleolus‐like bodies and blebbing of the nuclear envelope. In contrast, the elongated nuclei of later spermatids in the acrosome and maturation phases retained their original features, except that their acrosomes were deformed. Thus, ooplasm‐mediated transformation within activated oocytes at the pronuclear stage occurred only in nuclei containing dispersed chromatin and having nuclear pores in the envelope. Mol. Reprod. Dev. 52:66–73, 1999. © 1999 Wiley‐Liss, Inc.     

Ion channels in murine nuclei during early development and in fully differentiated adult cells

Summary The nuclear envelope functions as a selective barrier between nucleus and cytoplasm. During cycles of cell division the nuclear envelope repeatedly disassembles and re-associates. Presumably, each cycle re-establishes the functional and structural integrity of the nuclear envelope. After repeated rounds of cell division, as occurs during differentiation, the selectivity and configuration of the envelope may change. We compare the ionic conductance and the nuclear pore density in four types of murine nuclei: germinal vesicles in oocytes, pronuclei in zygotes, nuclei from two-cell blastomeres, and somatic cell nuclei from the liver. A large-conductance ion channel is present in all nuclear envelopes. Liver cell nuclei have a greater number of these channels than those from earlier developmental stages, and they also have a higher density of nuclear pores. In this article we hypothesize an association between the ion channels and the nuclear pores.     

Fine structure of division in ciliate protozoa. I. Micronuclear mitosis in Blepharisma

The mitotic, micronuclear division of the heterotrichous genus Blepharisma has been studied by electron microscopy. Dividing ciliates were selected from clone-derived mass cultures and fixed for electron microscopy by exposure to the vapor of 2% osmium tetroxide; individual Blepharisma were encapsulated and sectioned. Distinctive features of the mitosis are the presence of an intact nuclear envelope during the entire process and the absence of centrioles at the polar ends of the micronuclear figures. Spindle microtubules (SMT) first appear in advance of chromosome alignment, become more numerous and precisely aligned by metaphase, lengthen greatly in anaphase, and persist through telophase. Distinct chromosomal and continuous SMT are present. At telophase, daughter nuclei are separated by a spindle elongation of more than 40 µ, and a new nuclear envelope is formed in close apposition to the chromatin mass of each daughter nucleus and excludes the great amount of spindle material formed during division. The original nuclear envelope which has remained structurally intact then becomes discontinuous and releases the newly formed nucleus into the cytoplasm. The micronuclear envelope seems to lack the conspicuous pores that are typical of nuclear envelopes. The morphology, size, formation, and function of SMT and the nature of micronuclear division are discussed.     

Events associated with the initiation of mitosis in fused multinucleate HeLa cells

Large multinucleate (LMN) HeLa cells with more than 10–50 nuclei were produced by random fusion with polyethylene glycol. The number of nuclei in a particular stage of the cell cycle at the time of fusion was proportionate to the duration of the phase relative to the total cell cycle. The fused cells did not gain generation time. Interaction of various nuclei in these cells has been observed. The nuclei initially belonging to the G1-or S-phase required a much longer time to complete DNA synthesis than in mononucleate cells. Some of the cells reached mitosis 15 h after fusion, whereas others required 24 h. The cells dividing early, contained a larger number of initially early G1-phase nuclei than those cells dividing late. The former very often showed prematurely condensed chromosome (PCC) groups. In cells with a large number of advanced nuclei the few less advanced nuclei could enter mitosis prematurely. On the other hand, the cells having a large number of nuclei belonging initially to late S-or G2-phase took longer to reach mitosis. These nuclei have been taken out of the normal sequence and therefore failed to synthesize the mitotic factors and depended on others to supply them. Therefore the cells as a whole required a longer period to enter mitosis. Although the nuclei became synchronized at metaphase, the cells revealed a gradation in prophase progression in the different nuclei. At the ultrastructural level the effect of advanced nuclei on the less advanced ones was evident with respect to chromosome condensation and nuclear envelope breakdown. Less advanced nuclei trapped among advanced nuclei showed PCC and nuclear envelope breakdown prematurely, whereas mitotic nuclei near interphase or early prophase nuclei retained their nuclear envelopes for a much longer time. PCC is closely related to premature breakdown of the nuclear envelope. Our observations clearly indicate that chromosome condensation and nuclear envelope breakdown are two distinct events. Kinetochores with attached microtubules could be observed on prematurely condensed chromosomes. Kinetochores of fully condensed chromosomes often failed to become connected to spindle elements. This indicates that the formation of a functional spindle is distinct from the other events and may depend on different factors.     

The expression of nuclear lamin A and C epitopes is regulated by the developmental stage of the cytoplasm in mouse oocytes or embryos.

The cytoplasmic regulation of changes of nuclear lamin antigens was examined by transferring 16-cell stage blastomeres into mouse oocytes. Sixteen-cell stage blastomeres were transferred to either pronuclear eggs, enucleated pronuclear eggs or metaphase II oocytes, which were subsequently activated. Pronuclei react with a monoclonal antibody to A/C lamins (J9), whereas nuclei from 16-cell stage blastomeres do not react with J9. However, after transfer of 16-cell stage nuclei to activated metaphase II oocytes, the transferred nuclei acquire the antigen. This is in contrast to 16-cell nuclei that were transferred to intact or enucleated pronuclear eggs; i.e., the nuclei only faintly acquired the A/C epitope. These results suggest that the developmental stage of the cytoplasm regulates the exposure of nuclear lamina epitopes, perhaps by limiting the supply of lamin A/C in the oocyte or because nuclear lamina assembly can only occur at the telophase transition. Furthermore, it appears that there is some exchange of the A/C epitope between (pro)nuclei within the same cell but that the majority of the A/C lamin epitope can be removed from a cell with (pro)nuclear removal.     

Effect of divalent cations and chelators on metaphase to telophase progression and nuclear envelope formation in Chinese hamster cells

Chinese hamster DON cells in log phase were treated with Colcemid in the G₂ period with or without divalent cation chelating agents. The metaphase cells were isolated and incubated in two ways: 1) without Colcemid but with chelating agents or La³⁺ and observed for metaphase to telophase progression, and 2) with Colcemid, with or without chelating agents and the rate of micronuclei formation in the absence of anaphase monitored. The effect of the chelating agents on cellular ⁴⁵Ca²⁺ during metaphase to telophase progression was also studied.The results indicate that Ca²⁺ and possibly Mg²⁺ ions are involved in the regulation of certain segments of mitosis. The reduction of environmental and plasma membrane associated Ca²⁺ with the chelators and La³⁺ promoted the metaphase to telophase progression as well as nuclear envelope and micronuclei formation.