Distribution of fluorescently labeled tubulin injected into sand dollar eggs from fertilization through cleavage

Porcine brain tubulin labeled with fluorescein isothiocyanate (FITC) was able to polymerize by itself and co-polymerize with tubulin purified from starfish sperm flagella. When we injected the FITC-labeled tubulin into unfertilized eggs of the sand dollar, Clypeaster japonicus, and the eggs were then fertilized, the labeled tubulin was incorporated into the sperm aster. When injected into fertilized eggs at streak stage, the tubulin was quickly incorporated into each central region of growing asters. It was clearly visualized that the labeled tubulin, upon reaching metaphase, accumulated in the mitotic apparatus and later disappeared over the cytoplasm during interphase. The accumulation of the fluorescence in the mitotic apparatus was observed repeatedly at successive cleavage. After lysis of the fertilized eggs with a microtubule-stabilizing solution, fluorescent fibrous structures around the nucleus and those of the sperm aster and the mitotic apparatus were preserved and coincided with the fibrous structures observed by polarization and differential interference microscopy. We found the FITC-labeled tubulin to be incorporated into the entire mitotic apparatus within 20-30 s when injected into the eggs at metaphase or anaphase. This rapid incorporation of the labeled tubulin into the mitotic apparatus suggests that the equilibrium between mitotic microtubules and tubulin is attained very rapidly in the living eggs. Axonemal tubulin purified from starfish sperm flagella and labeled with FITC was also incorporated into microtubular structures in the same fashion as the FITC-labeled brain tubulin. These results suggest that even FITC-labeled heterogeneous tubulins undergo spatial and stage-specific regulation of assembly-disassembly in the same manner as does sand dollar egg tubulin.     

An ultrastructural analysis of mitosis and cytokinesis in the zygote of the sea urchin, Arbacia punctulata

Post-fertilization events leading to the cleavage of the zygote of the sea-urchin, Arbacia punctulata were examined with the light and electron microscopes. Prior to prophase of the first cleavage division, endoplasmic reticulum and annulate lamellae become organized around the zygotic nucleus to produce a crescent-shaped structure which is defined as the streak (Harvey, '56). With the advent of prophase the streak undergoes morphogenic events which lead to the formation of the mitotic asters. During this transition there is a loss of annulate lamellae and a concomitant increase in endoplasmic reticulum. Annulate lamellae are not found as a part of the mitotic apparatus and are not again observed within the embryo until the two cell stage. During telophase, karyomeres are formed which consist of chromosomes delimited by a porous bilaminar envelope. Blastomere nuclei are produced following the fusion of the outer laminae, and subsequently by the fusion of the inner laminae of the envelopes encompassing the karyomeres.     

Distribution of tubulin-containing structures in the egg of the sea urchin Strongylocentrotus purpuratus from fertilization through first cleavage

Eggs of the sea urchin Strongylocentrotus purpuratus were examined by indirect immunofluorescence microscopy for tubulin-containing structures at intervals from fertilization through first cleavage. The staining revealed that the monaster is made up not only of the sperm aster but also of tubulin-staining fibers originating elsewhere in the egg. The monaster does not divide directly but is broken down first before the amphiaster or interphase asters begin to form. The interphase asters reach a peak of development at the streak stage and are in turn broken down before the formation of the mitotic apparatus. The breakdown of the monaster, interphase asters, as well as the asters of the mitotic apparatus proceeds from the cell center or aster centers to the periphery of the cell and is followed by growth of new asters, also proceeding outward from the aster centers. The pattern suggests a transient wavelike movement of some condition, or factor, which favors microtubule depolymerization.     

Mitotic apparatus formation and cleavage induction by micromanipulation of the nucleus and centrosome: The centrosome forms a spindle together with only the chromosomes at a short distance

We micromanipulated the nucleus and centrosomes in the zygote of the starfish, Asterina pectinifera, in order to investigate their roles in mitotic apparatus formation and cleavage induction. The zygote cleaved without spindle formation when its nucleus was removed. When one or two centrosomes were transplanted, they formed asters in the recipient cell, which cleaved into three or four blastomeres so that each blastomere might contain one centrosome or aster. When one centrosome was removed, a half-spindle formed in the manipulated cell, which did not cleave until the other centrosome was duplicated. When both centrosomes were removed, no microtubular structures such as the spindle and the aster appeared in the manipulated cell, which failed to cleave. These results indicate that two centrosomes or more in the cell induce cleavage with or without the nucleus and that one centrosome or less does not induce cleavage. It is also concluded that the centrosome(s) together with the nucleus forms a half-spindle or bipolar spindle. However, from the experiments of nucleus transplantation and displacement, spindle formation is found to depend on the distance between chromosomes and centrosomes. The half-spindle formed when the distance from the centrosome to the chromosomes was shorter than 22 microns; on the other hand, when the distance was longer than 22 microns, the nucleus remained apart from the aster, which means that the functional range of the astral microtubule's ability to engage chromosomes was 22 microns from the centrosome.     

Detection of the membrane-calcium distribution during mitosis in Haemanthus endosperm with chlorotetracycline

The distribution of membrane-associated calcium has been determined at various stages of mitosis in Haemanthus endosperm cells with the fluorescent chelate probe chlorotetracycline (CTC). CTC fluorescence in Haemanthus has two components: punctate, because of mitochondrial and plastid membrane-Ca++; and diffuse, primarily because of Ca++ associated with endoplasmic reticulum membranes. Punctate fluorescence assumes a polar distribution throughout mitosis. Cones of diffuse fluorescence in the chromosomse-to-pole regions of the metaphase spindle appear to coincide with the kinetochore fibers; during anaphase, the cones of fluorescence coalesce and this region of the spindle exhibits uniform diffuse fluorescence. Perturbation of the cellular Ca++ distribution by treatment with lanthanum, procaine, or EGTA results in a loss of diffuse fluorescence with no accompanying change in the intensity of punctate fluorescence. Detergent extraction of cellular membranes causes a total elimination of CTC fluorescence. CTC fluorescence of freshly teased crayfish claw muscle sarcoplasmic reticulum coincides with the A bands and is reduced by perfusion with lanthanum, procaine, and EGTA in a manner similar to that for diffuse fluorescence in the endosperm cells. These results are consistent with the hypothesis that a membrane system in the chromosome-to-pole region of the mitotic apparatus functions in the localized release of sequestered Ca++, thereby regulating the mechanochemical events of mitosis.     

Axis establishment and microtubule-mediated waves prior to first cleavage in Beroe ovata

The single axis (oral-aboral) and two planes of symmetry of the ctenophore Beroe ovata become established with respect to the position of zygote nucleus formation and the orientation of first cleavage. Bisection of Beroe eggs at different times revealed that differences in egg organisation are established in relation to the presumptive oral-aboral axis before first cleavage. Lateral fragments produced after but not before the time of first mitosis developed into larvae lacking comb-plates on one side. Time-lapse video demonstrated that waves of cytoplasmic reorganisation spread through the layer of peripheral cytoplasm (ectoplasm) of the egg during the 80 minute period between pronuclear fusion and first cleavage, along the future oral-aboral axis. These waves are manifest as the progressive displacement and dispersal of plaques of accumulated organelles around supernumerary sperm nuclei, and a series of surface movements. Their timing and direction of propagation suggest they may be involved in establishing cytoplasmic differences with respect to the embryonic axis.Inhibitor experiments suggested that the observed cytoplasmic reorganisation involves microtubules. Nocodazole and taxol, which prevent microtubule turnover,blocked plaque dispersal and reduced surface movements.The microfilament-disrupting drug cytochalasin B did not prevent plaque dispersal but induced abnormal surface contractions. We examined changes in microtubule organisation using immunofluorescence on eggs fixed at different times and in live eggs following injection of rhodamine-tubulin. Giant microtubule asters become associated with each male pronucleus after the end of meiosis. Following pronuclear fusion they disappear successively, those nearest the zygote nucleus shrinking first, to establish gradients of aster size within single eggs. Regional differences in microtubule behaviour around the time of mitosis were revealed by brief taxol treatment, which induced the formation of small microtubule asters in the region of the nucleus or spindle during both first and second cell cycles. The observed wave of change may thus reflect the local appearance and spreading of mitotic activity as the zygote nucleus approaches mitosis.     

Distribution of Membrane-Associated Calcium in Fertilized Sea Urchin Eggs during Mitosis*

The distribution of membrane-associated calcium in dividing sea urchin eggs was examined with chlortetracycline as a fluorescent chelate probe. The fluorescence of bound chlortetracycline in fertilized eggs was initially evenly distributed, but began to gather around the nucleus in prophase, and formed a dumb-bell shaped condensation enclosing the mitotic apparatus by metaphase. During anaphase and telophase, the fluorescence was observed in kinetochore-to-pole regions of the spindle, with little fluorescence in the interkinetochore region. The astral regions showed intense fluorescence. The distribution of the chlortetracycline-fluorescence coincided with that of ER-like membranes seen in electron micrographs. The distribution of the fluorescence was obscure and the birefringence of spindles disappeared on perfusion on perfusion of the cells in metaphase with 1 mM tetracaine, which is known to displace membrane-bound calcium. These results suggest that intracellular free calcium ions are sequestered in the membrane system associated with the mitotic apparatus during mitosis.     

Electron and immunofluorescence microscopy on the fertilization ofFucus distichus (Fucales,Phaeophyceae)

Summary Processes of fertilization and zygote development inFucus distichus were studied by indirect immunofluorescence microscopy using anti- tubulin antibody and electron microscopy. Just after plasmogamy, sperm aster formation occurs during migration of a sperm nucleus toward an egg nucleus at the center of cytoplasm. Only sparse microtubules (MTs) exist around the egg nucleus. The sperm aster can be observed till karyogamy, but afterwards vanishes. Accompanying sperm aster formation, cortical MTs which are reticulately arranged develop further in the zygotes. In 4 h-old zygotes, characteristic structures which are composed of fine granular masses and consist of intermixed dense and lighter staining areas appear around the nucleus. These structures cannot be detected with anti- tubulin immunofluorescence microscopy. The two centrioles derived from the sperm separate and migrate to both poles. In 4 h-and 8 h-old zygotes, there are no defined MT foci around the zygote nucleus and MTs radiate from the circumference of it. In 12 h-old zygotes, each centriole has migrated to the poles and derivative centrioles are generated. The fine granular masses also migrate to both poles and finally disappear accompanying the appearance of numerous MTs radiating from the poles. Therefore, two distinct MT foci appear from 12 h onwards. Progressive stages of nuclear division were also examined with electron and immunofluorescence microscopy in 16 h-old zygotes. The sperm chloroplast with an eyespot and the sperm mitochondria with an intercristal tubular structure, which are distinctive from those of egg, can be detected after plasmogamy and karyogamy. The sperm chloroplast is still present in 16 h-old zygotes.     

THE FINE STRUCTURE OF PRONUCLEAR DEVELOPMENT AND FUSION IN THE SEA URCHIN, ARBACIA PUNCTULATA

Fertilization events following coalescence of the gamete plasma membranes and culminating in the formation of the zygote nucleus were investigated by light and electron microscopy in the sea urchin, Arbacia punctulata. Shortly after the spermatozoon passes through the fertilization cone, it rotates approximately 180° and comes to rest lateral to its point of entrance. Concomitantly, the nonperforated nuclear envelope of the sperm nucleus undergoes degeneration followed by dispersal of the sperm chromatin and development of the pronuclear envelope. During this reorganization of the sperm nucleus, the sperm aster is formed. The latter is composed of ooplasmic lamellar structures and fasciles of microtubules. The male pronucleus, sperm mitochondrion, and flagellum accompany the sperm aster during its migration. As the pronuclei encounter one another, the surface of the female pronucleus proximal to the advancing male pronucleus becomes highly convoluted. Subsequently, the formation of the zygote nucleus commences with the fusion of the outer and the inner membranes of the pronuclear envelopes, thereby producing a small internuclear bridge and one continuous, perforated zygote nuclear envelope.     

A spiral cortical fiber system in fertilized sea urchin eggs

Fiber systems of fertilized eggs of the sea urchin Strongylocentrotus purpuratus become aggregated and thus visible in phase-contrast light microscopy, when cells are fixed in 2% glutaraldehyde in 0.45 M Na-acetate buffer at pH 6.0 and embedded in epoxy. Studies of whole mounts and of 1-μm stained sections of the first-division cycle revealed a spiral array of subcortical fibers that apparently grow inward from the cell surface shortly after sperm entry and disappear prior to streak stage. They are independent of the microtubule system associated with the sperm aster, amphiaster, and mitotic apparatus. Their chemical identity is not known, but they may very likely be actin.     

RGS14 is a mitotic spindle protein essential from the first division of the mammalian zygote

Heterotrimeric G protein alpha subunits, RGS proteins, and GoLoco motif proteins have been recently implicated in the control of mitotic spindle dynamics in C. elegans and D. melanogaster. Here we show that "regulator of G protein signaling-14" (RGS14) is expressed by the mouse embryonic genome immediately prior to the first mitosis, where it colocalizes with the anastral mitotic apparatus of the mouse zygote. Loss of Rgs14 expression in the mouse zygote results in cytofragmentation and failure to progress to the 2-cell stage. RGS14 is found in all tissues and segregates to the nucleus in interphase and to the mitotic spindle and centrioles during mitosis. Alteration of RGS14 levels in exponentially proliferating cells leads to cell growth arrest. Our results indicate that RGS14 is one of the earliest essential product of the mammalian embryonic genome yet described and has a general role in mitosis.     

Localization of gamma-tubulin and cyclin B during early cleavage in physiologically polyspermic newt eggs

To understand the mechanism of the very slow block to polyspermy in physiologically polyspermic eggs of the newt Cynops pyrrhogaster, we used confocal laser microscopy to determine the distribution of gamma-tubulin and cyclin B1 in fertilized eggs. More gamma-tubulin was localized in the animal hemisphere than in the vegetal. The centrosomes of the principal sperm nucleus and the zygote nucleus had much accumulated gamma-tubulin, but little gamma-tubulin was associated with the centrosomes of the accessory sperm nuclei. These results are consistent with observations that the largest sperm aster is associated with the principal sperm nucleus. More cyclin B1 appeared in the animal hemisphere than in the vegetal at the end of interphase. The zygote nucleus had much accumulated cyclin B1, but little cyclin B1 was associated with the accessory sperm nuclei. Cyclin B1 disappeared earlier around the zygote nucleus at metaphase than around the accessory sperm nuclei. These findings correspond well with the earlier entry and exit into metaphase in the zygote nucleus than in the accessory sperm nuclei in newt eggs, supporting our maturation-promoting factor (MPF) model that accounts for the mechanism of nuclear degeneration in physiologically polyspermic eggs. Cyclin B1 began to accumulate in the nucleus during interphase in synchronous cleavage, and its greatest expression was in the centrosomes and the nucleus at prometaphase.     

Early developmental processes in the fertilised honeybee (Apis mellifera) oocyte

The behaviour of sperm from egg penetration until creation of the zygote, the development of the maternal pronucleus, and the two first cleavage divisions were studied by use of fluorescence microscopy. It was found that 4-12 sperm penetrate the egg membranes prior to oviposition. Contrary to previous reports, we found that only 1-7 sperm move from their initial location just beneath the vitelline membrane and into the cytoplasm, where they develop into paternal pronuclei. At the time of oviposition, the oocyte nucleus was usually at the stage of metaphase I, rather than anaphase I as previously reported. At 26+/-2.5 minutes the meiotic process had entered the stage of metaphase II. The paternal and maternal pronuclei formed at 55+/-2.6 minutes, and they fused at 93+/-7.3 minutes. The mitotic division of the zygote was completed at 119+/-6.5 minutes.     

The cleavage plane will bend when one aster of the mitotic apparatus stops growing in compressed sea urchin eggs

Astral microtubules are elongated greatly during anaphase and telophase in sea urchin eggs. The surface density of microtubules reaching the cell surface can be defined at each surface point. Gradients of the surface-density function were assumed to drive membrane proteins whose accumulation causes the formation of contractile-ring microfilaments. An equation was constructed to calculate the movements of the membrane proteins on a curved surface. The equation was applied to eggs compressed between a coverslip and a glass slide by regarding the egg shape as an oblate spheroid. The simulations explained the observations that contractile-ring microfilaments locally appeared and then developed into a complete ring in compressed eggs. When one aster in the mitotic apparatus stopped growing during anaphase, the equation predicted that the zone of contractile-ring microfilaments is displaced toward the inactivated aster, curves in the view from above and tapers off toward the cell edge. The curve gets sharper as eggs are compressed more greatly and as microtubules from the growing aster penetrate more deeply into the opposite hemisphere. The predictions were compared with the observations by Ishii and Shimizu in 1995 and by Hamaguchi in 1998 regarding the furrow formation by the asymmetric mitotic apparatus.     

Microtubule arrays present during the syncytial and cellular blastoderm stages of the early Drosophila embryo

The organization of microtubules within the surface caps of Drosophila embryos is described for the mitotic cycles of the syncytial blastoderm stage (particularly cycle 10), and for the subsequent cellularization process. Tubulin was labelled with the well characterized monoclonal antibody YL 1/2 (Kilmartin et al., J cell biol 93 (1982) 576). Each surface cap was found to contain an array of microtubules running around the nucleus. The microtubules originated at prominent centrosomes located close to the apical surface of each cap nucleus. During mitosis the spindle microtubules stained strongly for tubulin. A novel finding was that the spindle microtubules of the interzone region appeared to reduce their connections with the centrosomes at the end of anaphase. The spindle remnant remained in position during telophase but then became smaller in size, disappearing by interphase. At this phase of the cell cycle duplication of the aster centrosomes occurred. The cellular blastoderm stage was marked by a change in the main axis of microtubule orientation. The centrosomes of each cap separated somewhat and formed initiation centres for the development of a well developed basket of microtubules around each nucleus, but now perpendicular to the surface. The microtubule baskets were seen to extend in parallel with nuclear elongation, but not in concert with growth of the cell membranes, which extended some way beneath the bases of the nuclei.     

Determination of first cleavage plane: the relationships between the orientation of the mitotic apparatus for first cleavage and the position of meiotic division-related structures in starfish eggs

In order to understand when the orientation of the first cleavage plane is fixed along the animal-vegetal axis in starfish eggs, the behavior of the sperm aster was examined by indirect immunofluorescence staining. After duplication, the sperm aster organizes the mitotic apparatus for first cleavage perpendicular to the cleavage plane. The sperm aster located in the egg periphery just after fertilization and moved to the site close to the animal pole rather than the egg center by meiosis II. At early metaphase II, duplication of the sperm aster was detected but the axis of the resultant sperm diaster randomly pointed. Subsequently, its axis had already turned perpendicular to the animal-vegetal axis before pronucleus fusion. These results indicate that the orientation processes of the sperm diaster consist of positioning before its duplication and successive determining its azimuth. Furthermore, the azimuth and position of the mitotic apparatus for first cleavage did not change by shifting or eliminating the meiotic division-related structures such as the germinal vesicle, meiotic spindle, and female pronucleus by micromanipulation. These results show that none of them determines the first cleavage plane. Therefore, we discuss the pointing mechanism of the first cleavage plane without the influence of these meiotic division-related structures.     

Difference between Maturation Division and Cleavage in Starfish Oocytes: Dependency of Induced Cytokinesis on the Size of the Aster as Revealed by Transplantation of the Centrosome

Using the starfish oocyte and zygote, we investigated the abilities of the centrosome at maturation and cleavage divisions to form the aster and induce cytokinesis, in order to determine differences between these divisions. The transplanted centrosome originated from both maturation and cleavage, induced an additional furrow in cleavage in the recipient cells, but did not induce abnormal polar body formation at maturation. Although it organized an additional aster in the recipient cell in both divisions, a difference in size among asters formed was recognized. Therefore, mitotic asters were stabilized with hexylene glycol in order to measure their radius and clarify this difference. The mean radius (14.4 μm) of the first meiotic aster was significantly smaller than that (20.4 μm) of the aster at the first cleavage. The transplanted cleavage centrosome formed as small an aster as the recipient's own at maturation divisions. When zygotes were briefly treated with colcemid so that the zygotes could not perform cytokinesis but did perform karyokinesis, the size of aster became the same as that in meiosis. These results prove that although any centrosome functions as a microtubule organizing center independent of its origin, the size of the resultant aster decides whether or not cytokinesis would be induced.     

Asymmetry in the Mitotic Spindle Induced by the Attachment to the Cell Surface during Maturation in the Starfish Oocyte

In order to study the dynamic behavior of the mitotic apparatus leading to unequal cleavage, we investigated the distribution of mitotic microtubules (MTs) during maturation division of starfish oocytes. When the mitotic apparatus attached to the cell surface at metaphase, in both the first and second meiotic division, it is revealed, by immunofluorescence, that the MT distribution in the spindle, as well as in the aster, became asymmetric. MTs in the peripheral half spindle increased in number compared with those in the inner half spindle. Furthermore, these results were confirmed in the living cell by polarization microscopy; shortly after the attachment, the birefringence retardation of the peripheral half spindle became greater than that of the inner one, and the difference increased with time during anaphase. By inhibiting the attachment of the mitotic apparatus by means of centrifugation, the MT distribution maintained a symmetrical pattern through mitosis. These results suggest that the attachment of the mitotic apparatus to the cell surface induces the asymmetrical distribution of MTs not only in the aster but also in the spindle. Such a rich distribution of MTs in the peripheral half spindle appears to ensure chromosome exclusion into the polar body by anchoring them firmly to the cell surface of the animal pole.     

The vesicular compartment of the mitotic apparatus in mammalian cells

Intracellular membranes might play an eminent role in regulating several events during mitosis: In this paper the appearance and changing configurations of the vesicular compartment of the mitotic apparatus of HeLa cells was studied from anaphase to telophase. In early prophase electron opaque and transparent membranous vesicles are found in the pericentriolar region outside the nucleus. During prometaphase when the nuclear envelope opens and starts to disappear, an increasing number of these vesicles appears in the mitotic apparatus near the chromosomes. During metaphase vesicles are spread all over the mitotic apparatus, the number of electron opaque vesicles decreases while the total amount of vesicles does not change significantly. Anaphase shows the same pattern of distribution in the half-spindle and in the midbody. In telophase the amount of electron opaque vesicles increases again. They are now found around vacuoles and near the newly appearing Golgi-cisternae. We assume that the electron opaque vesicles are derived from the Golgi- apparatus which disintegrates during prophase and reappears in late telophase. The change in the appearance of the different types of vesicles during metaphase coincides with drastic changes in the ionic milieu in the mitotic apparatus (Wolniak et al., 1983).     

Life Cycle of the pseudocolonial dinoflagellate Polykrikos kofoidii (Gymnodiniales,Dinoflagellata)

The athecate, pseudocolonial polykrikoid dinoflag‐ellates show a greater morphological complexity than many other dinoflagellate cells and contain not only elaborate extrusomes but sulci, cinguli, flagellar pairs, and nuclei in multiple copies. Among polykrikoids, Polykrikos kofoidii is a common species that plays an important role as a grazer of toxic planktonic algae but whose life cycle is poorly known. In this study, the main life cycle stages of P. kofoidii were examined and documented for the first time. The formation of gametes, 2‐zooid‐1‐nucleus stages very different from vegetative cells, was observed and the process of gamete fusion, isogamy, was recorded. Karyogamy followed shortly after completed plasmogamy. A complex reorganization of furrows (cinguli and sulci) and flagella followed zygote formation, resulting in a 4‐zooid zygote with one nucleus. The fate of zygotes under different nutritional conditions was also investigated; well‐fed zygotes were able to reenter the vegetative cycle via meiotic divisions as indicated by nuclear cyclosis. However, nuclear cyclosis was preceded by a presumably mitotic division of the primary zygote nucleus which by definition would imply that P. kofoidii has a diplohaplontic life cycle. Nuclear cyclosis in germlings hatched from spiny resting cysts indicate that these cysts are of zygote origin (hypnozygotes). Hypnozygote formation, cyst hatching, the morphology of the germling (a 1‐zooid cell), and its development into a normal pseudocolony are documented here for the first time. There is evidence that P. kofoidii has a system of complex heterothallism.