Induced formation of asters and cleavage furrows in oocytes of Xenopus laevis during in vitro maturation

We have previously reported that injection of purified basal bodies or sperm into unfertilized eggs of Xenopus laevis induced the formation of asters and irregular cleavage furrows. Fully grown oocytes were found to be unable to form asters or cleavage furrows. In this paper we show that the oocyte acquires the ability to form asters upon basal body injection at the time of germinal vesicle breakdown during in vitro maturation. Our evidence indicates that aster formation requires progesterone-stimulated changes in the oocyte and mixing of cytoplasm and germinal vesicle plasm. The ability of the oocyte to form cleavage furrows arises six to eight hours after germinal vesicle breakdown. We infer that some maturational change in the cell cortex occurs to enable the egg surface to furrow. Experiments on the relationship of aster formation to furrow initiation indicates that asters stimulate furrow formation. However, some furrowing could be induced without aster formation in mature oocytes and unfertilized eggs by an activation stimulus, showing that asters are not essential for cleavage initiation. The significance of these observations are discussed in the light of our current understanding of meiotic maturation, cell cleavage and aster growth.     

The role of calcium, polyamines and centrosomes in the formation and organization of cleavage furrows in amphibian eggs.

Cleavage furrows of amphibian eggs exhibit characteristic morphological features: the presence of finger-like microvilli (MV) along their outer edges, the formation of furrow walls from new plasma membrane lacking MV, and the subsequent retrieval of this membrane during the infolding of the furrow. A similar structure can be induced, specifically, by certain cytoplasmic components such as centrosomes, polyamines and calcium. Their respective roles in the events associated with the furrowing process have been investigated by injecting these agents into nucleated and enucleated Pleurodeles eggs and evaluating their effects using cytochemical labelling of the egg surface with a biotin-streptavidin system. The injection of polyamines (spermine or spermidine) and in some cases, calcium into enucleated eggs provoked MV elongation and the appearance of newly formed, smooth plasma membrane. In these eggs, this membrane was not incorporated into the furrows, and as a consequence, the blastomeres did not actually separate. In contrast, the injection of centrosomes into enucleated eggs induced both the incorporation and internalization of new membrane, resulting in the formation of furrows and a true cellularization of the eggs, identical to the cleavage process observed in fertilized eggs. The present results provide further evidence that the establishment of the furrow depends on two complementary interacting systems: the contractile elements of the egg cortex which regulate the insertion of new membrane and the mitotic center which is essential for the invagination of the furrow.     

Cytological and biochemical analyses of the maternal-effect mutant embryos with abnormal cleavage furrow formation in Xenopus laevis

We describe an embryonic lethal mutation in Xenopus laevis that provokes regression of cleavage furrow formation. The mutant females (designated as af) were obtained by the back-cross of a female with one of her sons. All the fertilized eggs laid by the mutant females, regardless of the wild-type male used in the mating, failed to cleave although each furrow ran at a proper position superficially. Light and electron microscopic observations of the embryos revealed that the cleavage furrows stayed on the surface and cytoplasmic divisions did not take place at all, while nuclear divisions did. Two-dimensional gel-electrophoretic comparisons of af and wild-type embryos demonstrated that two proteins, having estimated molecular masses of about 38 kDa (pI 6.6) and 78 kDa (pI 7.6), were missing in af embryos. Microinjection of clear cytoplasm from a wild-type egg into fertilized af eggs provoked partial surface contraction and cleavage furrow formation in recipient af eggs. The results showed that the af females carry a lethal maternal-effect mutation which causes cleavage furrow regression by being deficient in a few proteins, and that cytoplasm of wild-type eggs can partially rescue the cleavage furrow formation of af eggs by furnishing the corrective material, presumably a product of the normal allele of af.     

Why does a cleavage plane develop parallel to the spindle axis in conical sand dollar eggs? A key question for clarifying the mechanism of contractile ring positioning

Three types of models have been proposed about how the mitotic apparatus determines the position of the cleavage furrow in animal cells. In the first and second types, the contractile ring appears in a cortical region that least and most astral microtubules reach, respectively. The third type is that the spindle midzone positions the contractile ring. In the previous study, a new model was proposed through analyses of cytokinesis in sand dollar and sea urchin eggs. Gradients of the surface density of microtubule plus ends are assumed to drive membrane proteins whose accumulation causes the formation of contractile-ring microfilaments. In the present study, the validity of each model is examined by simulating the furrow formation in conical sand dollar eggs with the mitotic apparatus oriented perpendicular to the cone axis. The new model predicts that unilateral furrows with cleavage planes roughly parallel to the spindle axis appear between the mitotic apparatus and the vertex besides the normally positioned furrow. The predictions are consistent with the observations by Rappaport & Rappaport (1994, Dev. Biol.164, 258-266). The other three types of models do not predict the formation of the ectopic furrows. Furthermore, it is pointed out that only the new model has the ability to explain the geometrical relationship between the mitotic apparatus and the contractile ring under various experimental conditions. These results strongly suggest the real existence of the membrane proteins postulated in the model.     

Furrowing in altered cell surfaces.

Understanding the process which established the cell division mechanism requires analysis of the role of the responding surface as well as that of stimulatory subsurface structures. Cell surface was altered by the expansion which occurs during exovate formation. Exovates appear on the surface of fertilized Arbacia lixula, Paracentrotus lividus and Echinarachnius parma eggs in response to extreme flattening. They result from cytoplasmic outflow initiated in a very restricted portion of the egg surface. Observations of the formation process in pigmented A. lixula eggs revealed that the original surface may be expanded about 100 fold as the exovate swells. When exovates formed 15-30 minutes after fertilization contain the mitotic apparatus, they divide synchronously with flattened controls. If nucleated exovates are established after the beginning of first cleavage, furrows appear in ten minutes. Exovates established after the beginning of second cleavage develop furrows four minutes after the entrance of the the mitsotic apparatus. Cytoplasm beneath damaged exovate surfaces sometimes develops partial constrictions independently of the surface in the plane the furrow would have occupied. These results suggest that normal surface structure is unnecessary for furrow establishment and function.     

Polarization of the Surface Membrane and Cortical Layer of Sea Urchin Blastomeres, and its Inhibition by Cytochalasin B

Sea-urchin blastomeres have two domains of the plasma membrane which can be distinguished immunocytochemically. An egg-surface antibody (anti-ES), which binds to the membrane of the entire surface region of eggs before cleavage, binds to the membrane of the outer surface region of blastomeres after cleavage, but not to that of the cleavage furrow region or interblastomeric surface region.
The anti-ES binding sites on the egg membrane were chased after cleavage by labeling the egg plasma membrane with FITC conjugated monovalent anti-ES (FITC-Fab anti-ES) before the first cleavage, and then allowing the eggs to cleave. The surface fluorescence increased in intensity in the cleavage furrow region with progress of furrowing, but after completion of the furrowing, the fluorescence became uniform and finally decreased in the interblastomeric surface region.
The distributions of pigment granules and NBD-phallacidin stainable microfilaments in the cortex after completion of furrowing were polarized in the same way as the anti-ES binding area. As cytochalasin B completely inhibited the polarization in both the surface and cortical layer but colchicine did not, polarization of the anti-ES binding area was concluded to be due to the post-cleavage polarized distribution of submembranous microfilaments in the cortical layer.     

Regional Difference in Mechanical Properties of the Cell Surface in Dividing Echinoderm Eggs*

Stiffness of the cell was surface was determined in fertilized sea urchin and starfish eggs by measuring the mechanical resistivity of the cell surface against negative pressure applied to a restricted part with a micropipette in contact with the cell surface at its tip (elastimetry). In both sea urchin and starfish eggs, the stiffness of the cell surface changed almost in parallel between the presumptive furrow and polar surfaces before the onset of the first cleavage, and the stiffness of the furrow surface became larger than that of the polar surface when cleavage started, although temporal changes in the stiffness were different between sea urchin and starfish eggs. The stiffness of the cell surface changed almost in parallel between the surfaces at the equator and at the animal pole in starfish eggs before the onset of polar body formation. The stiffness of the cell surface around the forming polar body increased during the formation of the polar body and remained at a high level after the polar body formation. It seems that the stiffness difference responsible for the formation of the contractile ring develops simultaneously with rather than prior to the formation of the cleavage furrow.     

Mitotic apparatus-surface interaction and cell division

Summary

Results of recent investigations concerning the mechanisms of animal cell division are reviewed. The mitotic apparatus was aspirated from a blastomere of a sand dollar (Echinarachnius parma) egg before second cleavage, and the time interval between removal and the appearance of the furrow in the control companion blastomere was measured. When the mitotic apparatus is removed 4 min or less before the furrows appear in the controls, furrows also develop in the operated cells. These results show that 4 min before furrowing begins, the surface changes which lead to formation of the division mechanism have become irreversible. When the mitotic apparatus of a cylindrical cell is shifted by pushing in one of the poles when the furrow appears, a new furrow develops in association with the new position of the mitotic apparatus. The same mitotic apparatus could elicit as many as 13 furrows over a 24.5 min period following the appearance of the first furrow. The results show that, in the proper geometrical circumstances, the mitotic apparatus and the surface can interact over a longer period than they do in normal cells.

By artificially constricting sand dollar eggs with a glass loop, the normal distance relations between the astral centers and the polar and equatorial surfaces can be reversed. Constricted cells cleave normally. The blocking effect of ethyl urethane can be reversed by moving the equatorial surface closer to the spindle portion of the mitotic apparatus. Relocation of other parts of the surface closer to the mitotic apparatus was ineffective. These results help elucidate the geometrical relations that are essential for furrow formation between the mitotic apparatus and the surface.

In cylindrical sand dollar eggs, single asters and the widely separated asters of a broken mitotic apparatus can cause furrow-like constrictions in the adjacent cylindrical surface. This reaction can be blocked by treating cells with ethyl urethane, which reduces astral size. The nature of the shape change that the aster causes depends upon the surface region affected. These results aid in understanding the nature of the change in surface physical activity caused by the mitotic apparatus.     

Evidences for direct involvement of microtubules in cleavage furrow formation in newt eggs

This paper aims at examining the effect of colchicine, a microtubular poison, on the process of furrow formation in whole eggs and egg fragments as well as the process of artificial induction of furrow-like dents, in eggs of the newt, Cynops pyrrhogaster. To apply colchicine locally to eggs, the eggs were slit across or along a furrow in a colchicine solution during first cleavage. When a slit was made across or in front of a growing furrow at the onset of its growth, the furrow quickly ceased growing and often regressed. Cortices containing an entire growing furrow were isolated along with a thin layer of subcortical cytoplasm immediately after the start of the first cleavage. Furrows in the cortices degenerated when the cortices were cultured in a colchicine solution, whereas they continued growing when they were cultured in Holtfreter's saline. Furrow-inducing cytoplasm was injected to a site beneath the cortex in the animal half of the egg during first cleavage. When a small slit was made close to the site of the injection in a colchicine solution, no furrow-like dent was induced. These results imply that microtubules are directly involved in the generation and growth of cleavage furrows.     

Effect of Microtubular Poisons on Cleavage Furrow Formation and Induction of Furrow-like Dent in Amphibian Eggs

The effects of the microtubular poisons colchicine, vinblastine and nocodazole, on cleavage furrow formation and induction of furrow-like dents in eggs of the newt, Cynops pyrrhogaster , were examined.
Solutions of the poisons were injected beneath the cortex around the small initial furrow, or around the advancing tip of the furrow of eggs during the first cleavage. This resulted in prompt block of the progress of the furrow at the injection site, and subsequent total regression of the furrow or incomplete cleavage.
The ability of the cortex of a cleavage-arrested blastomere to form a furrow-like dent was tested by inhibiting furrow formation of one blastomere of two-cell embryos by injection of the microtubular poisons, and then transplantation of the blastomere under the cortex of the animal half with furrow-inducing cytoplasm (FIC) taken from normally cleaving eggs. No dent was formed. Moreover, FIC from eggs treated with a poison had no ability to induce a dent on the surface of normally cleaving eggs.
These results show that microtubule structures are directly involved in formation of a cleavage furrow.     

Microinjection of Ca2+ store-enriched microsome fractions to dividing newt eggs induces extra-cleavage furrows via inositol 1,4,5-trisphosphate-induced Ca2+ release.

The cleavage signal transferred to the future cleavage cortex during anaphase has been proposed as "cleavage stimulus," but no signal has proved to induce cleavage furrows. The local Ca2+ transient along the cleavage furrow has been reported, but the Ca2+ source has remained unknown. To address these questions, we studied functions of Ca2+ stores in dividing newt eggs and found that microinjection of the Ca2+ store-enriched microsome fraction to the dividing newt egg induced a local extra-cleavage furrow at the injection site in 64-67% of the injected newt eggs while coinjection with inositol 1,4, 5-trisphosphate receptor (IP(3)R) antagonists heparin or anti-type 1-IP(3)R antibody clearly suppressed this induction (5 and 11% in induction rates, respectively). Injection of cerebellar microsomes from the type 1-IP(3)R-deficient mice induced extracleavage furrows albeit at a low rate (19%). Our observations strongly suggest that Ca2+ stores with IP(3)R induce and position a cleavage furrow via IP(3)-induced Ca2+ release (IICR) as Ca(2+)-releasing machinery and putative cleavage stimulus itself.     

Calcium waves along the cleavage furrows in cleavage-stage Xenopus embryos and its inhibition by heparin

Calcium signaling is known to be associated with cytokinesis; however, the detailed spatio-temporal pattern of calcium dynamics has remained unclear. We have studied changes of intracellular free calcium in cleavage-stage Xenopus embryos using fluorescent calcium indicator dyes, mainly Calcium Green-1. Cleavage formation was followed by calcium transients that localized to cleavage furrows and propagated along the furrows as calcium waves. The calcium transients at the cleavage furrows were observed at each cleavage furrow at least until blastula stage. The velocity of the calcium waves at the first cleavage furrow was approximately 3 microns/s, which was much slower than that associated with fertilization/egg activation. These calcium waves traveled only along the cleavage furrows and not in the direction orthogonal to the furrows. These observations imply that there exists an intracellular calcium-releasing activity specifically associated with cleavage furrows. The calcium waves occurred in the absence of extracellular calcium and were inhibited in embryos injected with heparin an inositol 1,4,5-trisphosphate (InsP3) receptor antagonist. These results suggest that InsP3 receptor-mediated calcium mobilization plays an essential role in calcium wave formation at the cleavage furrows.     

Simulation of the mechanism of determining the position of the cleavage furrow in cytokinesis of sea urchin eggs

In cytokinesis of sea urchin eggs, the numerical density of astral microtubules extending close to the cell surface has been thought to determine the position of the cleavage furrow. In the present study, a new model was constructed to simulate the relationship between the microtubule density and the furrow formation. In the model, gradients of the microtubule density drive fluid membrane proteins whose accumulation triggers the formation of contractile-ring microfilaments. The model could explain the behavior of the cleavage furrow under various experimental conditions. These simulations revealed two aspects of furrow formation. One is that in some cases, the cleavage furrow appears in a surface region where the microtubule density has neither a minimum nor a maximum. In all furrow regions, however, the second derivative of the microtubule-density function has large positive values. Membrane proteins greatly slow down to accumulate in such a region. The other is that the cleavage furrow is mobile, not fixed in one position, because of the fluidity of membrane proteins. These results strongly suggested that the mitotic apparatus determines the position of the cleavage furrow by redistributing membrane proteins through gradients of the microtubule density at the cell surface.     

Localized calcium signals along the cleavage furrow of the Xenopus egg are not involved in cytokinesis

It has been proposed that a localized calcium (Ca) signal at the growing end of the cleavage furrow triggers cleavage furrow formation in large eggs. We have examined the possible role of a Ca signal in cleavage furrow formation in the Xenopus laevis egg during the first cleavage. We were able to detect two kinds of Ca waves along the cleavage furrow. However, the Ca waves appeared after cleavage furrow formation in late stages of the first cleavage. In addition, cleavage was not affected by injection of dibromoBAPTA or EGTA into the eggs at a concentration sufficient to suppress the Ca waves. Furthermore, even smaller classes of Ca release such as Ca puffs and Ca blips do not occur at the growing end of the cleavage furrow. These observations demonstrate that localized Ca signals in the cleavage furrow are not involved in cytokinesis. The two Ca waves have unique characteristics. The first wave propagates only in the region of newly inserted membrane along the cleavage furrow. On the other hand, the second wave propagates along the border of new and old membranes, suggesting that this wave might be involved in adhesion between two blastomeres.     

Formation of new plasma membrane during the first cleavage cycle in the egg of Xenopus laevis: An immunocytological study

Polyclonal antibodies (IS1) reacting specifically with plasma membrane proteins of the Xenopus oocyte were used to study the formation of new plasma membrane in cleavage furrows. Membrane precursors were detected in the inner cytoplasm, then under the plasma membrane of the animal hemisphere and finally on the furrow's edges. Cycloheximide and colchicine caused abnormal distribution of stained material. IS1 antibodies conjugated to colloidal gold, were used to examine the local insertion of membrane precursors into the furrow region by electron microscopy. Membrane precursors were only detected in intracytoplasmic vesicles that fused with the plasma membrane at the edges of the furrow walls. Arrays of microtubules may guide membrane precursors to the site of their insertion in the furrow walls.     

Holoblastic early cleavage of Tetrodontophora bielanensis (Collembola) eggs, with special reference to its irregularity.

The fertilized eggs of Tetrodontophora bielanensis start to cleave 6 to 8 days after oviposition and initially only karyokineses occur. The cytokinesis begins after two karyokineses, when four nuclei are observed in the ooplasm. Two cleavage furrows, perpendicular to each other, appear simultaneously at the egg poles where polar bodies are located and gradually the furrows encompass the whole egg diameter. The furrow formation is initiated by the bundle of microfilaments that contract and pull superficial fragments of the oolemma into the yolk and subsequently new membranes, separating the daughter cells, start to form. However, they do not grow towards the egg centre but bifurcate, leaving the central part of the ooplasm outside of the newly formed blastomeres. Starting from the fourth or fifth cleavage division, the bifurcations permanently occur and multiple cleavage furrows are formed on the embryo surface. Moreover, fragments of the ooplasm, enclosed within the cell membrane but devoid of cell nucleus are observed. During further development such cell fragments become reincorporated into the embryo. This mode of cleavage leads eventually to the formation of cellular blastoderm on the embryo surface. The results presented in the paper suggest that the control of cleavage in T. bielanensis acts not at the level of cytoplasmic determinants but rather at the level of positional information of blastomeres.     

Vesicles and actin are targeted to the cleavage furrow via furrow microtubules and the central spindle

During cytokinesis, cleavage furrow invagination requires an actomyosin-based contractile ring and addition of new membrane. Little is known about how this actin and membrane traffic to the cleavage furrow. We address this through live analysis of fluorescently tagged vesicles in postcellularized Drosophila melanogaster embryos. We find that during cytokinesis, F-actin and membrane are targeted as a unit to invaginating furrows through formation of F-actin-associated vesicles. F-actin puncta strongly colocalize with endosomal, but not Golgi-derived, vesicles. These vesicles are recruited to the cleavage furrow along the central spindle and a distinct population of microtubules (MTs) in contact with the leading furrow edge (furrow MTs). We find that Rho-specific guanine nucleotide exchange factor mutants, pebble (pbl), severely disrupt this F-actin-associated vesicle transport. These transport defects are a consequence of the pbl mutants' inability to properly form furrow MTs and the central spindle. Transport of F-actin-associated vesicles on furrow MTs and the central spindle is thus an important mechanism by which actin and membrane are delivered to the cleavage furrow.     

Cytokinesis without myosin II

The ability of substrate-anchored Dictyostelium cells to divide without myosin II has opened the possibility of analysing the formation of cleavage furrows in the absence of a contractile ring made of filamentous myosin and actin. Similar possibilities exist in mutants of budding yeast and, less strictly, also in drug-treated mammalian cells. Myosin-II-independent activities in Dictyostelium include the microtubule-induced programming of the cell surface into ruffling areas and regions that are converted into a concave furrow, as well as the translocation of cortexillins and cross-linked membrane proteins towards the cleavage furrow. A centripetal flow of actin filaments followed by their disassembly in the cleavage furrow is proposed to underlie the translocation.     

Unequal first cleavage in the Tubifex egg: involvement of a monastral mitotic apparatus

The first cleavage in the freshwater oligochaete Tubifex hattai is unequal and meridional, and produces a smaller cell AB and a larger cell CD. This study traces the process of furrow formation, reorganization of cortical F-actin and the assembly of a mitotic apparatus during this unequal division. Cleavage furrow formation consists of two stages: (i) when eggs are viewed from the animal pole, meridionally running furrows emerge at two points of the egg's equator that are 90° apart from each other and approach the egg axis as they deepen; and (ii) at the midpoint between the equator and the egg center, the bottoms of these furrows link to each other on the animal and vegetal surfaces of the egg and form a continuous ring of constriction in a plane parallel to the egg axis. Egg cortices, isolated during the first step and stained with rhodamine-phalloidin, show that the bottoms of recently formed furrows are underlaid by a belt of tightly packed actin bundles (i.e. a contractile arc). The transition to the second stage of furrow formation coincides with the conversion of these actin belts into a continuous ring of F-actin. Whole-mount immunocytochemistry of microtubules reveals that the first cleavage in Tubifex involves an asymmetric mitotic spindle, which initially possesses an aster at one pole but not the other. This ‘monastral’ spindle is located at the egg's center and orients itself perpendicular to the egg axis. During anaphase, astral rays elongate to reach the cell surface, so that the array of astral microtubules in the plane of the egg's equator covers a sector of 270–300°. In contrast, it is not until the transition to telophase that microtubules emanating from the anastral spindle pole approach the cell margin. If eggs are compressed along the egg axis or forced to elongate, they form monastral spindles and divide unequally. In living compressed eggs, mitotic spindles, which are recognizable as bright streaks at the egg's center, appear not to shift their position along the spindle axis during division, suggesting that without eccentric migration of spindles Tubifex eggs are able to divide unequally. These results suggest that mechanisms that translocate the mitotic spindle eccentrically do not operate in Tubifex eggs during the first cell cycle. The mechanisms that generate asymmetry in spindle organization are discussed in the light of the present results.     

Cleavage and blastoderm formation in normal and experimentally deformed naked eggs of a dipteran insect

Summary The eggs of the gall midgeHeteropeza pygmaea develop parthenogenetically inside of the mother larva. They lack a chorion and remain enveloped by the follicular epithelium. After experimental elimination of the follicular epithelium naked eggs are formed, which reach the blastoderm stage but remain spherical instead of assuming an elongated shape. To analyze this peculiar egg development and the roles of egg shape and envelope during development, the ultrastructure of cleaving normal and naked eggs was investigated. It was shown that the number of elements of Golgi apparatus and endoplasmic reticulum strongly increases during early cleavage. Their association with cleavage furrows and nuclei suggests that these organelles play a dominant role in membrane production. Egg yolk consists of lipids and glycogen, wheareas no proteins are found. Cleaving eggs contain numerous vesicles with lysosomal characteristics, indicating intense autophagic processes. Cleavage furrow formation occurs independently from the positioning of cleavage nuclei. The numerous microtubules, which are associated with cleavage furrows and nuclei and located in the egg periphery, the intercellular bridges, and in the central part of the egg, suggest that the cytoskeleton has an important role in cleavage furrow formation, blastoderm layer establishment, and yolk localization. Since these processes are accurately accomplished in naked spherical eggs, they can be considered as independent of normal egg shape and the follicular epithelium.