Determination of the First Two Cleavage Furrows in Developing Eggs of Triturus Alpestris Compared with Other Forms

Eggs of Triturus alpestris were horizontally compressed at times before first and second cleavage in an experiment designed to measure the time at which the mitotic apparatus determines the direction of the subsequent cleavage furrow. The results showed that furrow determination was completed 0.46 Dettlaff units before the onset of furrowing. When a comparison was made of the times of furrow determination before cleavage in eggs of different animal groups using Dettlaff units, the results supported the idea that preparations for furrowing proceed differently in echinoderm eggs from eggs of sturgeon and amphibia.     

The fate of DNA originally existing in the zygote nucleus during achromosomal cleavage of fertilized echinoderm eggs in the presence of aphidicolin: microscopic studies with anti-DNA antibody

In fertilized echinoderm eggs, the male and female pronuclei fuse to form the diploid nucleus even in the presence of aphidicolin, a specific inhibitor of eukaryotic DNA polymerase-alpha. The subsequent first cleavage is independent of chromosomes but dependent on spindle and amphiaster. The fate of DNA originally existing in the fused nucleus during achromosomal cleavage of fertilized sea urchin and starfish eggs induced by aphidicolin was determined using antidenatured DNA antibody. The nucleus is not formed in the divided daughter cells at the two-cell stage but the nuclear-envelope-free chromatin mass which is unassociated with mitotic apparatus remains in the center region of embryos, especially near the first cleavage furrow. These results indicate that the condensed and nonreplicated chromatin can not be associated with spindle and asters in the presence of aphidicolin.     

AN INDIRECT METHOD TO ASSAY FOR MITOTIC CENTERS IN SAND DOLLAR (DENDRASTER EXCENTRICUS) EGGS

It is possible consistently to induce sea urchin and sand dollar eggs to cleave directly from one cell into four cells. This is done by exposing the fertilized eggs to benzimidazole for 20 to 30 min beginning about early metaphase. The mitotic apparatus regresses, the cells do not cleave, and shortly after they are returned to normal sea water an early-prophase-appearing nucleus is present in each cell. Each cell then organizes a tetrapolar tetrahedral mitotic apparatus de novo, instead of transforming a bipolar mitotic apparatus into a tetrapolar figure, and cleaves one-to-four. In another type of experiment, it appears that sand dollar eggs exposed to mercaptoethanol during the first period of mitotic center duplication have only half as many centers by first cleavage metaphase as the normal controls. This is consistent with an earlier report by Mazia et al (1960). Using this same experimental technique, it was demonstrated that benzimidazole, on the contrary, does not interfere with mitotic center duplication in sand dollar eggs. A labeling experiment demonstrated that benzimidazole does not interfere markedly with the normal pattern of incorporation of C¹⁴-thymidine into the DNA of sea urchin eggs. The data reported here suggest that judicious treatment of sand dollar eggs (and probably sea urchin eggs, too) with benzimidazole can induce the eggs to cleave into as many cells as there were mitotic centers sometime earlier, for example at early metaphase of the first cleavage division. This provides a very useful tool for studies on the process of mitotic center duplication.     

Identification of molecular components of the centrosphere in the mitotic spindle of sea urchin eggs

Monoclonal antibodies were prepared to identify molecular components specific to the mitotic apparatus of sea urchin eggs. The mitotic apparatus or asters induced within unfertilized eggs by taxol treatment were isolated from Strongylocentrotus purpuratus and used for immunization of mice. After fusion with spleen cells, the supernatant of hybridomas were screened in two stages by indirect immunofluorescence staining, first on isolated sea urchin mitotic spindles in 96-well microtiter plates to identify rapidly potential positive hybridomas, and second, on whole mitotic eggs on coverslips to distinguish between spindle-specific staining and adventitious contamination. Two hybridomas, SU4 and SU5, secreted antibodies reactive to microtubule-containing structures in eggs during the course of development. They preferentially stained the centrosphere both in isolated mitotic apparatus and in whole metaphase eggs, which was further confirmed by staining the isolated centrospheres with these antibodies. SU4 recognized a major 190-kD polypeptide on immunoblots as well as a species at 180 and 20 kD, whereas hybridoma SU5 stained a species at 50 kD. Thus, these polypeptides may be components of the centrosphere.     

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.     

Localization of tropomyosin in sea urchin eggs

Localization of tropomyosin in sea urchin eggs was investigated immunohistochemically. A rabbit antiserum against tropomyosin prepared from lantern muscle of the sea urchin was used for the indirect immunofluorescence staining of unfertilized and fertilized eggs. The tropomyosin-specific fluorescence was observed at the peripheral region beneath the plasma membrane, mitotic apparatus and contractile ring. The mitotic apparatus isolated from sea urchin eggs was also stained with the anti-tropomyosin serum.     

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.     

IMMUNOCHEMICAL STUDIES OF 22S PROTEIN FROM ISOLATED MITOTIC APPARATUS

Evidence is presented that the "22S protein" of mitotic apparatus isolated from sea urchin eggs is not microtubule protein. An antibody preparation active against 22S protein is described, and immunochemical studies of the distribution of 22S protein in various cellular fractions and among morphological features of mitotic apparatus are reported. The protein is ubiquitous in the metaphase egg fractions that were tested but is not found in sperm flagella. It is immunologically distinct from proposed microtubule protein isolated from mitotic apparatus by the method of Sakai, and from proposed microtubule protein obtained after extraction with mild acid. It exists in nontubule material of isolated mitotic apparatus but is not detectable in microtubules.     

Repeated furrow formation from a single mitotic apparatus in cylindrical sand dollar eggs

The methods used previously to demonstrate the ability of a single mitotic apparatus to elicit multiple furrows involved considerable cell distortion and did not permit the investigator to control the positioning of the parts or to observe satisfactorily the early stages of furrow development. In this investigation, Echinarachnius parma eggs were confined in 82 microns i.d. transparent, silicone rubber-walled capillaries, and the mitotic apparatus was moved by pushing the poles inward with 55-microns-diameter glass balls. When the mitotic apparatus was shifted immediately after the furrow first appeared, a new furrow appeared in the normal relation to the new position in 1-2 minutes. The same mitotic apparatus could elicit up to 13 furrows as it was shifted back and forth by alternately pushing in the poles. The previous furrow regressed as the new furrow developed. The operations protracted the furrow establishment period to as long as 24.5 minutes after establishment of the first furrow. The characteristics of furrow regression were related to the distance the mitotic apparatus was moved. It is unlikely that regression was caused either by stress imposed on the surface or the removal of the mitotic apparatus from the vicinity of the furrow.     

FURTHER STUDIES ON CELL DIVISION WITHOUT MITOTIC APPARATUS IN SEA URCHIN EGGS

A large quantity of paraffin oil, sucrose solution, or sea water was injected into the eggs of the heart urchin Clypeaster japonicus shortly before the onset of the first cleavage. The injected oil became spherical, pushing the mitotic apparatus aside. The sucrose solution mixed with the protoplasm and caused disintegration of the mitotic apparatus, and the sea water formed a vacuole at the center of the cell. In all these cases, cleavage may take place almost normally in spite of the absence of the mitotic apparatus or its displacement within the cell. In some eggs, furrowing may take place when more than fifty per cent of the endoplasm has been replaced with sea water before onset of cleavage.     

The Mitotic Apparatus with Unusually Many Microtubules from Sea Urchin Eggs Treated by Hexyleneglycol

The effect of hexyleneglycol on the structure of the mitotic apparatus was studied by light and electron microscopies. By treating sea urchin eggs at prometaphase and metaphase with hexyleneglycol, the mitotic apparatus was found to become remarkably decorated with unusually many astral microtubules which were conspicuously uniform in length. These microtubules appeared to be associated with the granular materials which are most likely microtubule initiating sites or microtubule-organizing centers.     

Mitotic Asters Separate, although Chromosomes Do Not Separate at Slightly Acidic pHi in the Fertilized Egg of the Sea Urchin, Hemicentrotus pulcherrimus

The effect of slightly acidic intracellular pH (pHi) on the development of the sea urchin, Hemicentrotus pulcherrimus was investigated. At first cleavage, the fertilized eggs were treated with artificial sea water containing sodium acetate (Ac-pHSW) at pH 6.8 or 7.0 at the onset of nuclear envelope breakdown, and their pHi decreased from 7.30 to 6.68 or 6.78, respectively. When the eggs were observed after fixation by indirect immunofluorescence and differential interference contrast microscopy, the mitotic stage of the treated eggs was arrested at metaphase and the mitotic apparatus was maintained until more than 50 min after the treatment, although it was smaller in size than that of non-treated eggs. On the other hand, the number of the mitotic asters increased from 2 to 3-4, and further to 6-8 following prolonged exposure, suggesting that the centrosomes had divided and replicated. These results suggest that the centrosome cycle advanced at slightly acidic pHi, even when the mitotic cycle did not advance beyond metaphase.     

Cleavage furrow establishment by the moving mitotic apparatus

The midpoint of the mitotic apparatus is fixed in the future division plane long before the division mechanism develops, and this static relationship has been considered essential in speculations concerning division mechanism establishment. The purpose of the present investigation was to determine whether prevention of the static relationship affects the establishment process. Sand dollar eggs were reshaped into cylinders by confinement in an elastic capillary tube and, beginning about 20 min before cleavage, the mitotic apparatus was kept in reciprocal motion by alternately compressing the poles. When the movement was continuous and the excursions were 25, 50 or 75 μm, furrow activity developed near the midpoint of the region underlain by the mitotic apparatus. The acuteness of the furrow decreased as the distance the mitotic apparatus was moved increased. When the movement was made discontinuous by allowing the mitotic apparatus to pause at the end of each excursion, the results depended upon the duration of the pause. Pauses 30 s long resulted in a single furrow formed in the midpoint of the entire region underlain by the mitotic apparatus. When the pauses were 45s long, furrowing activity developed in both regions where the mitotic apparatus was allowed to pause. The results indicated that the normal static relation between the mitotic apparatus midpoint and the division plane is unnecessary for division mechanism establishment. They also demonstrate that a restricted region of contractile activity can be established in the cortex despite experimentally induced spreading and dilution of mitotic apparatus effect.     

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.     

Division of constricted and urethane-treated sand dollar eggs: a test of the polar stimulation hypothesis

In spherical cells with a central mitotic apparatus, the centers of the asters are closer to the poles than to the equator. This circumstance is basic to several hypothetical explanations of the way in which the mitotic apparatus establishes the division mechanism. This investigation was designed to determine whether that geometrical relationship is necessary for division. Fertilized, mechanically denuded sand dollar eggs were inserted into glass loops, which reduced the diameter in the constriction plane from the normal 142 to 78-80 microns and partly constricted the cell into equal parts. The mitotic apparatus straddled the constriction, and its length was not significantly changed. The manipulation increased the distance from the astral centers to the poles and decreased the distance from the astral centers to the equator to a degree that reversed the normal distance relations. These cells divided normally. Ethyl urethane (0.06 M) reduces the size of the mitotic apparatus and blocks cleavage in spherical cells. When treated cells are confined in 80-microns i.d. capillaries, they divide. Treated cells also divide when they are constricted by an 80-microns i.d. glass loop if the mitotic apparatus straddles the constriction. An equal degree of constriction in the subfurrow and subpolar areas did not reverse the effect of urethane. The results demonstrate that cleavage does not depend on the normal distance relation between the mitotic apparatus and the poles, and that the urethane effect can be remedied only by reducing the distance between the mitotic apparatus and the equatorial surface. Both findings are inconsistent with the polar stimulation hypothesis.     

THE DIRECT ISOLATION OF THE MITOTIC APPARATUS

A method for isolating the mitotic apparatus from dividing sea urchin eggs without the use of ethyl alcohol or of detergents is described. In the present method, the eggs are dispersed directly in a medium containing 1 M (to 1.15 M) sucrose, 0.15 M dithiodiglycol, and 0.001 M Versene at pH 6, releasing the visibly intact mitotic apparatus. The method is designed for studies of enzyme activities, lipid components, and the variables affecting the stability of the apparatus.     

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.     

Two Ca2(+)-binding proteins in the mitotic apparatus of sea urchin eggs

Two Ca2(+)-binding proteins of sea urchin eggs were purified and partially characterized. They showed Ca2(+)-dependent binding to actin filaments and Ca2(+)-dependent changes of fluorescence intensity which was used to estimate the affinity constant of these proteins to Ca2+ ions. Ca2+ ions did not increase phospholipid binding ability of these proteins. Therefore these proteins are distinguished from the calpactin family. Staining of sections of metaphase eggs embedded in paraffin showed their localization in the mitotic apparatus. Furthermore, staining of whole mount eggs with anti-tubulin and antibodies against these proteins, followed by observations with confocal laser-scanning microscopy showed their co-localization with microtubules more clearly. In vitro co-sedimentation assay of microtubules with these proteins, however, showed no interaction between them. This suggested that some structures surrounding the mitotic apparatus microtubules are responsible for their localization.     

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.     

THE MITOTIC APPARATUS : Fine Structure of the Isolated Unit

The fine structure of the mitotic apparatus isolated from the sea urchin egg has been investigated. The isolation was accomplished by lysis of metaphase eggs in a 1 M solution of hexanediol, buffered at pH 6. The fine structure of the isolated apparatus was studied after fixation with osmium tetroxide directly in the isolation medium. The spindle is composed of fine fibrils, approximately 20 mµ in diameter, which appear tubular. Similar fibrils, radially oriented, are found in the aster. If the isolated mitotic apparatus is exposed to water at pH 6 before fixation, the structure is considerably modified. The most pronounced effects are an increase in the number of large membrane-bounded vesicles and in the amount of free granular material present. The conditions necessary for the fixation of the mitotic apparatus in dividing cells are discussed in the light of these observations on the isolated unit.