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.     

A Ca-activated ATPase in the mitotic apparatus of the sea urchin egg (isolated by a new method)

Steps in a new procedure for isolating the mitotic apparatus from sea urchin eggs (Strongylocentrotus purpuratus) are: (1) Cultivation of the eggs in sea water in which Na is replaced by Li, under which conditions the MA is stabilized in vivo and does not break down at the end of mitosis; (2) storage of the eggs containing the MA in 30% ethanol at −10 °C, preserving isolability and ATPase activity for several months; (3) isolation of the MA in the presence of ethanol and Triton X-100 at +10 °C by selective dispersal of the cytoplasm; (4) purification by washing in 30% ethanol, 0.1% Triton at low temperature. Because of the stabilization of the MA in the Li-sea water, the yield is large.     

A COMPARATIVE STUDY OF THE ISOLATION OF THE CORTEX AND THE ROLE OF THE CALCIUM-INSOLUBLE PROTEIN IN SEVERAL SPECIES OF SEA URCHIN EGG

A comparative study was made of the isolation of the cortex in the eggs of several sea urchin species. Since the isolation method developed by Sakai depends on the presence of magnesium in the medium, the protein composition of the cortex was investigated to determine whether the protein component of the egg described by Kane and Hersh which is gelled by divalent ions, is present in these cortices. Isolation of the cortex was found to require the same divalent ions at the same concentrations as protein gelation, and in the eggs of some species much of the gel protein of the cell was found in the isolated cortical material. In the eggs of other species a smaller fraction of this protein was found in the isolated cortex, although it was more concentrated there than in the endoplasm, and in one species this protein appeared to be uniformly distributed throughout the cell. These results indicate that this protein is localized in the cortical region of the eggs of some species of sea urchin, possibly in the cortical granules, but also point up the fact that results from one species cannot be uncritically extrapolated to others.     

LOCALIZATION OF DYNEIN IN SEA URCHIN EGGS DURING CLEAVAGE*

Detection and localization of dynein in cleaving sea urchin eggs were attempted using antidynein serum (prepared against a tryptic fragment of dynein, Fragment A, of sea urchin sperm flagella) and fluorescein conjugated goat antiserum to rabbit γ-globulin. In both unfertilized and newly fertilized eggs, fluorescence was distributed rather uniformly within the cells but was absent from the nuclei. At prophase, intense fluorescence was observed on both sides of nucleus, suggesting accumulation of dynein in developing asters. From metaphase to anaphase, the whole mitotic apparatus (MA) was stained with the exceptions of the chromosomes and pole areas. Fluorescence then again became dispersed within the eggs. Throughout the mitotic process and cytokinesis, the egg cortex including the cleavage furrow was stained intensely, presumably reflecting the presence of dynein in this region. Similar distributions of fluorescence were obtained with the isolated MAs. Neither non-immune serum nor the antiserum to which Fragment A was absorbed stained the eggs. Little staining was obtained with the antiserum against starfish egg myosin. The results, together with the finding that the chromosome motion in the isolated MAs was completely inhibited by anti-dynein serum, but not with the anti-myosin serum, suggest an active role played by a tubulin-dynein system in mitosis.     

pH regulates the polymerization of actin in the sea urchin egg cortex

The state of actin in the isolated cortex of the unfertilized sea urchin egg can be controlled by experimentally manipulating the pH of the isolation medium. Cortices isolated at the pH of the unfertilized egg (6.5--6.7) do not contain filamentous actin, while those isolated at the pH of the fertilized egg (7.3--7.5) develop large numbers of microvilli which contain bundles of actin filaments. Cortices that are isolated at pH 6.5 and then transferred to isolation medium buffered at pH 7.5 also develop actin filaments. However, the filaments are not arranged in bundles and microvilli do not form. Although the cortical granules in cortices isolated at pH 6.5 discharge at a free Ca++ concentration of approximately 10 micrometer, actin polymerization is not induced by increasing the Ca++ concentration of the isolation medium. These results suggest that the increase in cytoplasmic pH which occurs following fertilization induces the polymerization of actin in the egg cortex.     

THE MITOTIC APPARATUS : Structural Changes after Isolation

The fibrous structure of the mitotic apparatus (MA) isolated from dividing sea urchin eggs undergoes no changes visible in phase contrast during extended storage, but the solubility of the MA rapidly decreases after isolation. Polarization microscopy shows that a decrease in the birefringence of the MA also occurs after isolation and is correlated with the loss of solubility. This loss of birefringence indicates that some structural change takes place during this period, and such a change was demonstrated by means of electron microscopy. The tubular filaments which form the spindle of the intracellular MA and of the freshly isolated MA were found to break down during storage to rows of dense granules, this loss of continuity presumably accounting for the loss of birefringence. The interrelations of the observed changes and the significance of these observations for investigations on the isolated MA are discussed.     

INDUCTION OF CHROMOSOME MOTION IN THE GLYCEROL-ISOLATED MITOTIC APPARATUS: NUCLEOTIDE SPECIFICITY AND EFFECTS OF ANTIDYNEIN AND MYOSIN SERA ON THE MOTION*

Chromosome motion in glycerol-isolated mitotic apparatus (MA) of sea urchin and starfish eggs was investigated with respect to nucleotide specificity and the effects of antisera against tryptic fragment (Fragment A) of flagellar dynein and starfish egg myosin. The motion was highly specific for ATP. GTP, ITP, CTP, UTP, and ADP caused no displacement of the chromosomes towards the poles. The anti-Fragment A serum completely inhibited chromosome motion in the MA of the sea urchin egg, while antiserum against starfish egg myosin as well as its γ-globulin fraction did not inhibit the motion in the isolated MA of the starfish egg, suggesting that chromosome motion depends upon dynein-microtubule but not upon myosin-actin interaction. In addition, colchicine completely suppressed the chromosome motion in vitro.     

Mass isolation of mitotic apparatus using a glycerol/Mg/Triton X-100 medium

Mass isolation of pure mitotic apparatuses (MAs) from sea urchin eggs was achieved using a glycerol/Mg²⁺/Triton X-100 isolation medium. The Mg ions stabilized the fibrous structures of the spindle and asters, while Triton X-100 favored dispersion of cell membranes. The MAs were stable for at least 1 day at 20 °C as indicated by phase contrast microscopy. The MAs also showed stable birefringence and solubility properties over a period of several hours. Only centrospheres remained intact in 0.4 M KCl-containing isolation medium. The 0.4 M KCl extract contained tubulin as one of its major components. Transfer of isolated MAs to an Mg-free medium caused the otherwise stable MA birefringence to decay upon addition of sulfhydryl-blocking reagents or Ca ions that depolymerize MA microtubules. Furthermore, when Mg ions were omitted from the isolation medium, only unstable MAs were obtained. This method seems to be of great advantage in the preparation of pure MAs in large quantity.     

Role of phospholipase Cgamma at fertilization and during mitosis in sea urchin eggs and embryos

It is well known that stimulation of egg metabolism after fertilization is due to a rise in intracellular free calcium concentration. In sea urchin eggs, this first calcium signal is followed by other calcium transients that allow progression through mitotic control points of the cell cycle of the early embryo. How sperm induces these calcium transients is still far from being understood. In sea urchin eggs, both InsP3 and ryanodine receptors contribute to generate the fertilization calcium transient, while the InsP3 receptor generates the subsequent mitotic calcium transients. The identity of the mechanisms that generate InsP3 after fertilization remains an enigma. In order to determine whether PLCgamma might be the origin of the peaks of InsP3 production that punctuate the first mitotic cell cycles of the fertilized sea urchin egg, we have amplified by RT-PCR several fragments of sea urchin PLCgamma containing the two SH2 domains. The sequence shares similarities with SH2 domains of PLCgamma from mammals. One fragment was subcloned into a bacterial expression plasmid and a GST-fusion protein was produced and purified. Antibodies raised to the GST fusion protein demonstrate the presence of PLCgamma protein in eggs. Microinjection of the fragment into embryos interferes with mitosis. A related construct made from bovine PLCgamma also delayed or prevented entry into mitosis and blocked or prolonged metaphase. The bovine construct also blocked the calcium transient at fertilization, in contrast to a tandem SH2 control construct which did not inhibit either fertilization or mitosis. Our data indicate that PLCgamma plays a key role during fertilization and early development.     

A calsequestrin-like protein in the endoplasmic reticulum of the sea urchin: localization and dynamics in the egg and first cell cycle embryo

Using an antiserum produced against a purified calsequestrin-like (CSL) protein from a microsomal fraction of sea urchin eggs, we performed light and electron microscopic immunocytochemical localizations on sea urchin eggs and embryos in the first cell cycle. The sea urchin CSL protein has been found to bind Ca++ similarly to calsequestrin, the well-characterized Ca++ storage protein in the sarcoplasmic reticulum of muscle cells. In semi-thin frozen sections of unfertilized eggs, immunofluorescent staining revealed a tubuloreticular network throughout the cytoplasm. Staining of isolated egg cortices with the CSL protein antiserum showed the presence of a submembranous polygonal, tubular network similar to ER network patterns seen in other cells and in egg cortices treated with the membrane staining dye DiIC16[3]. In frozen sections of embryos during interphase of the first cell cycle, a cytoplasmic network similar to that of the unfertilized egg was present. During mitosis, we observed a dramatic concentration of the antibody staining within the asters of the mitotic apparatus where ER is known to aggregate. Electron microscopic localization on unfertilized eggs using peroxidase-labeled secondary antibody demonstrated the presence of the CSL protein within the luminal compartment of ER-like tubules. Finally, in frozen sections of centrifugally stratified eggs, the immunofluorescent staining concentrated in the clear zone: a layer highly enriched in ER and thought to be the site of calcium release upon fertilization. This localization of a CSL protein within the ER of the egg provides evidence for the ability of this organelle to serve a Ca++ storage role in the regulation of intracellular Ca++ in nonmuscle cells in general, and in the regulation of fertilization and cell division in sea urchin eggs in particular.     

Motility and centrosomal organization during sea urchin and mouse fertilization

Motility and the behavior and inheritance of centrosomes are investigated during mouse and sea urchin fertilization. Sperm incorporation in sea urchins requires microfilament activity in both sperm and eggs as tested with Latrunculin A, a novel inhibitor of microfilament assembly. In contrast the mouse spermhead is incorporated in the presence of microfilament inhibitors indicating an absence of microfilament activity at this stage. Pronuclear apposition is arrested by microfilament inhibitors in fertilized mouse oocytes. The migrations of the sperm and egg nuclei during sea urchin fertilization are dependent on microtubules organized into a radial monastral array, the sperm aster. Microtubule activity is also required during pronuclear apposition in the mouse egg, but they are organized by numerous egg cytoplasmic sites. By the use of an autoimmune antibody to centrosomal material, centrosomes are detected in sea urchin sperm but not in unfertilized eggs. The sea urchin centrosome expands and duplicates during first interphase and condenses to form the mitotic poles during division. Remarkably mouse sperm do not appear to have the centrosomal antigen and instead centrosomes are found in the unfertilized oocyte. These results indicate that both microfilaments and microtubules are required for the successful completion of fertilization in both sea urchins and mice, but at different stages. Furthermore they demonstrate that centrosomes are contributed by the sperm during sea urchin fertilization, but they might be maternally inherited in mammals.     

SELECTIVE EXTRACTION OF ISOLATED MITOTIC APPARATUS : Evidence That Typical Microtubule Protein Is Extracted by Organic Mercurial

Mitotic apparatus isolated from sea urchin eggs has been treated with meralluride sodium under conditions otherwise resembling those of its isolation. The treatment causes a selective morphological disappearance of microtubules while extracting a major protein fraction, probably consisting of two closely related proteins, which constitutes about 10% of mitotic apparatus protein. Extraction of other cell particulates under similar conditions yields much less of this protein. The extracted protein closely resembles outer doublet microtubule protein from sea urchin sperm tail in properties considered typical of microtubule proteins: precipitation by calcium ion and vinblastine, electrophoretic mobility in both acid and basic polyacrylamide gels, sedimentation coefficient, molecular weight, and, according to a preliminary determination, amino acid composition. An antiserum against a preparation of sperm tail outer doublet microtubules cross-reacts with the extract from mitotic apparatus. On the basis of these findings it appears that microtubule protein is selectively extracted from isolated mitotic apparatus by treatment with meralluride, and is a typical microtubule protein.     

THE MITOTIC APPARATUS: ISOLATION BY CONTROLLED pH

The isolation of the mitotic apparatus (MA) from the echinoderm egg was studied in detail, with particular attention given to the factors governing its stability. Successful isolation depends mainly on the pH of the isolation solution, slightly acid values being required. The use of a 1 M solution of hexanediol, buffered at pH 6.0 to 6.4, gives high yields of stable MA, while MA of poorer quality can be isolated in water buffered at pH 5.5 to 5.8. Isolation is possible only over a very narrow range of pH, as the cells become more difficult to break at lower values and the MA becomes unstable at higher values. Within this range the fibrous structure of the MA varies with the pH. The isolated MA disintegrates slowly when transferred to water at pH 7 and dissolves rapidly in solutions of high ionic strength.     

Effects of heavy water (D2O) on the length of the mitotic period in developing sea urchin eggs

The sequence of mitosis in sea urchin eggs was investigated in the presence and absence of D2O. Direct observations of living cells under a polarizing microscope and observations with fixation-staining procedures were used. The duration of mitosis was extended by the presence of D2O. The slight extension of anaphase was due to elongation of the spindle in D2O, but the period from prophase to metaphase was clearly prolonged in the deuterated condition. These results indicate that D2O does not suppress anaphase chromosome movement, but does affect prometaphase and delays the alignment of chromosomes on the equatorial plane of the mitotic spindle at metaphase. The stability of the isolated mitotic apparatus against Ca ions and low temperature also was investigated. There was no difference in the deterioration of isolated spindle birefringence under normal and deuterated conditions. The implications of these results are discussed in relation to the enhancement effect of D2O on the volume and birefringence of the living mitotic spindle.     

Isolation of intact sperm asters from fertilized sea urchin eggs

We have developed a procedure for isolating intact sperm asters in quantity from fertilized sea urchin eggs. This procedure is based on detergent-extraction methods developed previously for the bulk isolation of mitotic apparatuses. Using this protocol it is possible to isolate sperm asters as soon as they appear in the fertilized egg or at any subsequent point in their brief existence.     

The relationship between calcium, MAP kinase, and DNA synthesis in the sea urchin egg at fertilization

Fertilization releases the brake on the cell cycle and the egg completes meiosis and enters into S phase of the mitotic cell cycle. The MAP kinase pathway has been implicated in this process, but the precise role of MAP kinase in meiosis and the first mitotic cell cycle remains unknown and may differ according to species. Unlike the eggs of most animals, sea urchin eggs have completed meiosis prior to fertilization and are arrested at the pronuclear stage. Using both phosphorylation-state-specific antibodies and a MAP kinase activity assay, we observe that MAP kinase is phosphorylated and active in unfertilized sea urchin eggs and then dephosphorylated and inactivated by 15 min postinsemination. Further, Ca(2+) was both sufficient and necessary for this MAP kinase inactivation. Treatment of eggs with the Ca(2+) ionophore A23187 caused MAP kinase inactivation and triggered DNA synthesis. When the rise in intracellular Ca(2+) was inhibited by injection of a chelator, BAPTA or EGTA, the activity of MAP kinase remained high. Finally, inhibition of the MAP kinase signaling pathway by the specific MEK inhibitor PD98059 triggered DNA synthesis in unfertilized eggs. Thus, whenever MAP kinase activity is retained, DNA synthesis is inhibited while inactivation of MAP kinase correlates with initiation of DNA synthesis.     

Evidence that the Mg-ATPase in the cortical layer of sea urchin egg is dynein

Indirect immunofluorescence staining of cleaving sea urchin eggs with an antiserum against a tryptic fragment of dynein 1 (fragment 1A) from sea urchin sperm flagella suggested the presence of dynein in the cortex as well as in the mitotic apparatus. In the present study, we found that the Mg²⁺-ATPase activity of the isolated cortices from sea urchin eggs, which exhibited similar characteristics to those of flagellar dynein, was inhibited by 60–80% with the anti-fragment 1A serum. Faintly stained bands corresponding to the A-band (dynein 1) and the B-band of the sperm flagella was detected on sodium dodecylsulfate (SDS)-polyacrylamide gel electrophoresis of the isolated cortices. Furthermore, the SDS-gel electrophoresis revealed the presence of a polypeptide band corresponding to dynein 1 in the antigen-antibody complex precipitated from the KCl-extract of the cortices with the antiserum.     

ULTRASTRUCTURE AND BIREFRINGENCE OF THE ISOLATED MITOTIC APPARATUS OF MARINE EGGS

Isolated mitotic apparatuses (MA) of clam and sea urchin eggs were investigated by polarizing and electron microscopy. Examination of fixed MA in oils of different refractive index revealed that at least 90% of the retardation of isolated MA is due to positive, form birefringence, the remaining retardation deriving from positive, intrinsic birefringence. Electron micrographs reveal the isolated MA to be composed of microtubules, ribosome-like particles, and a variety of vesicles. In the clam MA the number of vesicles and ribosome-like particles relative to the number of microtubules is much lower than in the sea urchin MA. In clam MA this allows form and intrinsic birefringence to be related directly to microtubules. The relation of birefringence to microtubules in isolated sea urchin MA is more complex since ribosome-like particles adhere to microtubules, are oriented by them, and are likely to contribute to the form birefringence of the isolated MA. However, comparison of values of retardation for clam and sea urchin MA, indicates that the major part of the birefringence in sea urchin MA is also due to microtubules. The interpretation of the structures giving rise to birefringence in the MA of the living cells is likely to be even more complex since masking substances, compression, or tension on the living MA may alter the magnitude or sign of the birefringence.     

Alpha-actinin from sea urchin eggs: biochemical properties, interaction with actin, and distribution in the cell during fertilization and cleavage

A protein similar to alpha-actinin has been isolated from unfertilized sea urchin eggs. This protein co-precipitated with actin from an egg extract as actin bundles. Its apparent molecular weight was estimated to be approximately 95,000 on an SDS gel: it co-migrated with skeletal-muscle alpha-actinin. This protein also co-eluted with skeletal muscle alpha-actinin from a gel filtration column giving a Stokes radius of 7.7 nm, and its amino acid composition was very similar to that of alpha-actinins. It reacted weakly but significantly with antibodies against chicken skeletal muscle alpha-actinin. We designated this protein as sea urchin egg alpha-actinin. The appearance of sea urchin egg alpha-actinin as revealed by electron microscopy using the low-angle rotary shadowing technique was also similar to that of skeletal muscle alpha-actinin. This protein was able to cross-link actin filaments side by side to form large bundles. The action of sea urchin egg alpha-actinin on the actin filaments was studied by viscometry at a low-shear rate. It gelled the F-actin solution at a molar ratio to actin of more than 1:20, at pH 6-7.5, and at Ca ion concentration less than 1 microM. The effect was abolished by the presence of tropomyosin. Distribution of this protein in the egg during fertilization and cleavage was investigated by means of microinjection of the rhodamine-labeled protein in the living eggs. This protein showed a uniform distribution in the cytoplasm in the unfertilized eggs. Upon fertilization, however, it was concentrated in the cell cortex, including the fertilization cone. At cleavage, it seemed to be concentrated in the cleavage furrow region.     

Activation of sea urchin eggs by inositol phosphates is independent of external calcium.

We investigated the contribution of external calcium ions to inositol phosphate-induced exocytosis in sea urchin eggs. We show that: (a) inositol phosphates activate eggs of the sea urchin species Lytechinus pictus and Lytechinus variegatus independently of external calcium ions; (b) the magnitude and duration of the inositol phosphate induced calcium changes are independent of external calcium; (c) in calcium-free seawater, increasing the volume of inositol trisphosphate solution injected decreased the extent of egg activation; (d) eggs in calcium-free sea water are more easily damaged by microinjection; microinjection of larger volumes increased leakage from eggs pre-loaded with fluorescent dye. We conclude that inositol phosphates do not require external calcium ions to activate sea urchin eggs. This is entirely consistent with their role as internal messengers at fertilization. The increased damage caused to eggs in calcium-free seawater injected with large volumes may allow the EGTA present in the seawater to enter the egg and chelate any calcium released by the inositol phosphates. This may explain the discrepancy between this and earlier reports.