Ultrastructural Basis of the Tension Increase in Sea-Urchin Eggs Prior to Cytokinesis. (microfilament/sea-urchin egg/tension)

The ultrastructural organization of actin and myosin II filaments in the contractile ring: new support for an old model of cytokinesis

Despite recent advances in our understanding of the components and spatial regulation of the contractile ring (CR), the precise ultrastructure of actin and myosin II within the animal cell CR remains an unanswered question. We used superresolution light microscopy and platinum replica transmission electron microscopy (TEM) to determine the structural organization of actin and myosin II in isolated cortical cytoskeletons prepared from dividing sea urchin embryos. Three-dimensional structured illumination microscopy indicated that within the CR, actin and myosin II filaments were organized into tightly packed linear arrays oriented along the axis of constriction and restricted to a narrow zone within the furrow. In contrast, myosin II filaments in earlier stages of cytokinesis were organized into small, discrete, and regularly spaced clusters. TEM showed that actin within the CR formed a dense and anisotropic array of elongate, antiparallel filaments, whereas myosin II was organized into laterally associated, head-to-head filament chains highly reminiscent of mammalian cell stress fibers. Together these results not only support the canonical "purse-string" model for contractile ring constriction, but also suggest that the CR may be derived from foci of myosin II filaments in a manner similar to what has been demonstrated in fission yeast.

Quantification of surface tension and internal pressure generated by single mitotic cells

During mitosis, adherent cells round up, by increasing the tension of the contractile actomyosin cortex while increasing the internal hydrostatic pressure. In the simple scenario of a liquid cell interior, the surface tension is related to the local curvature and the hydrostatic pressure difference by Laplace's law. However, verification of this scenario for cells requires accurate measurements of cell shape. Here, we use wedged micro-cantilevers to uniaxially confine single cells and determine confinement forces while concurrently determining cell shape using confocal microscopy. We fit experimentally measured confined cell shapes to shapes obeying Laplace's law with uniform surface tension and find quantitative agreement. Geometrical parameters derived from fitting the cell shape, and the measured force were used to calculate hydrostatic pressure excess and surface tension of cells. We find that HeLa cells increase their internal hydrostatic pressure excess and surface tension from ≈ 40 Pa and 0.2 mNm(-1) during interphase to ≈ 400 Pa and 1.6 mNm(-1) during metaphase. The method introduced provides a means to determine internal pressure excess and surface tension of rounded cells accurately and with minimal cellular perturbation, and should be applicable to characterize the mechanical properties of various cellular systems.

Novel morphological traits in the early developmental stages of Temnopleurus toreumaticus

We have re-observed in detail the development of the sea urchin species Temnopleurus toreumaticus, which is considered to be a typical indirect-developing species with a feeding larval stage. In this re-observation, we discovered two new morphological traits in the early embryonic stages of T. toreumaticus. The first trait is that, immediately after fertilization, the egg enters a stage in which wrinkles form on its surface as a result of actin polymerization. The second new trait is that the blastulae form wrinkles; in sea urchins, this has previously been known only in direct-developing species that have a nonfeeding larval stage and form wrinkles during the blastula stage, before hatching. These phenomena indicate that after fertilization, the egg of T. toreumaticus undergoes a surface transformation that is unprecedented in echinoderms, and that an indirect-developing sea urchin can form a wrinkled blastula.

A global, myosin light chain kinase-dependent increase in myosin II contractility accompanies the metaphase-anaphase transition in sea urchin eggs

Myosin II is the force-generating motor for cytokinesis, and although it is accepted that myosin contractility is greatest at the cell equator, the temporal and spatial cues that direct equatorial contractility are not known. Dividing sea urchin eggs were placed under compression to study myosin II-based contractile dynamics, and cells manipulated in this manner underwent an abrupt, global increase in cortical contractility concomitant with the metaphase-anaphase transition, followed by a brief relaxation and the onset of furrowing. Prefurrow cortical contractility both preceded and was independent of astral microtubule elongation, suggesting that the initial activation of myosin II preceded cleavage plane specification. The initial rise in contractility required myosin light chain kinase but not Rho-kinase, but both signaling pathways were required for successful cytokinesis. Last, mobilization of intracellular calcium during metaphase induced a contractile response, suggesting that calcium transients may be partially responsible for the timing of this initial contractile event. Together, these findings suggest that myosin II-based contractility is initiated at the metaphase-anaphase transition by Ca2+-dependent myosin light chain kinase (MLCK) activity and is maintained through cytokinesis by both MLCK- and Rho-dependent signaling. Moreover, the signals that initiate myosin II contractility respond to specific cell cycle transitions independently of the microtubule-dependent cleavage stimulus.

Temporal change in local forces and total force all over the surface of the sea urchin egg during cytokinesis

We determined the tension over the entire surface of the sea urchin eggs during cytokinesis, on the basis of the intracellular pressure and cell shape. This allowed us to determine the temporal changes in both the distribution of local forces and the total force produced in the whole cell cortex. A spike-like peak at anaphase and a broader peak at the onset of furrowing were observed in the time-course of the total force. Treatment of the eggs with cytochalasin D, blebbistatin, ML-9, or ML-7 significantly lowered the total force when they inhibited cytokinesis, suggesting that the tension results mainly from the interaction between intact actin filaments and activated myosin II. Myosin II would function as a motor, not only in the furrow region, but over a wide area of the cell surface, because the sum of the tensions outside the furrow region was larger than that inside the furrow region throughout cytokinesis. The distribution of the local force revealed that a global increase in the cortical force started well before the onset of furrowing, and that the force inside the furrow region continued to increase despite the decrease in the force outside the furrow region after the onset of furrowing. The spatial and temporal patterns of the force over the entire surface support the hypothesis that there are two separate but coordinated actomyosin activation mechanisms, one of which induces global activation of the cortex and the other of which then maintains the contractility only inside the furrow region.

Absence of furrowing activity following regional cortical tension reduction in sand dollar blastomere and fertilized egg fragment surfaces

The purpose of the present investigation was to test experimentally the possibility that division mechanism establishment at the equator of sand dollar eggs may be a consequence of cortical tension gradients between the equator and the poles. Cytochalasin has been shown to decrease tension at the sea urchin egg surface. The concave ends of cytochalasin D-containing agarose cylinders were held against regions of the surface of Echinarachnius parma blastomeres and enucleated fertilized egg fragments. The ability to interfere with normal furrowing activity was used as a biological indicator of the effectiveness of cytochalasin. When agarose containing 2 microg/mL cytochalasin contacted the equatorial region of the blastomeres resulting from the first cleavage, or the equatorial surfaces of nucleated fertilized egg halves, furrowing was blocked, stalled or delayed, indicating that the concentration of cytochalasin was effective. When the same concentration of cytochalasin was applied to the poles, the cells and nucleated fertilized egg fragments divided in the same way as the controls, indicating that the effectiveness of the cytochalasin did not spread from the poles to the equator and that bisection did not interfere with the division of nucleated fertilized egg fragments. When the same concentration of cytochalasin was applied to diametrically opposed surfaces of enucleated, spherical egg fragments, there was no evidence of furrowing activity between the areas that contacted the cytochalasin or in any other part of the surface. Because of the tension-reducing effect of cytochalasin, a tension gradient existed between the regions affected and unaffected by cytochalasin. The results strongly suggest that establishment of the division mechanism by simple gradients of tension at the surface is unlikely.

Dynamics of filamentous actin organization in the sea urchin egg cortex during early cleavage divisions: implications for the mechanism of cytokinesis

We have used confocal laser scanning microscopy in conjunction with BODIPY-phallacidin staining of filamentous actin to investigate changes in the quantity and organization of cortical actin during the first two cell cycles following fertilization in eggs of the sea urchin Strongylocentrotus purpuratus. Quantification of fluorescent phallacidin staining reveals that the amount of filamentous actin (F-actin) in the cortex undergoes cyclical increases and decreases during early cleavage divisions, peaking near the beginning of the cell cycle and decreasing to a minimum at cytokinesis. Changes in the content of cortical F-actin are accompanied by the growth and disappearance of rootlet-like bundles of actin filaments which extend from the bases of microvilli that cover the surface of the egg. Actin rootlets reach their maximum degree of development by 20 min postfertilization, and then gradually decrease in number and length over the next 40 min. Small actin rootlets persist until cleavage, disappear during cytokinesis, and reform following division. The formation of actin rootlets requires cytoplasmic alkalization and is inhibited by cytochalasin D. Cytochalasin D washout experiments demonstrate that assembly of the cortical actin cytoskeleton can be blocked until 5 min before the onset of cleavage and still allow normal cytokinesis. These results illustrate the dynamic nature of cortical actin organization during early development and demonstrate that cytokinesis occurs at the point of minimum cortical F-actin content. They further demonstrate that cytokinesis can occur in embryos in which the normal developmental sequence of changes in cortical actin organization has been blocked by treatment with cytochalasin D, suggesting that these changes do not function in the establishment of the contractile apparatus for cytokinesis, but rather serve other developmental functions. Cell Motil. Cytoskeleton 36:30-42, 1997.

Isolation and characterization of a sea urchin zygote cortex that supports in vitro contraction and reactivation of furrowing

The isolation of the cortex of the sea urchin blastomere by detergent lysis was explored with the aim of analyzing components important in the structure and function of the cortical cytoskeleton, and their relationship to such phenomena as contraction. Buffered EGTA medium supplemented with isotonic glycerol and with magnesium, at a level close to the reported internal cellular concentration, yields stable cytoskeletal cortices that retain their spherical shape. Cortices prepared this way contain actin, myosin, fascin and spectrin, components normally associated with the cortical cytoskeleton in a similar distribution to that in intact zygotes. They retain the organized cortical filamentous structure, including the actin-fascin bundles that form cores of microvilli. ATP and NaCl caused changes in cortical shape, described as either contraction or expansion, respectively. Spectrin, but not myosin, was partially extracted by NaCl, resulting in expansion of the cortex that suggests a role for spectrin in maintenance of cortical structure. ATP (but not ADP nor ATP gamma S), which caused the partial removal of myosin and spectrin, led to the contraction of the cortex, consistent with a role for myosin in cortical tension. In cortices isolated from dividing eggs, the zygotes retained their cleavage furrows and ATP induced continuation of furrow progression. This preparation appears to be a useful in vitro model for cytokinesis.

Cleavage furrow: timing of emergence of contractile ring actin filaments and establishment of the contractile ring by filament bundling in sea urchin eggs

Cleavage furrow formation at the first cell division of sea urchin and sand dollar eggs was investigated in detail by fluorescence staining of actin filaments with rhodamine-phalloidin of either whole eggs or isolated egg cortices. Cortical actin filaments were clustered at anaphase and then the clusters became fibrillar at the end of anaphase. The timing when the contractile ring actin filaments appear was precisely determined in the course of mitosis: accumulation of the contractile ring actin filaments at the equatorial cell cortex is first noticed at the beginning of telophase (shortly before furrow formation), when the chromosomal vesicles are fusing with each other. The accumulated actin filaments were not well organized at the early stage but were organized into parallel bundles as the furrowing progressed. The bundles were finally fused into a tightly packed filament belt. Wheat germ agglutinin (WGA)-binding sites were distributed on the surface of the egg in a manner similar to the actin filaments after anaphase. The WGA-binding sites became accumulated in the contractile ring together with the contractile ring actin filaments, indicating an intimate relationship between these sites and actin filament-anchoring sites on the plasma membrane. Myosin also appeared in the contractile ring together with the actin filaments. The ‘cleavage stimulus’, a signal hypothesized by Rappaport (reviewed by R. Rappaport (1986) Int. Rev. Cytol. 105, 245–281) was suggested to induce aggregation or bundling of the actin filaments in the cortical layer.

Actin depolymerisation induces process formation on MAP2-transfected non-neuronal cells

We have previously shown that microtubules in nonneuronal cells form long, stable bundles after transfection with the embryonic neuronal microtubule-associated protein MAP2c. In this study, we found that treating MAP2c-transfected cells with the actin depolymerising drug cytochalasin B led to the outgrowth of microtubule-containing processes from the cell surface. This effect was specific to MAP2c and did not occur in untransfected cells whose microtubules had been stabilised by treatment with taxol. The outgrowth and retraction of these processes during repeated cycles of cytochalasin addition and removal was followed by video time-lapse microscopy and was suggestive of a physical interaction between compressive forces exerted by the MAP2c-stabilised microtubule bundles and tensile forces originating in the cortical actin network. We suggest that MAP2c confers three properties on cellular microtubules that are essential for process outgrowth: stability, bundling and stiffness. The latter probably arises from the linking together of neighbouring tubulin subunits by three closely spaced tubulin-binding motifs in the MAP2 molecule that limits their motion relative to one another and thus reduces the flexibility of the polymer. Similar multimeric tubulin-binding domains in other proteins of the MAP2 class, including tau in axons and MAP4 in glial cells, may play the same role in the development and support of asymmetric cell morphology. Axial bundles of microtubules are found in growing neurites but not in growth cones, suggesting that the regulated expression of these MAP-induced properties makes an important contribution to the establishment of a stable process behind the advancing growth cone.

Sensitivity of stretch-activated K+ channels changes during cell-cleavage cycle and may be regulated by cAMP-dependent protein kinase

The properties of stretch-activated K+ channels in the membrane of loach (Misgurnus fossilis) embryos were studied using the patch-clamp technique. It was found that in the early stages of embryogenesis (2-256 cells) the stretch sensitivity of stretch-activated (SA) channels changes dramatically during the cell cleavage cycle. At the beginning of interphase the stretch sensitivity of SA channels and the probability of being in the open state (P0) were minimal, whereas at prometaphase they were increased 10-100-fold. Application of ATP to the cytoplasmic surface of excised inside-out patches induced a reversible increase in resting P0 and of stretch sensitivity of the SA channels in 50% of the patches, but the non-hydrolysable analogue of ATP, 5'-adenylylimidodiphosphate (AMP-PNP), was not effective. Phosphatase inhibitors (orthovanadate and para-nitrophenyl phosphate) prolonged the effect of ATP. Combined application of ATP, cAMP and cAMP-dependent protein kinase (PK) induced a reversible increase in the SA channel activity in 70% of those excised patches which did not respond to ATP. Inhibitors of PK prevented its activating effect. Dibutyryl-cAMP (dB cAMP) transiently increased activity of SA channels in intact cells. These results suggest that activity of SA channels may be regulated through cAMP-dependent phosphorylation and thus provide the basis for explanation of stretch sensitivity modulation during the cell cycle.

Subcellular localization of sea urchin egg spectrin: evidence for assembly of the membrane-skeleton on unique classes of vesicles in eggs and embryos

A recent study from our laboratory on the sea urchin egg suggested that spectrin was not solely restricted to the plasma membrane, but instead had a more widespread distribution on the surface of a variety of membranous inclusions. (E. M. Bonder et al., 1989, Dev. Biol. 134, 327-341). In this report we extend our initial findings and provide experimental and ultrastructural evidence for the presence of spectrin on three distinct classes of cytoplasmic vesicles. Immunoblot analysis of membrane fractions prepared from egg homogenates establishes that spectrin coisolates with vesicle-enriched fractions, while indirect immunofluorescence microscopy on cryosections of centrifugally stratified eggs demonstrates that spectrin specifically associates with cortical granules, acidic vesicles, and yolk platelets in vivo. Immunogold ultrastructural localization of spectrin on cortices isolated from eggs and early embryos details the striking distribution of spectrin on the cytoplasmic surface of the plasma membrane and the membranes of cortical granules, acidic vesicles, and yolk platelets, while quantitative studies show that relatively equivalent amounts of spectrin are present on the different membrane surfaces both before and after fertilization. These data, in combination with the localization of numerous spectrin crosslinks between actin filaments in surface microvilli, suggest that spectrin plays a pivotal role in structuring the cortical membrane-cytoskeletal complex of the egg and the embryo.

Mechanical properties of the cortex before and during cleavage

The changes in stiffness of the cell before and during cleavage reported previously for various kinds of echinoderm eggs are classified into three types. There is no general rule that cleavage starts when the stiffness attains a maximum or a minimum. Because the stiffness of the cell surface is much greater than that of the mitotic apparatus, the change in stiffness of the cell represents mainly the change in stiffness of the cell surface. The tension at the cell surface changes in parallel over the entire surface before the onset of cleavage. After the onset of cleavage, the tension at the furrow surface becomes greater in the direction parallel to the furrow than perpendicular to it. A remarkable change in mechanical properties occurs at the furrow surface simultaneously with the onset of cleavage. Judging from the temporal and spatial coincidence between this change and the formation of the contractile ring reported previously in sea urchin eggs at the onset of cleavage, it is concluded that this change is due to the formation of the contractile ring that generates the motive force for cleavage.

Actomyosin organization during cytokinesis: reversible translocation and differential redistribution in Dictyostelium

Synchronized cultures of Dictyostelium discoideum were used to study organizational changes of the cytoskeleton during mitotic cell division. The agar-overlay technique (Yumura et al.: J. Cell Biol. 99:894-899, 1984) was employed for immunofluorescence localization and video microscopic observation of living mitotic cells. The mitotic phase was defined by changes in chromosome configuration by using a double stain with the fluorescent dye DAPI. This study showed that the actin- and myosin-containing cytoskeleton was reversibly redistributed between the cortical ectoplasm and the endoplasm during prophase and telophase. Both actin and myosin filaments were dissociated from the cell cortex in prophase. Most of the actin and myosin was filamentous and remained in the endoplasm until telophase. Saltatory movements of organelles stopped suddenly, coincident with the breakdown of the cytoplasmic microtubule network. This change in the microtubule system was temporally coupled with the disappearance of actomyosin from the cortex. At the same time, the local vibrating movement of particles almost stopped, suggesting that the viscoelastic nature of the endoplasm was altered. In the late anaphase, actin and myosin relocalized to the cortical ectoplasm. Early in this phase, myosin filaments were localized specifically at the anticipated cleavage furrow region of the cleavage furrow, whereas actin filaments were redistributed more uniformly in the cell cortex, with an extremely large accumulation in the polar pseudopods. Subsequently the actin formed an orderly parallel array of cables along with myosin filaments in the contractile ring. The spatial segregation of actin and myosin in late anaphase was clearly demonstrated by multipolar cell division of artificially induced giant cells. Actin was relocalized in both the polar and the proximal constricting regions whereas myosin was only localized in the center of each pair of daughter microtubule networks where the cleavage furrow was formed. This study demonstrates that actin and myosin are reorganized by a temporally coordinated but spatially different mechanism during cytokinesis of Dictyostelium.

Stretch-activated ion channels modulate the resting membrane potential during early embryogenesis

By using the patch-clamp technique, stretch-activated ionic channels were found in the membrane of cleaving freshwater fish embryos at the early stages of embryogenesis (2-256 cells). The application of negative pressure to the pipette increased the frequency of activation and the duration of bursts. This type of channel has a preferential K+ selectivity. When bathed on both membrane surfaces with 140 mM KCl the channel conductance was 71 pS. The kinetic behaviour did not depend markedly on either membrane potential (in the range from -70 to +70 mV) or calcium concentration on the cytoplasmic side of the membrane. On continuous recording, the probability of the channel being open was found to change periodically over a 5- to 20-fold range for different cells. These variations correlated with changes in resting potential and membrane conductance during the cell cycle. These results suggest that the oscillation of resting potential within the cell cycle is associated with the operation of stretch-activated ion channels.

Fourth cleavage of sea urchin blastomeres: microtubule patterns and myosin localization in equal and unequal cell divisions

This study traces the morphological appearance, organization, and disappearance of the cytoskeletal machinery for cell division during the fourth cell cycle of isolated sea urchin blastomeres by immunolocalization of tubulin and myosin. Mesomere-mesomeres (which divide equally) and macromere-micromeres (which divide unequally) are compared in terms of their asters (both mitotic and so-called interphase asters), spindle apparatus, and contractile ring. The results suggest that the distinctive nuclear positioning of these blastomeres is established in late interphase, that centrosomal alignment occurs in prophase, that all of the dominant astral configurations in the cell cycle belong to a single cycle of assembly-disassembly, that a second interphase-specific cycle of assembly-disassembly is confined to a diffuse cytoplasmic reticulum, and that contractile ring myosin concentrates and disperses in precise coincidence with the beginning and end of cleavage furrowing.

Cell cycle changes in water properties in sea urchin eggs

This study concerned changes in the motional properties of cellular water during the first cell cycle of fertilized sea urchin eggs (Lytechinus variegatus). There was a significant decrease in proton NMR T1 relaxation time and in cytoplasmic ice crystal growth during mitosis and a significant increase in T1 time and cytoplasmic ice crystal size during cleavage. This was not caused by egg water content changes as reflected by egg volume measurements. Removal of both the fertilization membrane and the hyaline layer shortly after fertilization did not alter the pattern of T1 time changes at mitosis and cleavage as compared to whole eggs; thus, the pattern of T1 time changes was attributed to intracellular events. Treatment of fertilized eggs with cytochalasin B, an inhibitor of actin polymerization, did not block the fall in T1 time at mitosis, but did block cytokinesis and the increase in T1 time, which normally occurred at cleavage. A significant pattern of actin disassembly and reassembly at mitosis and cytokinesis was found by studies on the total amount of monomeric actin (G actin) using the DNase I assay. This led to the hypothesis that the observed changes in T1 time and ice crystal size during the first cell cycle were due to the depolymerization and polymerization of cytoplasmic actin. To test this, the effect of the in vitro polymerization of purified actin on the T1 time and on ice crystal growth was examined. It was concluded that changes in the T1 time and ice crystal growth upon polymerization of actin in vitro resembled the changes seen in vivo. These results suggest that changes in the motional properties of cytoplasmic water during the first cell cycle are due, at least in part, to the state of polymerization of cytoplasmic actin.

"Pull" and "push" in neurite elongation: observations on the effects of different concentrations of cytochalasin B and taxol

Neurite elongation involves two distinct cytoskeletal functions the "push" of anterograde transport of the cytoskeleton and associated organelles to the neurite tip, and the "pull" exerted by protrusion and generation of tensions in the growth cone. We investigated the roles of these two activities in neurite elongation via the drugs taxol and cytochalasin B (CB), which act on the key cytoskeletal components, microtubules and actin filaments, respectively. When neurons are treated with concentrations of CB below 0.2 micrograms/ml, neurite elongation, growth cone protrusion, and neurite tension are all inhibited in a similar concentration dependent manner. Protrusive activity and tensions are absent at CB concentrations above 0.3 micrograms/ml, yet neurite elongation continues at a plateau level. Thus, "pull" does modulate, but it is not required for neurite elongation. Surprisingly, the inhibitory effects of taxol on neurite elongation are removed by the addition of CB at levels that substantially disrupt the actin filaments of neurites. The neurites extended by taxol-CB neurons are unbranched and curiously unattached to the substratum. When CB is added to taxol-treated neurons, neurite extension begins rapidly, even if protein synthesis is severely reduced. We propose that taxol inhibits microtubule transport in neurites, and this inhibition of "push" is reversed by the disruptive effects of CB on the cytoplasmic matrix, allowing taxol-induced microtubule bundles to be transported distally.

Effects of cytochalasin B on the cleavage furrow in mouse blastomeres

Blastomeres isolated from two-cell mouse embryos were cultured until they started to cleave. When the cleavage furrow developed they were subjected to cytochalasin B (CB) and were studied with the electron microscope. The initial response to CB is that the furrow is more folded and microvillous than in the control. Later the blastomeres round up. The protrusions covered with abundant long microvilli are found scattered within their equatorial surface. Extraction with glycerol solution before fixation permits visualization of condensations of felt-like filamentous material in contact with the cleavage furrow during the initial response to CB and in the protrusions of rounded cells. We consider clumping of filaments in surface protrusions to be a specific response to CB treatment of the contractile ring.

TAME stabilizes the cortex and mitotic apparatus of the sea urchin egg during isolation

The synthetic substrate p-tosyl-L-arginine methyl ester (TAME) has been included in buffered EGTA media used for the isolation of the mitotic apparatus from clam eggs and also for the isolation of the cortex from sea urchin eggs. In the course of an investigation of the role of actin-fascin and actin-myosin interactions in cytokinesis, the isolation of the sea urchin egg cortex was re-examined and the stability of the cortex to lysis in a buffered EGTA medium near neutrality found to depend directly on the presence of TAME. Lysis of eggs at metaphase in this medium yielded a mixture of cortices and mitotic apparatuses (MA); MA stability under these conditions also required the presence of TAME, although a reduced pH allowed MA isolation in its absence. The action of TAME in stabilizing the actin-based structure of the cortex and the microtubule-based structure of the MA is not duplicated by other proteolysis inhibitors and this compound will also induce actin polymerization and gelation in extracts of the soluble cytoplasmic proteins of the egg under conditions where these are normally inhibited.

An 100-kDa Ca2+-sensitive actin-fragmenting protein from unfertilized sea urchin egg

An actin-modulating protein was purified from unfertilized eggs of sea urchin, Hemicentrotus pulcherrimus, by means of DNase I affinity and DEAE-cellulose column chromatographies. This protein was a globular protein with a Stokes radius of 41-42 nm and consisted of a single polypeptide chain having an apparent molecular mass of 100 kDa on sodium dodecyl sulfate polyacrylamide gel electrophoresis. Gel filtration chromatography revealed that one 100-kDa protein molecule binds two or three actin monomers in the presence of Ca2+, but such binding was not observed in the absence of Ca2+. The effect of the 100-kDa protein on the polymerization of actin was studied by viscometry, spectrophotometry and electron microscopy. The initial rate of actin polymerization was decreased at a very low molar ratio of 100-kDa protein/actin. Acceleration of the initial rate of polymerization occurred at a relatively high, but still substoichiometric, molar ratio of 100-kDa protein/actin. The 100-kDa protein produced fragmentation of muscle actin filaments at Ca2+ concentrations greater than 0.3 microM as revealed by viscometry and electron microscopy. Evidence was also presented that the 100-kDa protein binds to the barbed end of the actin filament.

Establishment of the mechanism of cytokinesis in animal cells

The division mechanism is fixed in the surface during anaphase or about 4 minutes before furrowing begins in cylindrical cells. Under experimental conditions, the minimum time that the mitotic apparatus must act upon the surface is about 1 minute. The stimulus period is followed by a latent period of 2-3 minutes. The time of furrow formation can be advanced or delayed by manipulating the surface and the mitotic apparatus. Since furrows can be elicited long after normal division would have been completed, it is suggested that the brevity of the normal interaction period is not a consequence of the constitution of the interactants. The component of the mitotic apparatus that establishes the furrow moves from the region of the mitotic axis to the surface at 6-8 microns/minute, The components of the mitotic apparatus that are essential for furrow establishment are confined to the achromatic regions. In spherical cells with large asters, the spindles are not required, although the spindle's ability to establish furrows in spherical cells can be demonstrated by changing the cell's geometry. In nonspherical cells with small asters, the spindle is probably the normal active agent. Although the ability of the mitotic apparatus to establish furrows can be diminished or abolished by measures that reduce its overall size, there are no decisive data concerning which of its ultrastructural components play essential roles in cytokinesis. The effect of changing the geometrical relation between the mitotic apparatus and the surface differs according to the region affected. Division can be blocked or impeded only by changing the relation between the equatorial surface and the mitotic apparatus. The ability of the mitotic apparatus to establish furrows is diminished by increasing the distance between the astral centers and also by increasing the distance between the mitotic axis and the equatorial surface. The cleavage block that results from reduction in size of the mitotic apparatus can be reversed only by decreasing the distance from the mitotic axis to the equatorial surface. Artificial constrictions imposed in other regions are ineffective. The normal distance relation between the astral centers and the equatorial and polar surfaces in spherical eggs is not required for division. Cleavage can occur when the dimensional relations are reversed. Both the surface and the mitotic apparatus can interact to establish furrows after exposure to measures that disrupt their normal organization. Single, isolated asters can cause furrow-like constrictions. Their immediate effect is to cause local contraction in nearby surface.(ABSTRACT TRUNCATED AT 400 WORDS)

The egg cortex in early development of sea urchins and starfish

The cytoplasm can no longer be looked upon as so much passive material which the nucleus elaborates during development, but it has a complex organization and a development which may be synchronous with certain changes in the nucleus and the division mechanism, and yet is independent of these.

Dynamics of the actin microfilament system in the Tubifex egg during ooplasmic segregation

Following the second polar body formation (PBF), the Tubifex egg undergoes ooplasmic segregation consisting of two steps, i.e., centrifugal migration of membranous organelles forming a subcortical ooplasmic layer and then movements of these organelles along the egg surface. The present investigation was undertaken to examine the microfilament organization in eggs during these ooplasmic rearrangements. Microfilaments throughout the egg are identified as actin by their reversible heavy meromyosin binding. Before the second PBF, a distinct network of actin filaments is present in the endoplasmic region. It is disorganized during the second PBF; short actin filaments are caused to aggregate with membranous organelles. Following the second PBF, similar short filaments become localized in the subcortical layer but not in the underlying yolky region. However, it is not until 50-60 min after the second PBF that an elaborate actin network is established in the subcortical layer. The cortex contains a sheet-like lattice of actin filaments. It is thickest around the animal pole, and tapes toward the equator of the egg. At about 90 min after the second PBF, this polarized distribution of cortical filaments becomes more pronounced as the result of their movements. Chronologically, subcortical actin network formation and cortical reorganization correspond to the later portion of the first step and the earlier portion of the second step of ooplasmic segregation, respectively. These findings are discussed in terms of ooplasmic movements and rearrangements.

Periodic appearance and disappearance of microvilli associated with cleavage cycles in the egg of the ascidian, Halocynthia roretzi

The surface of eggs of the ascidian Halocynthia roretzi, observed with SEM, is essentially smooth until immediately before cell division when numerous microvilli appear and remain during cytokinesis. As the dividing blastomeres become closely adherent, however, the microvilli disappear and the eggs recover their smooth surface. This periodic appearance-disappearance of microvilli is repeated at each cleavage cycle up to at least the 32-cell stage. During blastomere adhesion, microvilli that have appeared near the plane of the first cleavage or of the bilateral symmetry seem to fuse together across the plane to form a zipper-like complex of cytoplasmic processes, which might be responsible for attachment of the two halves of these bilaterally symmetrical embryos via the blastomeres bordering the plane of symmetry.