Microtubules are required for centrosome expansion and positioning while microfilaments are required for centrosome separation in sea urchin eggs during fertilization and mitosis

Centrosomes undergo cell cycle-dependent changes in shape and separations, changes that govern the organization of the cytoskeleton. The cytoskeleton is largely organized by the centrosome; however, this investigation explores the importance of cytoskeletal elements in directing centrosome shape. Since the sea urchin egg during fertilization and mitosis displays dramatic and synchronous changes in centrosome shape, the effects of cytoskeletal inhibitors on centrosome compaction, expansion, and separation were explored by the use of anticentrosome immunofluorescence microscopy. Centrosome expansion and separation was studied during two phases: the transition after sperm incorporation, when the compact sperm centrosome enlarges and the sperm aster develops, and from prometaphase to telophase, when the compact spindle poles enlarge. Compaction was investigated when the dispersed centrosome at interphase condenses into the two spindle poles at prometaphase. Although centrosome expansion and separation typically occur concurrently, beta-mercaptoethanol results in centrosome separation independent of expansion. Microtubule inhibitors prevent centrosome expansion and separation, and expanded centrosomes collapse. Since pronuclear union is arrested by microtubule inhibitors, this treatment also affords the opportunity to explore the relative attractiveness of the male and female pronuclei for these centrosomal antigens. Both pronuclei acquire centrosomal material; though only the male centrosome is capable of organizing a functional bipolar mitotic apparatus at first division, the female centrosome nucleates a monaster. Microfilament inhibition (cytochalasin D) prevents centrosome separation but not expansion or compaction. These results demonstrate that as the centrosome shapes the cytoskeleton, the cytoskeleton alters centrosome shape.     

Chloride permeability of sea urchin eggs.

We have examined the content and permeability of chloride in sea urchin eggs. After fertilization there is a large increase in the permeability to chloride. We discuss the mechanism underlying this permeability change and the generalized increase in ion permeability observed after fertilization.     

Sulfhydryl groups are involved in the activation of sea urchin eggs

Unfertilized sea urchin eggs exposed to the sulfhydryl reagents Ag⁺ or N-ethylmaleimide either elevated fertilizationlike membranes, formed surface protrusions, developed a clear cortical layer devoid of organelles, or cytolysed. The relative fraction of each modification varied from batch to batch and was also dose and time dependent. With Ag⁺ and higher doses of N-EMI (10^?3 M), the most common effect was the elevation of a membrane indicating cortical exocytosis, while at lower doses of N-EMI protrusions were predominant. Glutathione (GSH) protected eggs against these reagents also in a dose-dependent manner. Eggs exposed to equimolar amounts of N-EMI and GSH, which otherwise formed membranes, produced protrusions, while increasing GSH tenfold afforded complete protection. We suggest there are two targets for the sulfhydryl reagents–the first, SH groups on proteins that regulate the release of Ca²⁺ from the intracellular sequestering mechanism which subsequently triggers cortical exocytosis; the second, SH groups on the egg surface that may regulate cortical organization.     

Simulation of density gradients of astral microtubules at cell surface in cytokinesis of sea urchin eggs

Astral microtubules extend close to the cell surface just before cytokinesis in sea urchin eggs. At this time, a small region with a constant area is considered around a point on the egg surface. To calculate the number of microtubules that reach the surface region, i.e. the microtubule density at the point, a simple mathematical model was set up. The density was estimated at many surface points in multipolar and distorted eggs by using the model. A contour map was drawn to investigate the density gradients. The gradient patterns were compared with the distributions of contractile-ring microfilaments. The simulated cases were: (1) an unusual distribution of contractile-ring microfilaments in an egg that had polyasters and was compressed by a coverslip; (2) formation of contractile-ring microfilaments at the equatorial region in compressed eggs with a centrally-located mitotic apparatus; (3) normal furrowing in the plane of the spindle midpoint in eggs inserted into a glass loop or confined in a capillary; (4) failure of furrow formation in spherical eggs treated with ethyl urethane and revival of furrowing by pushing the equatorial surface close to the spindle. These simulations proposed the hypothesis that contractile-ring microfilaments form at surface regions where the microtubule density has a local minimum, not a local maximum. In addition, it was suggested that the probability of the formation of the contractile-ring microfilaments is dependent on how abruptly the density gradient changes at the local-minimum point. These results support the idea that the gradient pattern of the microtubule density determines whether and where contractile-ring microfilaments appear.     

Dynein isoforms in sea urchin eggs

Biochemical and immunological analysis of unfertilized sea urchin eggs has revealed the presence of at least two distinct isoforms of cytoplasmic dyneins, one soluble and the other microtubule-associated. The soluble enzyme is a 20 S particle with a MgATPase activity that can be activated 5-fold by nonionic detergents. It contains heavy chain polypeptides that 1) comigrate with the dynein heavy chains of embryonic cilia; 2) cross-react with antibodies against flagellar dynein; and 3) are cleaved by UV irradiation in the presence of MgATP and sodium vanadate into specific peptide fragments. The soluble egg dynein is, therefore, closely related to axonemal dynein and may be a ciliary precursor. Egg microtubule preparations contain a distinct dynein-like polypeptide, previously designated HMr-3 (Scholey, J.M., Neighbors, B., McIntosh, J.R., and Salmon, E.D. (1984) J. Biol Chem. 259, 6516-6525). HMr-3 binds microtubules in an ATP-sensitive fashion; it sediments at 20 S on sucrose density gradients, and it is susceptible to vanadate-sensitized UV cleavage. However, HMr-3 can be distinguished from the soluble cytoplasmic dynein on the basis of its weak cross-reactivity with antiflagellar dynein antibodies, its heavy chain composition on high resolution sodium dodecyl sulfate-polyacrylamide gel electrophoresis, its low specific ATPase activity, and the molecular weight of its vanadate-induced UV cleavage fragments. HMr-3 may represent a dynein-like polypeptide that is distinct from the pool of ciliary dynein precursors.     

Action of colcemid in sea urchin eggs

The effects of Colcemid, the deacetyl-N-methyl derivative of colchicine, on the eggs of Arbacia punctulata were investigated. Colcemid in concentrations of 2.7 x 10^-5 M or greater blocks syngamy (the fusion of the pronuclei) in these eggs. Although a tenfold decrease in concentration of Colcemid usually permits the pronuclei to fuse, the subsequent division is blocked. In the sea urchin egg, the duration of presyngamy is about 15 min during which time there is no DNA synthesis. However, DNA synthesis is recorded in Colcemid-blocked cells prior to syngamy. Radioautographs of Colcemid-blocked cells which were immersed into thymidine-³H exhibited silver grains above each of the pronuclei. The action of Colcemid on Arbacia eggs is reversible. Nevertheless, exposures to 2.7 x 10^-5 M Colcemid for only 3 min, initiated 5 min after insemination, caused delays of 70 min in subsequent division. In general, cells are more sensitive to Colcemid prior to the time when the mitotic spindle is being assembled than at presyngamy stages. The results are discussed in terms of Colcemid action on pronuclear fusion and cell division.     

Ribosomal proteins of sea urchin eggs

Summary Ribosomal proteins from unfertilized eggs of three sea urchin species, Pseudocentrotus depressus, Hemicentrotus pulcherrimus, and Anthocidaris crassispina, were analyzed. Species-specific differences were observed in the profiles of large subunit proteins on two-dimensional slab gels, though the number of ribosomal proteins and the molecular weights of their counterparts were the same. The small subunit proteins revealed similarities in the electrophoretic profiles and in the phosphorylation patterns among these three species.     

Fertilization kinetics of sea urchin eggs

Eggs and sperm of the sea urchin Paracentrotus lividus of the Mediterranean are used for an in vitro study of fertilization kinetics. The results are analyzed in terms of two models. One of these models assumes that all sperm-egg encounters lead to permanent attachment; the other (less realistically) assumes that sperm continue their random search after an unsuccessful encounter. More than 100 spermatozoa per egg are needed to achieve a fertilization ratio of more than 95%. There are two explanations for this: only 1% of the egg surface is subject to fertilization, or only 1% of spermatozoa are intrinsically able to fertilize. In the same context, chemotactic attraction and the role of the jelly are discussed. Comparison with earlier work of Rothschild and Swann and of Hultin and Hagström clarifies some discrepancies between and within these papers.     

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.     

SHCBP1 is required for midbody organization and cytokinesis completion

The centralspindlin complex, which is composed of MKLP1 and MgcRacGAP, is one of the crucial factors involved in cytokinesis initiation. Centralspindlin is localized at the middle of the central spindle during anaphase and then concentrates at the midbody to control abscission. A number of proteins that associate with centralspindlin have been identified. These associating factors regulate furrowing and abscission in coordination with centralspindlin. A recent study identified a novel centralspindlin partner, called Nessun Dorma, which is essential for germ cell cytokinesis in Drosophila melanogaster. SHCBP1 is a human ortholog of Nessun Dorma that associates with human centralspindlin. In this report, we analyzed the interaction of SHCBP1 with centralspindlin in detail and determined the regions that are required for the interaction. In addition, we demonstrate that the central region is necessary for the SHCBP1 dimerization. Both MgcRacGAP and MKLP1 are degraded once cells exit mitosis. Similarly, endogenous and exogenous SHCBP1 were degraded with mitosis progression. Interestingly, SHCBP1 expression was significantly reduced in the absence of centralspindlin, whereas centralspindlin expression was not affected by SHCBP1 knockdown. Finally, we demonstrate that SHCBP1 depletion promotes midbody structure disruption and inhibits abscission, a final stage of cytokinesis. Our study gives novel insight into the role of SHCBP in cytokinesis completion.     

Giant pools of DNA precursors in sea urchin eggs.

Tritiated cytochalasin D (³H-CD) is rapidly taken up by monolayers of HEp-2 HeLa and rhabdomyosarcoma cells, reaching a maximum incorporation within 5 min at 37 °C. Upon rinsing and refeeding, 80% of the bound drug rapidly dissociates from the cells; the remaining 20 % is lost more slowly. Binding is dose-dependent in a non-linear fashion; Scatchard plots are biphasic, suggesting binding of higher and lower affinity. Inhibitors of energy metabolism do not diminish binding of ³H-CD. The plasma membrane fraction of HEp-2 exhibits the highest specific binding activity (146 dpm/μg protein) and contains both high and low affinity binding sites. Endomembranes (microsomes) have moderate specific binding activity (35 dpm/μg protein) and appear to contain only low affinity binding sites. Nuclear, mitochondrial, and cytosol fractions exhibit low, probably negligible, binding. These results are consistent with the evidence afforded by radioautography. Selective enzyme digestions of whole cells and the plasma membrane fraction indicate that binding of CD requires proteins not exposed on the outer surface of the cell. Because electron micrographs of the plasma membrane fraction demonstrate microfilaments attached to the membrane, the binding data may be interpreted as evidence for an interaction of CD either with the subplasmalemmal microfilaments or directly with the plasma membrane.     

Metal-binding proteins in eggs of various sea urchin species.

Metallothionein presence and amount were determined in the unfertilized eggs of six sea urchin species by silver saturation assay and gel-chromatography of cell extracts. The results showed high levels of metallothionein in the egg cytoplasm of the two Mediterranean species Paracentrotus lividus and Sphaerechinus granularis. No metallothionein was found either in the eggs of Arbacia lixula, or in those of the three Eastern species Strongylocentrotus intermedius, Temnopleurus hardwickii and Clypeaster japonicus. However, the extracts of the latter three species revealed the presence of zinc bound in a macromolecular form, thus suggesting the existence of metal-binding proteins distinct from metallothioneins.     

RNA synthesis in unfertilized sea urchin eggs

We have examined the synthesis of messenger-like RNA in unfertilized sea urchin eggs. Most of the RNA synthesized is restricted to the nucleus and sediments from 16 to 30S. A small fraction can be isolated from the postmitochondrial supernatant and displays a sedimentation profile typical of embryonic mRNA with peaks at 9 and 18S. This cytoplasmic RNA is largely present as free RNPs and we estimate that less than 20% of the RNA is in polysomes. The RNA made in the egg is unstable and reaches a steady state with a half-time of about 30 min. We have examined the accumulation of RNA in the egg and have calculated a rate of synthesis of 1.4 × 10^?14 g of RNA/min/egg which is similar, on a per-nucleus basis, to that found in the just-fertilized egg and very early embryo. It is approximately 10 times greater than the rate of RNA synthesis in the blastula nucleus. We estimate that the RNA synthesized by the unfertilized egg amounts to a maximum of 3 × 10^?13 g of potential mRNA at the time of fertilization, or 10–15% of its immediate needs. This RNA cannot account for the increase in protein synthesis that occurs after fertilization, which must be the result of the translation of another population of more stable egg or oogenic mRNA that is kinetically distinct from the RNA we have measured. The steady-state level of labeled RNA present in the egg does not change upon fertilization until after the first cleavage, at about 2.5 hr after fertilization. Thus the RNA synthesis that occurs in the just-fertilized zygote appears to be merely a continuation (at least quantitatively) of the RNA synthesis taking place in the egg.     

NAADP-induced calcium release in sea urchin eggs

Nicotinic acid adenine dinucleotide phosphate (NAADP) is the most potent activator of Ca2+ release from intracellular stores described. It acts on a mechanism distinct from inositol trisphosphate and ryanodine receptors, the two major Ca2+ release channels characterised. NAADP-gated Ca2+ release channels do not appear to be regulated by Ca2+ and may be better suited for triggering Ca2+ signals rather than propagating them. They exhibit a remarkable pharmacology for a putative intracellular Ca2+ release channel in that they are selectively blocked by potassium and L-type Ca2+ channel antagonists. Furthermore, in contrast to microsomal Ca2+ stores expressing IP3Rs and RyRs, those sensitive to NAADP are thapsigargin-insensitive, suggesting that they may be expressed on a different part of the endoplasmic reticulum. Perhaps the most unusual feature of the NAADP-gated Ca2+ release mechanisms is its inactivation properties. Unlike the mechanisms regulated by IP3 and cADPR in sea urchin eggs which after induction of Ca2+ release appear to become refractory to subsequent activation, very low concentrations of NAADP are able to inactivate NAADP-induced Ca2+ release fully at concentrations well below those required to activate Ca2+ release. The mechanism and physiological significance of this most unusual desensitisation phenomenon are unclear. More recently, NAADP has been shown to mobilise Ca2+ in ascidian oocytes, brain microsomes and pancreatic acinar cells suggesting a more widespread role in Ca2+ signalling. A possible role for this novel Ca2+ release mechanism in sea urchin egg fertilisation is discussed.     

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.