Induction of cytoplasmic maturation by 1-methyladenine in starfish oocytes after removal of the germinal vesicle

Fertilization in Starfish and Sea Urchin: Roles of Actin

Marine animals relying on "external fertilization" provide advantageous opportunities to study the mechanisms of gamete activation and fusion, as well as the subsequent embryonic development. Owing to the large number of eggs that are easily available and handled, starfish and sea urchins have been chosen as favorable animal models in this line of research for over 150 years. Indeed, much of our knowledge on fertilization came from studies in the echinoderms. Fertilization involves mutual stimulation between eggs and sperm, which leads to morphological, biochemical, and physiological changes on both sides to ensure successful gamete fusion. In this chapter, we review the roles of actin in the fertilization of starfish and sea urchin eggs. As fertilization is essentially an event that takes place on the egg surface, it has been predicted that suboolemmal actin filaments would make significant contributions to sperm entry. A growing body of evidence from starfish and sea urchin eggs suggests that the prompt reorganization of the actin pools around the time of fertilization plays crucial regulatory roles not only in guiding sperm entry but also in modulating intracellular Ca²⁺ signaling and egg activation.

Metabolic cooperation following fusion of starfish ootid and primary oocyte restores meiotic-phase-promoting activity

In the starfish Marthasterias glacialis, polyethylene glycol (PEG) homologous fused pairs consisting of two immature oocytes, blocked at the germinal vesicle stage, or two ootids, blocked at the female pronucleus stage, remain arrested at these specific stages, unless they are stimulated by the hormone 1-methyladenine. In contrast, heterologous pairs develop up to female pronucleus formation in the immature partner, indicating that maturation-promoting factor was formed under these conditions. Kinetics for this process, reconstitution of the nuclear envelopes after first polar body extrusion, and delaying effect of emetine argue for the existence of a true metabolic cooperation process requiring complementary factors present in each partner. The effect of inhibitors that penetrate the plasma membrane points to the possible involvement of endogenous proteases that may activate latent or neosynthesized maturation-promoting factor precursor and/or protein kinases.

Determination of first cleavage plane: the relationships between the orientation of the mitotic apparatus for first cleavage and the position of meiotic division-related structures in starfish eggs

In order to understand when the orientation of the first cleavage plane is fixed along the animal-vegetal axis in starfish eggs, the behavior of the sperm aster was examined by indirect immunofluorescence staining. After duplication, the sperm aster organizes the mitotic apparatus for first cleavage perpendicular to the cleavage plane. The sperm aster located in the egg periphery just after fertilization and moved to the site close to the animal pole rather than the egg center by meiosis II. At early metaphase II, duplication of the sperm aster was detected but the axis of the resultant sperm diaster randomly pointed. Subsequently, its axis had already turned perpendicular to the animal-vegetal axis before pronucleus fusion. These results indicate that the orientation processes of the sperm diaster consist of positioning before its duplication and successive determining its azimuth. Furthermore, the azimuth and position of the mitotic apparatus for first cleavage did not change by shifting or eliminating the meiotic division-related structures such as the germinal vesicle, meiotic spindle, and female pronucleus by micromanipulation. These results show that none of them determines the first cleavage plane. Therefore, we discuss the pointing mechanism of the first cleavage plane without the influence of these meiotic division-related structures.

NAADP+ initiates the Ca2+ response during fertilization of starfish oocytes

We have explored the role of the recently discovered second messenger nicotinic acid adenine nucleotide phosphate (NAADP+) in Ca2+ swings that accompany the fertilization process in starfish oocytes. The injection of NAADP+ deep into the cytoplasm of oocytes matured by the hormone 1-methyladenine (1-MA), mobilized Ca2+ exclusively in the cortical layer, showing that the NAADP+-sensitive Ca2+ pool is restricted to the subplasma membrane region of the cell. At variance with this, InsP3 initiated the liberation of Ca2+ next to the point of injection in the center of the cell. The initial cortical Ca2+ liberation induced by NAADP+ was followed by a spreading of the Ca2+ wave to the remainder of the cell and by a massive cortical granule exocytosis similar to that routinely observed on injection of InsP3. A striking difference in the responses to NAADP+ and InsP3 was revealed by the removal of the nucleus from immature oocytes, i.e., from oocytes not treated with 1-MA. Whereas the Ca2+ response and the cortical granule exocytosis induced by NAADP+ were unaffected by the removal of the nucleus, the Ca2+ response promoted by InsP3 was significantly slowed. In addition, the cortical granule exocytosis was completely abolished. When enucleated oocytes were fertilized, the spermatozoon still promoted the Ca2+ wave and normal cortical exocytosis, strongly suggesting that the Ca2+ response was mediated by NAADP+ and not by InsP3. InsP3-sensitive Ca2+ stores may mediate the propagation of the wave initiated by NAADP+ since its spreading was strongly affected by removal of the nucleus.

Cortical changes in starfish (Asterina pectinifera) oocytes during 1-methyladenine-induced maturation and fertilisation/activation

Maturation of the starfish oocyte cortex to produce an effective cortical granule reaction and fertilisation envelope is believed to develop in three phases: (1) pre-methyladenine (1-MA) stimulation; (2) post-1-MA stimulation, pregerminal vesicle breakdown; and (3) post-germinal vesicle breakdown. The present study was initiated to identify what each of these phases may encompass, specifically with respect to structures associated with the oocyte cortex, including cortical granules, microvilli and vitelline layer. 1-MA treatment brought about an orientation of cortical granules such that they became positioned perpendicular to the oocyte surface, and an approximately 4-fold decrease in microvillar length. A-23187 activation of immature oocytes treated with (10 min; pregerminal vesicle breakdown) or without 1-MA resulted in a reduction in cortical granule number of 21% and 41%, respectively (mature oocytes underwent a 96% reduction in cortical granules). Elevation of the fertilisation envelope in both cases was significantly retarded compared with activated mature oocytes. In activated mature oocytes, the vitelline layer elevated 20.0 +/- 5.4 mu m from the egg's surface, whereas in immature oocytes treated with just A-23187 or with 1-MA (10 min) and A-23187, it lifted 0.35 +/- 0.1 and 0.17 +/- 0.04 mu m, respectively. The fertilisation envelopes of activated (or fertilised) immature oocytes also differed morphologically from those of mature oocytes. In activated, immature oocytes, the fertilisation envelope was not uniform in its thickness and possessed thick and thin regions as well as fenestrations. Additionally, it lacked a complete electron-dense stratum that characterised the fertilisation envelopes of mature oocytes. The nascent perivitelline space of immature oocytes was also distinguished by the presence of numerous vesicles which appeared to be derived from microvilli. Differences in the morphology of cortices from activated (fertilised) and non-activated, immature and mature oocytes substantiate previous investigations demonstrating three phases of cortical maturation, and are consistent with physiological changes that occur during oocyte maturation, involving ionic conductance of the plasma membrane, establishment of slow and fast blocks to polyspermy and elevation of a fertilisation envelope.

A review of echinoderm oogenesis

This review of the anatomical, histological, biochemical, and molecular biological literature on echinoderm oogenesis includes the entire developmental history of oocytes; from their inception to the time they become ova. This is done from a comparative perspective, with reference to members of the five extant echinoderm classes; crinoids, holothurians, asteroids, ophiuroids, and echinoids. I describe the anatomy and fine structure of the echinoderm ovary, with emphasis on both the cellular relationships of the germ line cells to the somatic cells of the inner epithelium, and on the neuromuscular systems. I review the literature on the growth of oogonia into fully formed oocytes, including the process of vitellogenesis, presenting an ultrastructural analysis of the organelles and extracellular structures found in fully formed echinoderm oocytes. Echinoderm oocyte maturation is reviewed and a description of the ultrastructural, biochemical and molecular biological changes thought to occur during this process is presented. Finally, I discuss oocyte ovulation, the severing of cellular connections between the oocyte and its surrounding somatic epithelial cells.

Germinal vesicle components are not required for the cell-cycle oscillator of the early starfish embryo

We show that certain events of the cell cycle can still occur in starfish oocytes or fertilized eggs from which the germinal vesicle (the prominent nucleus of prophase-arrested oocytes) has been removed before the induction of meiotic maturation. Two meiotic asters develop following hormonal induction of meiotic maturation in these enucleated oocytes. The asters then divide to form a transient tetrapolar figure. When enucleated oocytes are fertilized, the sperm centrosome duplicates at the times corresponding to each cleavage in control nucleated embryos. Periodic changes in the organization of the asters and in the morphology of the cell surface also occur in synchrony with controls. Decondensation of the sperm nucleus, spindle formation, and cleavage do not occur when enucleated oocytes are fertilized. Ultimately the number of asters increases to approximately 520 (about 2(9] before the pseudo-embryo arrests and cytolyzes. Fertilized eggs from which both pronuclei but not the sperm aster have been removed undergo nine cleavages and then cease cell division. The cessation of division may be related to the events that cause the midblastula transition after seven cleavages in normal nucleated embryos.

Morphological changes during maturation of starfish oocytes: surface ultrastructure and cortical actin

The cell surface and extracellular investments of oocytes of the starfish Pisaster ochraceus are analyzed by Nomarski differential interference contrast microscopy and by scanning electron microscopy. The investing coats include a thin sheet of follicle cells, a jelly coat, and a vitelline layer; their morphologies are described. Methods are outlined for systematically removing them without altering the behavior of the oocyte so that the cell surface can be examined directly. The topography of denuded oocytes changes dramatically when they are treated with the maturation-inducing hormone, 1-methyladenine. The major topographical change is the early and transient formation of prominent surface spikes. These structures arise due to the rapid, reversible polymerization of actin into stout bundles. Polymerization and subsequent depolymerization of cortical actin is monitored by epifluorescence microscopy of oocytes stained with NBD-phallacidin, a stain which is specific for polymerized actin. Based on scanning electron microscopy, spikes apparently utilize preexisting plasma membrane of microvilli, and plasma membrane is apparently lost when spikes collapse. Long after microvilli are eliminated due to spike formation, the number of microvilli is somewhat restored, especially around the animal pole where the polar body forms. A chronology of events observed during oocyte maturation is discussed with reference to the possible mechanisms and implications of polymerization and depolymerization of cortical actin.

Cytoplasmic cycle in meiotic division of starfish oocytes

Nonnucleate fragments of sea urchin and amphibian eggs are known to show an autonomous cyclic activity whose interval is comparable to the cleavage interval of normal eggs. In order to examine for the presence of such a cytoplasmic cycle in meiotic division, maturing oocytes of the starfish, Asterina pectinifera, were bisected into halves about 10 min after germinal vesicle breakdown, and tension at the surface of the nonnucleate fragments was continuously measured by a compression method. The nonucleate fragments were found to show cyclic changes in the tension, with a temporal pattern very similar to that of the changes accompanying the two successive meiotic divisions of normal oocytes; i.e., the sharp peak in the tension was found to occur always twice, and only twice. However, the nonnucleate fragment of immature oocytes showed only a gradual rise in the tension without any cyclic change even when it was induced to mature by 1-methyladenine. When the maturing oocyte was bisected before germinal vesicle breakdown, the nonnucleate fragment still did not cycle. These results indicate that cytoplasm of maturing oocytes which underwent germinal vesicle breakdown is endowed not only with cyclic activity, but also with terminating it after two cycles. It is suggested that germinal vesicle material may trigger such an autonomous cyclic activity.

Electron microscopic study of the cortical reaction of an ophiuroid echinoderm

The egg coats of an ophiuroid echinoderm (Ophiopholis aculeata) are described by electron microscopy before and after fertilization. The unfertilized egg is closely invested by a vitelline coat about 40 A thick, and the peripheral cytoplasm is crowded with cortical granules five or six deep. During the cortical reaction, which rapidly follows insemination, exocytosis of cortical granules takes place. Some of the cortical granule material is evidently added to the vitelline coat to form a composite structure, the fertilization envelope, which is made up of a 400 A thick middle layer separating inner and outer dense layers, each about 50 A thick. The elevation of the fertilization envelope from the egg surface creates a perivitelline space in which the hyaline layer soon forms. The hyaline layer is about 2 micron thick, finely granular, and apparently derived from cortical granule material. The extracellular layers of the early developmental stages of ophiuroids and echinoids are quite similar in comparison to those of asteroids; this finding helps support Hyman's argument that the ophiuroids are more closely related to the echinoids than to the asteroids.

Cytoplasmic activation of starfish oocytes by sperm and divalent ionophore A-23187

The relationship between onset of the early cytoplasmic stages of oocyte activation (vitelline membrane separation and elevation) and nuclear meiotic maturation was investigated in starfish oocytes after their exposure to divalent ionophore (A-23187) or sperm. Meiotically mature oocytes, isolated in calcium-free seawater, underwent activation in response to sperm or ionophore as previously reported. Large, immature starfish oocytes, arrested in prophase I of meiosis (germinal vesicle stage), underwent vitelline membrane elevation when treated with divalent ionophore A-23187 or starfish sperm. Histological studies demonstrated that cortical granule breakdown in the oocyte cortex was associated with vitelline membrane elevation after these treatments. Activation of oocytes by sperm occurred only in response to starfish sperm. Sea urchin, sand dollar, surf clam, or marine worm sperm did not induce vitelline membrane elevation of either immature or mature starfish oocytes. Sperm- or ionophore-activated immature oocytes underwent nuclear maturation after addition of the meiosis-inducing hormone, l-methyladenine; however, parthenogenetic development did not occur and embryonic development was markedly inhibited. In contrast to previous studies, the present results indicate that cytoplasmic activation can be initiated before and without hormone induction of the nuclear maturation process. Differentiation of the oocyte cell surface or cortex reactivity therefore appears to occur during oogenesis rather than as a consequence of maturation. The data further support the view that divalent ions mediate certain of the early activation responses initiated by sperm at the time of fertilization and that synchronization of fertilization to the meiotic process in the oocyte is important for the occurrence of normal development.

Action potential and non-linear current-voltage relation in starfish oocytes

1. The electrical properties of the oocyte membrane of the starfish, Asterina pectinifera, were investigated using an intracellular microelectrode. 2. The resting potential in artificial sea-water ranged from -70 to -80 mV. 3. The starfish oocyte membrane was capable of generating an action potential as a result of permeability increases to both Ca and Na ions.4. The Ca component of the action potential was reversibly suppressed by Co or Mg ions, while the Na component was not affected by tetrodotoxin 5 times 10-minus 6 g/ml. 5. The steady-state relation of voltage vs. current was not linear but S-shaped. The curve wascomposed of inward-going rectification at the membrane potential more negative than -65 mV, outward-going rectification at the potential more positive than OmV and the transitional region between them. These findings are compared with those obtained in the mature egg of the tunicate.