Centrosome destined to decay in starfish oocytes.

In contrast to the somatic cell cycle, duplication of the centrioles does not occur in the second meiotic cycle. Previous studies have revealed that in starfish each of the two centrosomes in fully-grown immature oocytes consists of two centrioles with different destinies: one survives and retains its reproductive capacity, and the other is lost after completion of meiosis. In this study, we investigated whether this heterogeneity of the meiotic centrioles is already determined before the re-initiation of meiosis. We prepared a small fragment of immature oocyte containing the four centrioles and fused it electrically with a mature egg in order to transfer two sets of the premeiotic centrioles into the mature cytoplasm. Two asters were present in this conjugate, and in each of them only a single centriole was detected by electron microscopy. In the first mitosis of the conjugate artificially activated without sperm, two division poles formed, each of which doubled in each subsequent round of mitosis. These results indicate that only two of the four premeiotic centrioles survived in the mature cytoplasm and that they retained their reproductive capacity, which suggests that the heterogeneity of the maternal centrioles is determined well before re-initiation of meiosis, and that some factor in the mature cytoplasm is responsible for suppressing the reproductive capacity of the centrioles destined to decay.

Role of microtubules and centrosomes in the eccentric relocation of the germinal vesicle upon meiosis reinitiation in sea-cucumber oocytes.

In the oocytes of many animals, the germinal vesicle (GV) relocates from the center to the periphery of the oocyte upon meiosis reinitiation, which is a prerequisite to the formation of meiotic spindles beneath the cell surface in order for meiosis to succeed. In the present study, we have investigated nuclear positioning using sea-cucumber oocytes. Upon meiosis reinitiation, the GV relocates to the cell periphery beneath a surface protuberance. After GV breakdown, polar bodies were extruded from the top of the protuberance, which we therefore called the animal pole process. The GV relocation was inhibited by nocodazole but not by cytochalasin. Immunofluorescent staining and electron microscopy of microtubular arrays revealed that: (i) in immature oocytes, two centrosomes were situated beneath the animal pole process far apart from the GV, anchoring to the cortex via astral microtubules; (ii) upon meiosis reinitiation, microtubular bundles were newly formed between the centrosomes and the GV; and (iii) the microtubular bundles became short as GV migration proceeded. These observations suggest that microtubules and centrosomes participate in GV relocation. A very large mass of annulate lamellae, having a 20-microm diameter, was found in the vegetal pole of the oocytes.

Regulation of the paternal inheritance of centrosomes in starfish zygotes.

In most animals, fertilized eggs inherit one centrosome from a meiosis-II spindle of oocytes and another centrosome from the sperm. However, since first proposed by Boveri [Sitzungsber. Ges. Morph. Phys. Münch. 3 (1887) 151-164] at the turn of the last century, it has been believed that only the paternal (sperm) centrosome provides the division poles for mitosis in animal zygotes. This uniparental (paternal) inheritance of centrosomes is logically based on the premise that the maternal (egg) centrosome is lost before the onset of the first mitosis. For the processes of the selective loss of the maternal centrosome, three models have been proposed: One stresses the intrinsic factors within the centrosome itself; the other two emphasize external factors such as cytoplasmic conditions or the sperm centrosome. In the present study, we have examined the validity of one of the models in which the sperm centrosome overwhelms the maternal centrosomes. Because centrosomes cast off into both the first and the second polar bodies (PB) are known to retain the capacity for reproduction and cell-division pole formation, we observed the behavior of those PB centrosomes with reproductive capacity and the sperm centrosome in the same zygotic cytoplasm. We prepared two kinds of fertilized eggs that contain reproductive maternal centrosomes, (1) by micromanipulative transplantation of the PB centrosomes into fertilized eggs, and (2) by suppression of the PB extrusions of fertilized eggs with cytochalasin B. In both types of eggs, the PB centrosomes could double and form cell-division poles, indicating that they are not suppressed by the sperm centrosome, which in turn indicates that selective loss of the maternal centrosome is due to intrinsic factors within the centrosomes themselves.

Role of specialized microvilli and the fertilization envelope in the spatial positioning of blastomeres in early development of embryos of the starfish Astropecten scoparius.

In the eggs of a wide range of animal species, various factors that determine the blastomeres' presumptive fate are known to locate unevenly within the egg. In the embryos of these animals, cleavage occurs not just to increase cell numbers, but also to distribute the factors to the respective blastomeres, resulting in cell specialization at the later stages. In the early cleavage stages, before the establishment of a device such as desmosomes to directly join the blastomeres, some other means is needed to keep the blastomeres together and maintain the relative positions among them. In this study, we found that the embryos of the starfish Astropecten scoparius lack the hyaline layer seen in sea urchin embryos and that blastomeres adhere to the fertilization envelope (FE) via filamentous cellular projections (fixing processes). Electron microscopy revealed the fixing processes to be specialized microvilli formed, after the elevation of the FE, by the elongation of short microvilli that pre-exist in unfertilized eggs. After the first cleavage, the two blastomeres separate from each other and finally attach to the FE. In the subsequent cleavages, the blastomeres undergo repeated cell division without separating from the FE. Between the blastomeres and the FE, only shortened fixing processes were observed. Destruction of the fixing processes caused release of the blastomeres from the FE and disturbance of the relative positions of the blastomeres, resulting in abnormal development of the embryos. These observations suggest that the fixing process is a device to keep the egg placed centrally in the FE up to the first cleavage, and after the first cleavage and beyond to anchor the blastomeres to the FE so that the FE can be used as a scaffold for morphogenesis. Electron microscopy also suggests that the inner layer of the FE, which is derived from the contents of cortical granules, reinforces the adhesion of the fixing processes to the FE. Immuno-electron microscopy, using an antibody against sea urchin hyaline layer, showed that the inner layer of the FE of starfish eggs and the hyaline layer of sea urchin eggs, which are both derived from cortical granules, contain some common elements.

Ultrastructural Studies on the Behavior of Centrioles during Meiosis of Starfish Oocytes: (oocyte/meiosis/centriole/starfish).

The behavior of centrioles and ultrastructural changes of the nucleus were observed in maturing oocytes of the starfishes, Asterina pectinifera and Asterias amurensis. Observations were focused on the number and behavior of centrioles during two successive meiotic divisions. Examination of serial sections revealed that in meiosis I each division pole has a pair of centrioles, whereas in meiosis II each has only one centriole, confirming the observations by Sluder et al. (1989) on oocytes of Pisaster ocraceus and Asterias forbesi. The first polar body had two centrioles and the second polar body had only one. These results indicate that no duplication of centrioles occurs during the two successive meiotic divisions, and that the egg inherits one centriole from a primary oocyte.

Absence of Species Specificity of Germinal Vesicle Factor Required for the Cytoplamic Cycle During Meiotic Division: (starfish oocyte/meiotic division/germinal vesicle/cortical tension/cytoplasmic cycle).

Germinal vesicles (GV) of starfish oocytes are known to contain some factor(s) indispensable for inducing cyclic cytoplasmic activity, which may be involved in driving meiotic cell cycle. We have examined species specificity of the factor by injecting enucleated oocytes of the starfish, Asterina pectinifera, with GV contents of either different starfish (Asterias amurensis, Astropecten scoparius) or sea cucumber (Holothuria moebi). The injected oocytes showed cyclic changes in cortical tension after treatment with 1-methyladenine. Thus the nature of the factor appears similar among echinoderms. Growing oocytes of A. pectinifera much smaller (75% in diameter) than fully-grown oocytes did contain the factor to rescue the enucleated oocytes, even though such small oocytes themselves did not respond to 1-methyladenine. This result suggests that the factor begins to accumulate at the earlier stage of oogenesis.

Nature of the 1-Methyladenine-Requiring Phase in Maturation of Starfish Oocytes: (1-methyladenine/oocyte maturation/oocyte stiffness/caffeine/starfish).

Reinitiation of meiosis in starfish oocytes requires the continuous presence of 1-methyladenine (1-MeAde) in the surrounding medium for a definite period. The length of the 'hormone-dependent phase' (HDP) in Asterina pectinifera, which was defined as the time necessary for induction of 50% germinal vesicle breakdown (GVBD), was found to be about 11 min at 17°C, and 8 min at 20°C. Repeated treatments for shorter periods with 1-MeAde revealed that the action of this agent was cumulative, and that stable intermediate states between the unstimulated and fully stimulated levels existed during the HDP. Measurement of the stiffness of oocytes also demonstrated this stable intermediate state. Thus, there may be a factor(s) in the cytoplasm that accumulates continuously during the HDP and triggers GVBD when it reaches a critical level(s). When dithiothreitol (DTT) was used as an artificial maturation-inducing agent, the intermediate state was far less stable, suggesting a difference in the modes of action of 1-MeAde and DTT. Isotonic CaCl2 , the Ca2+ ionophore (A 23187) and methylxanthines, which are known to cause increase in intracellular Ca2+ , had additive effects with 1-MeAde. These results suggest that part of the action of 1-MeAde is to release Ca2+ in the oocyte cytoplasm.

MARKED DECREASE IN THE RIGIDITY OF STARFISH OOCYTES INDUCED BY 1-METHYLADENINE1.

Extreme rigidity of immature starfish oocytes as measured by compression method was found to decline during the early phase of their maturation when induced by 1-methyladenine (1-MeAde). The onset of this decrease in stiffness occurred within 5 to 9 min of 1-MeAde treatment, well before the breakdown of the germinal vesicle, progressively declining to reach a minimum stiffness after 20 min. Dithiothreitol, known as an artificial maturation-inducing agent, caused a similar change. The stiffness is thus expected to serve as a quantitative indicator of the early process of cytoplasmic events, which would induce the breakdown of the germinal vesicle. Cytochalasin B (3 µg/ml) also reduced the stiffness, but unlike the former two agents, the effect was reversible, and did not interfere with the process of maturation. Due to the effect of cytochalasin B, it became possible to enucleate immature oocytes by centrifugal force. Non-nucleate fragments thus obtained still maintained their marked stiffness, which was decreased by the action of 1-MeAde, with a time-course similar to that of intact oocytes.

PERIODIC CHANGES IN THE CONTENT OF PROTEIN-BOUND SULFHYDRYL GROUPS AND TENSION AT THE SURFACE OF STARFISH OOCYTES IN CORRELATION WITH THE MEIOTIC DIVISION CYCLE.

The sulfhydryl content of protein and the tension at the surface were measured for starfish oocytes from the first meiotic division to the cleavage stage. A cyclic change in both the protein-SH and the tension at the surface was found to accompany the division cycle, including the first and second meiotic divisions. It is concluded that the unequal meiotic divisions share the same character with the equal divisions of cleavage, with respect to changes both in the protein-SH and the tension at the surface.

CHANGES IN THE LEVEL OF ARGININE PHOSPHATE FOLLOWING FERTILIZATION OF ECHINODERM EGGS.

The content of arginine phosphate was measured following fertilization of sea-urchin eggs and starfish oocytes. In sea-urchin eggs, a rise in the level of arginine phosphate occurred within 2 min after insemination: this was not accompanied by any detectable alteration in the level of ATP. On the other hand, the level of arginine phosphate in starfish oocytes did not change on fertilization.