Calcium transients accompany ooplasmic segregation in zebrafish embryos

Through the injection of f -aequorin (a calcium-specific luminescent reporter), and the use of an imaging photon detector, transient localized elevations of free cytosolic calcium in the forming blastodisc (BD) and animal hemisphere cortex were visualized that correlated with ooplasmic segregation. The introduction of an appropriate concentration of the weak (K_D= 1.5 μmol/L) calcium buffer 5,5'-dibromo-BAPTA results in the dissipation of these calcium domains, and inhibits cytoplasmic streaming and the subsequent formation of a BD at the animal pole. These inhibitory actions are dependent on the final cytosolic concentration of buffer within the egg: ≥ 1.3 mmol/L blocks ooplasmic streaming; < 1.3 mmol/L eggs segregate normally. Injection of 5,5'-dimethyl-BAPTA (K_D= 0.15 μmol/L) to a final concentration of 1.5 mmol/L as a control has no effect on ooplasmic streaming. These results suggest that localized domains of elevated free cytosolic calcium are essential for ooplasmic segregation in zebrafish. Furthermore, a hypothetical model is presented linking these calcium transients to the contraction of a cortically located actin microfilament network as a possible mechanism providing the driving force for segregation.     

Obstruction of Blastodisc Formation by Cytochalasin B in the Zebrafish, Brachydanio rerio

The blastodisc formation in the zebrafish, Brachydanio rerio , was obstructed by treatment with 1.0 μg/ml of cytochalasin B (CB), but not by 1.0 μg/ml of colchicine. The cortex in normal eggs contained a meshwork of microfilaments associated with the plasma membrane. The cortex was thicker at the vegetal pole and thinner at the animal pole of the egg. In CB treated eggs the cortex contained masses of microfilaments detached in places from the plasma membrane. Microtubules were never observed in the cortex of eggs with or without CB treatment. These results suggest that ooplasmic segregation, which results in blastodisc formation, is carried out by activity of the cortex, which contains CB sensitive microfilaments.     

The effect of local cortical microfilament disorganization on ooplasmic segregation in the loach (Misgurnus fossilis) egg

Injections of cytochalasin D (CD) or DNase I under the surface of fertilized loach egg result in local disorganization of microfilamentous cortex (MC) as revealed by transmission electron microscopy. This effect correlates with the loss of the cortex ability to contract in vitro. The disorganization of MC in the vegetal hemisphere of the egg does not affect the ooplasm segregation or blastodisk cleavage. Injection under the animal pole suppresses blastodisk formation and results in the autonomous separation of ooplasm in the central part of the egg. The experiments suggest that (1) autonomous separation of ooplasm from the yolk granules can proceed in the central part of the egg without the participation of MC; (2) normal segregation of ooplasm at the animal pole requires that the structures of microfilaments in the animal hemisphere (but not in the vegetal one) be preserved.     

The cortical contraction related to the ooplasmic segregation inCiona intestinalis eggs

Summary The egg cytoplasm of ascidian,Ciona intestinalis, segregates towards both the animal and vegetal poles within a few minutes of fertilization or parthenogetic activation with ionophore A23187. A constriction appears first on the egg surface near the animal pole and then moves to the vegetal pole. Carmine granules and spermatozoa attached to the egg surface move towards the vegetal pole with the movement of the constriction. Microvilli, which are distributed uniformly in unfertilized egg, disappear on the animal side of the constriction and became more dense on the vegetal side of the constriction. Transmission electron microscopy revealed that sub-cortical cytoplasm, containing numerous mitochondria and sub-cortical granules, moves towards the vegetal pole with the movement of the constriction and then concentrates into a cytoplasmic cap at the vegetal pole. An electron-dense layer appears in the cortex of the cap. The ooplasmic segregation and the cortical contraction were inhibited by cytochalasin B and induced by ionophore A23187. These observations suggest that ooplasmic segregation is caused by the cortical contraction which is characterised by a surface constriction and by the formation of an electron-dense layer.     

The activation wave of calcium in the ascidian egg and its role in ooplasmic segregation

We have studied egg activation and ooplasmic segregation in the ascidian Phallusia mammillata using an imaging system that let us simultaneously monitor egg morphology and calcium-dependent aequorin luminescence. After insemination, a wave of highly elevated free calcium crosses the egg with a peak velocity of 8-9 microns/s. A similar wave is seen in egg fertilized in the absence of external calcium. Artificial activation via incubation with WGA also results in a calcium wave, albeit with different temporal and spatial characteristics than in sperm-activated eggs. In eggs in which movement of the sperm nucleus after entry is blocked with cytochalasin D, the sperm aster is formed at the site where the calcium wave had previously started. This indicates that the calcium wave starts where the sperm enters. In 70% of the eggs, the calcium wave starts in the animal hemisphere, which confirms previous observations that there is a preference for sperm to enter this part of the egg (Speksnijder, J. E., L. F. Jaffe, and C. Sardet. 1989. Dev. Biol. 133:180-184). About 30-40 s after the calcium wave starts, a slower (1.4 microns/s) wave of cortical contraction starts near the animal pole. It carries the subcortical cytoplasm to a contraction pole, which forms away from the side of sperm entry and up to 50 degrees away from the vegetal pole. We propose that the point of sperm entry may affect the direction of ooplasmic segregation by causing it to tilt away from the vegetal pole, presumably via some action of the calcium wave.     

Polarity and reorganization of the endoplasmic reticulum during fertilization and ooplasmic segregation in the ascidian egg

During the first cell cycle of the ascidian egg, two phases of ooplasmic segregation create distinct cytoplasmic domains that are crucial for later development. We recently defined a domain enriched in ER in the vegetal region of Phallusia mammillata eggs. To explore the possible physiological and developmental function of this ER domain, we here investigate its organization and fate by labeling the ER network in vivo with DiIC16(3), and observing its distribution before and after fertilization in the living egg. In unfertilized eggs, the ER-rich vegetal cortex is overlaid by the ER-poor but mitochondria-rich subcortical myoplasm. Fertilization results in striking rearrangements of the ER network. First, ER accumulates at the vegetal-contraction pole as a thick layer between the plasma membrane and the myoplasm. This accompanies the relocation of the myoplasm toward that region during the first phase of ooplasmic segregation. In other parts of the cytoplasm, ER becomes progressively redistributed into ER-rich and ER- poor microdomains. As the sperm aster grows, ER accumulates in its centrosomal area and along its astral rays. During the second phase of ooplasmic segregation, which takes place once meiosis is completed, the concentrated ER domain at the vegetal-contraction pole moves with the sperm aster and the bulk of the myoplasm toward the future posterior side of the embryo. These results show that after fertilization, ER first accumulates in the vegetal area from which repetitive calcium waves are known to originate (Speksnijder, J. E. 1992. Dev. Biol. 153:259-271). This ER domain subsequently colocalizes with the myoplasm to the presumptive primary muscle cell region.     

Ooplasmic segregation of the myoplasmic actin network in stratified ascidian eggs

Summary Ooplasmic segregation in ascidians includes the movement of the myoplasm, a pigmented cytoplasmic region thought to be involved in the determination of the embryonic muscle and mesenchyme cell lineages, into the vegetal hemisphere of the egg. A myoplasmic cytoskeletal domain (MCD), composed of a cortical actin network (the PML) and an underlying filamentous lattice extending deep into the cytoplasm, is present in this region. The MCD gradually recedes into the vegetal hemisphere during ooplasmic segregation. It has been proposed that the segregation of the myoplasm is mediated by the contraction of the PML. To test this possibility we have examined ooplasmic segregation in eggs in which the internal parts of the MCD were separated from the PML by centrifugal force. Transmission and scanning electron microscopy of eggs extracted with Triton X-100 showed that the PML remained intact when the internal portions of the MCD were displaced and stratified by centrifugation. When stratified eggs were fertilized there were no rearrangements of the visible cytoplasmic inclusions, but the cellular deformations and the recession of the PML characteristic of ooplasmic segregation occurred as usual. The results indicate that the recession of the PML occurs independently of the internal constituents of the MCD and suggest that PML contraction is the motive force for ooplasmic segregation.     

Dynamic organization of cortical actin filaments during the ooplasmic segregation of ascidian Ciona eggs

Spatial reorganization of cytoplasm in zygotic cells is critically important for establishing the body plans of many animal species. In ascidian zygotes, maternal determinants (mRNAs) are first transported to the vegetal pole a few minutes after fertilization and then to the future posterior side of the zygotes in a later phase of cytoplasmic reorganization, before the first cell division. Here, by using a novel fluorescence polarization microscope that reports the position and the orientation of fluorescently labeled proteins in living cells, we mapped the local alignments and the time-dependent changes of cortical actin networks in Ciona eggs. The initial cytoplasmic reorganization started with the contraction of vegetal hemisphere approximately 20 s after the fertilization-induced [Ca²⁺] increase. Timing of the vegetal contraction was consistent with the emergence of highly aligned actin filaments at the cell cortex of the vegetal hemisphere, which ran perpendicular to the animal–vegetal axis. We propose that the cytoplasmic reorganization is initiated by the local contraction of laterally aligned cortical actomyosin in the vegetal hemisphere, which in turn generates the directional movement of cytoplasm within the whole egg.     

Scanning electron microscope studies on blastodisc formation in the zebrafish,Brachydanio rerio

Upon fertilization, the zebrafish egg undergoes marked physiological and structural changes, one of which involves blastodisc formation. Before fertilization, yolk globules are rounded and the endoplasm extends throughout the oocyte. During blastodisc formation, the yolk globules become angular and the endoplasm is restricted to streamers among the yolk globules. The streamers are oriented in an anterior-posterior axis of the egg. During blastodisc formation the cytoskeleton consists of an extensive array of filamentous structures of variable width in both the cortex as well as within elongate endoplasmic streamers. Although the filamentous components in the cortex and endoplasmic streamers probably include both microfilaments and microtubules, frequently they are somewhat wider than the usual dimensions, and possible reasons for this are suggested. From their arrangement in both the cortex and endoplasm, it seems likely that the components of the cytoskeleton (e.g., microfilaments and microtubules) may provide, through contraction, the major force responsible for the streaming of the endoplasm into the forming blastodisc. It is assumed that the surface tension of the vegetal hemisphere exceeds that of the animal hemisphere, thus forcing, through differential contraction, the endoplasm to flow in the direction of the forming blastodisc. No distinct barrier between the yolk and forming blastodisc was observed. The compressed condition of the larger and many-sided yolk globules could prevent their movement into the blastodisc. Scanning electron microscopy is limited in the resolution with which it can depict the cytoskeleton, but nonetheless it provides useful information about structural interrelationships.     

Bipolar segregation of mitochondria,actin network,and surface in the Tubifex egg: Role of cortical polarity

The role of the cortex in ooplasmic segregation of the yolky eggs of Tubifex has been studied by epifluorescence microscopy. Living eggs labeled with rhodamine 123 and fine carbon particles placed on the surface showed that, following the second polar body formation, the egg surface cosegregates with subcortical mitochondria in a bipolar fashion, viz. toward the animal and vegetal poles in the animal and vegetal hemispheres, respectively. The egg surface of each pole moves spirally while the equatorial surface appears to remain stationary during this process. The rhodamine-phalloidin staining of whole eggs reveals that actin networks cosegregate with mitochondria. Isolated cortices which were stained with rhodamine-phalloidin demonstrated that cortical actin is organized bipolarly and that, during ooplasmic segregation, it undergoes reorganization directed toward both poles of the egg. The cortical polarity expressed as actin organization is not disrupted by centrifugal force sufficient to stratify the egg cytoplasm into five layers. The surface of a centrifuged egg moves according to the original cortical polarity. This surface movement is accompanied by the reorganization of cortical actin which appears to be identical to that in intact eggs. Other centrifugation experiments have demonstrated that the connection of the subcortical cytoplasm to the cortex is resistant to a centrifugal force of up to 650g. The nature of cortical polarity and its role in ooplasmic segregation are discussed in the light of the present results.     

Ca2+-ionophore-induced microvilli and cortical contractions inXenopus eggs. Evidence for involvement of actomyosin

Summary Using scanning electron microscopy, we show that the calcium ionophore A23187 has a profound effect on the surface morphology ofXenopus laevis eggs. The response to ionophore can be interpreted with respect to animal/vegetal polarity and the presence of an asymmetrically organized actomyosin-based contractile system in the egg cortex. When incubated in ionophore, the egg cortex contracts, pigment granules move towards the animal pole, and microvilli increase dramatically in size. While at first overall microvilli density decreases, many additional microvilli appear later in the animal hemisphere but not in the vegetal hemisphere. Eggs incubated in high concentrations of A23187 undergo the same surface changes at a faster rate, and rupture due to a massive cortical contraction. Local application of ionophore to the egg surface results in increased microvilli size and density in that area, with the animal hemisphere showing the greatest response. Since the effects of ionophore are inhibited by the actomyosin probe, N-ethylmaleimide-modified heavy meromyosin, actomyosin is implicated in the ionophore-induced surface changes.     

Distribution of actin filaments in fertilized egg of the ascidian Ciona intestinalis

Microfilaments in the contracting cortex during the bipolar ooplasmic segregation of Ciona intestinalis eggs were examined by two methods, staining with fluorescent phalloidin and decoration with myosin subfragment 1 (S1). Fluorescent (Fl-)phalloidin revealed prominent fluorescence in the contracting cortex between the surface constriction and the vegetal pole of fertilized eggs. The animal pole did not stain. After extraction in Triton X-100, the cortex appeared as a thin layer that easily separated from cytoplasmic mass, especially at the contracting stage after fertilization. This layer also stained strongly with Fl-phalloidin. S1-decoration confirmed that actin filaments were abundant in the thin layer of Triton-extracted cortex. The actin filaments are considered to compose a contractile network covering the vegetal side of the constriction.     

Ooplasmic segregation in theTubifex egg: Mode of pole plasm accumulation and possible involvement of microfilaments

Summary Ooplasmic segregation, i.e. the accumulation of pole plasm in theTubifex egg, consists of two steps: (1) Cytoplasm devoid of yolk granules and lipid droplets migrates toward the egg periphery and forms a continuous subcortical layer around the whole egg; (2) the subcortical cytoplasm moves along the surface toward the animal pole in the animal hemisphere and toward the vegetal pole in the vegetal hemisphere, and finally accumulates at both poles of the egg to form the animal and vegetal pole plasms. Whereas the subcortical layer increases in volume during the first step, it decreases during the second step. This is ascribed to the compact rearrangement in the subcortical layer of membraneous organelles such as endoplasmic reticulum and mitochondria. The number of membraneous organelles associated with the cortical layer increases during the second step. Electron microscopy reveals the presence of microfilaments not only in the cortical layer but also in the subcortical layer. Subcortical microfilaments link membraneous organelles to form networks; some are associated with bundles of cortical microfilaments. The thickness of the cortical layer differs regionally. The pattern of this difference does not change during the second step. On the other hand, the subcortical cytoplasm moves ahead of the stationary cortical layer. The accumulation of pole plasm is blocked by cytochalasin B but not by colchicine. The first step of this process is less sensitive to cytochalasin B than the second step, suggesting that these two steps are controlled by differnt mechanisms. The mechanical aspects of ooplasmic segregation in theTubifex egg are discussed in the light of the present observations.     

The repetitive calcium waves in the fertilized ascidian egg are initiated near the vegetal pole by a cortical pacemaker.

Ascidian eggs respond to fertilization with a series of repetitive calcium waves that originate mostly from the vegetal/contraction pole region (J. E. Speksnijder, C. Sardet, and L. F. Jaffe, 1990, Dev. Biol. 142, 246-249), where the myoplasm is concentrated during the first phase of ooplasmic segregation. This suggests that the myoplasm may be involved in initiating these calcium waves. To test this possibility, the starting position of the calcium waves was determined in eggs that had the subcortical, mitochondria-rich part of the myoplasm displaced by centrifugation. Such centrifuged eggs display four cytoplasmic layers: a large centrifugal yolk zone, a narrow clear zone, a mitochondria-rich layer, and a small clear zone at the centripetal pole. Imaging of the cytosolic calcium in centrifuged eggs that were injected with the calcium-specific photoprotein aequorin reveals a series of repetitive calcium waves after fertilization. About 70% of these waves start in the vegetal/contraction pole area, which is similar to the number of waves previously found to start in this area in uncentrifuged eggs. In contrast, only about 25% of the waves start close to the displaced mitochondria-rich layer. From this result it is concluded that the main wave initiation site is not displaced by the centrifugal forces that displace the subcortical, mitochondria-rich part of the myoplasm. Moreover, the observation that the animal-vegetal polarity of cortical components such as actin filaments and the endoplasmic reticulum has been retained after centrifugation further suggests that a cortical component located in the vegetal hemisphere--most likely the endoplasmic reticulum network in the cortical region of the myoplasm--is involved in initiating the repetitive calcium waves in the fertilized ascidian egg.     

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.     

Ultraviolet irradiation during ooplasmic segregation prevents gastrulation, sensory cell induction, and axis formation in the ascidian embryo

The effect of ultraviolet (uv) light on embryonic development was examined in the ascidian Styela clava. uv irradiation (3.0 x 10(-3) J mm-2) of the entire surface of fertilized eggs during ooplasmic segregation prevented gastrulation, sensory cell induction, and embryonic axis formation. The uv-irradiated embryos completed ooplasmic segregation and cleaved normally, but vegetal blastomeres did not invaginate at the beginning of gastrulation, sensory cells in the larval brain did not develop tyrosinase or melanin pigment, and the larval tail did not develop. Endoderm, epidermis, and muscle cells differentiated in the uv-irradiated embryos, however, as evidenced by expression of endodermal alkaline phosphatase (AP), an epidermal-specific antigen, and alpha-actin, myosin heavy chain, and acetylcholinesterase (AChE) in muscle cells. Higher doses of uv light (6.0-9.0 x 10(-3) J mm-2) suppressed expression of the epidermal antigen and muscle cell markers, whereas the development of endodermal AP was insensitive. Irradiation at various times between fertilization and the 16-cell stage revealed that gastrulation, sensory cell differentiation, and axis formation are sensitive to uv light only during ooplasmic segregation. Irradiation of restricted regions of the zygote during ooplasmic segregation showed that the uv-sensitive components are localized in the vegetal hemisphere. The absorption characteristics of the uv-sensitive components suggest that they are nucleic acids. The results show that uv-sensitive components that specify gastrulation, sensory cell induction, and embryonic axis formation are localized in the vegetal hemisphere of Styela eggs.     

Surface polarization in loach eggs and two-cell embryos: correlations between surface relief, endocytosis and cortex contractility

The aim of this study was to examine the reorganization of the microfilamentous cortical layer (MC) accompanying ooplasmic segregation in loach eggs. Using scanning (SEM) and transmission electron microscopy (TEM), we found that the MC is thicker in folded areas. Prior to fertilization, surface microvilli are distributed more or less uniformly throughout the egg. A similar, more or less uniform, distribution of endocytotic events was observed in the eggs 5-15 min after insemination using fluorescence microscopy of Lucifer yellow CH uptake. During ooplasmic segregation, the surface is progressively polarized so that before the first cleavage onset (50-60 min after insemination) only the blastodisc surface is folded and undergoes endocytosis, whereas the vegetal surface is smooth and does not show internalization. In two-cell embryos, the blastomeric surface is also regionalized according to its relief and endocytosis. When surface tension was lowered by sucking most yolk granules out of the egg, we observed contractile responses only in the animal folded surface. These data suggest that a polar distribution of contractile structures is established in the loach egg undergoing ooplasmic segregation.     

Fertilization Reaction without Changes in Intracellular Ca2+ in Medaka Eggs—An Experiment with Acetone-Treated Eggs

To investigate whether or not causal relationship exists between the increase in intracellular Ca²⁺ and other cortical reactions at fertilization in the medaka, Oryzias latipes , intracellular Ca²⁺ was determined from luminescence of aequorin previously microinjected into cortical cytoplasm in acetone-treated eggs, when they were inseminated or activated by microinjection of Ca²⁺. Neither an increase in cytoplasmic calcium nor exocytosis of cortical alveoli occurred in eggs treated with acetone, though other events of fertilization i.e. completion of meiosis, fusion of pronuclei, and accumulation of cortical cytoplasm with intact cortical alveoli in the animal pole region were observed in normal time sequence in these eggs. When denuded eggs were treated with acetone, contraction of the egg and slow resumption of meiosis (extrusion of polar body) were observed without insemination. When denuded eggs were inseminated immediately after acetone-treatment, the number of spermatozoa that penetrated into the egg was greater in the animal hemisphere than in the vegetal hemisphere. These results may indicate that acetone inactivates the egg plasma membrane or its adjacent cortical cytoplasm so that it cannot participate in a propagative increase in intracellular Ca²⁺ and exocytosis, while it also induces cytoplasmic activation leading to egg contraction, resumption of meiosis and formation of pronuclei. The present results suggest that sperm penetration, resumption of meiosis and ooplasmic segregation are regulated separately from the release of intracellular Ca²⁺ and exocytosis.     

Vegetal localization of the maternal mRNA encoding an EDEN-BP/Bruno-like protein in zebrafish

Asymmetric distribution of maternal mRNAs has not been well documented in zebrafish. Recently, we have shown that dazl mRNA is localized at the vegetal pole. Here we report a novel zebrafish gene, bruno-like (brul), which provides another example of vegetal mRNA localization. brul encodes an Elav-type RNA-binding protein that belongs to the Bruno-like family that includes mammalian CUG-BP, Xenopus EDEN-BP, and Drosophila Bruno. At 24 hpf, brul mRNA was abundant in lens fiber cells. At the onset of embryogenesis, maternal brul mRNA was detected at the vegetal pole, and it then migrated rapidly toward the blastoderm through yolk cytoplasmic streams. During oogenesis, brul mRNA became localized at the vegetal cortex at stage II, later than dazl mRNA. We found that anchoring of brul mRNA was dependent on microfilaments.     

Periodic calcium waves cross ascidian eggs after fertilization

Ascidian eggs respond to fertilization with one to two dozen periodic calcium pulses (J.E. Speksnijder, D.W. Corson, C. Sardet, and L.F. Jaffe, 1989a, Dev. Biol. 135, 182-190). We examined the spatial pattern of these pulses and found that they are initiated in discrete regions from which they propagate as waves. The first few pulses start in the animal hemisphere, whereas the later ones are mostly initiated near the vegetal pole. Such vegetal waves are often followed by a contraction of the egg surface. Since these waves are attenuated as they spread, they repeatedly expose the vegetal pole region to more calcium. The mechanism of these repetitive calcium waves and their possible role in establishing pattern or completing meiosis is discussed.