Ultraviolet light inhibits grey crescent formation on the frog egg

Summary Work by others has shown that ultraviolet (UV) irradiation of the vegetal half of the uncleaved frog egg causes defects in neural development. We find that the earliest effect of irradiation ofRana pipiens eggs is to prevent grey crescent formation, the first indication of dorso-ventral polarization of the egg. The UV effect on the grey crescent and on neural development shows similarities in timing, dose-responses, and reversal by cold. We suggest that the UV effect on neural morphogenesis may be caused by the inhibition of cortical-cytoplasmic movement involved in grey crescent formation.     

Regional Morphological and Cytochemical Differentiation in the Fertilized Egg of Discoglossus pictus (Anura)

A vertical column of cytoplasm poor in yolk (CPY) is located in the centre of the animal region of the unfertilised and fertilised egg of Discoglossus pictus. At the base of this column is found a central region of CPY designated as "clear cytoplasm". Cytochemical methods show that the CPY in this whole region is rich in glycogen and RNA.
By 60 min post opposition (p.o.) the pigmented cortical layer starts moving towards the future ventral side. It attains its definitive position by 90 min p.o. when the grey crescent, visible from 75 min p.o. onwards, achieves its maximal extension on the future dorsal side. The cytoplasmic column is now tilted towards the future ventral side. It progressively loses its direct contact with the cell membrane and disappears.
From 90 min p.o. onwards, the "clear cytoplasm" is found progressively closer to the dorsal grey crescent cortex. When the first cleavage furrow appears at 135 min p.o., the "clear cytoplasm" is situated very near the dorsal cortex and even extends somewhat below the equator. In places a relatively thin layer of cytoplasm containing medium-sized and a few large yolk granules intervenes between the grey crescent cortex and the "clear cytoplasm".
These displacements suggest that sperm entry evokes a dorsally directed cytoplasmic movement in the animal half of the egg which, among other things, may facilitate an interaction between the vegetative yolk and the grey crescent cortex, or may directly influence the dorso-ventral polarisation of the vegetative yolk.     

Development of cortical polarity in mouse eggs: involvement of the meiotic apparatus

Experiments were carried out to determine the origin of cortical polarity in mouse eggs and its possible relation to the meiotic apparatus. Cortices of mature eggs overlying the meiotic apparatus (microvillus-free area) were distinguished by an absence of microvilli and a thickened layer of actin. In contrast, the surfaces of immature oocytes were covered entirely with a dense population of microvilli and were subtended by a uniform layer of actin. When induced to undergo maturation, meiotic spindles formed in the center of immature oocytes and then moved peripherally. Coincident with the cortical localization of the meiotic spindle was the formation of a microvillus-free area, i.e., a loss of microvilli and a thickening of the actin layer associated with this region of the egg cortex. If immature oocytes were incubated in cytochalasin B, meiotic spindles formed; however, they failed to move peripherally and microvillus-free areas did not develop. Oocytes incubated in colchicine did not form meiotic spindles, although the chromosomes condensed and became localized to cortices where microvillus-free areas developed. Cytochalasin B-treated mature eggs maintained intact meiotic spindles and exhibited a disappearance of microvillus-free areas and a reduction in cortical actin. The chromosomes of mature eggs treated with colchicine remained associated with microvillus-free areas despite the disappearance of meiotic spindles. Occasionally, colchicine-treated eggs possessed more than one cortically located mass of chromosomes, each of which was associated with a microvillus-free area. These observations indicate that mechanisms involving the movement of the meiotic spindle to the oocyte cortex and development and maintenance of cortical polarity are cytochalasin B sensitive. Commensurate with the localization of meiotic chromosomes to the egg cortex is the reorganization of cortical actin and the formation of a microvillus-free area.     

EFFECTS OF CHEMICAL REAGENTS ON THE CYCLIC CHANGES OF CORTEX AND CYTOPLASM IN THE ACTIVATED ENUCLEATED EGG-FRAGMENTS OF THE SEA URCHIN*

Unfertilized eggs of sea urchins. Anthocidaris crassispina and Hemicentrotus pulcherrimus, were separated by centrifugation into two fractions (nucleated light and enucleated heavy fragments). The enucleated egg-fragments were activated by treatment with 1 M urea and then put into sea water solutions of the following three reagents; colcemid, cytochalasin B and Monogen at a concentration by which cleavage was suppressed. It was then examined whether the egg-fragments can exhibit cyclic changes of cytoplasm and cortex in correlation with the cleavage cycle in normally fertilized eggs without any influence of nuclear activity. The results obtained clearly showed that colcemid can suppress the cyclic appearance of cytoplasmic changes, but not that of cortical changes; on the contrary, in cytochalasin B- and Monogen-treated fragments, the periodicity in cortical activities is suppressed, while the periodic changes in the cytoplasm appear according to a timeschedule of the cleavage cycle. Therefore, it may be said that: 1) cyclic changes can occur in both the cytoplasm and the cortex independently, without the direct influence of nuclear activity; 2) if either of them is arrested, the cleavage does not take place; 3) the normal cleavage requires the simultaneous occurrence of periodic activities both in the cortex and in the cytoplasm after fertilization.     

Cytoplasmic phases in the first cell cycle of the activated frog egg

The first cell cycle of the activated frog egg is longer than subsequent cycles and several developmentally important events such as the determination of bilateral symmetry occur at this time. When eggs of Rana pipiens or Xenopus laevis are dissected at times after activation, differences in the consistency of the animal half cytoplasm can be detected visually, and the first cell cycle has been divided into four cytoplasmic phases on this basis. Phase 1 includes the events of activation and lasts about one-third of the first cycle. In phase 2, the cytoplasm becomes fluid except for the rigid, growing sperm aster, and most of the migration of the pronuclei occurs in phase 2. In phase 3, the cytoplasm becomes firm whether or not a sperm aster had been present, and the grey crescent forms, indicating the plane of bilateral symmetry. The firmness of the cytoplasm is colchicine sensitive but cytochalasin B insensitive as is grey crescent formation. In phase 4, the cortex detaches from the firm cytoplasm, and the firmness is now cytochalasin B sensitive and colchicine insensitive. The changes in cytoplasmic consistency during the first cell cycle probably reflect changes in the cytoskeleton, and the cytoplasmic consistency is functionally correlated with developmental events in the first cell cycle.     

Cytochalasin B blocks sperm incorporation but allows activation of the sea urchin egg

Cytochalasin B (CB) (2 × 10⁻⁶ M) prevents the incorporation of sperm into the eggs of Lytechinus pictus and Strongylocentrotus purpuratus as judged by light and transmission electron microscopy (TEM). At lower concentrations of CB (2 × 10⁻⁷ M), sperm are successfully incorporated into the egg, but their migration in the area of the egg cortex is impaired. The site of action of CB on the sperm may be on the initial rotation of the sperm nucleus in the cortex; the subsequent migration is not affected by CB. Although sperm incorporation is prevented at the higher CB concentrations, the eggs become activated—as judged by cortical reaction, increased protein synthesis and increased respiration. These findings raise the concept that egg activation by sperm could result from some pre-fusion event and hence that sperm-egg fusion would not be a prerequisite for the triggering of development. An alternative hypothesis is that fusion occurs between the acrosome process membrane and egg membrane, but since CB has destroyed the integrity of the cortex actin, the fusion bridge is so weak that it cannot be maintained without some contractile or cytoskeletal support by the cortex. The sperm may activate the CB-treated egg in the same manner as pricking with a microelectrode sometimes does.     

Actin and cortical fiber reticulation in the siphonaceous alga Vaucheria sessilis

Since light-induced organellae aggregation in the siphonaceous alga Vaucheria sessilis (Vauch.) D.C. is accompanied by the formation of a cortical fiber reticulum in the light, we proposed that this process of reticulation might be causally related to aggregation (Blatt and Briggs, 1980). In this paper we report the tentative identification of actin filaments and filament bundles in the cortical cytoplasm of V. sessilis, and present additional evidence, obtained using the inhibitors cytochalasin B and phalloidin and indicating that aggregation in response to low-intensity point irradiation with blue light is dependent upon the formation of a cortical fiber reticulum. Phalloidin stabilized the cortical fibers, preventing both reticulum formation and organelle aggregation in blue light. Cytochalasin B partially destabilized the cortical fibers to the extent of permitting light-induced reticulum formation and organelle aggregation in the light in the presence of phalloidin.C.I.W.-D.P.B. Publication No. 643     

Polar lobe formation and cytokinesis in fertilized eggs of Ilyanassa obsoleta. II. Large bleb formation caused by high concentrations of exogenous calcium ions

Fertilized eggs of the mollusk Ilyanassa obsoleta (Nassarius obsoletus) form large blebs resembling polar lobes within 12 min of exposure to solutions of isotonic CaCl₂, whereas control eggs in sea water remain spherical. Under identical conditions, fertilized eggs of the sea urchin, Strongylocentrotus purpuratus, an organism which normally does not form polar lobes, do not form blebs upon exposure to solutions of isotonic CaCl₂. The calcium-induced blebbing in Ilyanassa still occurs if other cations such as Na⁺, Mg²⁺, or Mn²⁺ are present in addition to Ca²⁺, but not if comparable concentrations of K⁺ are present. Cytochalasin B prevents the calcium-induced blebbing, whereas colchicine does not. Cytokinesis in both Ilyanassa and Strongylocentrotus and normal polar lobe formation in Ilyanassa appear to require exogenous K⁺ but not exogenous Ca²⁺. Preliminary electron microscopy of Ilyanassa eggs exposed to isotonic solutions of CaCl₂ has shown microfilaments in the cortical cytoplasm in the region of the bleb constriction but no microfilaments in spherical control eggs in sea water. These data suggest that high concentrations of exogenous Ca²⁺ trigger the polymerization and contraction of a ring of microfilaments in the cortical cytoplasm of the Ilyanassa egg which results in the formation of a lobelike bleb of cytoplasm. The observation that K⁺ antagonizes this Ca²⁺-induced blebbing has led to the formulation of a theory which postulates that the ratio of intracellular Ca²⁺ to intracellular K⁺ is critical in the control of polar lobe formation and cytokinesis.     

Ca2+ as a messenger of dorsal--ventral polarity formation in frog (Rana temporaria) eggs.

Three methods of Ca2+ administration were used to influence the location of the grey crescent and the dorsal lip of blastopore in R temporaria eggs, ie a Ca2+ microinjection into the subcortical cytoplasm, egg pricking in high Ca2+ solutions and Ca2+ ionophore A23187 microinjection and application. The treatments all induced grey crescent and dorsal lip of blastopore formation near the Ca2+ administration site. Inositol trisphosphate injections gave similar results. Colchicine injections into the eggs inhibited the appearance of both natural and Ca(2+)-induced grey crescents.     

The amphibian gray crescent region-A site of developmental information?

To evaluate the developmental significance of the amphibian gray crescent, vegetal hemispheres of fertilized eggs of Rana pipiens were irradiated with UV at 2537 Å. Acephalic or aneural embryos resulted suggesting that gray crescent inductive ability was destroyed. Two questions were asked: (1) Does the syndrome result from nuclei altered by interacting with UV lesions in the gray crescent region? (2) Does UV damage the gray crescent cytoplasm, cortex, or both?     

Early grey crescent formation experimentally induced by cycloheximide in the axolotl oocyte

Summary The effects of cycloheximide (CH) on grey crescent formation in artificially maturedAmbystoma mexicanum oocytes were determined. CH induced grey crescent formation after a few hours, especially after a 45° to 90° rotation from the vertical animal-vegetal axis. With low concentrations of CH (about 0.5 ng/oocyte), meiosis was still able to proceed normally to the stable second metaphase stage, but higher concentrations blocked it after 1st polar body extrusion and an interphasic nucleus appeared. Such effects were compared to those of inactone, an analogue of cycloheximide, which as a pure substance does not inhibit protein synthesis, but still contained a small amount of CH in the available samples. It is concluded that grey crescent formation can occur in non-activated oocytes. The effects of cycloheximide might be due to partial inhibition of protein synthesis and the presence of a proteinic inhibitor of the symmetry reaction in the normal oocyte is suggested.     

ON PROPAGATION OF CORTICLA FACTOR AND CYTOPLASMIC FACTOR PARTICIPATING IN CLEAVAGE FURROW FORMATION OF THE NEWT'S EGG*

From Cynops pyrrhogaster eggs just after the start of the first cleavage, a fragment of cortical layer with a small entire cleavage furrow was cut out. In the fragment, the cortex had already acquired susceptibility to and the subcortical cytoplasm had already accquired inducibility for furrow formation. The fragment was transplanted to the animal hemisphere of uncleaved fertilized eggs or eggs immediately after the onset of the first cleavage, from which a portion of the host cortex was removed. Observation was made on division of the graft, and on propagation of the cortical susceptibility and the cytoplasmic inducibility of the graft onto the host egg. The transplant divided succesively on the host egg in many cases, but the furrow of the graft never advanced to the surface of the host egg. Neither the cortical factor nor the cytoplasmic factor was transmitted across the graft to the recipient egg.     

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.     

Cortical differentiation of the animal pole during maturation division in fertilized eggs of Tubifex (Annelida,Oligochaeta): I. Meiotic apparatus formation

The fine structure of the animal pole cortex is examined in the fertilized Tubifex egg undergoing the formation of the second meiotic apparatus (MA). The fully formed MA which orients its axis at right angles to the surface is found at the animal pole about 40 min after formation of the first polar body. It is composed of a spindle and asters at its poles; a centriole is found in the inner aster, but not in the peripheral aster adjacent to the surface. During the formation of the MA, the animal pole surface is lined with a 0.15-μm-thick, electron-dense cortical layer, which is rich in microfilaments. The arrangement of the filaments in the layer changes from a parallel array to a meshwork with progressive formation of the MA. Microtubules of the peripheral aster terminate in the cortical layer. When a jet stream of glycerol/dimethyl sulfoxide solution is applied to an egg fragment glued on a polylysine-coated coverslip, an egg cortex-MA complex is isolated on the coverslip; the MA appears to be tethered to the egg surface by the structural connection between the filamentous cortical layer and microtubules of the peripheral aster. Cytochalasin B (50 μg/ml), when administrated at early phase of the MA formation, does not show any effect on the structure of the cortical layer and the MA; however, if eggs shortly before the termination of the first polar body formation are immersed in the same test solution, the cortical layer of the animal pole becomes thinner, and the filamentous material is not observed in it. Furthermore, in these eggs, the peripheral aster and the spindle are not structurally discernible because of the suppression of microtubule assembly, whereas microtubules on kinetochores and in the inner aster are normally developed. These results are discussed in relation to the role of the animal pole cortex in fixing of the MA to the egg surface and in forming of the MA.     

Sperm penetration and transformation of sperm entry site in eggs of the freshwater teleost Rhodeus ocellatus ocellatus

Eggs of bony fishes are enveloped by an egg envelope (chorion) in which a micropyle is present near the animal pole. Therefore, sperm penetration into the eggs is limited to the sperm entry site (SES), a region of plasma membrane just beneath the micropyle. In rose bitterling eggs, the SES transforms from a tuft of microvilli into a swollen mass (SM) that continues to plug the micropyle after sperm penetration. The present observations using the rose bitterling Rhodeus ocellatus ocellatus were conducted to examine: 1) whether or not sperm penetration is necessary for formation of the SM and 2) whether or not actin microfilaments are involved in the formation of the SM. Water activation without sperm transformed the SES from a tuft of microvilli into the SM, although it took a longer time for the transformation and the SMs were smaller than in the case of inseminated eggs. The SES presumably has the ability to transform into the SM upon activation of eggs in the present species. Cytochalasin B, which acts on actin microfilaments, did not prevent formation of the SM, irrespective of insemination or activation. The present observations suggest that sperm penetration is not necessary for SM formation and actin microfilaments do not participate in SM formation. © 1996 Wiley-Liss, Inc.     

Influence of cytochalasin B on oocyte maturation in Xenopus laevis

Cytochalasin B (CB) exerts an inhibiting effect on the formation, migration and anchoring in the cortex of the meiotic spindle in maturing Xenopus laevis oocytes. Regional sensitivity to CB (CB-sensitive zones) has been found in the oocytes which varies with reference to the stage of oocyte maturation at which CB is applied. Light and electron microscopy has shown that in these CB-sensitive zones the yolk and pigment granules, unlike the cortical ones, are displaced into the cytoplasm centripetally under the influence of CB.     

Local alteration of cortical actin in Xenopus eggs by the fertilizing sperm

Rhodamine phalloidin (Rph) staining was used to examine the microfilament organization of the Xenopus laevis egg cortex during the early stages of fertilization. Unactivated eggs possessed a cytochalasin B (CR)-insensitive Rph-stained matrix that was reorganized upon egg activation and diminished in the presence of CB. Xenopus laevis sperm caused a temporary local increase in Rph staining on the Xenopus cortex. In CB-treated eggs, the local increases of cortical Rph staining later changed to a Rph-free area. These temporary local increases of cortical Rph staining were also observed when Notophthalmus viridescens sperm fertilized Xenopus and Rana pipiens eggs, and were followed by the appearance of concentric rings of stained and unstained areas. Our data suggest that Xenopus and Notophthalmus sperm have activities that can both organize and disrupt the cortical filamentous actin of the Xenopus egg. © 1993 Wiley-Liss, Inc.     

Fine structure of the mammalian egg cortex

The cortices of a number of mammalian eggs are not structurally homogeneous but are polarized. In mouse ova the plasma membrane is a mosaic; the cytoplasm overlying the meiotic spindle is devoid of cortical granules and consists of a filamentous layer containing actin. Functionally, this cortical polarity may be related to the restriction of sperm-egg interaction and fusion to a specific region of the ovum cortex and to dynamic changes of the egg cortex during fertilization, including cortical granule exocytosis, polar body formation, and fertilization cone development. The origin of cortical polarity in mammalian oocytes and its possible relation to components of the cytoskeletal system and meiotic apparatus are discussed and compared with cortical features of eggs of other vertebrates and invertebrates.     

Changes in microtubule structures during the first cell cycle of physiologically polyspermic newt eggs

The unfertilized egg of the newt, Cynops pyrrhogaster, has a second meiotic spindle at the animal pole and numerous cortical cytasters. After physiologically polyspermic fertilization, all sperm nuclei incorporated into the egg develop sperm asters, and the cortical cytasters change into bundles of cortical microtubules. The size of the sperm asters in the animal hemisphere is ∼5.6-fold larger than that in the vegetal hemisphere. Only one sperm nucleus moves toward the center of the animal hemisphere to form a zygote nucleus with the egg nucleus. This movement is inhibited by nocodazole, but not by cytochalasin B. The centrosome in the zygote nucleus divides into two parts to form a bipolar spindle for the first cleavage synchronously with the nuclear cycle, but centrosomes of accessory sperm nuclei in the vegetal hemisphere remained to form monopolar interphase asters and subsequently degenerate around the first cleavage stage. The size of sperm asters in monospermically fertilized Xenopus eggs was ∼37-fold larger than those in Cynops eggs. Since sperm asters that formed in polyspermically fertilized Xenopus eggs exclude each other, the formation of a zygote nucleus is inhibited. Cynops sperm nuclei form larger asters in Xenopus eggs, whereas Xenopus sperm nuclei form smaller asters in Cynops eggs compared with those in homologous eggs. Since there was no significant difference in the concentration of monomeric tubulin between those eggs, the size of sperm asters is probably regulated by a component(s) in egg cytoplasm. Smaller asters in physiologically polyspermic newt eggs might be useful for selecting only one sperm nucleus to move toward the egg nucleus. Mol. Reprod. Dev. 47:210–221, 1997. © 1997 Wiley-Liss, Inc.