FORCE EXERTED BY THE CLEAVAGE FURROW OF SEA URCHIN EGGS

A drop of ferrofluid injected into the center of a dividing sea urchin egg is deformed into the shape of an hourglass when the cleavage furrow advances. The force applied to the drop is determined from the deformation of the drop and the interfacial tension between the ferrofluid and the protoplasm. The interfacial tension is determined from the deformation of a spherical drop in the protoplasm when a magnetic field is applied, and the force applied to the drop, which is estimated from the deformation by magnetic field of a similar drop in 2 per cent aqueous solution of Triton X-100 and the interfacial tension between the ferrofluid and this solution.
The force applied to the drop in the dividing egg increases during an early stage of cleavage and decreases during a later stage. The force attained a maximum of 9 × 10⁻³ dyne in an egg of Temnopleurus toreumaticus which pinched the drop into two when it divided. Smaller maximum forces, 3.9 × 10⁻³ dyne in the eggs of Temno-pleurus toreumaticus and 2.0 × 10⁻³ dyne in the eggs of Clypeaster japonicus (mean values), were obtained when the furrowing was arrested by the drop. The magnitude of the maximum tension developed in the contractile element located in the furrow cortex is discussed.     

微丝在卵子极性产生、分裂沟形成和极体排放中的作用

小鼠生发泡（ＧＶ）期卵母细胞在１μｇ／ｍｌ细胞松弛素Ｂ（ＣＢ）中培养,部分微丝解聚,卵母细胞不 能产生极性而在细胞中部形成分裂沟（假分裂）;极泡期印在１μｇ／ｍｌ ＣＢ中,分裂沟继续收缩,排放第 一极体。假分裂的分裂沟和极泡期的极区分裂沟形成均与分裂器中体位置相关。部分微丝解聚并不影响 假分裂和第一极体排放;全部微丝解聚（１０μｇ／ｍｌ ＣＢ）将中断假分裂和胞质分裂,分裂沟消失,卵恢 复球形。由此可见,成熟过程中卵母细胞极性的产生及分裂沟的形成都依赖于微丝的聚合。胞质分裂和 第一极体排放同样需一定量的微丝存在。     

多聚赖氨酸引起林蛙卵表面的聚集以及对分裂沟的影响

1.多聚赖氨酸能使经异硫氰基荧光素染色的卵表面均匀分布的荧光聚集成点状或块状的斑块,荧光聚集时膜下的色素颗粒随之同步聚集。早期的聚集有三种方式。2.聚集的迟早和出现斑块的大小在卵表面不同区域是不同的。腹方新月区最早;灰色新月区次之;动物性半球稍迟,荧光和色素颗粒最后都集中到动物性极形成顶帽,其余区域成为失去色素颗粒的区域;聚集引起收缩,最后植物性半球常常破裂。3.未受精卵亦出现与上述相同的反应,这提示腹方新月区可能是精子进入卵子的区域。4.细胞松弛素不能抑制多聚赖氨酸引起的聚集。5.多聚赖氨酸能抑制分裂沟的出现,能使已出现的分裂沟消失。6.失去色素颗粒区域的细胞膜在形态、功能等方面与分裂沟中的新膜相同。对新膜出现的位置和形成因素进行了讨论。     

INSERTION OF STRIPS OF CELLOPHANE OR POROUS FILTERS IN THE FUTURE COURSE OF THE ADVANCING CLEAVAGE FURROW OF THE NEWT EGG *

In the area between the equatorial and the upper vegetal regions of the egg of the newt, Cynops (Triturus) phrrhogaster, strips of cellophane, ordinary filter paper or Millipore filter respectively were inserted transversely at short distances ahead of the advancing cleavage furrow. When a cellophane strip is inserted across the future path of the furrow at 0.5–0.7 mm beyond the furrow tip, the furrow stops on reaching the position of the inserted cellophane strip. If, however, a strip of the Millipore filter is inserted at the same distances ahead of the cleavage furrow, the furrow reaches the one side of the Millipore filter strip and soon appears on the opposite side of it, just as the furrow jumps across the strip, to continue the previous course. Similar tendency is observed in the experiments on insertion of strips of the ordinary filter paper. It is suggested that certain propagating factors which are necessary to induce formation of the cleavage furrow can go through the pores of the Millipore filter to precede the advancing tip of the cleavage furrow.     

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.     

CORTICAL CHANGES IN GROWING OOCYTES AND IN FERTILIZED OR PRICKED EGGS OF RANA PIPIENS

The folded cortex of the growing oocyte of the frog extends as microvilli into the substance of the developing vitelline membrane and, internal to the folds, possesses a layer of cortical granules. Free ribosomes, smooth-walled vesicles, coated vesicles, tubules, and electron-opaque granules are abundant in the peripheral zone of the cortex. Mitochondria, lipochondria, pigment granules, and electron-opaque granules are conspicuous between cortical granules and in the underlying endoplasm. Yolk platelets are restricted to the endoplasm. Cortical granules contain neutral and acid mucopolysaccharides, and possibly protein. In the mature oocyte, microvilli are withdrawn and the surface folds eliminated. Cortical granules now lie close to the plasma membrane, sometimes contacting it. Fertilization or pricking causes a wave of breakdown of cortical granules lasting 1–1½ min. Breakdown begins immediately after pricking but not until about 10–15 min after insemination, because the fertilizing sperm takes that long to penetrate the jelly and vitelline membrane. Cortical granules erupt through the surface and discharge their contents into the perivitelline space. Cortical craters left at sites of eruption soon disappear, and pseudopodial protrusions retract. By 30 min after insemination, the surface of the egg is relatively smooth.     

INDUCTION OF ASTER FORMATION AND CLEAVAGE IN EGGS OF THE SEA URCHIN HEMICENTROTUS PULCHERRIMUS BY INJECTION OF SPERM COMPONENTS*

Studies were made on which components of sperm were able to induce aster formation and cleavage of eggs of the sea urchin Hemicentrotus pulcherrimus. The sperm components were separated by homogenization and centrifugation into the following 3 fractions: the head-midpiece, midpiece and tail. The head-midpiece fraction was then divided into 2 sub-fractions, the centriole sub-fraction and the centriole-free sub-fractions. Each fraction was injected into unfertilized eggs and after 15–30 min the eggs were inseminated. The ability of a fraction or a sub-fraction to induce aster formation and cleavage was deduced from the frequency of multipolar cleavage. The head-midpiece fraction and the centriole sub-fraction were effective in inducing aster formation and cleavage, but the other fractions were not. It was concluded that isolated centrioles from sea urchin sperm act as division centers in the egg.     

长毛对虾卵子皮层反应的研究

Morphology of the cortical reaction in the eggs of Penaeus penicillatus was studied with the light microscopy,scanning electron microscopy　and transmission electron microscopy. The cortical reaction is divided into four stages. These stages are unreacted stages, early stages, corona stages and dissipation stage. The cortical rods were released and formed a jelly coating around the surface of the egg. The jelly coating remained until the first cleavage had finished. In the end, the hatching membrane appeared around the egg. It is believed that these cortical reaction are responsible for the prevention of polyspermy by both a chemical and physical block and that also may establish a microenvironment inside a touch chorionic membrane for the developing embryo.     

AN ELECTRON MICROSCOPIC STUDY OF THE DEVELOPMENT OF THE CLEAVAGE FURROW IN MAMMALIAN CELLS

The process of cytoplasmic cleavage has been studied in thin sections of rat erythroblasts and the cells of mouse leukemia and Walker 256 carcinoma of the rat. The development of the cleavage furrow begins in relation to the mid-body, which, earlier, appears on the equatorial plane in association with the continuous fibers of the spindle. The earliest evidence of a cleavage furrow is the presence of a vesicle or vesicles close to the mid-body. Subsequently, many smaller vesicles are seen in the equatorial plane. The cleavage furrow probably develops by the fusion of these vesicles so that a new plasma membrane is formed between the daughter cells, and extends from the telophase intercellular bridge to the cell margin. During the stage of formation of the vesicles, cisternae, believed to be part of the endoplasmic reticulum, assume an intimate relationship with the cleavage plane, and they may perhaps be involved in the formation of the vesicles.     

EFFECTS OF THE SURFACTANTS ON THE CLEAVAGE AND FURTHER DEVELOPMENT OF THE SEA URCHIN EMBRYOS II. DISTURBANCE IN THE ARRANGEMENT OF CORTICAL VESICLES AND CHANGE IN CORTICAL APPEARANCE

After fertilization, two types of cortical vesicles ware examined under the electron microscope (the cortical vesicle I and II) and the light microscope (pigment granules and another kind of vesicles). The cortical vesicle I corresponds to the pigment granule and the cortical vesicle II does to the other vesicle.
The unequal division of the sea urchin embryo which occurs at the fourth cleavage was modified to an equal cleavage pattern by the treatment with sodium lauryl sulfate (SLS) or cetyl trimethyl ammonium bromide (CTAB). But other surfactants such as sodium deoxycholate, Tween 80, Lubrol PX did not have such an effect. The cell surface of the embryo which had been treated either SLS or CTAB became rough or smooth. Cortical vesicles and pigment granules disappeared and/or were dislocated from the cortex. However, cell organelles were as normal as the control. On the other hand, the cortical appearance of other surfactant-treated embryos showed no disturbance and cell organelles were also more or less normal. Therefore, the equalization of unequal cleavage is caused by the disturbance in the cortex and thus the cortex plays a major role on the micromere formation at the 16-cell stage and on the further sea urchin development.     

ENZYMO-CYTOCHEMICAL OBSERVATIONS ON THE CORTICAL CHANGE IN THE EGGS OF CYPRINUS CARPIO AND CARASSIUS AURATUS

Acid phosphatase (AcPase) and cholinesterase (ChE) activities were examined by ultracytochemical techniques in the mature unfertilized and the fertilized eggs of Cyprinus carpio and Carassitus auratus , to reveal the differences among three kinds of structures, cortical alveoli, CA- and CB-granules, which discharge their contents on fertilization into the perivitelline space. Deposits of the reaction product for AcPase activity are localized on the plasmalemma of unfertilized eggs, in the cortical alveoli, cytoplasmic matrix, lamellae of the Golgi apparatus and sometimes in multivesicular bodies but not in CA- and CB-granules, mitochondria, rough endoplasmic reticulum or on the plasmalemma of fertilized eggs. Deposits of the reaction product for ChE activity are localized on the inner surface of the plasmalemma, in the cytoplasmic matrix, in mitochondria and on a small number of tubular or cisternal membranes of the endoplasmic reticulum in mature unfertilized eggs, and on the outer surface of the limiting membrane of CB-granules and on membranous structures (possibly Golgi lamellae) associated with their formation, in fertilized eggs. The deposits on the plasmalemma rapidly disappear almost completely, with discharge of the cortical alveoli soon after fertilization, but they are again seen on the inner surface of the plasmalemma when emiocytotic discharge of the CB-granules begins about 10 min after fertilization.     

A FINE STRUCTURAL ANALYSIS OF CLEAVAGE INDUCTION AND FURROWING IN THE EGGS OF ARBACIA PUNCTULATA

A fine structural study has been carried out on the various formed elements present before, during, and after the first cleavage division, not only in normally developing Arbacia eggs, but also in eggs which have been induced to cleave prematurely by high-pressure centrifugation. The aim has been to ascertain whether or not any of the morphologically identifiable components may be involved in initiating the furrowing process. Also, attention has been given to the fine structure of the cytoplasmic cortex, particulary in the walls of the furrow, in the hope of reaching a better understanding of the mechanics of cleavage. The annulate lamellae and the membranous envelope of the nucleus are the only formed elements which disappear shortly before cleavage, not only in eggs undergoing normal division, but also in eggs which have been induced to cleave ahead of schedule by high-pressure, high-force centrifugation. Therefore, it is suggested as a tentative hypothesis that materials liberated upon disintegration of the nuclear membrane and the annulate lamellae play an essential role in initiating and effecting the furrowing reaction, especially since the stratification of these elements in experimentally induced eggs corresponds to the position of the developing furrow. Another of the membranous elements in the egg, the Golgi complex, shows considerable modification as a result of high-pressure centrifugation, but these structures do not undergo disintegration. Rather, they become curled into rounded bodies. The vacuole population is not greatly affected by inducing treatments. During cleavage, both naturally occurring and experimentally induced, a considerable number of 50 A filaments appear in the denser cytoplasmic cortex, but only in the walls of the furrow. These filaments are similar to those which have been demonstrated in a number of contractile cells. Accordingly, it is suggested that this fibrillar system may be actively involved in the development of the cleavage force.     

OCCURRENCE AND FINE STRUCTURE OF SUBCORTICAL CYTOPLASMIC ISLETS IN FERTILIZED EGGS OF CYNOPS PYRRHOGASTER

Fertilized and unfertilized eggs of Cynops pyrrhogaster were examined by light and electron microscopy. In fertilized eggs that have just been laid, there are numerous small cytoplasmic patches free of granules in the pigmented layer of the animal hemisphere. Many of these granule-free cytoplasmic islets gradually grow out subcortically from the pigmented layer and fuse to form a subcortical layer of yolk-free cytoplasm of varying thickness by the time of the first cleavage division. The cytoplasmic islets are present in 100% of the fertilized eggs, but not in unfertilized eggs. Electron microscopic observations showed that the cytoplasmic islets contain tubules and that development of a complex system of cortical tubules constitutes the basis of the early growth of the cytoplasmic islets. The cortical tubules are transient structures and are no longer observable a few hours after the eggs are laid. These phenomena are considered to be a response of the egg to the fertilization stimulus.     

EFFECTS OF TAURODEOXYCHOLATE AND CALCIUM ON CONTRACTILITY OF NEWT EGGS

Injection of taurodeoxycholate (TDOC) alone or in combination with 10⁻⁵ M Ca²⁺(Ca-EGTA buffer) into newt eggs induced a cup- or furrow-like depression on the egg surface. Reduction of the Ca²⁺ concentration inhibited the response. These findings imply that TDOC induces a cytoplasmic contraction associated with the membrane and that a micromolar Ca²⁺ concentration is required for this process. Injection of 10⁻⁵ M Ca²⁺(Ca-EGTA buffer) alone had no effect. On the basis of these findings, the roles of TDOC and Ca²⁺ in induction of contraction were discussed.     

STUDIES ON THE FORMATION AND STATE OF DETERMINATION OF THE TRUNK ORGANIZER IN THE NEWT, CYNOPS PYRRHOGASTER

Mesoderm formation in the presumptive trunk organizer was analyzed in gastrulae of Cynops pyrrhogaster. The presumptive trunk organizer showed little or no mesodermal differentiation in the beginning gastrula (0 h embryo). But as soon as the presumptive trunk organizer came into contact with the newly invaginated cranial archenteron roof, it rapidly formed mesoderm. This suggests that this differentiation was brought about by an inductive effect of the underlying cranial archenteron roof. For investigation of this possibility, the presumptive trunk organizer of 0 h embryos (Tr-0) and the newly invaginated cranial archenteron roof (presumptive pharyngeal endoderm and prechordal plate) of successive stages were cultured in isolation and by the sandwich technique. The newly invaginated presumptive pharyngeal endoderm and prechordal plate had no effect on mesoderm formation of the presumptive trunk organizer, and mesodermal differentiation of the combinations was similar to that of the Tr-0 alone. On the other hand, results showed that the prechordal plate, which came into contact with the still uninvaginated presumptive trunk organizer, stimulated dorsalisation of the weakly mesodermized trunk organizer. Based on these results, the stepwise process of mesoderm formation in the trunk organizer is discussed.     

WAVE OF STIFFNESS PROPAGATING ALONG THE SURFACE OF THE NEWT EGG DURING CLEAVAGE

In the eggs of the newt, Cynops (Triturus) pyrrhogaster, change in stiffness of the cortex was measured in various regions at the time of the cleavage. Measurements were performed by Mitchison and Swann's cell elastimeter method with a modification, in which two fine pipettes were attached to the surface of one egg at the same time, in order to compare the rigidity of two regions. The stiffness of the cortex changed very little before the start of the first cleavage. However, just before the appearance of the first cleavage furrow, the stiffness increased rapidly at the animal pole region, which later returned to the former level. As the cleavage furrow progressed, a wave of high stiffness travelled meridionally as a belt along the surface from the animal pole region toward the vegetal region. At second cleavage, the cycle of change in stiffness was repeated.     

A FINE STRUCTURAL INVESTIGATION OF SURFACE SPECIALIZATIONS AND THE CORTICAL REACTION IN EGGS OF THE CNIDARIAN BUNODOSOMA CAVERNATA

Developing oocytes of the cnidarian Bunodosoma cavernata are located within the mesoglea of the mesenteries of the gastrovascular cavity. The cortex of the more mature vitellogenic oocytes contains numerous, electron-dense, membrane-bound, cortical granules. The surface of these oocytes possesses prominent radially projecting structures termed cytospines. Each cytospine has a core of microfilaments, 50–70 Å in diameter, that extends basally as a rootlet through the cortical layer. During spawning, ova lacking any extraneous investments are released from the enclosing gastrodermis. As a consequence of fertilization or events associated with the earliest stages of development the ova undergo a massive cortical reaction. This reaction, which occurs during or just after release of the ova, involves extensive reorganization of the cortical layer. The cortical granule membranes and egg surface membrane fuse and vesiculate resulting in the massive discharge of granule contents. This event is accompanied by the loss of vesicular remnants of cortical ooplasm and the disruption of cytospine organization. Light and electron microscope comparisons of unreacted and reacted eggs show that the reaction results in a significant decrease in egg diameter with the oolemma of the reacted egg reorganizing in a position centripetal to its original location.     

CHANGES IN NUCLEOLI AT MATURATION OF NEWT OOCYTE

Changes in the nucleoli of maturing oocytes and the eggs of Cynops pyrrhogaster were studied with light and electron microscopy. Extrachromosomal nucleoli moved toward the center of the germinal vesicle in response to the maturation stimulus, released presumed ribosomal ribonucleoprotein, and further moved toward the center of the nucleus to form an aggregate with chromosomes which behaved in a similar manner. A few. ball-shaped nucleolar masses were formed from this aggregate, leaving the chromosomes and probably the extrachromosomal nucleolar organizer. The chromosomes then proceeded to the first meiotic metaphase. The nucleolar masses were surrounded by a layer of mitochondria and became smaller with formation of pinched-off fragments, which were also surrounded by mitochondria, during the time the egg was moving down the oviduct. Only fragments were observed in the subcortical area of the animal hemisphere of the egg after reaching the lowest part of the oviduct.