Independence of two microtubule systems in fertilized frog eggs: the sperm aster and the vegetal parallel array

Two microtubule-containing structures are implicated in dorsoventral polarization of the frog egg, and we examined the relationship between them. The sperm aster provides a directional cue for a cortical rotation specifying polarity, and a vegetal cortical array of parallel microtubules is likely part of the rotational machinery. The growing aster has an accumulation of microtubules marking the path of the sperm pronucleus, and its microtubules extend into the egg cortex as well as the cytoplasm. To test whether the vegetal parallel array was an extension of astral cortical growth, fertilized or activated eggs were bisected into animal and vegetal fragments. The vegetal fragments formed parallel arrays, even when isolated within a few minutes of egg activation. Neither the sperm centrosome nor another microtubule organizing center in the animal half of the egg is required for formation of the parallel array, but some animal half activity is involved in its disappearance. Correspondence to: R.P. Elinson     

Organization and regulation of cortical microtubules during the first cell cycle of Xenopus eggs.

Anti-tubulin antibodies and confocal immunofluorescence microscopy were used to examine the organization and regulation of cytoplasmic and cortical microtubules during the first cell cycle of fertilized Xenopus eggs. Appearance of microtubules in the egg cortex temporally coincided with the outgrowth of the sperm aster. Microtubules of the sperm aster first reached the animal cortex at 0.25, (times normalized to first cleavage), forming a radially organized array of cortical microtubules. A disordered network of microtubules was apparent in the vegetal cortex as early as 0.35. Cortical microtubule networks of both animal and vegetal hemispheres were reorganized at times corresponding to the cortical rotation responsible for specification of the dorsal-ventral (D-V) axis. Optical sections suggest that the cortical microtubules are continuous with the microtubules of the sperm aster in fertilized eggs, or an extensive activation aster in activated eggs. Neither assembly and organization, nor disassembly of the cortical microtubules coincided with MPF activation during mitosis. However, cycloheximide or 6-dimethylaminopurine, which arrest fertilized eggs at interphase, blocked cortical microtubule disassembly. Injection of p13, a protein that specifically inhibits MPF activation, delayed or inhibited cortical microtubule breakdown. In contrast, eggs injected with cyc delta 90, a truncated cyclin that arrest eggs in M-phase, showed normal microtubule disassembly. Finally, injection of partially purified MPF into cycloheximide-arrested eggs induced cortical microtubule breakdown. These results suggest that, despite a lack of temporal coincidence, breakdown of the cortical microtubules is dependent on the activation of MPF.     

Complementary roles for dynein and kinesins in the Xenopus egg cortical rotation

Aligned vegetal subcortical microtubules in fertilized Xenopus eggs mediate the "cortical rotation", a translocation of the vegetal cortex and of dorsalizing factors toward the egg equator. Kinesin-related protein (KRP) function is essential for the cortical rotation, and dynein has been implicated indirectly; however, the role of neither microtubule motor protein family is understood. We examined the consequence of inhibiting dynein--dynactin-based transport by microinjection of excess dynamitin beneath the vegetal egg surface. Dynamitin introduced before the cortical rotation prevented formation of the subcortical array, blocking microtubule incorporation from deeper regions. In contrast, dynamitin injected after the microtubule array was fully established did not block cortical translocation, unlike inhibitory-KRP antibodies. During an early phase of cortical rotation, when microtubules showed a distinctive wavy organization, dynamitin disrupted microtubule alignment and perturbed cortical movement. These findings indicate that dynein is required for formation and early maintenance of the vegetal microtubule array, while KRPs are largely responsible for displacing the cortex once the microtubule tracks are established. Consistent with this model for the cortical rotation, photobleach analysis revealed both microtubules that translocated with the vegetal cytoplasm relative to the cortex, and ones that moved with the cortex relative to the cytoplasm.     

Gavity and Microtubules in Dorsoventral Polarization of The Xenopus Egg

In Xenopus laevis , the dorsoventral axis of the embryo is specified by a 30° relative rotation between the cortex and the cytoplasm of the fertilized egg, and a cortical array of parallel microtubules may be part of the rotation machinery (7). The parallel microtubules are aligned with the sperm entry point in most of the eggs as expected, since the dorsoventral axis is usually defined by the sperm entry point. We show that gravity can play two roles in the formation of the dorsoventral axis. First, a simple 90° tilt off-axis before the start of the rotation overcomes the influence of the sperm and determines the orientation of the parallel microtubules. Second, a 90° tilt off-axis can specify the dorsoventral axis even in the absence of the parallel microtubules. Therefore, gravity can affect dorsoventral polarity by orienting the parallel microtubules or by moving cytoplasm directly without microtubules.     

Microtubules in ascidian eggs during meiosis, fertilization, and mitosis

The sequential changes in the distribution of microtubules during germinal vesicle breakdown (GVBD), fertilization, and mitosis were investigated with antitubulin indirect immunofluorescence microscopy in several species of ascidian eggs (Molgula occidentalis, Ciona savignyi, and Halocynthia roretzi). These alterations in microtubule patterns were also correlated with observed cytoplasmic movements. A cytoplasmic latticework of microtubules was observed throughout meiosis. The unfertilized egg of M. occidentalis had a small meiotic spindle with wide poles; the poles became focused after egg activation. The other two species had more typical meiotic spindles before fertilization. At fertilization, a sperm aster first appeared near the cortex close to the vegetal pole. It enlarged into an unusual asymmetric aster associated with the egg cortex. The sperm aster rapidly grew after the formation of the second polar body, and it was displaced as far as the equatorial region, corresponding to the site of the myoplasmic crescent, the posterior half of the egg. The female pronucleus migrated to the male pronucleus at the center of the sperm aster. The microtubule latticework and the sperm aster disappeared towards the end of first interphase with only a small bipolar structure remaining until first mitosis. At mitosis the asters enlarged tremendously, while the mitotic spindle remained remarkably small. The two daughter nuclei remained near the site of cleavage even after division was complete. These results document the changes in microtubule patterns during maturation in Ascidian oocytes, demonstrate that the sperm contributes the active centrosome at fertilization, and reveal the presence of a mitotic apparatus at first division which has an unusually small spindle and huge asters.     

Human sperm centrosomal function during fertilization, a novel assessment for male sterility

In human fertilization, the sperm introduces the centrosome-the microtubule organizing center-and microtubules are organized within the inseminated egg from the sperm centrosome. These microtubules form a radial array, the sperm aster, the functioning of which is essential for pronuclear movement for the union of the male and female genomes. We established functional assay for human sperm centrosomal function, by using heterologus ICSI system with bovine and rabbit eggs. After human sperm incorporation into mammalian egg, we observed that the sperm aster was organized from sperm centrosome, and the sperm aster enlarged as the sperm nuclei underwent pronuclear formation. The normal human sperm aster formation rate at 6 h post-ICSI were 60.0% in bovine egg and 36.1% in rabbit egg, respectively. However, sperm aster formation rate following heterologus ICSI into bovine eggs with teratozoospermia (globozoospermia, dysplasia of fibrous sheath) were low. These data indicate that human sperm centrosomal function is low in abnormal shaped sperm. Wherus, elucidation of human sperm centrosomal function can lead us to find a new type of failure in "post ICSI events in fertilization".     

Role of the cytoskeleton in sperm entry during fertilization in the freshwater bivalve Dreissena polymorpha

The present study examined the role of the cytoskeleton in sperm entry and migration through the egg cytoplasm during fertilization in the zebra mussel, Dreissena polymorpha (Bivalvia: Veneroida: Dreissenidae). Fertilization in this freshwater bivalve occurs outside the mantle cavity, permitting detailed observations of fertilization. After its initial binding to the egg surface, the sperm is incorporated in two stages: (1) a gradual incorporation of the sperm nucleus into the egg cortex, followed by (2) a more rapid incorporation of the sperm axoneme, and translocation of the sperm head through the egg cytoplasm. Initial incorporation into the egg cortex was shown to be microfilament dependent. Microfilaments were found in the sperm's preformed acrosomal filament, the microvilli on the egg surface, and in an actin-filled insemination cone surrounding the incorporating sperm. Treatment of eggs with cytochalasin B inhibited sperm entry in a dose- and time-dependent manner. Microtubule polymerization was not necessary for initial sperm entry. Following incorporation of the sperm head, the flagellar axoneme entered the egg cytoplasm and remained active for several minutes. Associated with the incorporated axoneme was a flow of cytoplasmic particles originating near the proximal end of the flagella. Inhibition of microtubule polymerization prevented entry of the sperm axoneme, and the subsequent cytoplasmic current was not observed. After sperm incorporation into the egg cortex, no appreciable microfilaments were associated with the sperm nucleus. A diminutive sperm aster was associated with the sperm nucleus during its decondensation, but no obvious extension toward the female pronucleus was observed. The sperm aster was significantly smaller than the spindle associated with the female pronucleus, suggesting a reduced role for the sperm aster in amphimixis.     

A transient array of parallel microtubules in frog eggs: potential tracks for a cytoplasmic rotation that specifies the dorso-ventral axis

The dorsoventral axis of the frog embryo is specified by a rotation of the egg cytoplasm relative to the cortex. When eggs undergoing the cortical/cytoplasmic rotation were examined by immunocytochemistry and electron microscopy, an extensive array of parallel microtubules was found covering the vegetal hemisphere of the egg. The microtubules were 1-3 microns deep from the plasma membrane and were aligned parallel to the direction of rotation. They formed at the start of rotation and disappeared at its completion. Colchicine and uv irradiation, inhibitors of the rotation, prevented the formation of the parallel microtubules. Based on these properties, we suggest that the parallel microtubules serve as tracks for the cortical/cytoplasmic rotation which specifies the dorsoventral axis of the embryo.     

Sperm aster formation and pronuclear decondensation during rabbit fertilization and development of a functional assay for human sperm

Microtubule organization and chromatin configurations in rabbit eggs after in vivo rabbit fertilization and after intracytoplasmic injection with human sperm were characterized. In unfertilized eggs, an anastral barrel-shaped meiotic spindle, oriented radially to the cortex, was observed. After rabbit sperm incorporation, microtubules were organized into a radial aster from the sperm head, and cytoplasmic microtubules were organized around the male and female pronuclei. The microtubules extending from the decondensed sperm head participated in pronuclear migration, and organization around the female pronucleus may also be important for pronuclear centration. Support for these observations was found in parthenogenetically activated eggs, in which microtubule arrays were organized around the single female pronucleus that formed after artificial activation. These observations support a biparental centrosomal contribution during rabbit fertilization as opposed to a strictly paternal inheritance pattern suggested from previous studies. In rabbit eggs that received injected human donor sperm, an astral array of microtubules radiated from the sperm neck and enlarged as the sperm head underwent pronuclear decondensation. gamma-Tubulin was observed in the center of the sperm aster. We conclude that the rabbit egg exhibits a blended centrosomal contribution necessary for completion of fertilization and that the rabbit egg may be a novel animal model for assessing centrosomal function in human sperm and spermatogenic cells following intracytoplasmic injection.     

Local inhibition of cortical rotation in Xenopus eggs by an anti-KRP antibody

The dorsal-ventral axis of amphibian embryos is specified by the "cortical rotation," a translocation of the egg cortex relative to the vegetal yolk mass. The mechanism of cortical rotation is not understood but is thought to involve an array of aligned, commonly oriented microtubules. We have demonstrated an essential requirement for kinesin-related proteins (KRPs) in the cortical rotation by microinjection beneath the vegetal cortex of an antipeptide antibody recognising multiple Xenopus egg KRPs. Time-lapse videomicroscopy revealed a striking local inhibition of the cortical rotation around the injection site, indicating that KRP-mediated translocation of the cortex is generated by forces acting across the vegetal subcortical region. Anti-tubulin immunofluorescence showed that the antibody disrupted both formation and maintenance of the aligned microtubule array. Direct examination of rhodamine-labelled microtubules by confocal microscopy showed that the anti-KRP antibody provoked striking three-dimensional flailing movement of the subcortical microtubules. In contrast, microtubules in antibody-free regions undulated only within the plane of the cortex, a significant population exhibiting little or no net movement. These findings suggest that KRPs have a critical role during cortical rotation in tethering microtubules to the cortex and that they may not contribute significantly to the translocation force as previously thought.     

Effects of motility inhibitors during sea urchin fertilization : Microfilament inhibitors prevent sperm incorporation and restructuring of fertilized egg cortex, whereas microtubule inhibitors prevent pronuclear migrations

The sensitivity of specific stages of fertilization to microfilament inhibitors (cytochalasins B (CB), D (CD), and E (CE) and phalloidin) and to inhibitors of microtubule assembly (colcemid (CMD), colchicine (CLC), griseofulvin (GSF), maytansine (MAY), nocodazole (NCD), podophyllotoxin (PDP), and vinblastine (VB)) was investigated using differential interference contrast, time-lapse video microscopy of the sea urchin Lytechinus variegatus. Cytochalasins (CDCE>CB) will prevent sperm incorporation if added prior to or simultaneous with insemination. Sperm-egg fusion and the cortical reaction appear normal, but then the subsequent elevation of the fertilization coat lifts and eventually detaches the ‘fertilizing’ sperm from the egg plasma membrane. When the cytochalasins are added after fusion, the forming fertilization cone is rapidly resorbed, and the lateral displacement of the sperm along the egg cortex is terminated; the pronuclear migrations and mitoses occur normally though cytokinesis is never observed. Cytochalasin treatment before or within 2 min of insemination results in the development of aberrant egg cortices, whereas cytochalasin treatments after 2 min post-fusion have little effect. Phalloidin results in large and long-lasting fertilization cones and a retardation of the rate of sperm incorporation. Eggs exposed to any of the microtubule inhibitors 15 min prior to insemination will incorporate the spermatozoon, though the formation of the sperm aster and the accompanying pronuclear migrations are prevented. Interestingly, the final stage of sperm incorporation involving a lateral displacement of the sperm along the egg cortex is greater (27.1 vs 12.4 μm in controls) and faster (5.4 vs 3.5 μm/min in controls) in microtubule-inhibited eggs. GSF and VB, which readily permeate fertilized eggs, will prevent the formation of the sperm aster if added 3 min after sperm-egg fusion, they will prevent the migration of the female pronucleus if added 5 or 7 min after sperm-egg fusion, pronuclear centration if added 10 min post-fusion, and syngamy if added 12 min post-fusion. CLC- or CMD- treated eggs will develop normally if these drugs are photochemically inactivated with 366 nm light within 4 min post-fusion, arguing that sperm incorporation is completely independent of assembling microtubules. These results indicate that microfilament inhibitors will prevent sperm incorporation and the restructuring of the fertilized egg cortex, and that microtubule inhibitors will prevent the formation and functioning of the sperm aster during the pronuclear migrations; an interplay between cortical microfilaments and cytoplasmic microtubules appears required for the successful completion of fertilization.     

Phases of cytoplasmic and cortical reorganizations of the ascidian zygote between fertilization and first division.

Many eggs undergo reorganizations that localize determinants specifying the developmental axes and the differentiation of various cell types. In ascidians, fertilization triggers spectacular reorganizations that result in the formation and localization of distinct cytoplasmic domains that are inherited by early blastomeres that develop autonomously. By applying various imaging techniques to the transparent eggs of Phallusia mammillata, we now define 9 events and phases in the reorganization of the surface, cortex and the cytoplasm between fertilization and first cleavage. We show that two of the domains that preexist in the egg (the ER-rich cortical domain and the mitochondria-rich subcortical myoplasm) are localized successively by a microfilament-driven cortical contraction, a microtubule-driven migration and rotation of the sperm aster with respect to the cortex, and finally, a novel microfilament-dependant relaxation of the vegetal cortex. The phases of reorganization we have observed can best be explained in terms of cell cycle-regulated phases of coupling, uncoupling and recoupling of the motions of cortical and subcortical layers (ER-rich cortical domain and mitochondria-rich domain) with respect to the surface of the zygote. At the end of the meiotic cell cycle we can distinguish up to 5 cortical and cytoplasmic domains (including two novel ones; the vegetal body and a yolk-rich domain) layered against the vegetal cortex. We have also analyzed how the myoplasm is partitioned into distinct blastomeres at the 32-cell stage and the effects on development of the ablation of precisely located small fragments. On the basis of our observations and of the ablation/ transplantation experiments done in the zygotes of Phallusia and several other ascidians, we suggest that the determinants for unequal cleavage, gastrulation and for the differentiation of muscle and endoderm cells may reside in 4 distinct cortical and cytoplasmic domains localized in the egg between fertilization and cleavage.     

Centrosomal function assessment in human sperm using heterologous ICSI with rabbit eggs: a new male factor infertility assay

Sperm centrosomal function was assessed by immunocytochemical analysis after the injection of human sperm into mature rabbit eggs. Three hours after intracytoplasmic sperm injection (ICSI), an astral microtubule array from the base of the human sperm was observed in the rabbit eggs. This sperm aster expanded in the egg cytoplasm, concomitant with pronuclear formation, and a dense microtubule array was organized at the time of pronuclear centration. Using fertile donor sperm, the sperm aster formation rate at 3 hr after ICSI was 35.0 +/- 1.5%. Using sperm from infertile patients, the average aster formation rate was lower (25.4 +/- 14.8%, P<0.05). Among infertile cases, there was no correlation between sperm aster formation rates and conventional parameters of semen analysis. However, the sperm aster formation rate correlated with the embryonic cleavage rate following human in vitro fertilization (IVF). These data suggest that this assay reflects sperm function during embryonic development after sperm entry and that reproductive success during the first cell cycle requires a functional sperm centrosome. Furthermore, sperm centrosomal function cannot be predicted from conventional parameters of semen analysis. We propose that insufficient centrosomal function could be the cause of certain cases of idiopathic infertility. These assays may lead to the discovery of new types of infertility, which have previously been treated as "unexplained infertility," and may also lead to the treatment of infertility incurable even by ICSI. Consequently, an accurate and relevant assay to help assure couples of the success of fertilization is warranted, perhaps prior to ICSI therapy.     

Evidence for the involvement of microtubules, ER, and kinesin in the cortical rotation of fertilized frog eggs

During the first cell cycle, the vegetal cortex of the fertilized frog egg is translocated over the cytoplasm. This process of cortical rotation creates regional cytoplasmic differences important in later development, and appears to involve an array of aligned microtubules that forms transiently beneath the vegetal cortex. We have investigated how these microtubules might be involved in generating movement by analyzing isolated cortices and sections of Xenopus laevis and Rana pipiens eggs. First, the polarity of the cortical microtubules was determined using the "hook" assay. Almost all microtubules had their plus ends pointing in the direction of cortical rotation. Secondly, the association of microtubules with other cytoplasmic elements was examined. Immunofluorescence revealed that cytokeratin filaments coalign with the microtubules. The timing of their appearance and their position on the cytoplasmic side of the microtubules suggested that they are not involved directly in generating movement. ER was visualized with the dye DiIC16(3) and by immunofluorescence with anti-BiP (Bole, D. G., L. M. Hendershot, and J. F. Kearney, 1986. J. Cell Biol. 102:1558-1566). One layer of ER was found closely underlying the plasma membrane at all times. An additional, deeper layer formed in association with the microtubules of the array. Antibodies to sea urchin kinesin (Ingold, A. L., S. A. Cohn, and J. M. Scholey. 1988. J. Cell Biol. 107:2657-2667) detected antigens associated with both the ER and microtubules. On immunoblots they recognized microtubule associated polypeptide(s) of approximately 115 kD from Xenopus eggs. These observations are consistent with a role for kinesin in creating movement between the microtubules and ER, which leads in turn to the cortical rotation.     

Human sperm aster formation and pronuclear decondensation in bovine eggs following intracytoplasmic sperm injection using a Piezo-driven pipette: a novel assay for human sperm centrosomal function.

In human fertilization, the sperm introduces the centrosome; the microtubule-organizing center and microtubules are organized within the inseminated egg from the sperm centrosome. These microtubules form a radial array, called the sperm aster, the functioning of which is essential to pronuclear movement for union of male and female genome. The sperm centrosomal function is considered to be necessary for the normal human fertilization process. Therefore, the dysfunction of sperm centrosome is a possible cause of human fertilization failure. However, little information is available regarding human sperm centrosomal function during fertilization in clinically assisted reproductive technology. To assess the human sperm centrosomal function, we examined sperm aster formation and pronuclear decondensation following intracytoplasmic sperm injection (ICSI) with human sperm into the bovine egg using a Piezo-driven pipette and ethanol activation of eggs. After human sperm incorporation into bovine egg, we observed that the sperm aster was organized from sperm centrosome, and that the sperm aster was enlarged as the sperm nuclei underwent pronuclear formation. The sperm aster formation rate at 6 h post-ICSI and the male pronuclear formation rate at 8-12 h post-ICSI were 60.0% and 83.3%, respectively. No difference of the sperm aster formation rate and the male pronuclear formation rate was observed between eggs activated with ethanol and eggs without artificial activation. We concluded that this heterologous Piezo-ICSI system into bovine egg can be a novel assay for human sperm centrosomal function, and it is possible to explicate a course of fertilization failure that was unknown until now.     

Deep cytoplasmic rearrangements during early development in Xenopus laevis

The egg of the frog Xenopus is cylindrically symmetrical about its animal-vegetal axis before fertilization. Midway through the first cell cycle, the yolky subcortical cytoplasm rotates 30 degrees relative to the cortex and plasma membrane, usually toward the side of the sperm entry point. Dorsal embryonic structures always develop on the side away from which the cytoplasm moves. Details of the deep cytoplasmic movements associated with the cortical rotation were studied in eggs vitally stained during oogenesis with a yolk platelet-specific fluorescent dye. During the first cell cycle, eggs labelled in this way develop a complicated swirl of cytoplasm in the animal hemisphere. This pattern is most prominent on the side away from which the vegetal yolk moves, and thus correlates in position with the prospective dorsal side of the embryo. Although the pattern is initially most evident near the egg's equator or marginal zone, extensive rearrangements associated with cleavage furrowing (cytoplasmic ingression) relocate portions of the swirl to vegetal blastomeres on the prospective dorsal side.     

Effects of cytoskeletal inhibitors on ooplasmic segregation and microtubule organization during fertilization and early development in the ascidian Molgula occidentalis

The effects of microtubule and microfilament inhibitors on ooplasmic segregation and microtubule organization were examined during fertilization, parthenogenetic activation, and early development in the ascidian Molgula occidentalis. At fertilization the egg cortex contracts as the first phase movement and shortly after mitochondria migrate as the myoplasmic crescent develops in the second phase. The microtubule inhibitors colcemid and nocodazole inhibit the second phase, but not the first phase, of ooplasmic segregation. The microfilament inhibitor cytochalasin E has the reciprocal effect of inhibiting the first, but not the second, phase. It appears that sperm may initially bind at any site on the egg surface and that the contractile activities at the first phase and during polar body formation occur independent of the microtubule system. Since the second phase migration occurs as the sperm astral microtubules assemble and since microtubule, but not microfilament, inhibitors arrest this aspect of ooplasmic segregation, microtubules appear necessary for mitochondrial migration. These results demonstrate that the two phases of ascidian ooplasmic segregation are mediated by different systems, the first by microfilaments and the second by microtubules. The microtubule and microfilament systems appear to operate independent of one another and their combined actions result in the completion of ooplasmic segregation. A model is proposed in which the cortical contraction following fertilization is important not only as the motive force for the first phase movement but also as a method to unite the myoplasm with the entering sperm which can initially bind anywhere on the egg surface. The association between myoplasmic components and the growing sperm aster would ensure that the migration and the spatial distribution of myoplasm in the second phase results in the formation of the myoplasmic crescent.     

Anti-tubulin immunofluorescence microscopy of microtubules present during the pronuclear movements of sea urchin fertilization

Anti-tubulin immunofluorescence microscopy is used here to demonstrate the configurations of the microtubule-containing structures which participate in the pronuclear movements of sea urchin fertilization. This technique shows that the egg is devoid of microtubules until after the fertilizing sperm is fully incorporated. All the microtubules which appear during the course of fertilization are organized around the base of the sperm head and the sperm aster thus formed behaves in a way that could account for the characteristic motions of the male and female pronuclei as documented by time-lapse video microscopy. Extension of astral microtubules appears to be responsible for the slow (ca. 2.5 μm min^?1) movement of the sperm aster into the cytoplasm of the egg; the rapid (ca. 15 μm min^?1) migration of the female pronucleus to the sperm aster seems to depend on connection of the female pronucleus to microtubules of the sperm aster. Continued extension of astral microtubules after the pronuclei are brought into conjunction can account for the centripetal motion of the paired (or fused) pronuclei and for the positioning of the zygote nucleus in the center of the egg. The behavior of astral microtubules during these motions suggests that they are capable of transmitting both pushing and pulling forces. All the pronuclear movements, and the assembly of detectable microtubules, are sensitive to the microtubule inhibitors griseofulvin and colchicine. Because of this sensitivity, and since all the observable microtubules within the egg during fertilization arise at the sperm aster, it is concluded that the pronuclear movements of fertilization result from the actions of the sperm aster. The pronuclear movements of sea urchin fertilization represent a simple but striking example of microtubule-mediated motility.     

Microtubule array observed in the posterior‐vegetal cortex during cytoplasmic and cortical reorganization of the ascidian egg

Body axis formation during embryogenesis results from asymmetric localization of maternal factors in the egg. Shortly before the first cleavage in ascidian eggs, cell polarity along the anteroposterior (A–P) axis is established and the cytoplasmic domain (myoplasm) relocates from the vegetal to the posterior region in a microtubule‐dependent manner. Through immunostaining, tubulin accumulation during this reorganization is observable on the myoplasm cortex. However, more detailed morphological features of microtubules remain relatively unknown. In this study, we invented a new reagent that improves the immunostaining of cortical microtubules and successfully visualized a parallel array of thick microtubules. During reorganization, they covered nearly the entire myoplasm cortical region, beneath the posterior‐vegetal cortex. We designated this microtubule array as CAMP (cortical array of microtubules in posterior vegetal region). During the late phase of reorganization, CAMP shrank and the myoplasm formed a crescent‐like cytoplasmic domain. When the CAMP formation was inhibited by sodium azide, myoplasmic reorganization and A–P axis formation were both abolished, suggesting that CAMP is important for these two processes.     

Analysis of microtubule movement on isolated Xenopus egg cortices provides evidence that the cortical rotation involves dynein as well as Kinesin Related Proteins and is regulated by local microtubule polymerisation

In amphibians, the cortical rotation, a translocation of the egg cortex relative to the cytoplasm, specifies the dorsoventral axis. The cortical rotation involves an array of subcortical microtubules whose alignment is mediated by Kinesin-related proteins (KRPs), and stops as M-phase promoting factor (MPF) activation propagates across the egg. To dissect the role of different motor proteins in the cortical rotation and to analyse their regulation, we have developed an open cell assay system involving reactivation of microtubule movement on isolated cortices. Microtubule movements were dependent on ATP and consisted mainly of wriggling and flailing without net displacement, consistent with a tethering of microtubules to the cortex. Reactivated movements were inhibited by anti-KRP and anti-dynein antibodies perfused together but not separately, the KRP antibody alone becoming fixed to the cortex. Neither antibody could inhibit movement in the presence of MPF, indicating that arrest of the cortical rotation is not due to MPF-dependent inhibition of motor molecules. In contrast, D(2)O treatment of live eggs to protect microtubules from progressive depolymerisation prolonged the cortical rotation. We conclude that the cortical rotation probably involves cytoplasmic dynein as well as cortical KRPs and terminates as a result of local MPF-dependent microtubule depolymerisation.