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.     

Cytological investigation of the mechanism of parthenogenesis in Drosophila mercatorum

Thelytokous parthenogenesis (female progeny only) in animals is believed to arise initially in unfertilized eggs produced by bisexual females via the fusion of two haploid nuclei following meiosis, to produce diploid female progeny. The transition from sexual to parthenogenetic mechanisms of reproduction requires that the egg replace the paternal contributions of a haploid genetic complement and the basal body, which is thought to be essential for centrosome formation. The transitional facultative parthenogenetic stage is usually associated with a high rate of failed or abortive development, but the molecular and mechanistic reasons for this failure remain unclear. We show that a facultative parthenogenetic strain of Drosophila mercatorum produces a high percentage of unfertilized eggs competent to restore diploidy and form centrosomes de novo following meiosis. The female meiotic products replicate and divide by an acentrosomal mechanism in most oocytes and cytoplasmic centrosomes form in 35% of the oocytes. However, after pronuclear replication the cytoplasmic centrosomes must "capture" two haploid nuclei in order to restore diploidy. In practice, this process frequently fails due to centrosome-mediated capture events of single or more than two haploid nuclei, as well as multiple nuclear capture events in a single embryo when excess free centrosomes are not inactivated following formation of the first zygotic nucleus. Additionally, as development proceeds, many of the centrosomes that initiate syncytial development do not remain functional, possibly due to centrosome maturation defects, and later stages of syncytial development fail. The combined effect of the high error rate associated with nuclear capture and the failure of centrosome maturation during later developmental prevents successful parthenogenesis in most of the eggs that initiate development. This shows that the high rate of failed development associated with the transition from sexual to parthenogenetic reproduction is limited by the low probability of the formation of a diploid zygotic nucleus with the correct complement of centrosomes in D. mercatorum.     

Regulation of the paternal inheritance of centrosomes in starfish zygotes

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

Drosophila parthenogenesis: a model for de novo centrosome assembly

The Drosophila egg contains all the components required to properly execute the early mitotic divisions but is unable to assemble a functional centrosome without a sperm-provided basal body. We show that 65% of unfertilized eggs obtained from a laboratory strain of Drosophila mercatorum can spontaneously assemble a number of cytoplasmic asters after activation, most of them duplicating in a cell cycle-dependent manner. Such asters are formed by a polarized array of microtubules that have their Asp-associated minus-ends converging at a main focus, where centrioles and typical centrosomal antigens are found. Aster assembly is spatially restricted to the anterior region of the oocyte. When fertilized, the parthenogenetic egg forms the poles of the gonomeric spindle by using the sperm-provided basal body, despite the presence within the same cytoplasm of maternal centrosomes. Thirty-five percent of parthenogenetic eggs and all unfertilized and fertilized eggs from the sibling bisexually reproducing D. mercatorum strain do not contain cytoplasmic asters. Thus, the Drosophila eggs have the potential for de novo formation of functional centrosomes independent of preexisting centrioles, but some control mechanisms preventing their spontaneous assembly must exist. We speculate that the release of the block preventing centrosome self-assembly could be a landmark for ensuring parthenogenetic reproduction.     

Cytological Investigation of the Mechanism of Parthenogenesis in Drosophila mercatorum

Thelytokous parthenogenesis (female progeny only) in animals is believed to arise initially in unfertilized eggs produced by bisexual females via the fusion of two haploid nuclei following meiosis, to produce diploid female progeny. The transition from sexual to parthenogenetic mechanisms of reproduction requires that the egg replace the paternal contributions of a haploid genetic complement and the basal body, which is thought to be essential for centrosome formation. The transitional facultative parthenogenetic stage is usually associated with a high rate of failed or abortive development, but the molecular and mechanistic reasons for this failure remain unclear. We show that a facultatively parthenogenetic strain of Drosophila mercatorum produces a high percentage of unfertilized eggs competent to restore diploidy and form centrosomes de novo following meiosis. The female meiotic products replicate and divide by an acentrosomal mechanism in most oocytes and cytoplasmic centrosomes form in 35% of the oocytes. However, after pronuclear replication the cytoplasmic centrosomes must "capture" two haploid nuclei in order to restore diploidy. In practice, this process frequently fails due to centrosome-mediated capture events of single or more than two haploid nuclei, as well as multiple nuclear capture events in a single embryo when excess free centrosomes are not inactivated following formation of the first zygotic nucleus. Additionally, as development proceeds, many of the centrosomes that initiate syncytial development do not remain functional, possibly due to centrosome maturation defects, and later stages of syncytial development fail. The combined effect of the high error rate associated with nuclear capture and the failure of centrosome maturation during later developmental prevents successful parthenogenesis in most of the eggs that initiate development. This shows that the high rate of failed development associated with the transition from sexual to parthenogenetic reproduction is limited by the low probability of the formation of a diploid zygotic nucleus with the correct complement of centrosomes in D. mercatorum.     

Dominant-negative mutant dynein allows spontaneous centrosome assembly, uncouples chromosome and centrosome cycles

Cleavage cycles commence and chromosome and centrosome cycles proceed in harmony following fertilization of Drosophila eggs and completion of the meiotic divisions. The sperm-introduced centrioles replicate, separate, and while recruit pericentriolar material centrosomes (CS) form. The CS nucleate asters of microtubules (MT). Spindles form following interaction of some astral MT with kinetochores. In unfertilized eggs, chromosomes do not replicate, and CS and MT asters never form, although their components are present in the egg cytoplasm; unknown mechanisms prevent chromosome replication and CS and MT assembly. In unfertilized Laborc(D) eggs, rudimentary CS assemble spontaneously and instantaneously and nucleate small MT asters. In fertilized Laborc(D) eggs, normal CS form and organize normal asters. However, the CS replicate prior to accomplishment of the first mitosis, and spindles with multiple CS develop. In fertilized Laborc(D) eggs, while the chromosome cycles cease, CS cycles proceed as in wild type. Knowing that Laborc(D) is a dominant-negative mutation and encodes the formation of mutant cytoplasmic dynein heavy chain molecules, we show here that cytoplasmic dynein is involved in prevention of CS assembly in unfertilized eggs and establishing harmony between the chromosome and the CS cycles.     

Motility and centrosomal organization during sea urchin and mouse fertilization

Motility and the behavior and inheritance of centrosomes are investigated during mouse and sea urchin fertilization. Sperm incorporation in sea urchins requires microfilament activity in both sperm and eggs as tested with Latrunculin A, a novel inhibitor of microfilament assembly. In contrast the mouse spermhead is incorporated in the presence of microfilament inhibitors indicating an absence of microfilament activity at this stage. Pronuclear apposition is arrested by microfilament inhibitors in fertilized mouse oocytes. The migrations of the sperm and egg nuclei during sea urchin fertilization are dependent on microtubules organized into a radial monastral array, the sperm aster. Microtubule activity is also required during pronuclear apposition in the mouse egg, but they are organized by numerous egg cytoplasmic sites. By the use of an autoimmune antibody to centrosomal material, centrosomes are detected in sea urchin sperm but not in unfertilized eggs. The sea urchin centrosome expands and duplicates during first interphase and condenses to form the mitotic poles during division. Remarkably mouse sperm do not appear to have the centrosomal antigen and instead centrosomes are found in the unfertilized oocyte. These results indicate that both microfilaments and microtubules are required for the successful completion of fertilization in both sea urchins and mice, but at different stages. Furthermore they demonstrate that centrosomes are contributed by the sperm during sea urchin fertilization, but they might be maternally inherited in mammals.     

Activation of maternal centrosomes in unfertilized sea urchin eggs.

Centrosomes are undetectable in unfertilized sea urchin eggs, and normally the sperm introduces the cell's microtubule-organizing center (MTOC) at fertilization. However, artificial activation or parthenogenesis triggers microtubule assembly in the unfertilized egg, and this study explores the reappearance and behavior of the maternal centrosome. During activation with A23187 or ammonia, microtubules appear first at the cortex; centrosomal antigen is detected diffusely throughout the entire cytoplasm. Later, the centrosome becomes more distinct and organizes a radial microtubule shell, and eventually a compact centrosome at the egg center organizes a monaster. In these activated eggs, centrosomes undergo cycles of compaction and decompaction in synchrony with the chromatin, which also undergoes cycles of condensation and decondensation. Parthenogenetic activation with heavy water (50% D2O) or the microtubule-stabilizing drug taxol (10 microM) induces numerous centrosomal foci in the unfertilized sea urchin egg. Within 15 min after incubation in D2O, numerous fine centrosomal foci are detected, and they organize a connected network of numerous asters which fill the entire egg. Taxol induces over 100 centrosomal foci by 15 min after treatment, which organize a corresponding number of asters. The centrosomal material in either D2O- or taxol-treated eggs aggregates with time to form fewer but denser foci, resulting in fewer and larger asters. Fertilization of eggs pretreated with either D2O or taxol shows that the paternal centrosome is dominant over the maternal centrosome. The centrosomal material gradually becomes associated with the enlarged sperm aster. These experiments demonstrate that maternal centrosomal material is present in the unfertilized egg, likely as dispersed undetectable material, which can be activated without paternal contributions. At fertilization, paternal centrosomes become dominant over the maternal centrosomal material.     

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.     

Centrosome inheritance in starfish zygotes: selective loss of the maternal centrosome after fertilization

The mature egg inherits a centrosome from the second meiotic spindle, and the sperm introduces a second centrosome at fertilization. Since only one of these centrosomes survives to be used in development, specific mechanisms must exist to control centrosome inheritance. To investigate how centrosome inheritance is controlled we used starfish eggs as a model system, because they undergo meiosis after fertilization. As a result, the fate of the maternal and paternal centrosomes can be followed by light microscopy and experimentally manipulated in vivo. We show initially that only the paternal centrosome is used in starfish zygote development; the maternal centrosome retained from meiosis II is functionally lost before first mitosis. We then tested a number of possible ways in which the zygote could exert this differential control over the stability of centrosomes initially residing in the same cytoplasm. The results of these experiments can be summarized as follows: (1) Although the microtubule organizing center activity of the maternal centrosome is not degraded after meiosis, the ability of this centrosome to double at successive mitoses is lost. (2) The sperm centrosome is not "masked" from cytoplasmic conditions which could destabilize all centrosomes during or after the meiotic sequence. (3) The functional loss of the maternal centrosome is not due to its cortical location. (4) The loss of this doubling capacity is determined by the egg, not by putative inhibitory factors from the fertilizing sperm. (5) The destabilization of the maternal centrosome is not due to the complete loss of its centrioles. Together, these results demonstrate that all maternal centrosomes are equivalent and that they are intrinsically different from the paternal centrosome. This intrinsic difference, in concert with a change in cytoplasmic conditions after meiosis, determines the selective loss of the maternal centrosome inherited from the meiosis II spindle.     

Aster self-organization at meiosis: a conserved mechanism in insect parthenogenesis?

Unfertilized eggs usually lack maternal centrosomes and cannot develop without sperm contribution. However, several insect species lay eggs that develop to adulthood as unfertilized in the absence of a preexisting centrosome. We report that the oocyte of the parthenogenetic viviparous pea aphid Acyrthosiphon pisum is able to self-organize microtubule-based asters, which in turn interact with the female chromatin to form the first mitotic spindle. This mode of reproduction provides a good system to investigate how the oocyte can assemble new centrosomes and how their number can be exactly monitored. We propose that the cooperative interaction of motor proteins and randomly nucleated surface microtubules could lead to the formation of aster-like structures in the absence of pre-existing centrosomes. Recruitment of material along the microtubules might contribute to the accumulation of pericentriolar material and centriole precursors at the focus of the asters, thus leading to the formation of true centrosomes. The appearance of microtubule asters at the surface of activated oocytes could represent a possible common mechanism for centrosome formation during insect parthenogenesis.     

Taxol inhibits the nuclear movements during fertilization and induces asters in unfertilized sea urchin eggs

Taxol blocks the migrations of the sperm and egg nuclei in fertilized eggs and induces asters in unfertilized eggs of the sea urchins Lytechinus variegatus and Arbacia punctulata. Video recordings of eggs inseminated in 10 microM taxol demonstrate that sperm incorporation and sperm tail motility are unaffected, that the sperm aster formed is unusually pronounced, and that the migration of the egg nucleus and pronuclear centration are inhibited. The huge monopolar aster persists for at least 6 h; cleavage attempts and nuclear cycles are observed. Colcemid (10 microM) disassembles both the large taxol-stabilized sperm aster in fertilized eggs and the numerous asters induced in unfertilized eggs. Antitubulin immunofluorescence microscopy demonstrates that in fertilized eggs all microtubules are within the prominent sperm aster. Within 15 min of treatment with 10 microM taxol, unfertilized eggs develop numerous (greater than 25) asters de novo. Transmission electron microscopy of unfertilized eggs reveals the presence of microtubule bundles that do not emanate from centrioles but rather from osmiophilic foci or, at times, the nuclear envelope. Taxol-treated eggs are not activated as judged by the lack of DNA synthesis, nuclear or chromosome cycles, and the cortical reaction. These results indicate that: (a) taxol prevents the normal cycles of microtubule assembly and disassembly observed during development; (b) microtubule disassembly is required for the nuclear movements during fertilization; (c) taxol induces microtubules in unfertilized eggs; and (d) nucleation centers other than centrioles and kinetochores exist within unfertilized eggs; these presumptive microtubule organizing centers appear idle in the presence of the sperm centrioles.     

Dynamics of microtubules and positioning of female pronucleus during bovine parthenogenesis

The zygote centrosome, consisting of both paternal and maternal centrosomal components, is the microtubule-organizing center necessary for pronuclear migration and positioning in fertilization. Maternal centrosomal function in microtubule organization and pronuclear positioning, however, remains unclear. In the present study, we sought to elucidate the function of maternal centrosomes during bovine parthenotes in the microtubule organizational processes required to move the pronucleus to the cell center without sperm centrosomal components. Microtubule organization, pronuclear position, and distribution of gamma-tubulin, which is thought to be the major component of maternal centrosomal material, were imaged by immunocytochemistry and conventional epifluorescence microscopy. In bovine parthenotes treated with paclitaxel, a microtubule-stabilizing drug, the cytoplasmic microtubule asters became organized after chemical activation, and the microtubules radiated dynamically toward the female pronucleus. The microtubule patterns correlated well with pronuclear movement to the cell center. Microtubules aggregated at regions of gamma-tubulin concentration, but gamma-tubulin did not localize to a spot until the first interphase of bovine parthenogenesis. These findings indicate that gamma-tubulin is responsible for microtubule organization as the maternal centrosome. In bovine parthenogenesis, the maternal centrosome then organizes cytoplasmic microtubules to move the female pronucleus into the cell center. We propose that the maternal centrosome plays a role as a functional centrosome despite the lack of a sperm contribution, making this structure less competent for microtubule organization in comparison with centrosomes containing sperm centrosomal components.     

Immunocytochemical evidence for centrosomal phosphoproteins in mitotic sea urchin eggs

The change in distribution of centrosomal phosphoproteins was examined in sea urchin eggs from fertilization to the first cleavage by immunofluorescence staining with the anti-phosphoprotein antibodies, MPM-1 and MPM-2. The antibodies reacted with female pronuclei in unfertilized eggs as well as centriolar complexes located at the base of sperm flagella. After insemination, male and female pronuclei fused together to form a zygotic nucleus which was visualized by staining of fertilized eggs with the antiphosphoprotein antibodies. No major change in staining pattern was detected in extracted whole eggs until mitosis. As the fertilized eggs approached mitosis, however, the antigens started to redistribute from nuclei to the perinuclear position where the mitotic centrosomes were located. Detailed immunofluorescence observation of isolated spindles revealed that the phosphoantigens were retained in isolated structures. A major 225 kd polypeptide was recognized by the antibodies, suggesting that the 225 kd protein is a phosphocomponent of centrosomes. The area recognized by the antibody in mitotic poles enlarged with the progress of mitosis, suggesting that the antigens were apparently localized in the centrosphere. Centrospheres prepared from isolated spindles by salt extraction strongly reacted with the antibodies. One or two bright dots, which may represent centrioles, were visible in the isolated centrosphere. At the end of mitosis, the antigens again appeared in the newly formed daughter nuclei. Centriole-containing cytasters and centriole-free monasters were parthenogenetically induced in unfertilized eggs (Kuriyama and Borisy, (1983) J. Cell Sci. 61: 175-189). The antibodies stained centers of both the asters whether they contained centrioles or not, indicating that the antibodies recognizes the components of the pericentriolar material.     

A bacterium targets maternally inherited centrosomes to kill males in Nasonia

Male killing is caused by diverse microbial taxa in a wide range of arthropods. This phenomenon poses important challenges to understanding the dynamics of sex ratios and host-pathogen interactions. However, the mechanisms of male killing are largely unknown. Evidence from one case in Drosophila suggests that bacteria can target components of the male-specific sex-determination pathway. Here, we investigated male killing by the bacterium Arsenophonus nasoniae in the haplo-diploid wasp Nasonia vitripennis, in which females develop as diploids from fertilized eggs and males develop parthenogenetically as haploids from unfertilized eggs. We found that Arsenophonus inhibits the formation of maternal centrosomes, organelles required specifically for early male embryonic development, resulting in unorganized mitotic spindles and developmental arrest well before the establishment of somatic sexual identity. Consistent with these results, rescue of Arsenophonus-induced male lethality was achieved by fertilization with sperm bearing the supernumerary chromosome paternal sex ratio (PSR), which destroys the paternal genome but bypasses the need for maternal centrosomes by allowing transmission of the sperm-derived centrosome into the egg. These findings reveal a novel mechanism of male killing in Nasonia, demonstrating that bacteria have evolved different mechanisms for inducing male killing in the Arthropods.     

IMMUNOFLUORESCENCE MICROSCOPY OF FERTILIZATION AND PARTHENOGENESIS IN LAMINARIA ANGUSTATA (PHAEOPHYTA)1

Normal fertilization and parthenogenesis of unfertilized eggs were observed in Laminaria angustata Kjellman by indirect immunofluorescence microscopy using a tubulin antibody. Sperm aster formation did not occur at plasmogamy. The centrosome of the egg gradually disappeared. Shortly after karyogamy, one centrosome reappeared near the zygote nucleus. During mitosis, the centrosome replicated and the daughter centrosomes migrated to opposite poles. The mitotic spindle was formed by microtubules that elongated from both poles. After the first cell division, each of the daughter cells received one centrosome that persisted throughout the development of the sporophyte. During parthenogenetic development, abnormal mono-, tri-, and multi-polar spindles were formed. These abnormal spindles caused abnormal nuclear and cytoplasmic division. Thus, cells were produced with 1) no nuclei, 2) multiple nuclei, 3) irregular numbers of chromosomes, and/or 4) no centrosomes. This is one of the reasons for the abortion and abnormal morphogenesis during parthenogenesis. Ultrastructural observations showed that, although cells of some parthogenetic sporophytes have centrioles, cells of almost all abnormally shaped parthenogenetic sporophytes lack centrioles. These results suggest that centrioles are required for normal centrosomal functions in Laminaria. Although centrioles are inherited paternally, some centrosomal material appears to be present or produced de novo in unfertilized eggs.     

Nuclei and microtubule asters stimulate maturation/M phase promoting factor (MPF) activation in Xenopus eggs and egg cytoplasmic extracts

Although maturation/M phase promoting factor (MPF) can activate autonomously in Xenopus egg cytoplasm, indirect evidence suggests that nuclei and centrosomes may focus activation within the cell. We have dissected the contribution of these structures to MPF activation in fertilized eggs and in egg fragments containing different combinations of nuclei, centrosomes, and microtubules by following the behavior of Cdc2 (the kinase component of MPF), the regulatory subunit cyclin B, and the activating phosphatase Cdc25. The absence of the entire nucleus-centrosome complex resulted in a marked delay in MPF activation, whereas the absence of the centrosome alone caused a lesser delay. Nocodazole treatment to depolymerize microtubules through first interphase had an effect equivalent to removing the centrosome. Furthermore, microinjection of isolated centrosomes into anucleate eggs promoted MPF activation and advanced the onset of surface contraction waves, which are close indicators of MPF activation and could be triggered by ectopic MPF injection. Finally, we were able to demonstrate stimulation of MPF activation by the nucleus-centriole complex in vitro, as low concentrations of isolated sperm nuclei advanced MPF activation in cycling cytoplasmic extracts. Together these results indicate that nuclei and microtubule asters can independently stimulate MPF activation and that they cooperate to enhance activation locally.     

Hydrozoan eggs can only be fertilized at the site of polar body formation

Hydrozoan eggs are normally fertilized at the site of polar body formation. The female pronucleus is just under the cell membrane at this site. Sperm are attracted to the eggs and aggregate at this site. This paper demonstrates that this site is the only region on the egg surface where the sperm can fuse with the egg. This has been done by cutting unfertilized eggs into fragments containing the site of polar body formation and fragments without this region. Sperm were added to the fragments and their ability to be fertilized was assayed by noting whether or not they cleaved. Only fragments containing the site of polar body formation cleaved. The absence of cleavage in fragments lacking the site of polar body formation cannot be attributed to the inability of these fragments to attract sperm. Such fragments attract sperm for several hours while fragments which contain the site of polar body formation stop attracting sperm a few minutes after fertilization. Cytological studies of egg fragments which do not contain the site of polar body formation show that they do not contain sperm nuclei. The lack of cleavage in these fragments cannot be attributed to the lack of a female pronucleus. By using centrifugation it is possible to move the female pronucleus away from the site of polar body formation. By cutting these centrifuged eggs in an appropriate way it is possible to create egg fragments with the site of polar body formation that lack the female pronucleus and egg fragments that lack the site of polar body formation but contain a female pronucleus. Only fragments which contain the site of polar body formation can be fertilized.     

Cytoskeleton and chromatin reorganization in horse oocytes following intracytoplasmic sperm injection: patterns associated with normal and defective fertilization

Intracytoplasmic sperm injection (ICSI) is the method of choice for fertilizing horse oocytes in vitro. Nevertheless, for reasons that are not yet clear, embryo development rates are low. The aims of this study were to examine cytoskeletal and chromatin reorganization in horse oocytes fertilized by ICSI or activated parthenogenetically. Additional oocytes were injected with a sperm labeled with a mitochondrion-specific vital dye to help identify the contribution of the sperm to zygotic structures, in particular the centrosome. Oocytes were fixed at set intervals after sperm injection and examined by confocal laser scanning microscopy. In unfertilized oocytes, microtubules were present only in the metaphase-arrested second meiotic spindle and the first polar body. After sperm injection, an aster of microtubules formed adjacent to the sperm head and subsequently enlarged such that at the time of pronucleus migration and apposition it filled the entire cytoplasm. During syngamy, the microtubule matrix reorganized to form a mitotic spindle on which the chromatin of both parents aligned. Finally, after nuclear and cellular cleavage were complete, the microtubule asters dispersed into the interphase daughter cells. Sham injection induced parthenogenetic activation of 76% of oocytes, marked by the formation of multiple cytoplasmic microtubular foci that later developed into a dense microtubule network surrounding the female pronucleus. The finding that a parthenote alone can produce a microtubule aster, whereas the aster invariably forms at the base of the sperm head during normal fertilization, indicates that both gametes contribute to the formation of the zygotic centrosome in the horse. Finally, 25% of sperm-injected oocytes failed to complete fertilization, mostly due to absence of oocyte activation (65%), which was often accompanied by failure of sperm decondensation. In conclusion, this study demonstrated that union of the parental genomes in horse zygotes is accompanied by a series of integrated cytoskeleton-mediated events, failure of which results in developmental arrest.     

Cargo Transport by Cytoplasmic Dynein Can Center Embryonic Centrosomes

To complete meiosis II in animal cells, the male DNA material needs to meet the female DNA material contained in the female pronucleus at the egg center, but it is not known how the male pronucleus, deposited by the sperm at the periphery of the cell, finds the cell center in large eggs. Pronucleus centering is an active process that appears to involve microtubules and molecular motors. For small and medium-sized cells, the force required to move the centrosome can arise from either microtubule pushing on the cortex, or cortically-attached dynein pulling on microtubules. However, in large cells, such as the fertilized Xenopus laevis embryo, where microtubules are too long to support pushing forces or they do not reach all boundaries before centrosome centering begins, a different force generating mechanism must exist. Here, we present a centrosome positioning model in which the cytosolic drag experienced by cargoes hauled by cytoplasmic dynein on the sperm aster microtubules can move the centrosome towards the cell’s center. We find that small, fast cargoes (diameter ∼100 nm, cargo velocity ∼2 µm/s) are sufficient to move the centrosome in the geometry of the Xenopus laevis embryo within the experimentally observed length and time scales.