Cyclin D and cdk4 are required for normal development beyond the blastula stage in sea urchin embryos

cdk4 mRNA and protein are constitutively expressed in sea urchin eggs and throughout embryonic development. In contrast, cyclin D mRNA is barely detectable in eggs and early embryos, when the cell cycles consist of alternating S and M phases. Cyclin D mRNA increases dramatically in embryos at the early blastula stage and remains at a constant level throughout embryogenesis. An increase in cdk4 kinase activity occurs concomitantly with the increase in cyclin D mRNA. Ectopic expression of cyclin D mRNA in eggs arrests development before the 16-cell stage and causes eventual embryonic death, suggesting that activation of cyclin D/cdk4 in cleavage cell cycles is lethal to the embryo. In contrast, blocking cyclin D or cdk4 expression with morpholino antisense oligonucleotides results in normal development of early gastrula-stage embryos but abnormal, asymmetric larvae. These results suggest that in sea urchins, cyclin D and cdk4 are required for normal development and perhaps the patterning of the developing embryo, but may not be directly involved in regulating entry into the cell cycle.     

Embryonic development of insect eggs formed without follicular epithelium

In the paedogenetic Dipteran insect Heteropeza pygmaea it is possible by physical or chemical means to obtain oocyte-nurse chamber complexes lacking the follicular epithelium. Such oocytes nevertheless complete oogenesis and begin embryonic development. Development of these “naked” eggs has been compared to normal egg development by cinematographic analysis. Eggs which are formed without follicular epithelium are completely spherical in shape and the increase in size which normally occurs during cleavage is much less extensive. Naked eggs show shape changes during the first part of cleavage, in which bulgy cytoplasmic protrusions are formed and disappear continuously. Protrusions which are present during the mitotic divisions are partly cleaved. Cleavage folds occur much earlier in naked eggs than in normal eggs. On the other hand, the duration of the mitotic cycles during nuclear multiplication of normal and naked eggs is similar. Development of naked eggs usually continues for some time after blastoderm formation before degeneration sets in. The events taking place prior to embryonic death are difficult to relate to normal gastrulation events. However, in some cases the morphogenetic movements of naked embryos resemble germ band formation of normal embryos.     

Transcriptome Analysis of Honeybee (Apis Mellifera) Haploid and Diploid Embryos Reveals Early Zygotic Transcription during Cleavage

In honeybees, the haplodiploid sex determination system promotes a unique embryogenesis process wherein females develop from fertilized eggs and males develop from unfertilized eggs. However, the developmental strategies of honeybees during early embryogenesis are virtually unknown. Similar to most animals, the honeybee oocytes are supplied with proteins and regulatory elements that support early embryogenesis. As the embryo develops, the zygotic genome is activated and zygotic products gradually replace the preloaded maternal material. The analysis of small RNA and mRNA libraries of mature oocytes and embryos originated from fertilized and unfertilized eggs has allowed us to explore the gene expression dynamics in the first steps of development and during the maternal-to-zygotic transition (MZT). We localized a short sequence motif identified as TAGteam motif and hypothesized to play a similar role in honeybees as in fruit flies, which includes the timing of early zygotic expression (MZT), a function sustained by the presence of the zelda ortholog, which is the main regulator of genome activation. Predicted microRNA (miRNA)-target interactions indicated that there were specific regulators of haploid and diploid embryonic development and an overlap of maternal and zygotic gene expression during the early steps of embryogenesis. Although a number of functions are highly conserved during the early steps of honeybee embryogenesis, the results showed that zygotic genome activation occurs earlier in honeybees than in Drosophila based on the presence of three primary miRNAs (pri-miRNAs) (ame-mir-375, ame-mir-34 and ame-mir-263b) during the cleavage stage in haploid and diploid embryonic development.     

Manipulation and In Vitro Maturation of Xenopus laevis Oocytes,Followed by Intracytoplasmic Sperm Injection,to Study Embryonic Development

Amphibian eggs have been widely used to study embryonic development. Early embryonic development is driven by maternally stored factors accumulated during oogenesis. In order to study roles of such maternal factors in early embryonic development, it is desirable to manipulate their functions from the very beginning of embryonic development. Conventional ways of gene interference are achieved by injection of antisense oligonucleotides (oligos) or mRNA into fertilized eggs, enabling under- or over-expression of specific proteins, respectively. However, these methods normally require more than several hours until protein expression is affected, and, hence, the interference of gene functions is not effective during early embryonic stages. Here, we introduce an experimental system in which expression levels of maternal proteins can be altered before fertilization. Xenopus laevis oocytes obtained from ovaries are defolliculated by incubating with enzymes. Antisense oligos or mRNAs are injected into defolliculated oocytes at the germinal vesicle (GV) stage. These oocytes are in vitro matured to eggs at the metaphase II (MII) stage, followed by intracytoplasmic sperm injection (ICSI). By this way, up to 10% of ICSI embryos can reach the swimming tadpole stage, thus allowing functional tests of specific gene knockdown or overexpression. This approach can be a useful way to study roles of maternally stored factors in early embryonic development.     

Nuclear cysteine-protease involved in male chromatin remodeling after fertilization is ubiquitously distributed during sea urchin development

Previously we have identified a cysteine-protease involved in male chromatin remodeling which segregates into the nuclei of the two blastomeres at the first cleavage division. Here we have investigated the fate of this protease during early embryogenesis by immunodetecting this protein with antibodies elicited against its N-terminal sequence. As shown in this report, the major 60 kDa active form of this protease was found to be present in the extracts of chromosomal proteins obtained from all developmental stages analyzed. In morula and gastrula the 70 kDa inactive precursor, which corresponds to the major form of the zymogen found in unfertilized eggs, was detected. In plutei larvas, the major 60 kDa form of this enzyme was found together with a higher molecular weight precursor (90 kDa) which is consistent with the less abundant zymogen primarily detected in unfertilized eggs. As reported here, either the active protease or its zymogens were visualized in most of the embryonic territories indicating that this enzyme lacks a specific pattern of spatial-temporal developmental segregation. Taken together our results indicate that this protease persists in the embryo and is ubiquitously distributed up to larval stages of development, either as an active enzyme and/or as an inactive precursor. These results suggest that this enzyme may display yet unknown functions during embryonic development that complement its role in male chromatin remodeling after fertilization.     

Egg formation and the early embryonic development of Aspidogaster limacoides Diesing, 1835 (Aspidogastrea: Aspidogastridae), with comments on their phylogenetic significance

Ultrastructural aspects of the early embryonic development of the aspidogastrean Aspidogaster limacoides are described and their phylogenetic implications discussed. Whereas the proximal regions of the uterine lumen usually contain unembryonated eggs or eggs with early embryos, the posterior or distal regions of the uterus are filled with eggs containing a fully-developed cotylocidium. The eggs of A. limacoides can be classified as polylecithal due to the presence of numerous vitellocytes which accompany each fertilized oocyte or ovum during egg formation. The results of the study are described in details under six headings: (1) general characteristics of the intrauterine eggs; (2) eggshell and operculum formation; (3) unembryonated eggs; (4) zygote formation and early cleavage divisions; (5) embryonic envelope formation; and (6) early degeneration or apoptosis of some blastomeres. The late differentiation of the operculum, possible functions of GER-bodies, and the early degeneration of vitellocytes and some blastomeres in this species are compared, drawn and discussed with corresponding observations reported for other parasitic Platyhelminthes. The most important differences are apparent in the number of egg envelopes and their mode of formation in A. limacoides compared with previous reports for both digeneans and cestodes. The results of the present TEM study indicate that the three macromeres, resulting from two cleavage divisions, take part in the formation of a single embryonic outer envelope in A. limacoides, and that this takes place at a very early stage of embryogenesis. Their fusion results in the formation of a single continuous cytoplasmic layer surrounding the early embryo, which is composed of only a small number of undifferentiated blastomeres. The early separation of the macromeres may indicate an equal cleavage pattern. These results suggest that the systematic position of the Aspidogastrea among the Platyhelminthes still remains somewhat equivocal, and indicate the need for more studies on the embryonic development, larval morphogenesis and molecular phylogeny for the elucidation of the relationships between this enigmatic group and related taxa.     

Determination of the dorsal-ventral axis in eggs of Xenopus laevis: Complete rescue of uv-impaired eggs by oblique orientation before first cleavage

Eggs of Xenopus laevis were exposed to ultraviolet (uv) radiation (2537 Å) on the vegetal hemisphere soon after fertilization at doses sufficient to impair greatly the subsequent development of dorsal structures. It was found that temporary orientation of irradiated eggs 90° off the natural vertical axis rescues these eggs, allowing them to develop into normal embryos. Complete rescue results when oblique orientation is initiated well before first cleavage, and eggs remain in this position until the 16-cell stage. Significant rescue is seen, however, in eggs which remain off axis for shorter periods of time or when eggs are obliquely oriented, even after first cleavage. Furthermore, a period of oblique orientation prior to uv irradiation results in insensitivity of eggs to irradiation. Ultraviolet irradiation is found to randomize the position of the dorsal side with respect to the sperm entrance point, whereas the position of the dorsal side of rescued embryos is strongly specified by the orientation of the egg during the rescue period, and not by the sperm entrance point. Other effects of uv irradiation on early development include decreased pigmentation differences among 4-cell stage blastomeres and delayed gastrulation. It is proposed (1) that oblique orientation promotes in irradiated eggs a set of internal rearrangements mimicking those normally accomplished by the unirradiated egg in a period prior to first cleavage and as part of an early dorsalization process, and (2) that the uv-sensitive targets are part of the morphogenic machinery used by the egg for internal rearrangements in this period and are not elements of a system of transmitted particulate dorsal determinants.     

Axis determination in polyspermic Xenopus laevis eggs

Polyspermic Xenopus laevis eggs can be identified easily because of regions of pigment accumulation and white stripes, which arise by a nocodazole-sensitive process. Eggs containing up to four sperm are capable of forming a single embryonic axis. Dispermic eggs display two regions of pigment accumulation, one around each sperm entry point (SEP), and one white stripe between the SEPs. Such eggs with a 180 degree separation between the SEPs were bisected before first cleavage along the white stripe, creating dorsal and ventral halves in many cases. Each half cleaved and formed a tadpole. When eggs were bisected early in the period of cytoplasmic reorganization (0.5-0.6 normalized time), each half could form a complete tadpole. When eggs were bisected after the period of reorganization (0.8-0.9), often one half formed a tadpole with a complete head but reduced or absent tail and the other half formed a tadpole with a complete tail but reduced or absent head. These results demonstrate that sperm cooperate to give a single embryonic axis in polyspermic eggs and the development of dorsal and ventral egg halves differs after egg reorganization before first cleavage.     

Fate of amplified nucleoli in Xenopus laevis embryos

We have followed the fate of two components of extrachromosomal nucleoli, amplified ribosomal DNA (rDNA) and 7.5 kb precursor rRNA, during early embryogenesis of Xenopus laevis. Other workers have shown that the amount of amplified rDNA accumulated during oogenesis remains unchanged through the 16-cell stage of embryogenesis. Here we show that as embryonic cleavage continues, the amount of amplified rDNA decreases until it is no longer detectable in the early gastrula embryo. In contrast, the amount of 7.5 kb precursor rRNA in eggs, early cleavage stage embryos, or blastula stage embryos is the same as in oocyte nuclei. Since no rRNA synthesis occurs during these early stages, we conclude that the precursor rRNA sequences synthesized in the oocyte are neither processed nor degraded during early development. The amplified rDNA is not replicated in the early embryo even though the chromosomal DNA of the embryo replicates every 30 min during the first 7.5 hr of embryogenesis. When amplified rDNA is purified and then injected into cleaving embryos, however, we find that it is replicated. This finding suggests that some factor(s) prevents the endogenous amplified rDNA from responding to the cellular replication signals. We show that methylation of cytosine in the rDNA is not related to the DNA's capacity for replication in this system since amplified (unmethylated) and chromosomal (methylated) rDNA are both replicated when injected into embryos. The methylation pattern of these rDNAs appears to be maintained after replication in the embryo.     

Pattern formation during early amphibian development: Embryogenesis in inverted anuran and urodele eggs

Early embryogenesis was monitored in Xenopus, Rana (anurans), and Ambystoma (urodele) eggs which were inverted at various times between fertilization and first cleavage. The pattern of cleavage furrow formation, site of involution, and extent of organogenesis were observed. In several instances, pattern formation was dramatically altered. The small/large blastomere pattern was, for example, reversed in some inverted embryos. Developmental arrest at early organogenesis usually followed pattern reversal. By employing a series of tissue transplantations, it was possible to establish that the activity of the primary embryonic organizer of inverted embryos was diminished drastically. The developmental competence of the prospective ectoderm of inverted embryos was, however, reversed. Incomplete organogenesis in inverted embryos is therefore probably due to either abnormal mesoderm formation or defective tissue interactions.     

Early embryonic development of the dipteran insect Heteropeza pygmaea in the presence of cytoskeleton-affecting drugs

Summary Embryos of the paedogenetically reproducing gall midge Heteropeza pygmaea develop floating in the haemocoel of a so-called mother larva. The egg membranes remain permeable and the embryos increase in size during embryonic development by taking up nutrients from the haemolymph. Such embryos can be cultured in vitro, i.e. in haemolymph drops obtained from mother larvae. We tested the effects of several drugs known to interact with cytoskeletal elements on different stages of embryonic development, including cleavage and gastrulation. The drugs were added to the in vitro cultures and the effects were studied with time-lapse cine-micrography. Colchicine and vinblastine blocked cleaving eggs in metaphase stage and arrested yolk globule oscillation. In spite of such a block blastoderms once formed continued development through germ band formation and extension and also increased in size. Cytochalasin B did not affect the stage of cleavage; however, it inhibited gastrulation and subsequent morphogenetic processes and also prevented size increase. We conclude that (1) the functioning of microtubules is needed for yolk globule oscillation during cleavage interphases but not for the gastrulation processes subsequent to blastoderm formation and (2) microfilaments do not play an important role in cleavage, at least not for the orderly succession of the cleavage divisions, but are essential for the morphogenetic movements associated with gastrulation. We suggest that during cleavage a limited stock of microtubules and their precursors is responsible for both transport of chromosomes during mitoses and translocation of organelles during interphase. Yolk oscillation seems to be a secondary effect and of minor or no importance for the normal course of embryonic development.Dedicated to Professor Gerhard Krause on the occasion of his 80th birthday     

Insemination of immature sea urchin (Arbacia punctulata) eggs

Nuclei from osmotically opened erythrocytes and erythroblasts were injected into nucleated or enucleated Xenopus laevis eggs. Although the cleavage pattern of the recipient eggs which started to divide was normal in about half of the cases, nuclei from erythrocytes injected into nucleated or enucleated eggs never promoted development beyond the early gastrula stage. In contrast, nuclei from osmotically opened erythroblasts injected into enucleated eggs promoted development to early tadpole stages (stages 29–36). Frequently, injection of osmotically broken erythroblasts injected into nonenucleated eggs gave rise to triploid larvae which all died at roughly the same early tadpole stages (29–36). Surprisingly, development did not proceed to the stage of advanced organogenesis (stages 44–47), which is easily reached by gynogenetic haploids: The presence of the haploid genome derived from the egg pronucleus did not significantly improve the developmental capacity. Embryos obtained by single injection of erythrocyte nuclei into nucleated eggs were unable to pass the gastrula stage. To invalidate the interpretation that the observed arrest in development was related to nuclear damage during injection of the recipient eggs, single unbroken erythrocytes and unbroken erythroblasts were transferred into nucleated and enucleated eggs. No cleavage was observed in both classes of eggs injected with unbroken erythrocytes. In contrast, erythroblasts were found to induce cleavage in the recipient eggs at a frequency of about 11%. To ascertain that the nucleus of unbroken erythroblasts participated in development, the 1-nucleolar marker was used. Diploid embryos with only one nucleolus present were found following injection of unbroken erythroblasts into enucleated eggs from 2nu females. Triploid 2nu embryos were detected following injection of (diploid) 1nu erythroblasts into nonenucleated eggs from 2nu females. The most advanced development stages reached by these embryos did not, however, differ from the best results found in the first class of experiments: Nuclei from erythroblasts injected undamaged into nucleated or enucleated eggs never developed into a normal tadpole. Serial transfer experiments were performed using normally gastrulating embryos which had developed, following the injection of 1nu unbroken erythroblasts into recipient eggs. These donors for serial transfer experiments were checked for the presence of the 1nu marker. In addition they had passed through a normally cleaving eight-cell stage. No improvement in developmental capacity as compared to first transfer experiments could be found.     

斑马鱼胚胎第一次卵裂过程中胞内钙信号的研究

钙离子作为广泛存在的细胞内信使物质,在动物胚胎早期发育过程中扮演重要角色.为了研究钙离子在斑马鱼胚胎发育过程中的空间分布和浓度变化,采用Fluo-4和Indo-1作为钙离子指示剂,利用激光共聚焦和双波长荧光比例成像技术,对斑马鱼胚胎第一次卵裂过程中的钙信号进行了详细的跟踪观察.在第一次卵裂过程中,斑马鱼胚胎的动物极顶端首先出现高钙斑,然后在分裂沟部位出现高浓度的钙信号,这一信号在卵裂过程中持续存在.利用Indo-1双波长荧光比例成像对上述过程中钙离子的时空分布进行了定量测定,表明,胞内钙离子在卵裂开始之前是均匀分布的,随着分裂沟的出现,其附近区域的钙浓度显著升高,而胞内其他区域的钙浓度则保持不变.双波长荧光比例成像排除了荧光染料分布不均匀造成的干扰,为钙信号与胚胎分裂的密切关系提供了确凿的定量依据.     

Early intrauterine embryonic development of the bothriocephalidean cestode Clestobothrium crassiceps (Rudolphi, 1819), a parasite of the teleost Merluccius merluccius (L., 1758) (Gadiformes: Merlucciidae)

The early intrauterine embryonic development of the bothriocephalidean cestode Clestobothrium crassiceps (Rudolphi, 1819), a parasite of the teleost Merluccius merluccius (L., 1758), was studied by means of light (LM) and transmission electron microscopy (TEM). Contrary to the generic diagnosis given in the CABI Keys to the cestode parasites of vertebrates, the eggs of C. crassiceps, the type of species of Clestobothrium Lühe, 1899, are operculate and embryonated. Our LM and TEM results provide direct evidence that an operculum is present and that the eggs exhibit various stages of intrauterine embryonic development, and in fact represent a good example of early ovoviviparity. The intrauterine eggs of this species are polylecithal and contain numerous vitellocytes, generally ∼ 30, which are pushed to the periphery and remain close to the eggshell, whereas the dividing zygote and later the early embryo remain in the egg centre. During early intrauterine embryonic development, several cleavage divisions take place, which result in the formation of three types of blastomeres, i.e. macro-, meso- and micromeres. These can be readily differentiated at the TEM level, not only by their size, but also by the ultrastructural characteristics of their nuclei and cytoplasmic organelles. The total number of blastomeres in these early embryos, enclosed within the electron-dense eggshells, can be up to ∼ 20 cells of various sizes and characteristics. Mitotic divisions of early blastomeres were frequently observed at both LM and TEM levels. Simultaneously with the mitotic cleavage divisions leading to blastomere multiplication and their rapid differentiation, there is also a deterioration of some blastomeres, mainly micromeres. A similar degeneration of vitellocytes begins even earlier. Both processes show a progressive degeneration of both vitellocytes and micromeres, and are good examples of apoptosis, a process that provides nutritive substances, including lipids, for the developing embryo.     

Axis determination in eggs of Xenopus laevis: A critical period before first cleavage,identified by the common effects of cold,pressure and ultraviolet irradiation

Exposure of eggs of Xenopus laevis to a temperature of 1.0°C for 4 min or a pressure of 8000 psi for 5 min in a critical period before first cleavage results in embryos exhibiting a reduction and loss of structures of the body axis. The deficiencies occur in a craniocaudal progression which is dose dependent. In the extreme, totally axis-deficient embryos with radial symmetry are formed. Maximum sensitivity to cold and pressure occurs at 0.6 of the time from fertilization to first cleavage and extends from approximately 0.4 to 0.8, the period between pronuclear contact and mitosis, and the approximate period of gray crescent formation. The effects of cold and pressure resemble those previously reported for uv irradiation in that (1) the types of axis-deficient embryos produced are morphologically indistinguishable; (2) sensitivity in all cases ends before 0.8; (3) cold and uv effects, although not those of pressure, can be prevented by cotreatment with D₂O; and (4) impaired eggs can be rescued by oblique orientation. We interpret these results as follows: during the 0.4–0.8 period the egg reorganizes its contents in a manner critical for subsequent development of the embryonic body axis. The reorganization process involves cytoskeletal elements, some of which are sensitive to cold, pressure, and uv, and protected by D₂O. Rescue by oblique orientation can be understood as the result of a gravity-driven reorganization of the egg's contents, supplanting the normal mechanochemical process impaired in treated eggs.     

First cleavages,preblastula and blastula in the parthenogenetic mite Archegozetes longisetosus (Acari,Oribatida) indicate holoblastic rather than superficial cleavage

The mode of cleavage in the Acari is generalized as superficial or intralecithal, with a preceding phase of total (holoblastic) cleavage, but the knowledge is fragmentary and conclusions have been inconsistent, even when relating to the same species. Since no data about early embryology is available for the speciose group Oribatida, we studied Archegozetes longisetosus using transmission electron microscopy. We focused on early cleavages and the formation of the blastula, as these are the important and controversial points in early embryology of the Acari. We expected, as postulated for other acarine eggs, the early cleavages to be holoblastic and followed by a superficial preblastoderm stage. The early cleavages of A. longisetosus are holoblastic and blastomeres give rise to yolk-free micromeres and macromeres containing all the yolk. In contrast to expectations, the micromeres do not form a superficial preblastoderm layer. They are scattered along the embryonic surface and form an external, monocellular layer that covers the whole surface of the embryo. Since each of the existing TEM studies of mites shows this same pattern, and since this specialized form of total cleavage seems to be unique in Chelicerata, it may be the general mode of cleavage in Acari. However, the question will require much more investigation, especially since most data relate to the Actinotrichida and very few are currently available for species in the other major group, the Anactinotrichida.     

Post-transcriptional regulation of protein synthesis in Ilyanassa embryos and isolated polar lobes

The experimental removal of the polar lobe, an anucleate cytoplasmic protrusion formed in preparation for the first cleavage, from the egg of Ilyanassa obsoleta results in grossly abnormal embryonic development. In experiments reported here normal and delobed embryos, as well as isolated polar lobes, were incubated with [³⁵S]methionine for 4 hr beginning at the completion of the first cleavage or 21 hr later during epiboly. Proteins were extracted and examined by fluorography after resolution by two-dimensional polyacrylamide gel electrophoresis. In normal embryos the synthesis of several proteins begins or ends between the two stages investigated. In isolated polar lobes a subset of these developmental changes in protein synthesis occurs, indicating that the regulation of these events is independent of concomitant nuclear activity and probably involves selective regulation of the translation of mRNA stored in the eggs. The patterns of protein synthesis in normal embryos and delobed embryos are qualitatively extremely similar, though quantitative differences are also observed. No proteins can be detected which are synthesized exclusively in polar lobes.     

Early patterning of the mouse embryo--contributions of sperm and egg

The first cleavage of the fertilised mouse egg divides the zygote into two cells that have a tendency to follow distinguishable fates. One divides first and contributes its progeny predominantly to the embryonic part of the blastocyst, while the other, later dividing cell, contributes mainly to the abembryonic part. We have previously observed that both the plane of this first cleavage and the subsequent order of blastomere division tend to correlate with the position of the fertilisation cone that forms after sperm entry. But does sperm entry contribute to assigning the distinguishable fates to the first two blastomeres or is their fate an intrinsic property of the egg itself? To answer this question we examined the distribution of the progeny of early blastomeres in embryos never penetrated by sperm - parthenogenetic embryos. In contrast to fertilised eggs, we found there is no tendency for the first two parthenogenetic blastomeres to follow different fates. This outcome is independent of whether parthenogenetic eggs are haploid or diploid. Also unlike fertilised eggs, the first 2-cell blastomere to divide in parthenogenetic embryo does not necessarily contribute more cells to the blastocyst. However, even when descendants of the first dividing blastomere do predominate, they show no strong predisposition to occupy the embryonic part. Thus blastomere fate does not appear to be decided by differential cell division alone. Finally, when the cortical cytoplasm at the site of sperm entry is removed, the first cleavage plane no longer tends to divide the embryo into embryonic and abembryonic parts. Together these results indicate that in normal development fertilisation contributes to setting up embryonic patterning, alongside the role of the egg.