Identification of a cytoskeletal protein localized in the myoplasm of ascidian eggs: localization is modified during anural development

The myoplasm of ascidian eggs is a localized cytoskeletal domain that is segregated to presumptive larval tail muscle cells during embryonic development. We have identified a cytoskeletal protein recognized by a vertebrate neurofilament monoclonal antibody (NN18) which is concentrated in the myoplasm in eggs and embryos of a variety of ascidian species. The NN18 antigen is localized in the periphery of unfertilized eggs, segregates with the myoplasm after fertilization, and enters the larval tail muscle cells during embryonic development. Western blots of one-dimensional and two-dimensional gels showed that the major component recognized by NN18 antibody is a 58 x 10(3) Mr protein (p58), which exists in at least three different isoforms. The enrichment of p58 in the Triton X-100-insoluble fraction of eggs and its reticular staining pattern in eggs and embryos suggests that it is a cytoskeletal protein. In subsequent experiments, p58 was used as a marker to determine whether changes in the myoplasm occur in eggs of anural ascidian species, i.e. those exhibiting a life cycle lacking tadpole larvae with differentiated muscle cells. Although p58 was localized in the myoplasm in eggs of four urodele ascidian species that develop into swimming tadpole larvae, this protein was distributed uniformly in eggs of three anural ascidian species. The eggs of two of these anural species contained the actin lamina, another component of the myoplasm, whereas the third anural species lacked the actin lamina. There was no detectible localization of p58 after fertilization or segregation into muscle lineage cells during cleavage of anural eggs. NN18 antigen was uniformly distributed in pre-vitellogenic oocytes and then localized in the perinuclear zone during vitellogenesis of urodele and anural ascidians. Subsequently, NN18 antigen was concentrated in the peripheral cytoplasm of post-vitellogenic oocytes and mature eggs of urodele, but not anural, ascidians. It is concluded that the myoplasm of ascidian eggs contains an intermediate filament-like cytoskeletal network which is missing in anural species that have modified or eliminated the tadpole larva.     

Interactions between cytoskeletal components during myoplasm rearrangement in ascidian eggs

Ooplasmic segregation in ascidian eggs consists of two phases of cytoplasmic movement, the first phase is mediated by the microfilament system and the second is mediated by the microtubule system. Recently, two novel proteins, p58 and myoplasmin-C1, which are localized to the myoplasm, were suggested to have important roles in muscle differentiation. In order to analyze the molecular mechanisms underlying ooplasmic segregation, the interactions between actin, tubulin, p58 and myoplasmin-C1 were examined. During the first segregation, microtubule meshwork in the unfertilized egg disappeared. At the second segregation, a novel structure of the microtubules that extended from the sperm aster and localized in the cortical region of the myoplasm was found. Moreover, uniform distribution of the cortical actin filament was observed at the second segregation. During the course of myoplasm rearrangement, p58 and myoplasmin-C1 are colocalized and can form a molecular complex in vitro. This complex of p58 and myoplasmin-C1 is a good candidate for a cytoskeletal component of the myoplasm, and is likely to be involved in the correct distribution of cytoplasmic determinants.     

Molecular characterization of myoplasmin-C1: a cytoskeletal component localized in the myoplasm of the ascidian egg

 Myoplasmin-C1 is a polypeptide detected by a monoclonal antibody, which is localized in the myoplasm of ascidian eggs. Since microinjection of the antibody blocks larval muscle development, myoplasmin-C1 may play a role in muscle cell differentiation (Nishikata et al. 1987). Isolation and characterization of myoplasmin-C1 cDNA clones revealed that the predicted amino acid sequence of myoplasmin-C1 had no similarity to any known protein. However, the deduced protein contains heptad repeats similar to those in myosin heavy chain, tropomyosin and the Drosophila Bicaudal D gene product, suggesting that it is a filamentous component of the myoplasmic cytoskeleton. The predicted amino acid sequence also showed several possible phosphorylation sites. Consistent with the prediction that myoplasmin-C1 is a cytoskeletal component, the protein remained in the myoplasmic cytoskeletal domain after detergent extraction. These results suggest that myoplasmin-C1 is a cytoskeletal component of the myoplasm and that it plays a role in anchoring and segregating muscle determinants. Received: 6 October 1995 / Accepted in revised form: 7 December 1995     

A yellow crescent cytoskeletal domain in ascidian eggs and its role in early development

In this investigation, Triton X-100 extraction was utilized to examine the cytoskeleton of ascidian eggs and embryos. The cytoskeleton contained little carbohydrate or lipid and only about 20–25% of the total cellular protein and RNA. It was enriched in polypeptides of molecular weight (M_r) 54, 48, and 43 × 10³. The 43 × 10³M_r polypeptide was identified as actin based on its M_r, isoeletric point, and affinity for DNase I. Electron microscopy of the detergent-extracted eggs showed that they contained cytoskeletal domains corresponding to colored cytoplasmic regions of specific morphogenetic fate in the living egg. A yellow crescent cytoskeletal domain in the myoplasm was examined and shown to consist of a plasma membrane lamina (PML) and a deeper lattice of filaments which appeared to connect the yellow crescent pigment granules to the PML. The PML probably consists of integral membrane proteins stabilized by an underlying network of actin filaments since NBD-phallacidin stained this area of the egg cortex and the PML was extracted from the cytoskeleton by DNase I treatment. The yellow crescent cytoskeletal domain was found throughout the cortex of the unfertilized egg. During ooplasmic segregation it progressively receded into the vegetal hemisphere and was subsequently partitioned to the presumptive muscle and mesenchyme cells of the 32-cell embryo. It is suggested that contraction of the actin network in the yellow crescent cytoskeletal domain is the motive force for ooplasmic segregation. This structure may also serve as a framework for the positioning of morphogenetic determinants involved in muscle cell development.     

Spatial distribution of messenger RNA in the cytoskeletal framework of ascidian eggs

Maternal poly(A)⁺RNA, histone mRNA, and actin mRNA exhibit unique spatial distributions in the different ooplasmic regions of ascidian eggs. These RNAs also appear to migrate with their respective ooplasms during the episode of extensive cytoplasmic rearrangement that occurs after fertilization, suggesting they are associated with a structural framework. The role of the cytoskeletal framework (CF) in determining the spatial distribution of maternal mRNA was tested by subjecting Triton X-100 extracted (Styela plicata) eggs and early embryos to in situ hybridization with poly(U) and cloned DNA probes. Grain counts indicated that substantial proportions of the egg poly(A)⁺RNA, histone mRNA, and actin mRNA were present in the CF and that there was no alteration in the extent of mRNA-CF interactions during the period between fertilization and the two-cell stage. Analysis of grain distributions indicated that poly(A)⁺RNA, histone mRNA, and actin mRNA were concentrated in the same regions of detergent-extracted eggs as they are in intact eggs. The proportions and spatial distribution of these RNAs in the CF were not affected when the actin cytoskeleton was destabilized by cytochalasin B or DNAse I. The data suggest that maternal mRNA is associated with the CF, that this association is responsible for mRNA rearrangement during ooplasmic segregation, and that mRNA-CF interactions are not dependent on the integrity of the actin cytoskeleton.     

Activation of ascidian eggs with lectins

Eggs of Phallusia mammillata, dechorionated with trypsin, were activated in solutions of concanavalin A and wheat germ agglutinin. The polar bodies were extruded, and an aster appeared, but there was no cleavage. Ooplasmic segregation took place and mitochondria accumulated at the vegetal pole. Large chromatic granules formed in older eggs. The striking parallel between the migration of lectin receptors to the vegetal pole and “capping” was noted.     

The spatial distribution of maternal mRNA is determined by a cortical cytoskeletal domain in Chaetopterus eggs

Messenger RNA molecules are localized in the cortical region of eggs and unevenly segregated to the embryonic cells during early development of the annelid Chaetopterus. The egg cortex is enriched in two organelles, ectoplasmic spherules and associated structures, which are similar in appearance to nuage. The physical basis of cortical mRNA localization was examined in stratified eggs and in eggs extracted with the nonionic detergent Nonidet P-40 (NP-40). The cortical organelles were displaced to the most centrifugal zone of stratified eggs. In situ hybridization with poly(U) or cloned DNA probes showed that a large proportion of the poly(A)+RNA, histone mRNA, and actin mRNA molecules was also displaced to the centrifugal zone. Extraction with NP-40 revealed a detergent-insoluble cytoskeletal domain (CD) in the egg cortex which contained the remnants of ectoplasmic spherules and nuage embedded in a fibrous network. Although most of the total protein and RNA was extracted by NP-40, a large proportion of the poly(A)+RNA, histone mRNA, and actin mRNA molecules was retained in the CD. In situ hybridization of stratified eggs extracted with NP-40 indicated that the CD, with its associated organelles and mRNA molecules, is displaced to the centrifugal zone as a unit. The results suggest that the tenacious association of mRNA molecules with the cortical CD may be responsible for maternal mRNA localization during early development.     

The embryonic development of Schistosoma mansoni eggs: proposal for a new staging system

Schistosomiasis is a water-borne parasitic illness caused by neoophoran trematodes of the genus Schistosoma. Using classical histological techniques and whole-mount preparations, the present work describes the embryonic development of Schistosoma mansoni eggs in the murine host and compares it with eggs maintained under in vitro conditions. Two pre-embryonic stages occur inside the female worm: the prezygotic stage is characterized by the release of mature oocytes from the female ovary until its fertilization. The zygotic stage encompasses the migration of the zygote through the ootype, where the eggshell is formed, to the uterus. Fully formed eggs are laid still undeveloped, without having suffered any cleavage. In the outside environment, eight embryonic stages can be defined: stage 1 refers to early cleavages and the beginning of yolk fusion. Stage 2 represents late cleavage, with the formation of a stereoblastula and the onset of outer envelope differentiation. Stage 3 is defined by the elongation of the embryonic primordium and the onset of inner envelope formation. At stage 4, the first organ primordia arise. During stages 5 to 7, tissue and organ differentiation occurs (neural mass, epidermis, terebratorium, musculature, and miracidial glands). Stage 7 is characterized by the nuclear condensation of neurons of the central neural mass. Stage 8 refers to the fully formed larva, presenting muscular contraction, cilia, and flame-cell beating. This staging system was compared to a previous classification and could underlie further studies on egg histoproteomics (morphological localizome). The differentiation of embryonic structures and their probable roles in granulomatogenesis are discussed herein. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users.     

Localization of mitochondrial large ribosomal RNA in the myoplasm of the early ascidian embryo

Mitochondrial large ribosomal RNA (mtlrRNA) is transferred out of mitochondria and associates with germinal granules in Drosophila and Xenopus embryos. It has been revealed that mtlrRNA outside of mitochondria is required for formation of the germ-line progenitor, or pole cells in Drosophila. In the present study, the distribution of mtlrRNA was examined in embryos of the ascidian, Halocynthia roretzi, during cleavage stages by whole-mount in situ hybridization. Until the 4-cell stage, the distribution of mtlrRNA coincided with that of mitochondria. which are localized to the cortical cytoplasm in the posterior region of the embryos. Both mitochondria and mtlrRNA were preferentially partitioned into muscle-lineage blastomeres during cleavage stages. After the 8-cell stage, a discrepancy in intracellular localization of mitochondria and mtlrRNA became evident. Mitochondria translocated into central yolkless cytoplasm, while mtlrRNA remained in the posterior cortex in the posterior muscle-lineage b astomeres. The significance of the cortical localization of mtlrRNA in muscle precursor cells in ascidian embryos is obscure. However, the results suggest that mtlrRNA is also transferred out of mitochondria in early ascidian embryos and may play some roles in developmental processes.     

The embryonic development of attached and isolated eggs of Carcinus maenas

Eggs of the shore crab, Carcinus maenas, were reared in the laboratory both attached to and in isolation from the female. With continuous agitation the isolated eggs showed better survival and faster embryonic development than attached eggs under comparable conditions. Embryonic development was successful at temperatures from 11 to 25°C. and for attached eggs the development time decreased with temperature according to the equation: D = 20326 (T + 3.3)^?2.09. At all temperatures development was slower than for a comparable study at Plymouth by Wear [8]. Isolated eggs were reared under a wide range of salinities, and appreciable survival beyond the prezoea occurred from 26‰ to 39‰.     

Fliih, a gelsolin-related cytoskeletal regulator essential for early mammalian embryonic development

The Drosophila melanogaster flightless I gene is required for normal cellularization of the syncytial blastoderm. Highly conserved homologues of flightless I are present in Caenorhabditis elegans, mouse, and human. We have disrupted the mouse homologue Fliih by homologous recombination in embryonic stem cells. Heterozygous Fliih mutant mice develop normally, although the level of Fliih protein is reduced. Cultured homozygous Fliih mutant blastocysts hatch, attach, and form an outgrowing trophoblast cell layer, but egg cylinder formation fails and the embryos degenerate. Similarly, Fliih mutant embryos initiate implantation in vivo but then rapidly degenerate. We have constructed a transgenic mouse carrying the complete human FLII gene and shown that the FLII transgene is capable of rescuing the embryonic lethality of the homozygous targeted Fliih mutation. These results confirm the specific inactivation of the Fliih gene and establish that the human FLII gene and its gene product are functional in the mouse. The Fliih mouse mutant phenotype is much more severe than in the case of the related gelsolin family members gelsolin, villin, and CapG, where the homozygous mutant mice are viable and fertile but display alterations in cytoskeletal actin regulation.     

Proteomic profiles of embryonic development in the ascidian Ciona intestinalis

We report here proteomics-based protein profiles of three embryonic stages of the ascidian Ciona intestinalis. Two-dimensional gel electrophoresis revealed 416, 539, and 695 protein spots in the unfertilized eggs, 16 cell-stage embryos, and tadpole larvae, respectively. Comparative and quantitative analyses of the spot patterns identified proteins showing an increase or decrease in amount during embryonic development. Protein identification by MALDI-TOF/MS indicated not only the abundance and importance of metabolic enzymes and translation elongation factors but also the functional importance of actin-binding proteins and molecular chaperones during ascidian development. Global changes in spots for vitellogenin-like protein suggested post-translational modification or proteolytic digestion of this protein during embryogenesis. Comparison between mRNA and protein levels among unfertilized eggs, 16 cell-stage embryos and tadpole larvae indicated nonparallel expression patterns of genes and proteins. Ascidians provide an excellent system for studying gene expression and cell differentiation during development, and the present study should shed light on the associated molecular mechanism at the protein level.     

POU domain transcription factors in embryonic development

Molecular Biology Reports -     

The roles of parathyroid hormone-like hormone during mouse preimplantation embryonic development

Parathyroid hormone-like hormone (PTHLH) was first identified as a parathyroid hormone (PTH)-like factor responsible for humoral hypercalcemia in malignancies in the 1980s. Previous studies demonstrated that PTHLH is expressed in multiple tissues and is an important regulator of cellular and organ growth, development, migration, differentiation, and survival. However, there is a lack of data on the expression and function of PTHLH during preimplantation embryonic development. In this study, we investigated the expression characteristics and functions of PTHLH during mouse preimplantation embryonic development. The results show that Pthlh is expressed in mouse oocytes and preimplantation embryos at all developmental stages, with the highest expression at the MII stage of the oocytes and the lowest expression at the blastocyst stage of the preimplantation embryos. The siRNA-mediated depletion of Pthlh at the MII stage oocytes or the 1-cell stage embryos significantly decreased the blastocyst formation rate, while this effect could be corrected by culturing the Pthlh depleted embryos in the medium containing PTHLH protein. Moreover, expression of the pluripotency-related genes Nanog and Pou5f1 was significantly reduced in Pthlh-depleted embryos at the morula stage. Additionally, histone acetylation patterns were altered by Pthlh depletion. These results suggest that PTHLH plays important roles during mouse preimplantation embryonic development.     

Distribution of ion channels in ascidian eggs and zygotes

Ascidian eggs and zygotes were whole-cell voltage-clamped and inward membrane currents, generated by stepping the membrane potential, studied from fertilization up to cytokinesis. Currents, induced by changing the voltage in steps from -80 to -30 mV, or to 0 mV, had maximum amplitudes which ranged from 400 to 1200 pA in the unfertilized egg and 100 to 1300 pA in the zygote. At 5 to 10 min after fertilization it was not possible to generate inward currents owing to the activity of nonspecific fertilization channels. Preceding cytokinesis, we observed a reduction in amplitude of the inward currents. By cutting eggs and zygotes into fragments, we have shown that the ion channels generating these inward currents are symmetrically distributed over the egg plasma membrane, but regionalized in the zygote with a maximum density at the animal pole.