Spicule Formation-Inducing Substance in Sea Urchin Embryo

Isolated micromeres of sea urchin produced spicules in sea water containing blastocoelic fluid (BCF) taken from embryos, or in a medium in which embryos had previously been dissociated (dissociated solution, DS). When isolated micromeres were cultured in vitro , their descendants initiated spicule formation only when BCF was added to the culture medium by the time when, in normal development, primary mesenchyme cells form two aggregates in the vegetal region. After the initiation of spicule formation, growth of spicules occurred under the continuous influence of DS. Spicule formation-inducing (SFI) activity in DS was first detected at the mesenchme blastula stage. The activity in BCF was heat-labile and was inactivated by trypsin.     

Spicule Formation by Isolated Micromeres of the Sea Urchin Embryo

Micromeres are isolated at the 16-cell stage from three speciesof Japanese sea urchins, Hemicentrotus pulcherrimus, Pseudocentrotusdepressus, and Anthocidaris crassispina, and are cultured insea water containing a small amount of horse serum. In all speciesused, isolated micromeres first divide unequally as they doin vivo. The pattern and number of the subsequent cleavagesare also the same as in vivo, although they are not necessarilyclear in all cases, since the border of the adjacent cells becomeinvisible at each resting stage in some batches of embryos. After cleavage, passing through the stage when the contoursof the individual cell are obscure, decendants of the isolatedmicromeres form cell aggregates similar to the group of primarymesenchyme cells in a blastula. Within such aggregates, a spicularrudiment appears which develops either into a triradiate spiculeas in normal gastrulae or into a rod. The triradiate spiculegrows into a three-dimensional skeleton which is very similarto the normal pluteus skeleton, not only in its final shapeand size including species-specific characters but in its developmentalcourse and crystallographic nature. The rod, on the other hand,develops into either a one-dimensional or two-dimensional skeleton.These skeletons probably correspond to a part of the completeskeleton.     

Establishing Robust Left-Right Asymmetry in the Vertebrate Embryo

Media player

Early Reciprocal Interactions between Ectoderm and Chordamesoderm: Statistical Evaluation of Classical Embryological Experiments

Embryos of the urodele Ambystoma mexicanum were used in time set experiments for the analysis of ectoderm-chrodamesoderm interactions in "primary embryonic induction". The influence of chordamesoderm-age (CM-age), ectoderm-age (CM-age), ectoderm-mass (E-mass) on differentiation processes were investigated. The results revealed that early interactions exist, which, however, seem to be dominated by the ectoderm in various respect: a) the segregations of the CNS is due to the autonomous change in ectoderm competence phases; b) based on the temporal sequence of competence phases, influences are exerted by the ecto-neuroderm which support the chordamesoderm in its self-differentiation capability to chorda and other mesodermal tissues. Consequently, reciprocal impulses from these newly differentiated tissues are warranted (feedback to ectoderm); c) co-ordination of the cranialization effect and corresponding ectodermal competence phase is achieved; d) the inductive efficiency of the chordamesoderm is strongly supported.
Three statistical tests (regression, correlation, information analyses) were conducted (dependant variables: quality and quantity of the differentiated structures; independant variables: experimental factors). All three tests equally rendered statistical significance for the following order of decreasing importance the experimental factors play in induction and differentiation processes: E-age, E-mass, CM-age.     

Effect on Inhibition of Micromere Segregation on the Mitotic Pattern in the Sea Urchin Embryo

Detergent treatment of sea urchin eggs at the mid 4-cell stage results in prevention of micromere segregation at the fourth cleavage. In these embryos not only the formation of the primary mesenchyme is suppressed, but synchrony of cell division, which is the rule during the first four cleavage cycles, continues for several cycles after the 16-cell stage while the typical mitotic phase wave that sets in after micromere segregation is abolished.
These results support the hypothesis that micromeres act as coordinators of the mitotic activity of the embryo.     

Developmental Expression of Echinonectin, an Endogenous Lectin of the Sea Urchin Embryo

Echinonectin (EN) is a galactose-binding lectin present in eggs and embryos of the sea urchin Lytechinus variegatus . Recent studies have suggested that EN is a hyaline layer protein that may function as a substrate adhesion molecule (SAM) during development. We have used monoclonal and affinity-purified polyclonal antibodies that specifically recognize this protein to determine its spatial and temporal expression during embryogenesis. EN is stored in granules or vesicles in the unfertilized egg. After fertilization, these granules are rapidly redistributed to the apical cytoplasm of the zygote. Our results show that at subsequent stages of development the lectin is expressed by cells of all three germ layers, including cells of the developing gut, coelomic pouches, and ectoderm, and by both primary and secondary mesenchyme cells. In contrast to previous observations based solely upon light level immunofluorescent staining, immunoelectron microscopy demonstrates that EN is localized in intracellular, membrane-bounded vesicles. In epithelial cell types these vesicles have a highly polarized distribution and are found in the apical cortical cytoplasm. In mesenchyme cells the distribution of EN-containing vesicles is not obviously polarized. Steady-state levels of EN protein in the embryo remain almost constant from fertilization to the pluteus larva stage, Metabolic labeling studies show that synthesis of EN in L. variegatus begins immediately after fertilization and continues throughout embryogenesis. Monospecific antibodies raised against L. variegatus EN have also been used to determine whether this lectin is expressed in other echinoid species.     

Occurrence of Fibronectin on the Primary Mesenchyme Cell Surface During Migration in the Sea Urchin Embryo

The distribution of fibronectin in situ in the sea urchin embryo was examined by using indirect immunofluorescence with an antibody raised against human plasma fibronectin. Fibronectin was detected on the surfaces of primary mesenchyme cells in the mid-mesenchyme blastula stage, when these cells are migratory. However, it was not detected on these cells at the early mesenchyme blastula or early gastrula stages. Also, it was not detected in the blastocoel nor on the basal surface of the blastular wall. The migration of the primary mesenchyme cells is therefore correlated with a stage-dependent occurrence of cell surface-associated fibronectin.     

Micromere Differentiation in the Sea Urchin Embryo: Two-Dimensional Gel Electrophoretic Analysis of Newly Synthesized Proteins

A method for large-scale culture of isolated blastomeres of sea urchin embryos in spinner flasks was developed. Micromeres and meso-, macromeres isolated from sea urchin embryos at the 16-cell stage were cultured by this method and the patterns of protein synthesis by their descendants were examined by two-dimensional gel electrophoresis of [³⁵S] methionine-labeled proteins. Six distinct proteins with molecular weights of 140–kDa, 105–kDa, 43–kDa, 32–kDa, and 28–kDa (two components) were specifically synthesized by differentiating micromeres. Quantitative analysis of the two-dimensional gel patterns demonstrated that all these proteins, except the 32–kDa protein, appeared at the time of ingression of primary mesenchyme cells (PMC's) in vivo , several hours earlier than the onset of spicule formation. The synthesis of 32–kDa protein was paralleled to active spicule formation and the uptake of Ca²⁺. Cell-free translation products directed by poly (A)⁺ RNAs isolated from descendant cells of micromeres and meso-, macromeres were compared by two-dimensional gel electrophoresis. Several spots specific to the micromere lineage were detected. However, none of them comigrated with the proteins synthesized specifically by the cultured micromeres. The results suggest that the expression of these proteins specific to differentiating micromeres may involve post-translational modification.     

1-Methyl-4-thiohistidine and Glutathione in the Developing Embryo of the Sea Urchin, Paracentrotus lividus.

4-thiohistidines occur as free amino acids in the eggs of several marine organisms, in particulary relevant concentrations in the eggs of echinoderms. Since nothing is known about their biological role or biosynthesis and metabolic fate, we measured the concentration of 1-methyl-4-thiohistidine together with the two most common small molecular weight thiols, glutathione and cysteine, during embryonic development of the sea urchin Paracentrotus lividus until the pluteus stage. The thiols were determined by high performance liquid chromatography as fluorescent derivatives of monobromobimanes. 1-methyl-4-thiohistidine and glutathione are present until the pluteus stage with an approximate ratio of 2: 1. Cysteine was detected at the blastula stage and found to increase thereafter. 1-methyl-4-thiohistidine was absent, or present in traces, in sperm and in somatic tissues of adults. It is concluded that 1-methyl-4-thiohistidine is typical of eggs and embryos and may be metabolized during metamorphosis into an as yet unknown compound.     

Micromere Differentiation in the Sea Urchin Embryo: Expression of Primary Mesenchyme Cell Specific Antigen during Development

The temporal and spatial expression of antigen specific for primary mesenchyme cell (PMC) lineage cells during early development of the sea urchins Hemicentrotus pulcherrimus and Stronglyocentrotus nudus was studied with a monoclonal antibody (P4). P4 was produced by a hybridoma cell line prepared by fusion of myeloma cells and spleen cells from a mouse immunized with cultured spicule-forming cells. Immunofluorescence studies demonstrated that P4 antibody reacted strongly with the surfaces of PMC's and spicule-forming cells of both species. Immunoblot analysis showed that P4 antibody reacted with several proteins including those of 140–kDa, 120–kDa, 53-kDa, 43–kDa, and 41–kDa in H. pulcherrimus and with those of 130–kDa, 110–kDa, 51–kDa, and 43–kDa in S. nudus . These proteins appeared sequentially after the hatching blastula stage. Tunicamycin inhibited the expressions of these P4 antigens as well as spicule formation. Two of the P4-reactive antigens, the 140–kDa and 43–kDa proteins, in H. pulcherrimus were synthesized de novo and shown to be identical to micromere differentiation specific proteins. These results suggest that P4 binds to specific molecules that are important in spicule formation in developing sea urchin embryos.     

The Discovery of a Reciprocal Relationship between Tyrosine-Kinase Signaling and Cullin Neddylation

While neddylation is known to activate cullin (CUL)-RING ubiquitin ligases (CRLs), its role in regulating T cell signaling is poorly understood. Using the investigational NEDD8 activating enzyme (NAE) inhibitor, MLN4924, we found that neddylation negatively regulates T cell receptor (TCR) signaling, as its inhibition increases IL-2 production, T cell proliferation and Treg development in vitro. We also discovered that loss of CUL neddylation occurs upon TCR signaling, and CRLs negatively regulate IL-2 production. Additionally, we found that tyrosine kinase signaling leads to CUL deneddylation in multiple cell types. These studies indicate that CUL neddylation is a global regulatory mechanism for tyrosine kinase signaling.     

Reconstitution of Embryo-Like Structures from Sea Urchin Embryo Cells: Distinction Between Cell-Cell and Cell-Substrate Associations

Sea urchin embryos can be dissociated into a suspension of single cells that reconstitute embryo-like structures. When reconstitution is conducted in stationary cultures the first step is attachment of the cells to the culture plate, which requires calcium and metabolic energy but not protein synthesis. We have found that protease treated cells form cell-cell associations in stationary cultures without attaching to the culture plates, and that cell-plate attachments are unaffected by inhibition of protein synthesis. These data suggest that cell surface proteins are needed for cell-plate attachment and that these proteins are present on freshly dissociated cells. We also demonstrated that butanol extracted cells attach to the plates, but do not form functional cell-cell associations unless the butanol extracted material is restored to them. We conclude that sea urchin embryo cells contain two classes of attachment components. The first class functions in the cell-plate attachments, is protease sensitive, and not extracted by butanol; the second class is necessary for cell-cell associations, is protease insensitive, and extracted by butanol. Since protease treated cells reconstitute embryo-like structures without attaching to the culture plates, only the second class of attachment components is necessary for embryo reconstitution.