Effects of inhibitors of the synthesis of catecholamines and spiperone on sea urchin and murine embryos

We studied the effects of three inhibitors of catecholamine synthesis on the development of sea urchinsSphaerechinus granularis andParacentrotus lividus. These drugs affected the early embryogenesis, which was expressed in inhibition of the cleavage divisions, appearance of abnormal embryos, and developmental arrest. The addition of arachidonic acid amide and dopamine to the incubation medium weakened the effects of the inhibitors. Spiperone induced developmental defects in preimplantation mouse embryos and sea urchin embryos. Arachidonic acid amide with dopamine exerted a protective effect against spiperone when introduced to sea urchin embryos at the blastula or late gastrula stages, rather than after fertilization. In murine embryos, this amide induced developmental defects and arrest itself, and its effect was reversible. Possible mechanisms underlying the effects of these drugs are discussed.     

Dermatan sulfate formation in gastrulae of the sea urchin Clypeaster japonicus

Gastrullation of sea urchin embryos is arrested in sulfate-free sea water. This developmental arrest has been considered to be due to lack of sulfation of glycosaminoglycans in the extracellular matrix of the embryos. In the present study, we characterized a dermatan sulfate type component formed in gastrula-stage embryos of the sea urchin Clypeaster japonicus and examined the effects of sulfate deprivation on the formation. Glycosamino-glycans were prepared from gastrula-stage embryos incubated with [3H]acetate in normal and sulfate-free sea water. Enzymatic analyses indicated that embryos formed a glycosaminoglycan of the dermatan sulfate type which contained an N-acetylgalactosamine-6-sulfate-containing disaccharide as a major unit, plus a minor unidentified component. Under sulfate-free conditions, embryos formed an under-sulfated chondroitin/dermatan sulfate copolymer which mainly consisted of non-sulfate, glucuronic acid-containing (chondroitin) disaccharide units. These results suggest that sulfate deprivation diminishes not only the degree of sulfation but also the formation of L-iduronic acid-containing (dermatan) disaccharide units in dermatan sulfate in sea urchin embryos.     

HSP90 function is required for morphogenesis in ascidian and echinoid embryos

Treatment of embryos of the ascidians Boltenia villosa and Cnemidocarpa finmarkiensis and the sea urchin Strongylocentrotus purpuratus with the anti-HSP90 drugs geldanamycin and radicicol caused morphogenetic arrest. All embryonic stages during which obvious morphogenesis was observed were sensitive to treatment, including formation of the sea urchin blastular epithelium. Arrested embryos were viable for many hours to days post-treatment, indicating a low general toxicity of these drugs. Morphogenetic movements including gastrulation and migration (but not ingression) of sea urchin primary and secondary mesenchyme cells were arrested 8-10 h after treatment began. Cell division and developmentally regulated expression of some genes continued after morphogenesis was arrested. Anti-HSP90 drugs cause selective inactivation or degradation of proteins with which the protein chaperone HSP90 interacts. Therefore, morphogenetic arrest subsequent to the disruption of HSP90 function may result from the reduction in concentration, or activity, of client proteins required for morphogenetic movements of cells. The use of these drugs may provide a means to identify novel activities or proteins involved in morphogenesis.     

Effects of retinoic acid and dimethylsulfoxide on the morphogenesis of the sea urchin embryo

Sea urchin embryos of the species Paracentrotus lividus were treated continuously with different concentrations of all-trans retinoic acid (RA) or dimethylsulfoxide (DMSO) at different developmental stages. A delay in embryonic development was observed when embryos were cultured in the presence of 2x10^?5 M RA, between 1 and 12 hours of development. Hence, at 48 hours of development, while control embryos had reached the pluteus stage, RA-treated embryos were at the prism stage. At 72 hours of development RA-treated embryos recovered and continued normal development reaching the pluteus stage. No effect was observed when treatment was performed before 1 hour or after 12 hours of developmet. DMSO treatment had no effect on normal sea urchin embryo development, although we observed that pigment cells, clearly visible at the pluteus stage, become visible earlier with respect to control embryos. This report confirms the advantages that the sea urchin embryo offers for the study of problems in cellular and developmental biology.     

First cell cycles of sea urchin Paracentrotus lividus are dramatically impaired by exposure to extremely low-frequency electromagnetic field

Exposure of fertilized eggs of the sea urchin Paracentrotus lividus to an electromagnetic field of 75-Hz frequency and low amplitudes (from 0.75 to 2.20 mT of magnetic component) leads to a dramatic loss of synchronization of the first cell cycle, with formation of anomalous embryos linked to irregular separation of chromatids during the mitotic events. Because acetylcholinesterase (ACHE) is thought to regulate the embryonic first developmental events of the sea urchin, its enzymatic activity was assayed in embryo homogenates and decreased by 48% when the homogenates were exposed to the same pulsed field. This enzymatic inactivation had a threshold of about 0.75 +/- 0.01 mT. The same field threshold was found for the effect on the formation of anomalous embryos of P. lividus. Moreover, ACHE inhibitors seem to induce the same teratological effects as those caused by the field, while blockers of acetylcholine (ACh) receptors are able to antagonize those effects. We conclude that one of the main causes of these dramatic effects on the early development of the sea urchin by field exposure could be the accumulation of ACh due to ACHE inactivation. The crucial role of the membrane in determining the conditions for enzyme inactivation is discussed.     

The role of lysyl oxidase and collagen crosslinking during sea urchin development

Lysyl oxidase, the only enzyme involved in collagen crosslinking, is shown to be present in embryos of the sea urchin Strongylocentrotus purpuratus. The enzyme specific activity increases over six-fold during development, showing the greatest rise during gastrulation and prism larva formation. The enzyme is inhibited by the specific inhibitor, beta-aminoproprionitrile (BAPN). Continuous BAPN treatment of S. purpuratus and Lytechinus pictus embryos from late cleavage stages onward increases the amount of noncrosslinked collagen present in prism larvae. When BAPN is added at the 128- or 256-cell stage it causes developmental arrest at the mesenchyme blastula stage. Embryos can be maintained in the arrested state for at least 96 h and will resume normal development and morphogenesis following BAPN removal. If BAPN is added after the mesenchyme blastula stage, it has little adverse effect on development; consequently nonspecific toxic effects of the drug are unlikely. The results suggest that lysyl oxidase and collagen crosslinking play a vital role in primary mesenchyme migration, gastrulation, and morphogenesis during sea urchin development and indicate that BAPN may be very useful in studying the extracellular matrix-cell interactions at the cellular and molecular level.     

Inhibition of mitogen activated protein kinase signaling affects gastrulation and spiculogenesis in the sea urchin embryo

The mitogen activated protein (MAP) kinase signaling cascade has been implicated in a wide variety of events during early embryonic development. We investigated the profile of MAP kinase activity during early development in the sea urchin, Strongylocentrotus purpuratus, and tested if disruption of the MAP kinase signaling cascade has any effect on developmental events. MAP kinase undergoes a rapid, transient activation at the early blastula stage. After returning to basal levels, the activity again peaks at early gastrula stage and remains high through the pluteus stage. Immunostaining of early blastula stage embryos using antibodies revealed that a small subset of cells forming a ring at the vegetal plate exhibited active MAP kinase. In gastrula stage embryos, no specific subset of cells expressed enhanced levels of active enzyme. If the signaling cascade was inhibited at any time between the one cell and early blastula stage, gastrulation was delayed, and a significant percentage of embryos underwent exogastrulation. In embryos treated with MAP kinase signaling inhibitors after the blastula stage, gastrulation was normal but spiculogenesis was affected. The data suggest that MAP kinase signaling plays a role in gastrulation and spiculogenesis in sea urchin embryos.     

Mechanism for electrosilent Ca2+ transport to cause calcification of spicules in sea urchin embryos

Embryos of the sea urchin, Hemicentrotus pulcherrimus, kept in sea water containing the calcium antagonists, diltiazem and verapamil, or an anion transport inhibitor, 4,4'-diisothiocyano-2,2'-disulfonic acid stilbene (DIDS), during a developmental period between the mesenchyme blastula and the pluteus corresponding stage, became abnormal plutei with poorly developed arms and quite small spicules. Treatment with ethacrynic acid and furosemide, inhibitors of chloride transport, during the same period of development yielded quasi-normal plutei with poor spicules and somewhat developed arms. In late gastrulae, the inhibitory effects of these calcium antagonists and DIDS on the uptake of 45Ca2+ in whole embryos were as strong as those on 45Ca deposition in spicules, whereas the effects of chloride transport inhibitors on calcium deposition in the spicules were markedly stronger than on its uptake in whole embryos. Electrosilent uptake of Ca2+ seems to be established mainly by coupled influx of chloride in the cells which mediate spicule calcification, and by concomitant influx of anions in the other cells. In swimming blastulae, 45Ca2+ uptake was inhibited by calcium antagonists and DIDS, but not by chloride transport inhibitors. Ca2+ uptake probably becomes coupled with chloride influx only in embryos in which spicule calcification occurs.     

Inhibition by aphidicolin of cell cycle progression and DNA replication in sea urchin embryos.

We have recently found that aphidicolin, a tetracyclic diterpene-tetraol produced by several fungi, blocks DNA synthesis of sea urchin embryos by interfering with the activity of DNA polyermase alpha. These cells fail to proliferate in the presence of aphidicolin. In continuation of these studies, we determined the drug-sensitive stage in the first cell cycle of the sea urchin Clypeaster japonicus embryo. In continuous exposure to aphidicolin (2 micrograms/ml) from five minutes after fertilization, mitotic division of the embryo was completely suppressed. Embryos were exposed to the drug at progressively later intervals and their capability for cytokinesis was examined. Evidence was thereby obtained that aphidicolin acts at the S-period to inhibit DNA synthesis resulting in developmental arrest of the embryo.     

Apoptosis: focus on sea urchin development

It has been proposed that the apoptosis is an essential requirement for the evolution of all animals, in fact the apoptotic program is highly conserved from nematodes to mammals. Throughout development, apoptosis is employed by multicellular organisms to eliminate damaged or unnecessary cells. Here, we will discuss both developmental programmed cell death (PCD) under normal conditions and stress induced apoptosis, in sea urchin embryos. Sea urchin represent an excellent model system for studying embryogenesis and cellular processes involved in metamorphosis. PCD plays an essential role in sculpting and remodelling the embryos and larvae undergoing metamorphosis. Moreover, this marine organism directly interacts with its environment, and is susceptible to effects of several aquatic contaminants. Apoptosis can be adopted as a defence mechanism against any environmental chemical, physical and mechanical stress, for removing irreversibly damaged cells. This review, while not comprehensive in its reporting, aims to provide an overview of current knowledge on mechanisms to regulate physiological and the induced apoptotic program in sea urchin embryos.     

Effect of calcium ionophore A23187 on the sensitivity of early sea urchin embryos to cytotoxic neuropharmacological drugs

The ability of cytotoxic neurochemicals (indole and amphetamine derivatives) to block first cleavage division in the embryos of the sea urchin Arbacia lixula abruptly increases when the embryos are incubated in calcium-free seawater and decreases when the external Ca concentration is raised up to 46.4 mM. Sensitivity of the embryos to these drugs decreases also in the presence of the Ca-ionophore A23187. It is suggested that Ca ions are involved in the realization of physiological effects of "prenervous" neurotransmitters whose presence in early sea urchin embryos was shown by us earlier.     

Sea urchin embryo as a model organism for the rapid functional screening of tubulin modulators

Identification of antimitotic molecules that affect tubulin dynamics is a multistep procedure. It includes in vitro tubulin polymerization assay, studies of a cell cycle effect, and general cytotoxicity assessment. To simplify this lengthy screening protocol, we have introduced and validated an assay system based on the sea urchin embryos. The proposed two-step procedure involves the fertilized egg test for mitotic arrest and the behavioral assessment of a free-swimming blastula. In order to validate the assay, we have analyzed the effect of a panel of known antiproliferative agents on the sea urchin embryo. For all tubulin destabilizing drugs, we observed rapid spinning and lack of forward movement of an embryo. Both effects are likely to result from the in vivo microtubule disassembly caused by test molecules. Notably, the described assay yields rapid information on antiproliferative, antimitotic, cytotoxic, and tubulin destabilizing activities of the molecules along with their solubility and permeability potential. Moreover, measured potencies of the test articles correlated well with the reported values in both in vitro and cell based assays.     

Vegetalization Induced by Procaine and Tetracaine in Sea Urchin Embryos

Vegetalization of sea urchin embryos was induced by the treatment with procaine and tetracaine, inhibitors of Ca²⁺mobilization, for 3 hr starting 3–5 hr after insemination at 20°C. The treatment starting 7 hr after insemination sometimes produced similar type of vegetalized embryos. The pulse treatment starting at the other stages hardly yielded vegetalized embryos. The stages at which these compounds were effective to produce vegetalized embryos were almost the same to those for Li⁺to make embryos vegetalized. On the basis of known inhibitory effects of tetracaine, procaine and Li⁺on Ca²⁺mobilization, we postulate that Ca²⁺dependent reactions participate in the process of cell determination at these stages. Inhibitory effects of procaine, tetracaine and Li⁺on Ca²⁺dependent induction of fertilization membrane formation, found in the present study, indicate that these compounds block Ca²⁺mobilization in sea urchin eggs.     

The effects of aphidicolin on morphogenesis and differentiation in the sea urchin embryo

Aphidicolin, an inhibitor of DNA polymerase alpha, blocks DNA synthesis and cell division in sea urchin embryos. The effects of this inhibition appear to be stage dependent. Blastulae treated with aphidicolin before the thickening of the vegetal plate undergo developmental arrest prior to gastrulation. The extent of inhibition of DNA synthesis varies from 60 to 93% in these embryos. However, when aphidicolin is added after the vegetal plate has thickened, development continues normally through pluteus formation, even though DNA synthesis is inhibited by greater than or equal to 90% and cell division has ceased. These observations indicate that, from the vegetal plate stage onward, morphogenesis and overt differentiation are independent of DNA synthesis and cell division.     

Cost of protein synthesis and energy allocation during development of antarctic sea urchin embryos and larvae

Cold environments represent a substantial volume of the biosphere. To study developmental physiology in subzero seawater temperatures typically found in the Southern Ocean, rates and costs of protein synthesis were measured in embryos and larvae of Sterechinus neumayeri, the Antarctic sea urchin. Our analysis of the "cost of living" in extreme cold for this species shows (1) that cost of protein synthesis is strikingly low during development, at 0.41 +/- 0.05 J (mg protein synthesized)(-1) (n = 16); (2) that synthesis cost is fixed and independent of synthesis rate; and (3) that a low synthesis cost permits high rates of protein turnover at -1 degrees C, at rates comparable to those of temperate species of sea urchin embryos developing at 15 degrees C. With a low synthesis cost, even at the highest synthesis rates measured (gastrulae), the proportion of total metabolism accounted for by protein synthesis in the Antarctic sea urchin was 54%-a value similar to that of temperate sea urchin embryos. In the Antarctic sea urchin, up to 87% of metabolic rate can be accounted for by the combined energy costs of protein synthesis and the sodium pump. We conclude that, in Antarctic sea urchin embryos, high rates of protein synthesis can be supported in extreme-cold environments while still maintaining low rates of respiration.     

Polyenic acid 5-hydroxytryptamides and 3-hydroxytyramides as tools for studying of the pre-nervous biogenic monoamine functions

Three main effects of the amides on embryos of opistobranch molluscs, sea urchins and starfish, were revealed. First, a rather independent and clear protective action of 5-HYDROXYTRYPTAMIDES AND 3-HYDROXYTYRAMIDES against cytostatic antagonists of serotonin and dopamine, resp. Second, prevention of developmental abnormalities induced by protein kinase C activators both by hydroxytryptamides and hydroxytyramides. Third, the cytostatic effect of 3-HYDROXYTRIPTAMIDES eliminated or prevented by 5-HYDROXYTRYPTAMIDES. These effects quantitatively depended on the structure of their fatty acids part. Some functionally active regulatory substances similar to 5-HYDROXYTRYPTAMIDES AND 3-HYDROXYTYRAMIDES may exist in the early embryos.     

Effect of antimediator preparations on the intercellular relations in early embryos of the sea urchin]

The dated treatment of the early embryos of an irregular (flat) sea urchin Scaphechinus mirabilis by neuropharmacological drugs (anti-neurotransmitters) during one of the first four cleavage divisions results in the impairment of intercellular connections and leads to the formation of twin embryos, dwarf embryos, embryos of the dumb-bell shape etc. In the experiments with some of the drugs under study such developmental abnormalities were not seen or were expressed much more weakly when serotonin or bufotenin (N,N-dimethylserotonin) were added to the medium. A suggestion is put forward that the early embryos possess an intracellular mechanism participating in the interaction between the cells and operating via endogenous monoamines, primarily serotonin.     

Survivorship, development, and DNA damage in echinoderm embryos and larvae exposed to ultraviolet radiation (290-400 nm)

Laboratory experiments utilizing ecologically relevant irradiances of ultraviolet radiation (UVR) known to occur in shallow Gulf of Maine waters were conducted on the planktonic embryos and larvae of two common benthic echinoids; the green sea urchin Strongylocentrotus droebachiensis and the sand dollar Echinarachnius parma. Significant decreases in survivorship were observed in freshly fertilized embryos of both species with greater mortality in E. parma that was associated with the absence of UVR-absorbing compounds, the mycosporine-like amino acids. Experiments on blastula, gastrula, and prism larval stages of S. droebachiensis also showed significant decreases in survivorship, delays in development, and abnormal embryos and larvae associated with exposure to UVR. Additionally, all developmental stages of S. droebachiensis experimentally exposed to UVR resulted in significant increases in DNA damage, measured as cyclobutane pyrimidine dimer photoproducts. The observed delays in early cleavage and subsequent developmental stages for S. droebachiensis are correlated with DNA damage. It is postulated that cell cycle arrest at critical checkpoints after DNA damage, mediated by a suite of cell cycle genes, is a component of the observed UVR induced developmental delays.     

Effects of 5 azacytidine on DNA methylation and early development of sea urchins and ascidia

5-azacytidine (5-azaCR), an analogue of cytidine, inhibits nuclear DNA methylation in early sea urchin embryos. This inhibition is specific and dose-dependent. Exposure of sea urchin embryos at any stage between one-cell and blastula, to micromolar quantities of 5-azaCR invariably inhibits development beyond the blastula stage. In a substantial number of embryos arrested at the blastula stage, spicule formation proceeds although other morphological differentiation is lacking. No significant effect on development is seen if sea urchin embryos are exposed to 5-azaCR at post-blastula stages. 5-azaCR also inhibits the development of a mosaic egg such as the ascidian Phallusia mammilata at the blastula stage, indicating that both regulative (sea urchin) and mosaic (ascidian) embryos respond more or less similarly to 5-azaCR treatment.     

A Century of Sea Urchin Development

SYNOPSIS. In the last quarter of the nineteenth century severalinvestigators including Richard and Oskar Hertwig, Theodor Boveri,Hans Driesch, Curt Herbst, T. H. Morgan and others turned theirattention to sea urchin eggs and early embryos. This favorablecombination of outstanding investigators and the sea urchinembryo as an experimental organism contributed to a fundamentalunderstanding of the cell, fertilization and heredity. The advantagesof the sea urchin continued to be recognized as experimentalembryologists used these embryos to develop the concepts ofgradients, regulative development and inductive interactions.Then, as developmental biology arose from chemical embryology,the sea urchin embryo once again emerged as an ideal experimentalanimal, pivotal in the understanding of the molecular and developmentalbiology of eukaryotic organisms.