Cell lineage-specific inhibition of cytokinesis by concanavalin A in a molluscan embryo (Nassarius reticulatus,Gastropoda)

Summary The effects of the lectin concanavalin A (Con A) on cleavage were studied in early embryos of the gastropodNassarius reticulatus. Progression of the first cleavage furrow is inhibited by incubating eggs before the first cleavage with 0.3–20 μg/ml Con A. Treatment with 1.0–20 μg/ml Con A during first cleavage causes regression of the cleavage furrow. Treatment with low concentrations (0.3–1.0 μg/ml) during the same period does not affect first cleavage. However, when further development of such eggs is followed, one finds that second cleavage is inhibited typically in only one of the two blastomeres of the 2-cell stage, i.e. the CD-blastomere. As a result, a 3-cell embryo is formed. At third cleavage of such embryos, the CD-blastomere forms either one double-sized micromere (1cd-micromere) or two normal-sized micromeres (1c and 1d) simultaneously. Sometimes micromere formation in the CD-blastomere is inhibited. Con A binding does not affect karyokinesis, nor does it affect the division asynchronies typical for normal development. On the basis of these and other results it is argued that binding of Con A to sites located at the vegetal pole of the egg is responsible for the cell lineage-specific inhibition of cleavage by Con A. This effect is most probably mediated by changes in the organization of the egg cortex.     

Monensin interferes with the determination of the mesodermal cell line in embryos of Patella vulgata

Summary In embryos of the equally cleaving marine gastropod Patella vulgata, the mesodermal stem cell is determined during the interval between the fifth and sixth cleavage by means of cellular interactions between one of the four vegetally located macromeres with the overlying animal micromeres. Shortly before and during this interaction phase an extracellular matrix (ECM) is present between the interacting cells. In this study the glycosylation-perturbing ionophore monensin was used to investigate the possible morphogenetic significance of the ECM. Incubation of 32-cell-stage Patella embryos in 10^–6 M monensin results in radialized embryos in which none of the four macromeres interacts with the overlying animal micromeres. None of the macromeres is determined, therefore, to form mesoderm in such embryos. Trochophore larvae reared from these embryos retain their radial symmetry, as is indicated by the presence of four shell glands and four blastopore- or stomodeum-like invaginations in these larvae. The monensin-treated embryos probably secrete abnormal ECM that does not provide the proper conditions for the blastomeres to stretch and interact with the micromeres. Changes in intracellular ionic concentrations may also be involved.     

Regulation of stage-specific gene expression during early mouse development: effect of cytochalasin B and aphidicolin on stage-specific protein synthesis in mouse eggs

Mechanisms regulating stage-specific translation in mouse embryos were studied by inhibitor experiments. When fertilized eggs were continuously treated with cytochalasin B, cleavage was prevented, whereas karyokinesis proceeded, resulting in protein synthesis patterns changing stage-specifically as in control embryos through preimplantation development. When fertilized eggs were continuously exposed to aphidicolin, cleavage and DNA synthesis were inhibited, thus keeping their protein synthesis at the level of fertilized eggs with few new polypeptides appearing after one day. The next day these eggs stopped translation almost completely. Stage-specific translation therefore might be controlled by nuclear replications rather than by cytoplasmic clock.     

Variation of cleavage pattern permitting normal development in a sand dollar,Peronella japonica: comparison with other sand dollars

 Peronella japonica, a sand dollar, forms an abbreviated pluteus larva and metamorphoses within 3 days without feeding. In the present study, the cleavage pattern of Peronella embryos was found to be quite irregular in the vegetal blastomeres at the fourth cleavage. Less than half of the embryos examined formed four typical micromeres. The majority formed zero, one, two or three typical micromeres of regular size, and the blastomere(s) remaining in the vegetal-most region was atypical in size and/or its direction of division. Most embryos were able to form pluteus larvae and a considerable proportion of these metamorphosed into juvenile sea urchins, regardless of whether or not they had formed four typical micromeres of regular size, although embryos which formed no typical micromeres developed into pluteus larvae less frequently. The micromere progeny in Peronella embryos form skeletogenic mesenchyme cells. The average numbers of skeletogenic mesenchyme cells in the three sand dollar species, Clypeaster japonicus, Astriclypeus manni and P. japonica were 62, 122 and 219, respectively. In these species, the skeletogenic mesenchyme cell-specific glycoprotein (msp130) was first detected immediately after ingression of the primary mesenchyme cells, spicules appeared at the early gastrula stage and triradiate spicules were found in late gastrulae. Appearance of these characteristics was markedly accelerated in the embryos of A. manni and P. japonica in comparison with those of C. japonicus. Each step in the formation of larval spicules was equally accelerated in A. manni and P. japonica, although the appearance of the adult skeleton was further accelerated in P. japonica in comparison with A. manni, possibly because of omission of the four- to eight-armed pluteus stages. Received: 1 September 1995 / Accepted in revised form: 21 May 1995     

Evolutionary modification of specification for the endomesoderm in the direct developing echinoid <Emphasis Type="Italic">Peronella japonica</Emphasis>: loss of the endomesoderm-inducing signal originating from micromeres

We investigated the inductive signals originating from the vegetal blastomeres of embryos of the sand dollar Peronella japonica, which is the only direct developing echinoid species that forms micromeres. To investigate the inductive signals, three different kinds of experimental embryos were produced: micromere-less embryos, in which all micromeres were removed at the 16-cell stage; chimeric embryos produced by an animal cap (eight mesomeres) recombined with a micromere quartet isolated from a 16-cell stage embryo; and chimeric embryos produced by an animal cap recombined with a macromere-derived layer, the veg1 or veg2 layer, isolated from a 64-cell stage embryo. Novel findings obtained from this study of the development of these embryos are as follows. Micromeres lack signals for endomesoderm specification, but are the origin of a signal establishing the oral–aboral (O–Ab) axis. Some non-micromere blastomeres, as well as micromeres, have the potential to form larval skeletons. Macromere descendants have endomesoderm-inducing potential. Based on these results, we propose the following scenario for the first step in the evolution of direct development in echinoids: micromeres lost the ability to send a signal endomesoderm induction so that the archenteron was formed autonomously by macromere descendants. The micromeres retained the ability to form larval spicules and to establish the O–Ab axis.     

The ‘organizing’ role of the D quadrant in an equal-cleaving spiralian,Lymnaea stagnalis as studied by UV laser deletion of macromeres at intervals between third and fourth quartet formation

Summary

In the spiralian embryos studied which display unequal-cleavage at the first two cleavages (either by a polar lobe or an asymmetric cleavage mechanism) the D quadrant is determined at the four cell stage by an unequal segregation of cytoplasmic stuffs. The normal formation of eyes, foot, and shell by overlying micromeres in these forms requires the inductive interaction with the D quadrant before the formation of the third quartet of micromeres. In equal-cleaving spiralians the D quadrant (3D macromere) becomes determined as a result of inductive interactions with first quartet derivatives (animal-vegetal interaction) sometime after the production of the third quartet of micromeres. This paper investigates the exact timing of D quadrant determination and the inductive role of third-order macromeres on the development of micromere derived structures in an equal-cleaving spiralian. Deletions of third-order macromeres, and their derivatives, were performed without rupturing the egg capsule membrane of the Lymnaea embryo with a UV laser microbeam. Virtually normal snails were produced when the 3A, 3B, 3C, or 4D macromere was irradiated. Juvenile snails lacking all mesodermal structures but possessing eyes, foot, and shell were obtained when the mesentoblast (4d) or its progenitor (3D) were deleted. Furthermore, ‘mesoderm-less’ snails were produced by deleting one of the two possible 3D candidates (cross furrow macromeres) as early as 20 min after third quartet formation. These results indicate that the 3D macromere begins to become determined at, or soon after, animal-vegetal interaction; before the 3D macromere becomes visibly distinguishable from the 3B macromere. The results also demonstrate that normal pattern formation in the overlying micromeres does not require the ‘prolonged’ interaction with an asymmetrically positioned 3D macromere. Possible adhesive differences between the 3D macromere and the remaining three macromeres are also revealed.     

A Stereometric Analysis of Karyokinesis, Cytokinesis and Cell Arrangements during and following Fourth Cleavage Period in the Sea Urchin, Lytechinus variegatus

Fourth cleavage of the sea urchin embryo produces 16 blastomeres that are the starting point for analyses of cell lineages and bilateral symmetry. We used optical sectioning, scanning electron microscopy and analytical 3-D reconstructions to obtain stereo images of patterns of karyokinesis and cell arrangements between 4th and 6th cleavage. At 4th cleavage, 8 mesomeres result from a variant, oblique cleavage of the animal quartet with the mesomeres arranged in a staggered, offset pattern and not a planar ring. This oblique, non-radial cleavage pattern and polygonal packing of cells persists in the animal hemisphere throughout the cleavage period. Contrarily, at 4th cleavage, the 4 vegetal quartet nuclei migrate toward the vegetal pole during interphase; mitosis and cytokinesis are latitudinal and subequatorial. The 4 macromeres and 4 micromeres form before the animal quartet divides to produce a 12-cell stage. Subsequently, macromeres and their derivatives divide synchronously and radially through 8th cleavage according to the Sachs-Hertwig rule. At 5th cleavage, mesomeres and macromeres divide first; then the micromeres divide latitudinally and unequally to form the small and large micromeres. This temporal sequence produces 28-and 32-cell stages. At 6th cleavage, macromere and mesomere descendants divide synchronously before the 4 large micromeres divide parasynchronously to produce 56- and 60-cell stages.     

Inhibition of spicule elongation in sea urchin embryos by the acetylcholinesterase inhibitor eserine

The activity of acetylcholinesterase (AchE) increases rapidly after the gastrula stage of sea urchin development. In this report, changes in activity and in the molecular differentiation of AchE were investigated. AchE activity increased slightly during gastrulation and rose sharply thereafter, and was dependent on new RNA synthesis. No activity of butyrylcholinesterase was found. Morphogenesis in sea urchin embryos was inhibited by the AchE inhibitor eserine, which specifically inhibited arm rod formation but not body rod formation. Spicule formation and enzyme activity in cultured micromeres were inhibited by eserine in a dose-dependent manner. During gastrulation, two molecular forms of AchE were detected with polyacrylamide gel electrophoresis. The appearance of an additional band on the gel was consistent with the occurrence of a remarkable increase in the enzyme activity. This additional band appeared as a larger molecular form in Anthocidaris crassispina, Hemicentrotus pulcherrimus, Stomopneustes variolaris, and Strongylocentrotus nudus, and as a smaller form in Clypeaster japonicus and Temnopleurus hardwicki. These results suggest that the change in the molecular form of AchE induced a change in enzymatic activity that in turn may play a role in spicule elongation in sea urchin embryos.     

Wheat germ agglutinin binding to the micromeres and primary mesenchyme cells of sea urchin embryos

Fluorescein isothiocyanate-conjugated wheat germ agglutinin (WGA-FITC) binds exclusively to the primary mesenchyme cells when the lectin is microinjected into the blastocoels of living Lytechinus pictus and Strongylocentrotus droebachiensis embryos. WGA-FITC binding increases throughout the period of primary mesenchyme cell migration and aggregation. Similar binding is observed in embryos cultured in sulfate-free seawater (SFSW) but not in seawater (ASW) containing tunicamycin. The temporal expression of WGA-FITC binding sites in vivo is also correlated with the pattern of binding observed in vitro. Sixteen-cell stage Arbacia punctulata embryos were dissociated in Ca²⁺ and Mg²⁺-free seawater (CMFSW) and the micromeres isolated using sucrose gradients. Arbacia micromeres, cultured in ASW containing calf serum, first bind WGA-FITC during the period when primary mesenchyme cell ingression occurs in control embryos. Micromeres cultured in the presence of tunicamycin do not develop WGA binding sites. The temporal expression of WGA-FITC binding in micromere cultures is unaffected by the absence of sulfate, but the size and morphology of aggregates cultured in SFSW differ from that of the controls.     

A mathematical investigation of a Clock and Wavefront model for somitogenesis

Somites are transient blocks of cells that form sequentially along the antero-posterior axis of vertebrate embryos. They give rise to the vertebrae, ribs and other associated features of the trunk. In this work we develop and analyse a mathematical formulation of a version of the Clock and Wavefront model for somite formation, where the clock controls when the boundaries of the somites form and the wavefront determines where they form. Our analysis indicates that this interaction between a segmentation clock and a wavefront can explain the periodic pattern of somites observed in normal embryos. We can also show that a simplification of the model provides a mechanism for predicting the anomalies resulting from perturbation of the wavefront.     

Cleavage in<Emphasis Type="Italic"> Nemertoderma westbladi</Emphasis> (Nemertodermatida) and its phylogenetic significance

Recent phylogenetic analyses of ribosomal and protein coding nuclear genes place the marine worms within the Nemertodermatida as one of the oldest lineages among the bilaterian animals. We studied the early embryonic cleavage in Nemertoderma westbladi to provide the first account of nemertodermatid early development. Live embryos were studied with interference microscopy and fixed embryos were either sectioned or studied with confocal laser scanning microscopy. Initially the divisions in the embryo are radial, but then micromeres are shifted clockwise generating a spiral pattern. The four-cell stage is characterized by duets of macromeres and micromeres and thus resembles the duet cleavage reported from members of the Acoela. However, subsequent stages differ from the acoel duet pattern and also from quartet spiral cleavage. The optimization of the cleavage pattern on current phylogenetic hypotheses with Nemertodermatida and Acoela as early bilaterian branches is discussed.     

Carbonic anhydrase activity in developing sea urchin embryos with special reference to calcification of spicules

Eggs and embryos of the sea urchins Anthocidaris crassispina and Hemicentrotus pulcherrimus did not exhibit significant changes in carbonic anhydrase activity during early development. Acetazolamide inhibited enzyme activity in homogenates of embryos and inhibited the formation of calcified spicules in a culture of micromeres at concentrations between 40 and 100 μM. Acetazolamide allowed intact embryos to develop to quasi-normal plutei but inhibited calcium deposition in the spicules. It is suggested that carbonic anhydrase contributes to CaCO₃ deposition in the spicule.     

Protein synthesis in mouse embryos with experimentally produced asynchrony between chromosome replication and cell division

Summary The cleavage of fertilized mouse eggs was prevented during cytochalasin B incubation and consequently these eggs became tetraploid the following day during in vitro culture. When the eggs were cultured further in normal medium, they cleaved and gave rise to tetraploid blastocysts. Protein synthesis was analysed in these embryos at different developmental stages using two-dimensional polyacrylamide gel electrophoresis. The protein synthesis pattern of one-cell tetraploid eggs was intermediate between those of normal one- and two-cell embryos. Tetraploid two-cell embryos expressed protein sets equivalent to those of untreated four-cell embryos, and tetraploid four-cell embryos synthesized proteins similar to those of four- to eight-cell controls. At subsequent pre-implantation stages the asynchrony was no longer detectable. When fertilized eggs were cultured continuously in the presence of cytochalasin B, they became tetraploid, octoploid and more and more polyploid without cleavage occurring. The protein synthesis patterns expressed by these one-cell polyploid eggs did not resemble that of normal fertilized eggs, but were similar to those of cleaving control embryos and blastocysts of equivalent age and nuclear division. These results strongly suggest that in early mouse embryos stage-specific translation is temporally correlated with chromosome replication (karyokinesis) and independent of cell division (cytokinesis) or cell interaction.Some of these results were presented at the IX Congress of the International Society of Developmental Biologists in Basle, Switzerland, August 28–September 1, 1981     

The importance of larval eyes in the polychaete Capitella teleta: effects of larval eye deletion on formation of the adult eye

In many marine invertebrates with biphasic life cycles, juvenile/adult traits begin to develop before metamorphosis. For structures that are present at multiple developmental stages, but have distinct larval and adult forms, it is unclear whether larval and adult structures have shared or distinct developmental origins. In this study, we examine the relationship between the larval and adult eyes in the polychaete Capitella teleta. In addition, we describe a novel marker for larval and juvenile photoreceptor cells. Infrared laser deletion of individual micromeres in early embryos suggests that the same micromeres at the eight‐cell stage that are specified to generate the larval eyes also form the adult eyes. Direct deletion of the larval eye, including the pigment cell and the corresponding photoreceptor cell, resulted in a lack of shading pigment cells in juveniles and adults, demonstrating that this structure does not regenerate. However, a sensory photoreceptor cell was present in juveniles following direct larval eye deletions, indicating that larval and adult photoreceptors are separate cells. We propose that the formation of the adult eye in juveniles of C. teleta requires the presence of the pigment cell of the larval eye, but the adult photoreceptor is either recruited from adjacent neural tissue or arises de novo after metamorphosis. These results are different from the development and spatial orientation of larval and adult eyes found in other polychaetes, in which two scenarios have been proposed: larval eyes persist and function as adult eyes; or, distinct pigmented adult eyes begin developing separately from larval eyes prior to metamorphosis.     

Studies on Unequal Cleavage in Sea Urchins III. Micromere Formation under Compression

When sea urchin embryos at 2-cell stage are flattered between agar plates, the direction of cleavage is rotated by 90° in each division in reference to the preceding cleavage and no micromere is formed. But under this condition, micromeres are formed in 2 cases; 1) When the egg axis is parallel to the plane of flattening, 2 micromeres are formed on one side of a square 16-cell stage. 2) when the egg axis is perpendicular to the plane, 4 micromeres are formed at the center of the square.
When put into a groove, a string of 4 cells is formed showing that the spindle direction is further deflected by the groove. In the following 16-cell stage in the groove, which consists of 2 layers of 8 cells, cases with 2 micromeres on one side and 4 micromeres at the center are still found. If the 2-cell stage is introduced into a groove after the formation of mitotic apparatus, the spindle direction can no longer be changed and the 4-cell stage becomes like 4 pancakes stuck in 2 layers, indicating that 2 asters are holding the ends of a spindle in fixed positions.     

Mechanisms of calcium elevation in the micromeres of sea urchin embryos

The micromeres, the first cells to be specified in sea urchin embryos, are generated by unequal cleavage at the fourth cell division. The micromeres differentiate autonomously to form spicules and dispatch signals to induce endomesoderm in the neighbouring macromeres cells in the embryo. Using a calcium indicator Fura-2/AM and a mixture of dextran conjugated Oregon green-BAPTA 488 and Rhodamine red, the intracellular calcium ion concentration ([Ca2+]i) was studied in embryos at the 16-cell stage. [Ca2+]i was characteristically elevated in the micromeres during furrowing at the 4th cleavage. Subsequently, Ca2+ oscillated for about 10 min in the micromeres, resulting in episodic high levels of [Ca2+]i. High [Ca2+]i regions were associated with regional localizations of the endoplasmic reticulum (ER), though not with ER accumulated at the vegetal pole of the micromeres during the 4th division. Pharmacological studies, using a blocker of IP3-mediated Ca2+ release (Xestospongin), a store-operated Ca2+ entry inhibitor (2 aminoethoxydiphenyl borate (2-APB)) and an inhibitor of stretch-dependent ion channels (gadolinium), suggest that the high [Ca2+]i and oscillations in the micromeres are triggered by calcium influx caused by the activation of stretch-dependent calcium channels, followed by the release of calcium ions from the endoplasmic reticulum. On the basis of these new findings, a possible mechanism for autonomous formation of the micromeres is discussed.     

Similarity of proteins synthesized by isolated blastomeres of early sea urchin embryos

The 16-cell sea urchin embryo has blastomeres of three distinct size classes: micromeres, mesomeres, and macromeres. Each class is already restricted in its developmental fate, micromeres being committed to formation of primary mesenchyme cells. The three classes of blastomeres were isolated in high purity and incubated in [³⁵S]methionine until the next cleavage. Nearly all the radioactive protein was solubilized and subjected to two-dimensional electrophoresis according to O'Farrell. Of approximately 1000 spots resolved, there are no qualitative differences among the three blastomeres. When embryos were labeled between the first and fourth cleavages and blastomeres then isolated, no qualitative differences in protein synthesis were observed. Moreover, there are very few changes when unfertilized eggs are compared to 16-cell embryos. Thus cellular determination during embryonic development is not accompanied by qualitative changes in the distribution within the embryo of abundantly synthesized proteins, virtually all of which are coded for by sequences present in the egg.     

A correlative study of experimentally changed first cleavage and Janus development in the trunk of Platynereis dumerilii (Annelida,Polychaeta)

Summary Among zygotes of Platynereis dumerilii treated with cytochalasin B (CCB) prior to first cleavage, a wide variety of developmental effects were observed. One effect is a delay in the first cleavage. Treated embryos may skip the first or even more than one cleavage cycle and become multinucleated. Once these eggs start cleaving their cleavage plane takes the same position as in synchronously fertilized controls. Accordingly, the first cleavage in embryos having skipped the first normal cleavage cycle is meridional and equal, but their second cleavage is equatorial as in the third cleavage in controls. None of the embryos that were observed to skip early cleavages showed normal organogenesis, but developed into vesicle-shaped embryos with little cytological differentiation. Another effect of CCB treatment is altered blastomere size in those embryos which begin cleaving in synchrony with controls. While the majority of treated embryos followed a normal cleavage pattern, i.e. they cleaved at the right time and inequally, some of them cleaved equally or almost equally (adequally). Most of these embryos showed cleavage defects in subsequent cleavage cycles and became abnormal vesicle-shaped embryos. However, some of these embryos cleaving on schedule and equally or adequally developed into juvenile worms showing complete duplication of urites and parapodial rows (0.3% of all treated eggs) and are described as Janus duplicitates. This means that the occurrence of duplicitates and geometrically altered first cleavage patterns are correlated phenomena. The character and origin of the duplications and the consequences for dorsoventral polarity are discussed.     

The embryonic development of the polyclad flatworm Imogine mcgrathi

In this paper we describe the embryonic development of the polyclad flatworm Imogine mcgrathi. Imogine is an indirect developer that hatches as a planctonic Goette’s larva after an embryonic period of approximately 7 days. Light and electron microscopic analyses of sections of staged embryos were combined with antibody stainings of wholemounted embryos to reconstruct the origin and movement of the primordia of the various organ systems, with particular emphasis on the nervous system. We introduce a system of morphologically defined stages aimed at facilitating future studies and cross-species comparisons among flatworm embryos. Imogine embryos undergo typical spiral cleavage. Micromere quartets 1–3 form an irregular double layer of mesenchymal cells that during gastrulation expands over micromere quartet 4. Micromere 4d divides into several large mesendodermal precursors whose position defines the ventral pole of the embryo. These cells, along with the animal micromeres that obtained a sub-surface position during cleavage, form a deep layer of cells that gives rise to all internal structures, including the nervous system, musculature, nephridia, and gut. Micromeres 4a–c are large yolky cells that are incorporated into the lumen of the gut, but do not themselves contribute to the gut epithelium. Shortly after gastrulation, cell differentiation sets in. Cells located at the surface adopt epithelial characteristics and form cilia that result in continuous movement of the post-gastrula stage embryo. Deep cells at the lateral margins of the embryo become organized into a protonephridial tube. A cluster of approximately 50 deep cells at the anterior pole forms the brain, in which we have identified sets of founder neurons of the brain commissure and the dorsal and ventral connectives. The early differentiating neurons, along with other cells forming stabilized microtubules (ciliated cells of the epidermis, gut and protonephridia; apical gland cells) could be analyzed in detail because of their labeling with an antibody against acetylated α-tubulin. Our findings indicate that, despite significant differences in the cleavage pattern and arrangement of blastomeres in the early embryo, morphogenesis and organ formation of a polyclad embryo follows a pattern that is very similar to the pattern observed by us and others in phylogenetically more evolved rhabdocoel flatworms. Received: 10 February 2000 / Accepted: 10 April 2000