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.     

Communication compartments in the ectoderm of embryos of Patella vulgata

Summary Patterns of gap junctional communication in the ectoderm of embryos of Patella vulgata have been studied by intracellular injection of the fluorescent dye Lucifer Yellow, and by analysis of its subsequent spread to adjacent cells (dye-coupling). We found that dye-coupling became progressively restricted to different domains of the ectoderm, forming communication compartments. These communication compartments are characterized by their high coupling abilities within the compartment, and reduction of coupling across their boundaries. During development, the pretrochal (anterior) ectoderm becomes subdivided into two communication compartments, the apical organ and the anlage of the head ectoderm. The posttrochal (posterior) ectoderm becomes subdivided into different communication compartments in two successive phases. Firstly, in the 15-h embryo the dorsal and ventral domains of the ectoderm form separate communication compartments. A dorso-ventral communication boundary restricts the passage of dye between the two domains. Secondly, in the 24-h embryo dye-coupling becomes further compartmentalized in both the dorsal and ventral domains. These compartments correspond to the anlagen of different ectodermal structures. In order to study whether any level of coupling persists between the ectodermal compartments we injected currents through a microelectrode inserted into one cell of one compartment and monitored its spread by means of a second microelectrode inserted into one cell of another compartment (electrical coupling). Despite the absence of dye-coupling, electrical coupling between the ectodermal dye-coupling compartments was detected, which suggests that some level of communication is maintained between compartments. Our results demonstrate that within the ectoderm layer of Patella vulgata the transfer of dyes becomes progressively restricted to communication compartments and, concomitantly with the specification of the different ectodermal anlagen, these compartments become subdivided into smaller communication compartments.     

FGF-8 stimulates neuronal differentiation through FGFR-4a and interferes with mesoderm induction in Xenopus embryos

The role of fibroblast growth factors (FGFs) in neural induction is controversial [1,2]. Although FGF signalling has been implicated in early neural induction [3-5], a late role for FGFs in neural development is not well established. Indeed, it is thought that FGFs induce a precursor cell fate but are not able to induce neuronal differentiation or late neural markers [6-8]. It is also not known whether the same or distinct FGFs and FGF receptors (FGFRs) mediate the effects on mesoderm and neural development. We report that Xenopus embryos expressing ectopic FGF-8 develop an abundance of ectopic neurons that extend to the ventral, non-neural, ectoderm, but show no ectopic or enhanced notochord or somitic markers. FGF-8 inhibited the expression of an early mesoderm marker, Xbra, in contrast to eFGF, which induced ectopic Xbra robustly and neuronal differentiation weakly. The effect of FGF-8 on neurogenesis was blocked by dominant-negative FGFR-4a (DeltaXFGFR-4a). Endogenous neurogenesis was also blocked by DeltaXFGFR-4a and less efficiently by dominant-negative FGFR-1 (XFD), suggesting that it depends preferentially on signalling through FGFR-4a. The results suggest that FGF-8 and FGFR-4a signalling promotes neurogenesis and, unlike other FGFs, FGF-8 interferes with mesoderm induction. Thus, different FGFs show specificity for mesoderm induction versus neurogenesis and this may be mediated, at least in part, by the use of distinct receptors.     

Changes in junctional communication associated with cell cycle arrest and differentiation of trochoblasts in embryos of Patella vulgata

In early embryos of molluscs, different clones of successively determined trochoblasts differentiate into prototroch cells and together contribute to the formation of a ciliated ring of cells known as the prototroch. Trochoblasts differentiate after cell cycle arrest, which occurs two cell cycles after the commitment of their stem cell. To study the changes of junctional communication in embryos of Patella vulgata in relation to commitment, cell cycle arrest, and differentiation of the trochoblasts, we have monitored electrical coupling as well as transfer of fluorescent dyes. The appearance of dye coupling in embryos of Patella occurs after the fifth cleavage (at the 32-cell stage), when the cell cycles of all embryonic cells become asynchronous and longer. At the 32- and 64-cell stages all cells are well coupled. However, after the 72-cell stage dye transfer to or from any cell of the four interradial clones of four primary trochoblasts becomes abruptly reduced, whereas electrical coupling between these cells and the rest of the embryo can still be detected. From scanning electron microscopical analysis of the cell pattern we conclude that this change in gap junctional communication coincides with cell cycle arrest and with the development of cilia in all four clones of primary trochoblasts. Similarly, after the 88-cell stage the four radial clones of accessory trochoblasts stop dividing, reduce cell coupling, and become ciliated. By the formation of the prototroch, the embryo becomes subdivided into an anterior (pretrochal) and a posterior (posttrochal) domain which will develop different structures of the adult. At the 88-cell stage, the cells within each of these two domains remain well coupled and form two different communication compartments that are separated from each other by the interposed ring of uncoupled trochoblasts. The relations among control of cell cycle, changes in junctional communication, and differentiation are discussed.     

Spatial and temporal coincidence of induction processes and gap-junctional communication in Patella vulgata (Mollusca,Gastropoda)

In the early development of the gastropod mollusc Patella vulgata, two inductive processes take place between the animal and vegetal hemispheres. One is the induction of the vegetally-located stem cell of the mesoderm (the 3D macromere) by the first-quartet micromeres (which are located in the animal hemisphere). The other is the induction of dorsoventral symmetry in the first-quartet micromeres by the 3D macromere. As a consequence of the latter induction process, a dorsoventrally-organised prototroch is formed. In this paper, the moment of 3D induction is determined by deleting the inducing first-quartet micromeres at successive stages of development. Furthermore, the role of gap junctions in the two above-mentioned induction processes is investigated. This was done by studying lucifer yellow dye transfer between the 3D macromere and the first-quartet micromeres, in relation to these two induction processes. Analysis of the pattern of dye-transfer in vivo, in sections and with confocal laser scanning microscopy demonstrated that the moment of dye transfer coincides with the moment of 3D induction and with the moment of induction of the dorsoventral pattern of the prototroch. This indicates that gap-junctional communication may be involved in these two induction processes.     

Cyclin A, cyclin B and stringlike are regulated separately in cell cycle arrested trochoblasts of Patella vulgata embryos

 Trochoblasts are the first cells to differentiate during the development of spiralian embryos. Differentiation is accompanied by a cell division arrest. In embryos of the limpet Patella vulgata, the participation of cell cycle-regulating factors in trochoblast arrest was analysed as a first step to unravel its cause. We determined the cell cycle phase in which the trochoblasts are arrested by analysing the subcellular locations of mitotic cyclins. The results show that the trochoblasts are most likely arrested in the G2 phase. This was supported by measurement of the DNA content in trochoblast nuclei after the last division. Trochoblasts complete their final division at the sixth mitotic cycle. This mitotic cycle resembles the first postblastoderm cell cycle of Drosophila, in which mitotic activity is controlled by expression of the string gene. As failure of string expression results in cell cycle arrest in the G2 phase, negative regulation of a Patella string homolog could be responsible for trochoblast arrest. Although Stl messengers disappeared from trochoblasts during their final division, expression was observed again 20 min later. Messengers remained present in all trochoblasts at low levels during further development. Thus, expression of the stringlike gene allows the cell cycle arrest of these cells, whereas in Drosophila cells arrested in division lack string messengers. Received: 10 February 1997 / Accepted: 23 November 1997     

Development of dorsoventral polarity and mesentoblast determination in Patella vulgata

In Patella vulgata the 32-cell stage represents a pause in the mitotic activity prior to the differentiation of the mesentoblast mother cell 3D. At the onset of this stage, the embryo is radially symmetrical. Nevertheless, the plane of bilateral symmetry is indicated as it passes through the macromeres forming the vegetal cross-furrow. From the early beginning of the 32-cell stage, all four macromeres intrude far into the interior and touch the centrally radiating cells of the first quartet of micromeres. The two cross-furrow forming macromeres (3B and 3D) intrude the farthest and come into contact with the greatest number of micromeres. Finally, the contacts are extended significantly and maintained with only one of these macromeres. From that moment, this cell can be called the macromere 3D and the dorsoventral axis is determined. The evolution of the internal cell contacts between the micromeres of the first quartet and the macromeres indicates an essential role of the former in the determination of one of the latter as the mesentoblast mother cell, and thus in the determination of dorsoventral polarity.     

The expression of a caudal homologue in a mollusc,Patella vulgata

We cloned and analyzed the expression of a caudal homologue (PvuCdx) during the early development of the marine gastropod, Patella vulgata. PvuCdx is expressed at the onset of gastrulation in the ectodermal cells that constitute the posterior edge of the blastopore, as well as in the paired mesentoblasts, the stem cells that generate the posterior mesoderm of the trochophore larva. During larval stages, PvuCdx is expressed in the posterior neurectoderm of the larva, as well as in part of the mesoderm. This is the first report of the expression of a caudal gene in a lophotrochozoan species. The striking similarities with the expression of caudal in other organisms, such as chordates, suggest that a posterior expression of caudal is ancestral to Bilateria.     

Differential induction of regulatory genes during mesoderm formation in Xenopus laevis embryos

Mesoderm development in Xenopus laevis depends on inductive cell interactions mediated by diffusible molecules. The mesoderm inducer activin is capable of redirecting the development of animal explants both morphologically and biochemically. We have studied the induction of four regulatory genes, Mix. 1, goosecoid (gsc), Xlim-1 and Xbra in such explants by activin, and the influence of other factors on this induction. Activin induction of gsc is strongly enhanced by dorsalization of the embryo by LiCl, while expression of the other genes is only slightly enhanced. The protein synthesis inhibitor cycloheximide (CHX) inhibits the activin-dependent induction of Xbra partially, while induction of Mix. 1 and Xlim- 1 is essentially unaffected. In contrast, gsc shows strong superinduction in the presence of activin and CHX, and can be induced in animal explants by CHX alone. Induction and superinduction by CHX have previously been observed for immediate early genes in a variety of systems, notably for the activation of c-fos expression by serum stimulation, but have not been reported in early amphibian embryos. © 1993Wiley-Liss, Inc.     

The presence of an extracellular matrix between cells involved in the determination of the mesoderm bands in embryos ofPatella vulgata (Mollusca,gastropoda)

Summary In 32-cell stage embryos ofPatella vulgata one of the macromeres contacts the animal micromeres, and as a result is induced to differentiate into the stem cell of the mesodermal cell line. In this study we show the presence of an extracellular matrix (ECM) between these two interacting cell types. The ECM appears to be formed by the micromeres during the 32-cell stage. Staining experiments with alcian blue and tannic acid indicate that in contains glycoconjugates, possibly in the form of proteoglycans. The characteristics of the ECM were examined further by fluorescein isothiocyanate (FITC)-lectin labelling. Of 17 lectins tested, concanavalin A (ConA), succinyl-ConA, LCH-B (Lens culinaris) and PEA (Pisum sativum) showed a positive labelling of the ECM. These results are in accordance with the electron microscopic data. The appearance of the ECM at this specific stage and place suggests that it might play an important role in the induction of the mesodermal cell line.     

Reactivity of five N-acetylgalactosamine-recognizing lectins with preimplantation embryos, early postimplantation embryos, and teratocarcinoma cells of the mouse

The expression of receptors for N-acetylgalactosamine-recognizing lectins, namely Helix pomatia agglutinin (HPA), Sophora japonica agglutinin (SJA), Bauhinia purpurea agglutinin (BPA), Vicia villosa agglutinin (VVA), and Wistaria floribunda agglutinin (WFA) was studied in early mouse embryos and teratocarcinoma cells. Each of these lectins as well as Dolichos biflorus agglutinin (DBA) bound differently to early embryonic cells, with the exception of VVA and WFA which showed indistinguishable reactivities. SJA reacted intensely with visceral endoderm, but hardly at all with parietal and primitive endoderm. Therefore, SJA will be useful for analyzing the mechanism of visceral-endoderm formation. Furthermore, the inner cell mass (ICM) of early blastocysts reacted intensely with DBA, while the ICM of late blastocysts reacted only faintly with this lectin. Primary endoderm derived from the ICM reacted faintly with SJA, HPA, and DBA, and these reactivities increased again during the differentiation of the endoderm. Therefore, these three lectins could be used in the analysis of early stages during the differentiation of endoderm from the ICM. The results illustrate the highly complex nature of developmentally regulated alterations of cell-surface carbohydrates during the early stages of embryogenesis.     

Microinjection of cultured rat embryos: studies with retinol, 13-cis- and all-trans-retinoic acid

Retinol, all-trans-retinoic acid or 13-cis-retinoic acid were intraamniotically microinjected in rat embryos on day 10 of gestation and cultured until day 11.5. A comparison of the concentration-effect relationships of the retinoids showed that the dysmorphogenic effects were qualitatively similar for all three, but were elicited by a low concentration of all-trans-retinoic acid (250 ng/ml), a 6- to 7-fold higher concentration of 13-cis-retinoic acid and an approximately 16-fold higher concentration of retinol. After microinjection of 2,000 ng/ml of retinol, no dysmorphogenesis was observed but instead an increase in all growth parameters as compared to the controls.     

Germinal vesicle nucleoplasm and intracellular pH requirements for cytoplasmic maturity in oocytes of the prosobranch mollusk Patella vulgata

The respective roles of germinal vesicle (GV) nucleoplasm dispersion and intracellular alkalinization in the acquisition of cytoplasmic maturity by oocytes of the prosobranch mollusk Patella vulgata have been investigated in experiments involving premature fertilization of prophase-blocked oocytes. These were then either enucleated and treated with 10 mM NH₄Cl, pH 8.5, or induced to break their germinal vesicle in the absence of any evoked intracellular pH change. Results indicate that male pronuclear decondensation, sperm aster differentiation and cleavage require both GV nucleoplasm dispersion and intracellular pH alkalinization. These data are discussed in relation to the respective roles of calcium, pH, and nucleoplasm during maturation and activation of invertebrate and vertebrate oocytes.     

Dorsoventral polarity and mesentoblast determination as concomitant results of cellular interactions in the mollusk Patella vulgata.

In mollusks with an equal four-cell stage, dorsoventral polarity becomes noticeable in the interval between the formation of the third and fourth quartet of micromeres, i.e., between the fifth and sixth cleavage. One of the two macromeres at the vegetal cross-furrow then partly withdraws from the surface and becomes located more toward the center of the embryonic cell mass than the other three macromeres. Only this specific macromere (3D) contacts the micromeres of the animal pole, divides with a delay, and develops into the stem cell of the mesentoblast (4d). After suppression of the normal contacts between micromeres and macromeres either by dissociation of the embryos or by deletion of first quartet cells, the normal differentiation of the macromeres fails to appear. By deleting a decreasing number of first quartet cells, an increasing percentage of embryos shows the normal differentiation pattern. Deletion of one of the cross-furrow macromeres does not preclude formation of the mesentoblast, which then originates by differentiation of an other macromere. It is concluded that initially the embryo is radially symmetrical and that the four quadrants have identical developmental capacities; mesentoblast differentiation from one macromere is induced through the contacts of the first quartet cells and that single macromere.     

在非洲爪蛙胚胎中过表达atf4影响早期神经发育及眼睛的形成

越来越多的证据表明转录激活因子4(atf4)是一个与胚胎发育相关的基因.该文研究了非洲爪蛙atf4在胚胎发育过程中的表达和功能.atf4特异性地表达在非洲爪蛙胚胎的脑部、眼睛、血岛、原肾、肝脏、胰腺以及胃和十二指肠的部分细胞.在非洲爪蛙胚胎的动物极半球过表达适量(不影响胚胎整体形态发生的剂量)的atf4,对神经上皮细胞中sox3的表达无明显影响,也不引起细胞凋亡;但是对原始神经元的标记基因以及预定形成前脑、中脑、视网膜和晶状体的前体细胞的标记基因表达都有不同程度的抑制,最终导致无晶状体小眼的表型.该研究结果首次提示对正常的早期神经发育及眼睛形成而言,atf4的活性需受到严格的调控.     

FGF signalling and the mechanism of mesoderm spreading in Drosophila embryos

FGF signalling is needed for the proper establishment of the mesodermal cell layer in Drosophila embryos. The activation of the FGF receptor Heartless triggers the di-phosphorylation of MAPK in the mesoderm, which accumulates in a graded fashion with the highest levels seen at the dorsal edge of the mesoderm. We have examined the specific requirement for FGF signalling in the spreading process. We show that only the initial step of spreading, specifically the establishment of contact between the ectoderm and the mesoderm, depends upon FGF signalling, and that unlike the role of FGF signalling in the differentiation of heart precursors this function cannot be replaced by other receptor tyrosine kinases. The initiation of mesoderm spreading requires the FGF receptor to possess a functional kinase domain, but does not depend upon the activation of MAPK. Thus, the dispersal of the mesoderm at early stages is regulated by pathways downstream of the FGF receptor that are independent of the MAPK cascade. Furthermore, we demonstrate that the activation of MAPK by Heartless needs additional cues from the ectoderm. We propose that FGF signalling is required during the initial stages of mesoderm spreading to promote the efficient interaction of the mesoderm with the ectoderm rather than having a long range chemotactic function, and we discuss this in relation to the cellular mechanism of mesoderm spreading.     

Food supply, grazing activity and growth rate in the limpet Patella vulgata L.: a comparison between exposed and sheltered shores

The limpet Patella vulgata L. is an important microphagous grazer on intertidal rocky shores of north-west Europe, occurring across the wave exposure gradient. Groups of P. vulgata were selected at mid-tide level of two exposed shores and two sheltered, fucoid dominated shores on the Isle of Man, British Isles, and manipulated to equivalent densities and population structure. The level of grazing activity and growth rate were determined over a 1-year period. At the same time, the abundance of epilithic microalgae, measured as the concentration of chlorophyll a, was determined as an estimate of food supply. Microagal abundance showed a seasonal pattern in both exposed and sheltered conditions, with higher levels in winter compared to summer. In both seasons, the microalgal resource was more abundant on the sheltered shore studied. The level of grazing activity in P. vulgata showed a seasonal pattern on the exposed but not the sheltered shores. Averaged over the year, grazing activity on the exposed shores was over double that on sheltered shores. Thus, in sheltered conditions, food supply for limpets was high and grazing activity low; in exposed conditions, food supply was low and grazing activity high. The growth rate of P. vulgata, measured as increase in shell length, showed no significant difference between exposed and sheltered shores. Growth rate was also determined in P. vulgata at natural densities. Although the overall density declined with decreasing exposure to wave action, the density per unit area of grazeable substance was higher in shelter. In these populations, the mean growth rate was over twice as high on exposed compared to sheltered shores.