Intercellular communication is cell cycle modulated during early Xenopus laevis development

We investigated intercellular communication during the seventh and tenth cell cycles of Xenopus laevis development using microinjection of Lucifer yellow and FITC-dextran as well as freeze-fracture electron microscopy. We found that gap junction-mediated dye coupling visualized using Lucifer yellow was strongly cell cycle modulated in the tenth cell cycle. Cytoplasmic bridge-mediated dye coupling visualized via FITC-dextran was also, of course, cell cycle modulated. The basis of cell cycle-modulated gap junctional coupling was investigated by measuring the abundance of morphologically detectable gap junctions through the tenth cell cycle. These proved to be six times more abundant at the beginning than at the end of this cell cycle.     

Intercellular connectivity in the eight-cell Xenopus embryomcorrelation of electrical and morphological investigations.

The distribution of individual intercellular electrical junctions has been examined in eight-cell Xenopus embryos using linear systems analysis. Morphological evidence for corresponding intercellular contacts has been sought by light microscopy and scanning electron microscopy. The electrical investigation indicated that each cell is directly coupled to each of the other seven cells by identical resistive junctions. Scanning electron microscopy of the cell surfaces of cleaved embryos revealed protrusions from the surfaces of the cells which could mediate such intercellular connections. Light microscopy of serial sections through the embryos also showed fine processes of the cell surfaces which come into contact with several other cells. The complete intercellular connectivity suggested by these results appears to be an extension of similarly close connectivity in the two- and four-cell embryos. The possible significance of this high connectivity to morphogenesis is discussed.     

Reversal of dorsoventral polarity in Xenopus laevis embryos by 180 degrees rotation of the animal micromeres at the eight-cell stage

The 180 degrees rotation of the animal cell quartet at the 8-cell stage of Xenopus laevis embryos leads to a reversal of dorsoventral polarity in a majority of the embryos. Dorsal micromeres appear to instruct the macromeres in contact with them to initiate later steps in dorsal development. This inductive process is most apparent in the second half of the third cell cycle and is largely lost by the beginning of the fourth cell cycle.     

Histological development of the cement gland in Xenopus laevis: a light microscopic study

The differentiation and degeneration of the cement gland in Xenopus laevis is described. The gland is first observed histologically at stage 19 (neural tube stage) as a packed group of apical ectoderm cells heavily laden with oocyte pigment granules, lying ventral to the cranial neural fold. By tailbud stage 35/36, the gland cells have increased in height and are approximately ten times taller than nonglandular apical ectoderm cells. The nuclei divide the gland cells into an apical region that is eosinophilic and contains oocyte pigment granules, and a basal region that contains clear droplets. The cells are decreasing in height by stage 40 (early tadpole) and begin to lose their pigment granules. Between stages 45 and 48, the pigment is extruded and the clear basal droplets diminish in number. From stage 48 to 49 the cells become vacuolated and the histotypic characteristics of the functional gland are lost. The gland is not vascularized, nor do phagocytic cells appear in its vicinity during any stage of its development. It remains bordered at its base by subjacent basal ectoderm during its entire life cycle of 10 to 12 days at room temperature.     

Intercellular communication between follicular angiotensin receptors and Xenopus laevis oocytes: medication by an inositol 1,4,5- trisphosphate-dependent mechanism

In Xenopus laevis oocytes, activation of angiotensin II (AII) receptors on the surrounding follicular cells sends a signal through gap junctions to elevate cytoplasmic calcium concentration ([Ca2+]i) within the oocyte. The two major candidates for signal transfer through gap junctions into the oocyte during AII receptor stimulation are Ins(1,4,5)P3 and Ca2+. In [3H]inositol-injected follicular oocytes, AII stimulated two- to fourfold increases in phosphoinositide hydrolysis and production of inositol phosphates. Injection of the glycosaminoglycan, heparin, which selectively blocks Ins(1,4,5)P3 receptors, prevented both AII-stimulated and Ins(1,4,5)P3-induced Ca2+ mobilization in Xenopus follicular oocytes but did not affect mobilization of Ca2+ by ionomycin or GTP. These results indicate that the AII-regulated process of gap junction communication between follicular cells and the oocyte operates through an Ins(1,4,5)P3-dependent mechanism rather than through transfer of Ca2+ into the ooplasm and subsequent Ca(2+)-induced Ca2+ release.     

Intercellular communication in the multicellular stage of Dictyostelium discoideum

Abstract. The aim of the present study was to draw inferences regarding the properties of single cells responsible for co-operative behaviour in the slug of the soil amoeba Dictyostelium discoideum. The slug is an integrated multicellular mass formed by the aggregation of starved cells. The amoebae comprising the slug differentiate according to their spatial locations relative to one another, implying that, as in the case of other regulative embryos, they must be in mutual communication. We have previously shown that one manifestation of this communication is the time taken for the anteriormost fragment of the slug, the tip, to regenerate from slugs which have been rendered tipless by amputation. We present results of tip-regeneration experiments performed on genetically mosaic slugs. By comparing the mosaics with their component pure genotypes, we were able to discriminate between a set of otherwise equally plausible modes of intercellular signalling. Neither a'pacemaker' model, in which the overall rate of tip regeneration is determined by the cell with the highest frequency of autonomous oscillation, nor an 'independent-particle' model, in which the rate of regeneration is the arithmetical average of independent cell-dependent rates, is in quantitative accord with our findings. Our results are best explained by a form of signalling which operates by means of cell-to-cell relay. Therefore intercellular communication Seems to be essential for tip regeneration.     

Intercellular communication inAzolla roots: II. Electrical coupling

Summary There is a predictable and well defined variation in numbers of plasmodesmata in roots ofAzolla. As the apical cell of the root ages, it lays down walls with progressively fewer plasmodesmata, thereby gradually cutting itself off from the rest of the root (Gunning 1978). Electrical coupling was examined between the apical cell and an adjacent merophyte in roots of various lengths. The apical cell becomes increasingly electrically isolated from the rest of the root as it ages. Electrical coupling is strongly correlated with the number of the plasmodesmata between the coupled cells. The resistance of a plasmodesma, as estimated from equivalent electrical circuits, was 150–600 times more resistive than a value based on theoretical considerations. No evidence was found for a change in the physiology of plasmodesmata as the root ages. Coupling experiments, both on root hairs and at the apex, gave some suggestion that plasmodesmata may be less resistive towards the apical cell than away from it.     

Fate map for the 32-cell stage of Xenopus laevis

A complete fate map has been produced for the 32-cell stage of Xenopus laevis. Embryos with a regular cleavage pattern were selected and individual blastomeres were injected with the lineage label fluorescein-dextran-amine (FDA). The spatial location of the clones was deduced from three-dimensional (3D) reconstructions of later stages and the volume of each tissue colonized by labelled cells in each tissue was measured. The results from 107 cases were pooled to give a fate map which shows the fate of each blastomere in terms of tissue types, the composition of each tissue by blastomere, the location of each prospective region on the embryo and the fate of each blastomere in terms of spatial localization. Morphogenetic movements up to stage 10 (early gastrula) were assessed by carrying out a number of orthotopic grafts at blastula and gastrula stages using donor embryos uniformly labelled with FDA. Although there is a regular topographic projection from the 32-cell stage this varies a little between individuals because of variability of positions of cleavage planes and because of short-range cell mixing during gastrulation. The cell mixing means that the topographic projection fails for anteroposterior segments of the dorsal axial structures and it is not possible to include short segments of notochord or neural tube or individual somites on the pregastrulation fate map.     

Emerin expression in early development of Xenopus laevis

Emerin is an integral protein of the inner nuclear membrane in the majority of differentiated vertebrate cells. In humans, deficiency of emerin causes a progressive muscular dystrophy of the Emery-Dreifuss type. The physiological role of emerin is poorly understood. By screening and sequencing of EST clones we have identified two emerin homologues in Xenopus laevis, Xemerin1 and Xemerin2. Xemerins share with mammalian emerins the N-terminal LEM domain and a single transmembrane domain at the C-terminus. As shown by immunoblot analysis with Xemerin-specific antibodies, both proteins have an apparent molecular mass of 24 kDa but differ in their isoelectric points. Xemerin1 and Xemerin2 proteins are not detectable in oocytes nor during early embryogenesis. Protein expression is first found at stage 43 and persists in somatic cells. However, RT-PCR and Northern blot analysis show Xemerin mRNAs of approximately 4.0 kb to be present in oocytes and throughout embryogenesis. During embryogenesis the level of Xemerin mRNAs increases at stage 22 and is particularly abundant in mesodermal and neuro-ectodermal regions of the embryo. These data provide the necessary background to further investigate the role of emerin in nuclear envelope assembly, gene expression and organ development of X. laevis as a model organism.     

Expression of ribosomal-protein genes in Xenopus laevis development

Using probes to Xenopus laevis ribosomal-protein (r-protein) mRNAs, we have found that in the oocyte the accumulation of r-protein mRNAs proceeds to a maximum level, which is attained at the onset of vitellogenesis and remains stable thereafter. In the embryo, r-protein mRNA sequences are present at low levels in the cytoplasm during early cleavage (stages 2-5), become undetectable until gastrulation (stage 10) and accumulate progressively afterwards. Normalization of the amount of mRNA to cell number suggests an activation of r-protein genes around stage 10; however, a variation in mRNA turnover cannot be excluded. Newly synthesized ribosomal proteins cannot be found from early cleavage up to stage 26, with the exception of S3, L17 and L31, which are constantly made, and protein L5, which starts to be synthesized around stage 7. A complete set of ribosomal proteins is actively produced only in tailbud embryos (stages 28-32), several hours after the appearance of their mRNAs. Before stage 26 these mRNA sequences are found on subpolysomal fractions, whereas more than 50% of them are associated with polysomes at stage 31. Anucleolate mutants do not synthesize ribosomal proteins at the time when normal embryos do it very actively; nevertheless, they accumulate r-protein mRNAs.     

Onset of competence to respond to activin A in isolated eight-cell stage Xenopus animal blastomeres

Single animal hemisphere blastomeres isolated from the eight-cell stage Xenopus embryos differentiate into mesoderm when treated with activin A, whereas when cultured without activin they form atypical epidermis. The mesoderm tissue induced by activin is different between dorsal and ventral blastomeres. In the present study, the duration and timing of activin treatment was varied, in order to identify the critical stage when animal blastomeres acquire competence to respond to activin A. It was shown that the critical time was 45 min after blastomere isolation, which corresponds approximately to NF stage 6 (32-cell stage) of normal development. The competence gradually increased during the morula stages.