Quantitative analysis of epithelial cell aggregation in the simple metazoan Hydra reveals a switch from homotypic to heterotypic cell interactions

Hydra, a member of the diploblastic phylum Cnidaria, exhibits the most basic type of organized metazoan tissues. Two unicellular sheets of polarized epithelial cells - ectoderm and endoderm - form a double layer throughout the body column. The double layer can be reestablished from single-cell suspensions by tissue-specific cell-sorting processes. However, the underlying pattern of interactions between ectodermal and endodermal epithelial cells responsible for double-layer formation is unclear. By analyzing cell interactions in a quantitative adhesion assay using mechanically dissociated Hydra epithelial cells, we show that aggregation proceeds in two steps. First, homotypic interactions within ectodermal epithelial cells (ecto-ecto) and within endodermal epithelial cells (endo-endo) form homotypic cell clusters. Second, at an aggregate size of about ten epithelial cells/cluster, ectodermal and endodermal clusters start to form heterotypic aggregates. Homotypic ecto-ecto interactions are inhibited by a polyclonal anti-Hydra membrane antiserum, and under these conditions homotypic endo-endo interactions do not proceed beyond a size of about ten epithelial cells/cluster. These data suggest that homotypic cell clusters reduce their initial homotypic affinity and acquire a new heterotypic affinity. A link between cell adhesion and cell signaling in early Hydra aggregates is discussed.     

Diffusion and deformations of single hydra cells in cellular aggregates

Cell motion within cellular aggregates consists of both random and coherent components. We used confocal microscopy to study the center of mass displacements and deformations of single endodermal Hydra cells in two kinds of cellular aggregates, ectodermal and endodermal. We first carefully characterize the center of mass displacements using standard statistical analysis. In both aggregates, cells perform a persistent random walk, with the diffusion constant smaller in the more cohesive endodermal aggregate. We show that a simple parametric method is able to describe cell deformations and relate them to displacements. These deformations are random, with their amplitude and direction uncorrelated with the center of mass motion. Unlike for an isolated cell on a substrate, the random forces exerted by the surrounding cells predominate over the deformation of the cell itself, causing the displacements of a cell within an aggregate.     

The effects of antimicrotubule agents on cell motility in fibroblast aggregates

Spherical aggregates of chick heart, sclera and skin fibroblasts were fused with tritiated thymidine-labelled aggregates of the identical cell type. After being placed in contact, the two aggregates cohered and broadened the area of contact to form a single aggregate with a planar interface between the labelled and unlabelled halves. The motility of cells in the aggregate was determined by measuring the movement of labelled cells across the boundary into the unlabelled half. Exposure to pharmacological doses of antimicrotubule agents resulted in a significant reduction in fibroblast motility in the three-dimensional aggregates.     

Totipotent migratory stem cells in a hydroid

Hydroids, members of the most ancient eumetazoan phylum, the Cnidaria, harbor multipotent, migratory stem cells lodged in interstitial spaces of epithelial cells and are therefore referred to as interstitial cells or i-cells. According to traditional understanding, based on studies in Hydra, these i-cells give rise to several cell types such as stinging cells, nerve cells, and germ cells, but not to ectodermal and endodermal epithelial cells; these are considered to constitute separate cell lineages. We show here that, in Hydractinia, the developmental potential of these migratory stem cells is wider than previously anticipated. We eliminated the i-cells from subcloned wild-type animals and subsequently introduced i-cells from mutant clones and vice versa. The mutant donors and the wild-type recipients differed in their sex, growth pattern, and morphology. With time, the recipient underwent a complete conversion into the phenotype and genotype of the donor. Thus, under these experimental conditions the interstitial stem cells of Hydractinia exhibit totipotency.     

Scanning electron microscopy of the muscle system of Hydra magnipapillata

The fine structure of the ectodermal and endodermal muscle layers of Hydra magnipapillata has been analyzed by scanning electron microscopy after hydrolytic removal of the mesoglea with NaOH and subsequent exposure of the basal and lateral aspects of the layers by mechanical dissection. The ectodermal muscle layer consists of fibrous processes of epithelial cells extending longitudinally to the body axis, whereas the endodermal muscle layer comprises cells with hexagonal bases and several strands of myonemes oriented circularly. In each layer, the muscular elements tightly interdigitate, extending a continuous muscle sheet along the mesoglea. The ectodermal and endodermal muscle sheets communicate with each other via foliate microprojections penetrating the mesoglea. On the lateral aspect of the ectodermal epithelium, spiny nerve fibers run along the upper surface of the muscle processes. The spines are often attached to muscle processes, suggesting that the former monitor muscle contraction. Nerve fibers occasionally come into contact with the mesoglea through narrow gaps between the muscle processes. In the hypostomal ectoderm, a small spindle-shaped cell, probably sensory in nature, extends an apical cilium and a long basal process.     

In the multiheaded strain (mh-1) of Hydra magnipapillata the ectodermal epithelial cells are responsible for the formation of additional heads and the endodermal epithelial cells for the reduced ability to regenerate a foot

Hydra consist of three self-renewing cell lineages: the ectodermal epithelial, endodermal epithelial and interstitial cell lineages. The role of these cell lineages in head formation and foot regeneration in Hydra magnipapillata was studied by comparing the multiheaded strain mh-1 with the wild-type. Adult polyps of this strain show a reduced ability to regenerate a foot in the apical body half several days before additional heads are formed there. Cell lineage chimeras were produced, and it was found that in mh-1, the ectodermal epithelial cell lineage is responsible for the formation of additional heads, whereas the endodermal epithelial cell lineage and, to a lesser extent, the derivatives of the interstitial cell lineage, are responsible for the reduced ability of foot regeneration.     

Stem cells of the beetle midgut epithelium

At the completion of metamorphosis, adult insect cells have traditionally been assumed to halt cell divisions and terminally differentiate. While this model of differentiation holds for adult ectodermal epithelia that secrete cuticular specializations of exoskeletons, adult endodermal epithelia are populated by discrete three-dimensional aggregates of stem cells that continue to divide and differentiate after adult emergence. Aggregates of these presumptive adult stem cells are scattered throughout larval and pupal midgut monolayers. At the beginning of adult development (pupal-adult apolysis), the number of cells within each aggregate begins to increase rapidly. Dividing cells form three-dimensional, coherent populations that project as regenerative pouches of stem cells into the hemocoel surrounding the midgut. Stem cell pouches are regularly spaced throughout endodermal monolayers, having adopted a spacing pattern suggesting that each incipient pouch inhibits the formation of a similar pouch within a certain radius of itself—a process referred to as lateral inhibition. At completion of adult development (pupal-adult ecdysis), a distinct basal-luminal polarity has been established within each regenerative pouch. Dividing stem cells occupying the basal region are arranged in three-dimensional aggregates. As these are displaced toward the lumen, they transform into two-dimensional monolayers of differentiated epithelial cells whose apical surfaces are covered by microvilli. This organization of stem cell pouches in insect midguts closely parallels that of regenerative crypts in mammalian intestines.     

Size,shape and orientation of cells in budding hydra and regulation of regeneration in cell aggregates

Summary Changes in the number, shape, volume, orientation and vacuolization of cells involved in the budding of hydra were measured in histological sections. Before evagination, a group of about 800 epithelial cells are visibly recruited for the bud to be produced and this number increases to about 5,000 within a day. Thereafter, bud size increases mainly by proliferation of the cells within the bud. Upon recruitment for budding, the epithelial cells assume a columnar shape, with a smaller contact area facing the mesoglea, accompanied by a decrease in volume which is mostly accounted for by devacuolization. In later stages, cells progressively resume the form typical for non-budding areas of hydra. Evagination proceeds without reorientation of epithelio-muscular fibers, whereas elongation of the bud is accompanied by fiber reorientation.The process of sorting out and regeneration in aggregates of previously dissociated hydra cells was followed using various ratios of endodermal to ectodermal epithelial cells. From different initial compositions, the ratio in the regenerate rapidly approaches 11, the ratio found in normal hydra tissue.The experimental findings are discussed in the context of theoretical notions on pattern formation, evagination, elongation and stability of layered structures.     

The regulation of embryonic stem cell differentiation by leukaemia inhibitory factor (LIF)

LIF (leukaemia inhibitory factor) is commonly used to maintain mouse embryonic stem cells in an undifferentiated state. These cells spontaneously differentiate when allowed to aggregate in the absence of LIF, forming embryoid bodies in which early embryonic cell lineages develop. Using embryoid bodies cultured in the presence and absence of LIF, we show that although LIF inhibited the development of visceral and parietal endodermal cells, it did not affect the differentiation of the primitive endodermal cell precursors of these extraembryonic cell lineages. Furthermore, deposition of the basement membrane produced by the primitive endodermal cells, which separates them from the remaining cells of the embryoid body, still occurred. The differentiation of primitive ectodermal cells and their progeny was inhibited by LIF, as evidenced by the lack of expression of FGF-5, muscle, and neuronal markers. However, cavitation of the embryoid body and maintenance of the cells in contact with the primitive endodermal basement membrane as an epiblast epithelium still occurred normally in the presence of LIF. These results indicate that cavitation and formation of the epiblast epithelium are regulated by mechanisms distinct from those controlling the differentiation of epiblast cell lineages. Furthermore, although epithelium formation and cavitation do not require the differentiation of visceral endodermal cells, the results are consistent with the hypothesis that the primitive endodermal basement membrane is sufficient to induce the epithelialization of undifferentiated embryonic stem cells necessary for cavitation.     

Cnidarian and bilaterian promoters can direct GFP expression in transfected hydra

Complete sexual development is not easily amenable to experimentation in hydra. Therefore, the analysis of gene function and gene regulation requires the introduction of exogenous DNA in a large number of cells of the hydra polyps and the significant expression of reporter constructs in these cells. We present here the procedure whereby we coupled DNA injection into the gastric cavity to electroporation of the whole animal in order to efficiently transfect hydra polyps. We could detect GFP fluorescence in both endodermal and ectodermal cell layers of live animals and in epithelial as well as interstitial cell types of dissociated hydra. In addition, we could confirm GFP protein expression by showing colocalisation between GFP fluorescence and anti-GFP immunofluorescence. Finally, when a FLAG epitope was inserted in-frame with the GFP coding sequence, GFP fluorescence also colocalised with anti-FLAG immunofluorescence. This GFP expression in hydra cells was directed by various promoters, either homologous, like the hydra homeobox cnox-2 gene promoter, or heterologous, like the two nematode ribosomal protein S5 and L28 gene promoters, and the chicken beta-actin gene promoter. This strategy provides new tools for dissecting developmental molecular mechanisms in hydra; more specifically, the genetic regulations that take place in endodermal cells at the time budding or regeneration is initiated.     

Intercellular Contacts Between the Embryonic or Extraembryonic Ectoderm and the Primitive Endoderm in Rat Egg Cylinders Prior to the Formation of Primitive Streak

In pre-primitive streak-stage rat egg cylinders, both the embryonic and extraembryonic ectodermal cells projected cytoplasmic protrusions through gaps in the basal lamina and formed intimate cell-to-cell contact with the primitive endodermal cells. The 70 Å microfilaments were considered to participate in the production of these cytoplasmic protrusions. However, direct cell contact mediated by adherent junctions was occasionally found between the embryonic or extraembryonic ectodermal cells and the primitive endodermal cells. It has been proposed that these cell-to-cell contacts may play a role either in the supporting effect of primitive endodermal cells in the maintenance of cellular organization of the ectodermal cells, or in the facilitation of transport of nutritive materials from the primitive endodermal cells to both types of ectodermal cells.     

An SEM study of cellular morphology,contact, and arrangement,as related to gastrulation inXenopus laevis

Summary Cellular morphology, contact, and arrangement in the late blastula and in various stages of gastrulation ofXenopus were examined by SEM of specimens dissected after fixation or fractured in amyl acetate. The prospective ectoderm of the blastocoel roof consists of several layers of interdigitating cells connected by numerous small protrusions which may function in the decrease in number of cell layers observed during ectodermal epiboly. During gastrulation, prospective mesoderm is regionally differentiated by cellular morphology and arrangement into preinvolution mesoderm, the mesodermal involution zone, and involuted mesoderm. The involuted anterodorsal (head), lateral, and ventral mesoderm consists of a stream of loosely-packed, irregularly shaped cells having large extensions of the cell body attached locally to other cells by small protrusions. Involuted posterodorsal mesoderm (chordamesoderm) consists of elongated cells arranged in palisade fashion and connected by similar protrusions. Involuted mesodermal cells in all regions are attached to the overlying prospective ectodermal cells by numerous small protrusions along the entire interface between the two cell layers. Suprablastoporal endodermal cells involute as an epithelial sheet, changing in shape in the process, to form the roof of the archenteron. Bottle cell morphology, arrangement, and position with respect to the mesodermal cell stream is described. Evidence presented here and elsewhere suggests that involution of mesoderm and of the archenteron roof inXenopus is dependent primarily upon the relative movement of the mesodermal cell stream and of the overlying ectoderm.     

Improved tolerance to bile salts of aggregated Bifidobacterium longum produced during continuous culture with immobilized cells

The effect of cell immobilization and continuous culture was studied on selected physiological and technological characteristics of Bifidobacterium longum NCC2705 cultivated for 20 days in a two stage continuous fermentation system. Continuous immobilized cell (IC) cultures with and without glucose limitation exhibited formation of macroscopic cell aggregates after 12 and 9 days, respectively. Auto-aggregation resulted in underestimation of viable cell counts by plate counts by more than 2 log units CFU/ml compared with qPCR method. Modifications of cell membrane composition might partially explain aggregate formation in IC cultures. Decreases in the ratio of unsaturated to saturated fatty acid content from 1.74 to 0.58 might also contribute to the enhanced tolerance of IC cells to porcine bile salts and aminoglycosidic antibiotics compared with free cells from batch cultures.The enhanced resistance against bile salts in combination with auto-aggregation may confer an advantage to probiotic bacteria produced by IC technology.     

Pseudomonas aeruginosa interacts with epithelial cells rapidly forming aggregates that are internalized by a Lyn-dependent mechanism

Growing evidence is pointing to the importance of multicellular bacterial structures in the interaction of pathogenic bacteria with their host. Transition from planktonic to host cell-associated multicellular structures is an essential infection step that has not been described for the opportunistic human pathogen Pseudomonas aeruginosa. In this study we show that P. aeruginosa interacts with the surface of epithelial cells mainly forming aggregates. Dynamics of aggregate formation typically follow a sigmoidal curve. First, a single bacterium attaches at cell-cell junctions. This is followed by rapid recruitment of free-swimming bacteria and association of bacterial cells resulting in the formation of an aggregate on the order of minutes. Aggregates are associated with phosphatidylinositol 3,4,5-trisphosphate (PIP3)-enriched host cell membrane protrusions. We further show that aggregates can be rapidly internalized into epithelial cells. Lyn, a member of the Src family tyrosine kinases previously implicated in P. aeruginosa infection, mediates both PIP3-enriched protrusion formation and aggregate internalization. Our results establish the first framework of principles that define P. aeruginosa transition to multicellular structures during interaction with host cells.     

Modular microsystem for epithelial cell culture and electrical characterisation

We have realised a microsystem for the culture and electrical characterisation of epithelial cell layers for cell-based diagnostic applications. The main goal of this work is to achieve both cell culture and impedimetric and potentiometric characterisation on a single device. The miniaturised cell culture system enables the uses of scarce epithelial cells, as obtained from transgenic mice or from human biopsies. The device is completely modular and offers high flexibility: a polycarbonate membrane used as cell substrate is glued in between two moulded Polydimethylsiloxane (PDMS) layers to form a sandwich, which is placed between two stacks, containing the microfluidic channels and integrated measurement electrodes. The polycarbonate membrane sandwich can be removed, replaced or analysed at any time. We have characterised the impedimetric properties of our microsystem, demonstrated epithelial cell layer growth within it, and have done the initial electrical characterisation of epithelial cell layers.     

Embryonic cellular organization: differential restriction of fates as revealed by cell aggregates and lineage markers

Cleavage-stage Lytechinus variegatus embryos were dissociated and the cells were aggregated in an experimental system designed to address questions of embryonic organizational capability. Using monoclonal antibodies against stage- and structure-specific antigens, it was determined that germ-layer specific molecules were expressed in the expected locations in aggregates and that the germ layers differentiated in the normal temporal sequence, but the dorsoventral axis of the embryo was not reestablished properly. In other experiments individual rhodamine-labeled blastomeres were incorporated into unlabeled aggregates. Micromeres localized and differentiated normally. Mesomeres, however, which in normal embryos form only ectoderm, were found to change their specified fate and participate in gut formation. The sequence of aggregate organization revealed other properties of the embryo. Ectodermal and endodermal epithelia formed via two temporally distinct epithelialization events. Ectoderm separated from a mass of interior cells at about 12 hrs, and endoderm compacted from the interior cells at about 20 hr. A lathrytic agent that prevents gut formation in normal embryos also prevented gut formation in aggregates; however, it did not affect formation of the ectoderm. Hence, formation of the triploblastic structure in aggregates appears to be dependent upon developmentally regulated, distinct cell adhesion events.     

Some factors controlling cell polarity in chick retinal pigment epithelial cells in clonal culture

In clonal culture differentiated chick retinal pigmented epithelial (RPE) cells form a monolayer which shows little or no cellular division. The cells usually rest on a basal and reticular lamina and are polarized with their apical surface towards the medium. The apical surface is characterized by apical protrusions, an extensive apical web of microfilaments and junctional complexes which join the apical-lateral borders. A PA/S positive material with a felt-like appearance from the serum component of the medium coats the surfaces of the tissue culture plates. A similar material is found on any membrane filter which has been exposed to medium containing serum. When such a filter brought in contact with the upper surfaces of the RPE cells, the apical surface characteristics are lost, the cells often accumulate Alcian Blue positive material between the cells and the filter and secrete a reticular and a basal lamina, i.e. they establish a second basal surface. Once this has occurred, the cells appear to either detach from the plate and reverse their polarity, or undergo division forming two cell layers. In the latter case new apical surfaces are created between the cell layers but the cells appear to join to form circular structures rather than sheets. These results suggest that contact with this felt-like material initiates formation of a basal surface. They further suggest that where the apical surface has been converted to a basal one the cell attempts to restore the apical surface either by separating from the plate and reversing its polarity or by creating circular structures and developing new apices oriented toward the center of the circle.     

Nodal signaling regulates endodermal cell motility and actin dynamics via Rac1 and Prex1

Embryo morphogenesis is driven by dynamic cell behaviors, including migration, that are coordinated with fate specification and differentiation, but how such coordination is achieved remains poorly understood. During zebrafish gastrulation, endodermal cells sequentially exhibit first random, nonpersistent migration followed by oriented, persistent migration and finally collective migration. Using a novel transgenic line that labels the endodermal actin cytoskeleton, we found that these stage-dependent changes in migratory behavior correlated with changes in actin dynamics. The dynamic actin and random motility exhibited during early gastrulation were dependent on both Nodal and Rac1 signaling. We further identified the Rac-specific guanine nucleotide exchange factor Prex1 as a Nodal target and showed that it mediated Nodal-dependent random motility. Reducing Rac1 activity in endodermal cells caused them to bypass the random migration phase and aberrantly contribute to mesodermal tissues. Together, our results reveal a novel role for Nodal signaling in regulating actin dynamics and migration behavior, which are crucial for endodermal morphogenesis and cell fate decisions.     

Effects of Inducers on Inner and Outer Gastrula Ectoderm Layers of Xenopus laevis

Abstract. Gastrula ectoderm, isolated from Xenopus laevis , was cultured in Holtfreter solution or modified Leibovitz medium (L-15) by the sandwich-method with or without inducer. The ectoderm (SD cell layers) consists of two cell sheets, representing a superficial (S) and a deep (D) layer. In the L-15 medium rather than in Holtfreter solution, the two cell layers separate out into distinct cell masses. This difference in cell affinity under certain experimental conditions could indicate that the deep layer contains endodermal cells. However, an endodermal character of the deep layer can be ruled out by induction experiments with vegetalizing factor or dorsal blastopore lip as inducers. Under the influence of vegetalizing factor the outer as well as the inner ectoderm layer differentiated into mesodermal derivatives such as notochord and somites. The results of the experiments with dorsal blastopore lip as inducer indicate that both inner and outer ectoderm layers are responsive to the neural stimulus. The lower neural competence of the outer ectoderm layer observed by several authors in normogenesis is discussed with regard to the hypothesis about short distance diffusion of the neuralizing factor and/or close cell-to-cell contact between inducing tissue and ectodermal target cells.     

Ripply3 is required for the maintenance of epithelial sheets in the morphogenesis of pharyngeal pouches

During tissue development, the morphogenesis of epithelial sheets is regulated by many factors, including mechanical force, although the underlying mechanisms remain largely unknown. In the pharyngeal region of the vertebrate embryo, endodermal epithelium is reiteratively folded outward to form pharyngeal pouches, making partitions between the pharyngeal arches. Ripply3, encoding a member of the Ripply family of adaptor proteins, is required for the pouch formation posterior to the 2nd pharyngeal pouch. In this study, we found that the expression of mouse Ripply3 was specifically activated in accordance with the bending of the endodermal epithelium during the pouch formation. In Ripply3‐deficient embryos, a continuous monolayer of the endodermal epithelium was not maintained posterior to the 2nd pharyngeal pouch. Corresponding to the endodermal region of the deformed epithelium, the activated form of Integrin β1, which was localized at the basal side of the epithelial cells in the wild‐type embryos, was not persistently observed in the mutants. On the other hand, cell proliferation and apoptotic cell death in the endoderm were not obviously affected by the Ripply3 deficiency. Significantly, Ripply3 expressed in cultured cells was found to be preferentially accumulated in the focal adhesions, which are Integrin‐mediated adhesive contact sites transmitting mechanical force between the extracellular matrix and attached cells. Furthermore, Ripply3 promoted the maturation of focal adhesions in these cells. Thus, Ripply3 appears to have been activated to enhance the connection between the extracellular matrix and endodermal epithelial cells, as a mechanism to resist the mechanical stress generated during the bending of the epithelial sheets.