On the role of fibronectin during the compaction stage of somitogenesis in the chick embryo

During the early stages of somitogenesis in the chick embryo the presomitic cells in the segmental plate undergo compaction. The aggregation of segmental plate cells is stimulated by fibronectin. The stimulation of segmental plate cells to aggregate and undergo compaction can be effected in isolated segmental plate cells, in isolated segmental plates, and in intact embryos removed from the yolk. The fact that the segmental plate cells react with greater vigor to cellular fibronectin than to plasma fibronectin suggests a specific molecular mechanism in the initiation of somitogenesis.     

Preliminary characterization of cell surface-extracellular matrix linkage complexes in cultured retinal pigmented epithelial cells

In this report, we describe the relative distribution of vinculin, talin, and fibronectin in cultured retinal pigmented epithelial cells from chick embryo eyes. We show that in these cells vinculin is present in both focal cell-substratum and cell-cell contacts, whereas talin is present only in the cell-substratum contacts. When cells are double-labeled for talin and fibronectin and viewed at the substratum level, fibronectin is not detectable and talin is concentrated in plaques corresponding to focal contacts. However, when the same cells are viewed at the apical level, both talin and fibronectin are present in a fibrillar pattern. In addition to fibrils which are both talin- and fibronectin-positive, there are areas which are either talin-positive and fibronectin-negative or, vice versa, talin-negative and fibronectin-positive. These observations indicate an interesting variability in the composition of transmembrane linkages in retinal pigmented epithelial cells in vitro.     

Transitions between epithelial and mesenchymal states and the morphogenesis of the early mouse embryo

Multicellular organisms arise from the generation of different cell types and the organization of cells into tissues and organs. Cells of metazoa display two main phenotypes, the ancestral epithelial state and the recent mesenchymal derivative. Epithelial cells are usually stationary and reside in twodimensional sheets. By contrast mesenchymal cells are loosely packed and can move to new positions, thereby providing a vehicle for cell rearrangement, dispersal and novel cell-cell interactions. Transitions between epithelial and mesenchymal states drive key morphogenetic events in the early vertebrate embryo, including gastrulation, germ layer formation and somitogenesis. The cell behaviors and molecular mechanisms promoting transitions between these two states in the early mouse embryo are discussed in this review.Key words: mouse embryo, EMT, MET, morphogenesis, gastrulation, somitogenesis, epiblast, mesoderm, endoderm, primitive streak, paraxial mesoderm     

Basal lamina is not a barrier to neural crest cell emigration: documentation by TEM and by immunofluorescent and immunogold labelling

One of the factors proposed to control initiation of migration of neural crest (NC) cells is disruption of the basal lamina (BL) that is presumed to exist over the dorsal portion of the neural tube. Previously, we discovered that, in the mouse embryo, a continuous BL is not deposited over the dorsal portion of the neural tube until emigration of the NC cells is terminated. Here, we show that the pattern of BL deposition in chick embryos is similar, but not identical, to that in the mouse. In particular, (i) patches of BL are deposited on the premigratory NC cells in the chick but not in the mouse and (ii) BL is thicker and more interstitial matrix is deposited at the same stage of development in the chick. In addition, immunofluorescent and immunogold labelling of collagen IV, laminin and fibronectin show that (i) patches of young BL contain all three molecules; (ii) collagen IV and laminin are present in BL throughout neurulation but fibronectin either disappears or becomes masked in more mature BL and (iii) collagen IV and especially fibronectin are present in the interstitial matrix, but the relative abundance of fibronectin changes with time. The simultaneous use of immunolabelling for both light and TEM sections has allowed us to determine unambiguously that presence of a basement membrane (light microscopy) does not necessarily imply presence of basal lamina. We conclude that, as in mouse, the BL cannot be involved in the timing of the initiation of migration of NC cells. Our evidence in both the mouse and the chick, together with work in the axolotl, suggests that the basic pattern of BL deposition during neurulation may be a general phenomenon in embryonic development. Moreover, these results, in conjunction with the work of others, suggest that the critical step for initiation of migration of NC cells may be the loss of adhesions between cells.     

The distribution of fibronectin and laminin in the somitogenesis of Xenopus laevis

Abstract. Two different types of somitogenesis are present in vertebrates. Primarily, somites are formed by segmentation and epithelialization of mesenchyme (rosette formation type). In Xenopus , however, somitogenesis is characterized by a rotation of blocks of mesodermal cells following segmentation. Since this morphogenetic process involves cell movement as well as cell detachment and cell adhesion we analyzed the distribution of fibronectin and laminin in the somitogenesis of Xenopus . For laminin and fibronectin detection we used cross-reacting antibodies. We demonstrated their specific reaction with the Xenopus antigens by Western blots and by immunostainings of different tissues. Tracing both proteins immunohistologically during somitogenesis, our results show that fibronectin appears in the first steps of somitogenesis - during rotation, whereas laminin occurs after somites have already been formed. The different distribution of both proteins during somite formation indicates that fibronectin, but not laminin, is a possible substrate for the rotating cells.     

Behavior of cells seeded in isolated fibronectin matrices

Cell-free fibronectin matrix (FN-matrix) isolated from chick embryo fibroblasts was used to study cell-matrix interaction. After 24 h, most fibroblastic cells, including those without cell surface fibronectin, adopted bipolar fusiform morphology. Cells grew in parallel arrays and aligned with each other apparently along FN-matrix. Since the orientation of fibronectin fibers was determined by chick embryo fibroblasts, our results suggested that intercellular organization of "matrix-using" cell type may be influenced by "matrix-producing" cell type. Whereas the elongation and alignment effects induced by FN-matrix have been detected in fibroblasts (both normal and transformed), myoblast, aortic endothelial cells, neural cell lines (B103 and RT4D1), and cardiac muscle cells, similar effects are not detected in bone marrow hemopoietic cells, circulating lymphocytic T and B cells, and sympathetic neurons. For epithelial cells, FN-matrix has varying effects. Elongation and alignment effects are detected only in transformed epithelial cells with a great reduction in keratin expression. The morphology of normal or transformed epithelial cells with abundant keratin appears unaffected by FN-matrix. FN-matrix reduced the growth of several transformed fibroblastic lines up to 25%, but did not restore the appearance of actin stress fibers and the normal migratory activities of Rous sarcoma virus-transformed rat cells.     

Oscillations of the snail genes in the presomitic mesoderm coordinate segmental patterning and morphogenesis in vertebrate somitogenesis

The segmented body plan of vertebrate embryos arises through segmentation of the paraxial mesoderm to form somites. The tight temporal and spatial control underlying this process of somitogenesis is regulated by the segmentation clock and the FGF signaling wavefront. Here, we report the cyclic mRNA expression of Snail 1 and Snail 2 in the mouse and chick presomitic mesoderm (PSM), respectively. Whereas Snail genes' oscillations are independent of NOTCH signaling, we show that they require WNT and FGF signaling. Overexpressing Snail 2 in the chick embryo prevents cyclic Lfng and Meso 1 expression in the PSM and disrupts somite formation. Moreover, cells mis-expressing Snail 2 fail to express Paraxis, remain mesenchymal, and are thereby inhibited from undergoing the epithelialization event that culminates in the formation of the epithelial somite. Thus, Snail genes define a class of cyclic genes that coordinate segmentation and PSM morphogenesis.     

Segmentation and somitogenesis derived from phase dynamics in growing oscillatory media

The formation of spatially repetitive structures along the growth axis of a developing embryo is a common theme in developmental biology. Here we apply the novel flow-distributed oscillator (FDO) mechanism of wave pattern formation to the problem of axial segmentation in general and to somitogenesis in particular. We argue that the conditions for formation of FDO waves are satisfied during somitogenesis in the chick and mouse and that the waves of gene expression observed in these species arise from phase dynamics in a growing oscillatory medium. We substantiate this claim by showing that the FDO mechanism allows the waves to be mimicked by an inorganic experiment and that it predicts a wavelength that coincides with that observed experimentally. To see whether the FDO mechanism is compatible with other aspects of somitogenesis, we construct an FDO-based model of somitogenesis and successfully test it against a number of experimental observations, including the effect of heat shock. Our analysis provides a rigorous physical basis for the hypothesis that the phase dynamics of a segmental clock controls important stages of segmentation during somitogenesis in the chick and mouse as well as in other organisms that undergo segmentation during their axial growth.     

Activin disrupts somitogenesis in cultured chick embryos

The anatomical and cell biological aspects of somite formation in the chick embryo have been rather well studied. Molecular regulation of somitogenesis in vertebrates is just beginning to be understood. We have studied the effects of human recombinant activin on somitogenesis in gastrulating chick embryos cultured in vitro with a view to assessing the possible role of activin-related molecules in this phenomenon. Activin disrupted somitogenesis in treated embryos, resulting in the formation of abnormal, split or ectopic somites. Light microscopic examination indicated that the ability of activin to interfere with somitogenesis might be partly due to initiation of somite formation at ectopic sites. We show that these cells are indeed somitogenic by their expression of one of the earliest somite-specific marker genes, Pax3. Scanning electron microscopic examination of control and treated embryos revealed direct effects of activin on cell-cell interactions. Cells from treated embryos exhibited disrupted intercellular adhesion leading to large intercellular spaces, altered cell shapes and modification of cell surface protrusions. The effects of activin on somitogenesis appear to be specific, since the neural structures, which are generally more susceptible to chemical insults during gastrulation, were relatively less affected. The results clearly point to a role of activin-related molecules in somitogenesis in the chick embryo.     

Transitions between epithelial and mesenchymal states and the morphogenesis of the early mouse embryo

Multicellular organisms arise from the generation of different cell types and the organization of cells into tissues and organs. Cells of metazoa display two main phenotypes, the ancestral epithelial state and the recent mesenchymal derivative. Epithelial cells are usually stationary and reside in two-dimensional sheets. By contrast mesenchymal cells are loosely packed and can move to new positions, thereby providing a vehicle for cell rearrangement, dispersal and novel cell-cell interactions. Transitions between epithelial and mesenchymal states drive key morphogenetic events in the early vertebrate embryo, including gastrulation, germ layer formation and somitogenesis. The cell behaviors and molecular mechanisms promoting transitions between these two states in the early mouse embryo are discussed in this review.     

The migratory behavior of avian embryonic cells does not require phosphorylation of the fibronectin-receptor complex

When locomotory embryonic cells become stationary, they acquire new substratum-adhesion properties. In particular, the distribution of fibronectin receptors shifts from diffuse and highly mobile on the cell membrane to immobilized in close association with fibronectin molecules and cytoskeletal elements in focal contacts. Receptor phosphorylation has been proposed as a possible regulator of the interaction between the receptor and its intracellular and extracellular ligands. In the present study, we have compared the phosphorylation state of the fibronectin receptor in motile neural crest and somitic cells, in stationary somitic cells, and in Rous-sarcoma virus transformed-chick embryo fibroblasts, using immunoprecipitation following metabolic labeling. While no receptor phosphorylation was detected in motile embryonic cells, the beta subunit of the receptor was phosphorylated in stationary cells. This subunit was also highly phosphorylated in Rous-sarcoma virus-transformed chicken cells. These results suggest that phosphorylation of the fibronectin receptor cannot account for its distribution in the cell membrane and for the nature of the interactions between this receptor and its ligands in embryonic cells.     

Fluorescein-Conjugated Bandeiraea simplicifolia Lectin as a Marker of Endodermal, Yolk Sac, and Trophoblastic Differentiation in the Mouse Embryo

Abstract. The Bandeiraea simplicifolia lectin I (BSA-I) conjugated to fluorescein isothiocyanate was used as a histochemical reagent to study the mouse embryos from fertilization to early somitogenesis. No lectin binding could be detected on the embryonic cells in the preimplantation embryo. Lectin labeled intensely the zona pellucida. In the implanting embryos lectin binding was detected along the subtrophectodermal and Reichert's membrane, in the cytoplasm of the parietal and visceral endoderm, and the trophoblastic giant cells, but not in the ectodermal cells. Studies on explanted blastocyts cultured in vitro disclosed that the cytoplasmic BSA-I binding sites in trophoblastic cells develop gradually. In the 9-day somitic embryo BSA-I reacted with epithelial cells of the yolk sac, but not with the mesenchymal cells. A continuity between the lectin-reactive endoderm and the foregut epithelium could be demonstrated. These data indicated that BSA-I lectin can be used as a histochemical probe for endodermal (yolk sac) and trophoblastic differentiation in the peri-implantational mouse embryo.     

Tumor promoters induce changes in the chick embryo fibroblast cytoskeleton

We have examined the effect of the tumor promoter, 12-0-tetradecanoyl phorbol-13-acetate (TPA), on the actin-containing elements of the cytoskeleton of chick embryo fibroblasts (CEF). TPA at concentrations as low as 7.3 times 10-10M indices a reversible change in the cytoskeleton as visualized by indirect immunofluorescence using anti-actin antibodies. Cells incubated with TPA lose the ordered actin-containing structures found in normal cells and resemble Rous sarcoma virus-transformed cells in that the immunofluorescent actin pattern is diffuse. The TPA effects are both dose-and time-dependent. Analogs of TPA which are inactive as tumor promoters do not induce cytoskeletal changes at the concentrations tested, while a second tumor promoter, PDD, is also able to cause alterations in actin-containing structures. The action of TPA requires de novo synthesis of both RNA and protein. The direct cytoskeletal changes are neither plasmin-dependent nor subject to inhibition by incubating the cells with high levels of protease inhibitors during the exposure to TPA. However, plasminogen does increase the sensitivity of cells to TPA.     

A developmental study of murine epidermal Langerhans cells

Prospective skin prior to invasion by neural crest cells was dissected from 10.5-day mouse embryos and cultivated in chick embryo hosts. The graft tissue was prepared for the demonstration of both mouse and chick cells, pigment cells, and Langerhans cells. Chick cells were not found in the graft mouse epidermis; however, ATPase-positive and osmium iodide-positive cells were present. Electron microscopic examination revealed that, in younger grafts, only indeterminate cells could be found among the keratinocytes. In older grafts, both indeterminate cells and Langerhans cells with granules were seen. The evidence affirms that epidermal Langerhans cells are not related to pigment cells.Based on the developmental nature of Birbeck (Langerhans) granules from the cytomembrane, it is proposed that the granule no longer be considered as specific to and characteristic of epidermal Langerhans cells. Rather, Langerhans cells should be defined as ATPase-positive, desmosome-free cells within stratified squamous, potentially keratinizing, epithelia. Thus epidermal, ATPase-positive indeterminate cells and such cells with Birbeck granules both should be considered as components of the Langerhans cell series.Normal chick skin does not show ATPase-positive cells. However, when 10.5-day mouse embryo ectoderm was inserted under the ectoderm of chick embryos, the resulting chimeric epidermis possessed ATPase-positive cells. It is proposed that epidermal Langerhans cells are of ectodermal origin.     

Isolation of focal contact membrane using saponin

The fragments of lower cell surface remained attached to the substrate after incubation of mouse or chick fibroblasts in 0.2% saponin solution and subsequent removal of cells under the action of shearing force. These fragments corresponded exactly to the cellular focal contacts seen by interference reflection microscopy. Ultrastructurally they were membrane fragments with typical three-layered structure. No cytoskeletal components were found in saponin-isolated focal contact membranes either by immunofluorescence or electron microscopy. Only one major cell-derived protein with an apparent molecular weight (MW) of 51 kD (chick embryo fibroblasts) or 47 kD (mouse embryo fibroblasts) remained on the substrate after saponin treatment and removal of cells.     

Fibronectin distribution during somitogenesis in the chick embryo

Somite formation in vertebrates is a multi-stage process. From a relatively homogeneous rod of mesenchyme, the segmental plate, somites are formed in a repeating sequence. Cell-cell adhesion has been proposed as a causal factor in somitogenesis. This led to an analysis of fibronectin in the segmental plate with respect to the initiation of somitogenesis. The pattern of fibronectin distribution can be correlated with the initiation of somitogenesis in the anterior portion of the segmental plate. Fibronectin distribution was determined using a high resolution antibody localization technique. Differences in fibronectin distribution were verified with computer-assisted image analysis. The evidence presented supports the hypothesis that an increase in cell-cell adhesion is a significant factor in the initiation of somitogenesis.     

Regulation of cell substrate adhesion: effects of small galactosaminoglycan-containing proteoglycans.

Cell adhesion is a process which is initiated by the attachment of cells to specific sites in adhesive matrix proteins via cell surface receptors of the integrin family. This is followed by a reorganization of cytoskeletal elements which results in cell spreading and the formation of focal adhesion plaques. We have examined the effects of a class of small galactosaminoglycan-containing proteoglycans on the various stages of cell adhesion to fibronectin-coated substrates. Our results indicate that dermatan sulfate proteoglycans (DSPGs) derived from cartilage, as well as other related small proteoglycans, inhibit the initial attachment of CHO cells and rat embryo fibroblasts to substrates composed of the 105-kD cell-binding fibronectin fragment, but do not affect cell attachment to intact fibronectin. Although this effect involves binding of DSPGs to the substrate via the protein core, the intact proteoglycan is necessary for the observed activity. Isolated core proteins are inactive. The structural composition of the galactosaminoglycan chain does not appear to be functionally significant since both chondroitin sulfate and various dermatan sulfate proteoglycans of this family inhibit cell attachment to the fibronectin fragment. Neither the percentage of cells spread nor the mean area of spread cells adhering to substrates of intact fibronectin was significantly affected by the DSPGs. However, significantly fewer cells formed focal adhesions in the presence of DSPGs as compared with untreated control cells. These results suggest that the binding of small galactosaminoglycan-containing proteoglycans to a fibronectin substrate may affect several stages in the cell adhesion process.     

Studies of fibronectin matrices in living cells with fluoresceinated gelatin

We have used fluorescein isosthiocyanate-conjugated gelatin (FITC- gelatin) (1 mg/ml) to localize cell surface fibronectin in unfixed live cells in cultures. FITC-gelatin stains the fibronectin matrix on primary cultures of rat and chick embryo fibroblasts as well as untransformed, established cell lines. In live cultured cells, fibronectin in many areas of the extracellular matrix is inaccessible to antibody and cannot be visualized by immunofluorescence staining. In contrast, fibronectin in these areas is fully stainable by FITC- gelatin. At a low concentration (20 micrograms/ml), FITC-gelatin stains the fibronectin matrix of primary cultured cells but not of "untransformed" established cell lines. SEM can detect only the matrix stainable with the low concentration of FITC-gelatin, such as that expressed by primary chick embryo fibroblasts. The binding of fibronectin to the extracellular matrix is very stable and FITC-gelatin remained bound to the matrix for at least 10 d in culture. Radioiodinated gelatin has been used to quantitate the level of cell surface fibronectin in living normal and transformed cells. FITC- gelatin appears to be a useful probe for studying the fibronectin of living cells in culture.     

Radioimmunoassay for tubulin: a quantitative comparison of the tubulin content of different established tissue culture cells and tissues

A quantitative estimate of the cellular tubulin concentration can be obtained by the use of a radioimmunoassay based upon the competition between tubulin in cell extracts and a known amount of radioactively labeled homogeneous tubulin during binding to a limited amount of antitubulin antibodies. This assay shows that a variety of widely used tissue culture cells (mouse L cells, mouse 3T3 cells, chick embryo fibroblasts) have a tubulin content which corresponds to approximately 2.5-3.3% of their total protein. Transformation of mouse 3T3 cells by the DNA virus SV40, and of chick embryo cells by the RNA Rous sarcoma virus, does not change the intracellular tubulin concentration. Transformed cells of brain origin, such as some glia tumor cell lines and some neuroblastoma cell lines, have a much lower tubulin content than does normal brain tissue.The intracellular concentration of tubulin in mouse 3T3 cells is discussed in relation to the number of microtubules detected during interphase by immunofluorescence microscopy. These results are also discussed in view of a mechanism of microtubule elongation in vivo driven by self-assembly.     

The effects of collagen synthesis inhibitory drugs on somitogenesis and myogenin expression in cultured chick and mouse embryos

The role of fibrillar collagen on myogenic differentiation has previously been studied in tissue culture cell lines but has not been studied in situ. We treated cultured chick and mouse embryos with collagen synthesis inhibitors to determine the role of fibrillar collagen on somitogenesis and on myogenic differentiation in vivo. Stage 12 chick embryos and 8.7 dpc mouse embryos were cultured in control medium or a range of concentrations of the collagen synthesis inhibitors ethyl-3,4-dihydroxybenzoate (EDHB) or cis-hydroxy-proline (CHP). Chick embryos were cultured for 24 h and mouse embryos were cultured for 30 h. Both collagen synthesis inhibitors produced a range of somite abnormalities including formation of fewer and irregular somites in both chick and mouse at high drug concentrations, as well as formation of double somites in EDHB-treated chick embryos. Examination of EDHB-treated mouse embryos by scanning electron microscopy demonstrated a dosage-dependent loss of fibrillar collagen and associated extracellular matrix. Expression of myogenin in EDHB-treated mouse embryos, examined by whole-mount in situ hybridization, was suppressed at higher dosage levels. This study suggests that inhibition of fibrillar collagen production and/or loss of fibrillar collagen in the developing avian and mammalian embryo results in abnormal somite formation and perturbed myogenic differentiation.