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.     

The chick embryo: a leading model in somitogenesis studies

The vertebrate body is built on a metameric organization which consists of a repetition of functionally equivalent units, each comprising a vertebra, its associated muscles, peripheral nerves and blood vessels. This periodic pattern is established during embryogenesis by the somitogenesis process. Somites are generated in a rhythmic fashion from the presomitic mesoderm and they subsequently differentiate to give rise to the vertebrae and skeletal muscles of the body. Somitogenesis has been very actively studied in the chick embryo since the 19th century and many of the landmark experiments that led to our current understanding of the vertebrate segmentation process have been performed in this organism. Somite formation involves an oscillator, the segmentation clock whose periodic signal is converted into the periodic array of somite boundaries by a spacing mechanism relying on a traveling threshold of FGF signaling regressing in concert with body axis extension.     

Adhesion molecules during somitogenesis in the avian embryo

In avian embryos, somites constitute the morphological unit of the metameric pattern. Somites are epithelia formed from a mesenchyme, the segmental plate, and are subsequently reorganized into dermatome, myotome, and sclerotome. In this study, we used somitogenesis as a basis to examine tissue remodeling during early vertebrate morphogenesis. Particular emphasis was put on the distribution and possible complementary roles of adhesion-promoting molecules, neural cell adhesion molecule (N-CAM), N-cadherin, fibronectin, and laminin. Both segmental plate and somitic cells exhibited in vitro calcium-dependent and calcium-independent systems of cell aggregation that could be inhibited respectively by anti-N-cadherin and anti-N-CAM antibodies. In vivo, the spatio-temporal expression of N-cadherin was closely associated with both the formation and local disruption of the somites. In contrast, changes in the prevalence of N-CAM did not strictly accompany the remodeling of the somitic epithelium into dermamyotome and sclerotome. It was also observed that fibronectin and laminin were reorganized secondarily in the extracellular spaces after CAM-mediated contacts were modulated. In an in vitro culture system of somites, N-cadherin was lost on individual cells released from somite explants and was reexpressed when these cells reached confluence and established intercellular contacts. In an assay of tissue dissociation in vitro, antibodies to N-cadherin or medium devoid of calcium strongly and reversibly dissociated explants of segmental plates and somites. Antibodies to N-CAM exhibited a smaller disrupting effect only on segmental plate explants. In contrast, antibodies to fibronectin and laminin did not perturb the cohesion of cells within the explants. These results emphasize the possible role of cell surface modulation of CAMs during the formation and remodeling of some transient embryonic epithelia. It is suggested that N-cadherin plays a major role in the control of tissue remodeling, a process in which N-CAM is also involved but to a lesser extent. The substratum adhesion molecules, fibronectin and laminin, do not appear to play a primary role in the regulation of these processes but may participate in cell positioning and in the stabilization of the epithelial structures.     

Alterations of fibroblast interactions with fibronectin and laminin during chick embryo development

Eight day (8-d CEF) and 16 day old chick embryo fibroblasts (16-d CEF) obtained after a mild trypsin treatment (50 micrograms/ml in Ca2+ and Mg2+-free PBS, plus 10 mM EDTA) for 10 min at 37 degrees C present the same number of fibronectin (FN) binding sites at their surface (approximately 550,000 sites per cell) with a Kd approximately equal to 1.40 microM in both cases. Furthermore, FN interacted with high molecular weight plasma membrane proteins (150,000 and 125,000) insensitive to trypsin treatment. Both 8-d and 16-d CEF adhered and spread to the same extent on a fibronectin coated substratum (80% of the CEF adhered in 60 min). In contrast, 8-d and 16-d CEF behaved differently towards laminin (LM). 8-d CEF exhibited approximately 5500 binding sites per cell with a Kd of 1.5 nM (Codogno P., Doyennette, M.-A. and Aubery M., 1987, Experimental Cell Research, 169, 478-489.) and were highly sensitive to trypsin treatment, whereas 16-d CEF do not express cell surface binding sites for laminin. Differences were also observed in the adhesive capacities of 8-d and 16-d CEF on LM substrata: 8-d CEF adhered and spread on LM in a very specific manner (60% of the cells adhere in 60 min) and 16-d CEF did not adhere to LM even after long periods of incubation exceeding 360 min.     

CD14 major role during lipopolysaccharide-induced inflammation in chick embryo cardiomyocytes

CD14 is a surface differentiation antigen that functions as a receptor for bacterial lipopolysaccharide. The cellular signaling events that lead to lipopolysaccharide-induced production of inflammatory mediators are the primary cause of myocardial dysfunction observed in sepsis. Here, we evaluated the role of CD14 in chick embryo cardiomyocytes stimulated with lipopolysaccharide. CD14 expression was detected by confocal laser microscopy observation and by immunoblotting analysis. Moreover, we provided evidence for CD14-dependent functional responses of lipopolysaccharide-stimulated cardiomyocytes in terms of tumor necrosis factor (TNF)-alpha and nitric oxide (NO) production. Attenuated TNF-alpha and NO secretion, following anti-CD14 treatment of cardiomyocytes, suggested a role for this receptor in lipopolysaccharide-mediated cell responses. We also evidenced that labeled lipopolysaccharide was internalized and localized next to the Golgi complex, at the level of lysosomes, and in the perinuclear zone. The intracytoplasmatic transport seems to depend on the contractile apparatus, because cell pretreatment with cytochalasin D prevented lipopolysaccharide internalization and reduced both TNF-alpha and NO release. Lipopolysaccharide internalization was dependent on CD14 receptor, since anti-CD14 pre-treatment prevented endotoxin uptake by cardiomyocytes. Results demonstrated: (1) CD14 is expressed on the surface membrane of cardiomyocytes; (2) CD14 is involved in cytoskeletal dependent lipopolysaccharide internalization at specific cytoplasmatic locations; (3) CD14 plays a role in lipopolysaccharide-mediated responses by cardiomyocytes after lipopolysaccharide internalization.     

Researches on the formation of axial organs in the chick embryo. XI. Experimental investigations into the role of Hensen's node in somitogenesis

In order to obtain new data with respect to the role of the node area in somitogenesis and to its "individuality" and real regression, three experimental models were applied to 1-7 somite chick embryo 1) UV irradiation of the node area (in vitro); 2) subnodal transsection (in vitro and in ovo); 3) combination of the two interventions. The main results obtained were as follows: The UV irradiation of the node area in chick embryos of early somite stage (1-7 somites) prevents, by necrotizing the cell population of the irradiated zone, the further regression of the node. This result attests the existence of a real, distinct, node cell population and the real character of regression movement. The subnodal transsection of similar embryos of about 0.1-0.2 mm caudal of the node leads (as observed also by several other authors) to the development of a "tail", projecting into the hole formed after the intervention. The "tail" contains axial organs and results from an "autonomous" regression of the node area. The previous irradiation of the node area prevents the shaping of the "tail". In both experimental models, segmentation and somite differentiation is possible caudal of the stopped node area (with the development of median somite blocks) and on the edges of the hole, respectively. Thus the node seems not to be an absolute contributor--by its regression--to the determination (to the second morphogenetic "wave") of somitogenesis (Cooke and Zeeman, 1976; Bellairs, 1980). The arrest of the node area regression does not influence (during the developmental stages studied) the rate of somitogenesis in the anterior part of the segmental plate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Asymmetric distribution of PAR proteins in the mouse embryo begins at the 8-cell stage during compaction

In many organisms, like Caenorhabditis elegans and Drosophila melanogaster, establishment of spatial patterns and definition of cell fate are driven by the segregation of determinants in response to spatial cues, as early as oogenesis or fertilization. In these organisms, a family of conserved proteins, the PAR proteins, is involved in the asymmetric distribution of cytoplasmic determinants and in the control of asymmetric divisions. In the mouse embryo, it is only at the 8-cell stage during compaction that asymmetries, leading to cellular diversification and blastocyst morphogenesis, are first observed. However, it has been suggested that developmentally relevant asymmetries could be established already in the oocyte and during fertilization. This led us to study the PAR proteins during the early stages of mouse development. We observed that the homologues of the different members of the PAR/aPKC complex and PAR1 are expressed in the preimplantation mouse embryo. During the first embryonic cleavages, before compaction, PARD6b and EMK1 are observed on the spindle. The localization of these two proteins becomes asymmetric during compaction, when blastomeres flatten upon each other and polarize. PARD6b is targeted to the apical pole, whereas EMK1 is distributed along the baso-lateral domain. The targeting of EMK1 is dependent upon cell-cell interactions while the apical localization of PARD6b is independent of cell contacts. At the 16-cell stage, aPKCzeta colocalizes with PARD6b and a colocalization of the three proteins (PARD6b/PARD3/aPKCzeta can occur in blastocysts, only at tight junctions. This choreography suggests that proteins of the PAR family are involved in the setting up of blastomere polarity and blastocyst morphogenesis in the early mammalian embryo although the interactions between the different players differ from previously studied systems. Finally, they reinforce the idea that the first developmentally relevant asymmetries are set up during compaction.     

Researches on the formation of axial organs in the chick embryo. X. Further investigations on the role of ecto- and endoderm in somitogenesis

In continuation of previous experiments, recent results concerning the determinism of somitogenesis are reported. By means of two experimental devices on explanted chick embryos the influence upon mesoderm segmentation of the early removal of ectoderm (neural plate)--before and during the formation of the first somite pairs--and removal of endo- and ectoderm after 36-40 hours of incubation was investigated. Up to date results attest that during the shaping of the first somites no essential epigenetic interrelations between overlying ectoderm (neural plate) and paraxial mesoderm are necessary for segmentation. Just before the onset of segmentation a labile determination seems to be present in the presumptive somitogenic mesoderm. As to the later role of endo- and ectoderm in segmentation, present results reveal a relative independence of the segmentation process. The absence of the above-mentioned layers does not prevent further segmentation but induces a progressive slowing down of the process.     

A traction-based mechanism for somitogenesis in the chick

Summary This paper suggests that chick somites form because presomitic cells exert tractional forces on one another. These forces derive from the increase in cell adhesion and density that occurs as N-CAM and N-cadherin are laid down by the motile cells of the presomitic mesoderm, well before the somites form. Harris et al. (1984) have shown that adhesive and motile cells in an appropriate environment in vitro can spontaneously form aggregates under the influence of the tractional forces that they exert. Presomitic mesodermal cells may behave similarly: as CAM production increases local adhesivity, the tractional forces between the cells should become sufficiently strong for groups of cells to segment off the mesenchyme as somites. The successive expression of CAMs down the presomitic mesoderm will thus lead to the formation of an anterior-posterior sequence of somites. This mechanism can explain several aspects of somitogenesis that models generating a repetitive pre-pattern through gating cohorts of cells find hard to explain: first, mesodermal segregation occurs among highly adherent cells; second, that multiple rows of somites can form in embryos cultured on highly adherent substrata; third, that stirred mesoderm will still form normal somites; and, fourth, how somite size can be altered in heat-shocked embryos and elsewhere. Suggestions are given as to how the mechanism may be tested and where else in the embryo it could apply.     

Distribution of type IV collagen, laminin, and fibronectin during maxillary process formation in the chick embryo

The presence and distribution of laminin, type IV collagen, and fibronectin were analyzed in the facial primordia and developing primary palates of chick embryos from stages of development corresponding to maxillary process formation and primary palate closure. Frozen sections through the maxillary process and roof of the stomodeum were prepared for indirect immunofluorescence employing a biotin-avidin system using monoclonal antibodies against laminin, type IV collagen, and fibronectin. Light microscopic examination of sections stained with antibodies against type IV collagen revealed a much stronger fluorescent signal in the roof of the stomodeum than in the maxillary process at all stages examined. Regional differences in signal intensity and staining patterns were noted within the maxillary process; for example, the lateral surface of the maxillary process displayed a much less intense signal at most stages examined than the inferior and medial surfaces. The signal from sections of the maxillary process stained with laminin was much stronger than the signal from the same tissues stained with collagen. Regional differences in signal intensity within the maxillary process were minimal in sections stained with antibodies to laminin, in contrast to the differences seen in sections stained with antibodies to type IV collagen. Differences in signal intensity between the maxillary process and the roof of the stomodeum with laminin were slight. Sections stained with antibody to fibronectin displayed intense staining throughout the mesenchyme in both the maxillary process and the roof of the stomodeum. From comparison of the data of type IV collagen and laminin, the following hypothesis is proposed. In structures which undergo rapid change in form, such as the facial primordia, collagen distribution and/or organization is altered to a much greater extent than laminin, which is more uniformly distributed and which may be required for structural support of other developmentally regulated macromolecules. Where tissue morphology must be maintained, such as the roof of the stomodeum, the concentration and organization of type IV collagen is maintained in a manner that confers stability to these regions.     

Cell coherence during production of the presomitic mesoderm and somitogenesis in the mouse embryo

In this study, we investigated (in the early mouse embryo) the clonal properties of precursor cells which contribute to the segmented myotome, a structure derived from the somites. We used the laacZ method of single cell-labelling to visualise clones born before segmentation and bilateralisation. We found that clones which contribute to several segments both unilateral and bilateral were regionalised along the mediolateral axis and that their mediolateral position was maintained in successive adjacent segments. Furthermore, clones contributed to all segments, from their most anterior to their most posterior borders. Therefore, it appears that mediolateral regionalisation of myotomal precursor cells is a property established before bilateralisation of the presomitic mesoderm and that coherent clonal growth accompanies cell dispersion along both the mediolateral and anteroposterior axes. These findings in the mouse correlate well with what is known in the chick, suggesting conservation of the mode of production and distribution of the cells of the presomitic mesoderm. However, in addition, we also found that the mediolateral contribution of a clone is already determined in the pool of self-renewing cells that produces the myotomal precursor cells and thus that this pool is itself regionalised. Finally, we found that bilateral clones exhibit symmetry in right and left sides in the embryo at all levels of the mediolateral axis of the myotome. All these properties indicate synchrony and symmetry of formation of the presomitic mesoderm on both sides of the embryo leading to formation of a static embryonic structure with few cell movements. We suggest that sequential production of groups of cells with an identical clonal origin for both sides of the embryo from a single pool of self-renewing cells, coupled with acquisition of static cell behaviour, could play a role in colinearity of expression of Hox genes and in the segmentation system of higher vertebrates.     

Intracellular events are responsible for the differential expression of fibronectin on the fibroblast surface during chick embryo development

We previously showed that differences in the adhesive behaviour of fibroblasts obtained from 8-day-old (8-day CEF) and 16-day-old chick embryos (16-day CEF) were not due to alterations of cell surface fibronectin receptors. Herein we show that fibronectin (FN) was expressed more rapidly on the 8-day CEF surface (30 min) than on the 16-day CEF surface (60 min). In order to elucidate the mechanism responsible for these differences in the expression of cell surface FN we investigated the biosynthesis and the post-translational modifications of FN in 8- and 16-day CEF. Pulse-chase experiments revealed that FN was processed more slowly to an endo-beta-N-acetylglucosaminidase H (endo H)-resistant form in 16-day CEF than in 8-day CEF, whereas the kinetic of FN biosynthesis was similar in both cell populations. This difference was not related to a differential retention of FN in endoplasmic reticulum (ER) as determined after saponin-permeabilization. These results suggested that the rate-limiting step in the transport of FN to the cell surface in 16-day cells occurred between the ER and the medial part of the Golgi apparatus. It seems that the delay in the processing of endo H-resistant N-glycans was sufficient to account for differences between 8- and 16-day CEF in the rate of surface expression of FN and CEF adhesion to a plastic substratum.     

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.     

The role of mechanical forces in dextral rotation during cardiac looping in the chick embryo

Cardiac looping is a vital morphogenetic process that transforms the initially straight heart tube into a curved tube normally directed toward the right side of the embryo. While recent work has brought major advances in our understanding of the genetic and molecular pathways involved in looping, the biophysical mechanisms that drive this process have remained poorly understood. This paper examines the role of biomechanical forces in cardiac rotation during the initial stages of looping, when the heart bends and rotates into a c-shaped tube (c-looping). Embryonic chick hearts were subjected to mechanical and chemical perturbations, and tissue stress and strain were studied using dissection and fluorescent labeling, respectively. The results suggest that (1) the heart contains little or no intrinsic ability to rotate, as external forces exerted by the splanchnopleure (SPL) and the omphalomesenteric veins (OVs) drive rotation; (2) unbalanced forces in the omphalomesenteric veins play a role in left-right looping directionality; and (3) in addition to ventral bending and rightward rotation, the heart tube also bends slightly toward the right. The results of this study may help investigators searching for the link between gene expression and the mechanical processes that drive looping.     

Distribution and functional role of laminin during induction of the embryonic axis in the chick embryo

Laminin is a major glycoprotein of basement membranes and has been shown to promote cell adhesion, and movement of various nonepithelial cells and tumour cells. Using antibodies to laminin in paraffin sections and cultured embryos, we have studied the distribution of laminin and its involvement in the first morphogenetic events, beginning with the first extensive cellular migrations and interactions that result in the induction of the primitive streak (PS) and of the neural plate in the early chick embryo. Laminin immunogold labeling was not detected in the blastoderm at stage X. At stage XIII, laminin immunoreactivity was detected at the ventral surface of the epiblast and in the entire hypoblast. The intense labeling of the hypoblast indicated that these cells are active in laminin synthesis. Extracellular matrix (ECM) started accumulating as the first embryonic spaces were forming, before the morphogenetic movements of gastrulation were initiated. Immunogold labeling revealed a punctate pattern of laminin distribution in the ECM in the blastocoele, and in the space below the neural plate. Laminin, which is a multidomain molecule known to interact with other molecules of the ECM and with the cell surface, could serve as the scaffold for highly specific contact points of migrating cells and for the folding of epithelial sheets during this time in the developing embryo. We incubated blastoderms at stages X and XIII with laminin antibodies (1:30 dilution) for 4 h, then cultured the blastoderms further in plain egg albumin. The laminin antibodies did not interfere with triggering of PS cell movements, but perturbed the normal migration pattern of these cells. A normal PS did not form and, as a consequence, the embryonic axis was not induced.(ABSTRACT TRUNCATED AT 250 WORDS)     

Uncoupling segmentation and somitogenesis in the chick presomitic mesoderm

Little is known about the tissue interactions and the molecular signals implicated in the sequence of events leading to the subdivision of the somite into its rostral and caudal compartments. It has been demonstrated that rostrocaudal identity of the sclerotome is acquired at the presomitic (PSM) level. However, it is not known whether this compartment specification is fully determined in the PSM or whether it is dependent upon maintenance cues from the surrounding environment, as is the case for somite epithelialization. In this report, we address this issue by examining the expression profiles of C-Delta-1 and C-Notch-1, the avian homologues of mouse Delta-like1 (Delta1) and Notch1 which have been implicated in the specification of the somite rostrocaudal polarity in mouse. In chick, these genes are expressed in distinct but partially overlapping domains in the PSM and subsequently in the caudal regions of the somites. We have used an in vitro assay that consists of culturing PSM explants to examine the regulation of these genes in this tissue. We find that PSM explants cultured without overlying ectoderm continue to lay down stripes of C-Delta-1 expression, although epithelialization is blocked. These results suggest that somite rostrocaudal patterning is an autonomous property of the PSM. In addition, they demonstrate that segmentation is not necessarily coupled with the formation of somites. Dev. Genet. 23:77–85, 1998. © 1998 Wiley-Liss, Inc.