Vitronectin and thrombospondin promote retinal neurite outgrowth: developmental regulation and role of integrins.

Extracellular matrix (ECM) glycoproteins regulate neuronal development and axonal growth. In this paper, the ECM glycoprotein vitronectin was identified and localized in the embryonic chick neuroretina. To identify potentially important neurite outgrowth-promoting molecules, responses of embryonic chick retinal neurons to vitronectin and thrombospondin, another retinal ECM constituent, were examined. These neurons were shown to attach and extend neurites on either glycoprotein. Integrins containing the alpha v or beta 1 subunits mediate both responses to vitronectin and neurite outgrowth on thrombospondin. Attachment to thrombospondin was inhibited by heparin, suggesting that neurons also utilize a proteoglycan or sulfated glycolipid as a receptor for this glycoprotein. Thus, retinal neurons use specific receptors to interact with vitronectin and thrombospondin, two glycoproteins present in the embryonic neuroretina, suggesting roles for these ligands and their receptors in retinal development.     

Histogenesis of the semilunar valves: an immunohistochemical analysis of tenascin and type-I collagen distribution in developing chick heart valves

Summary The development of the semilunar valves takes place in association with septation of the outflow tract in the embryonic heart. Although numerous studies have focused on this process, the causal mechanisms of valvular development remain obscure. This paper reports an immunohistochemical analysis of tenascin and type-I collagen distribution in developing chick heart valves. Tenascin is a glycoprotein that is present on some embryonic extracellular matrices. It plays several significant roles in tissue differentiation, cell growth, and tissue interactions; it is also important for the formation of specific zones of connective tissue that fulfill mechanical functions. Our results show that tenascin is present during valvular morphogenesis and histogenesis, and that its distribution is associated with zones specialized in bearing mechanical loads.     

Effects of taxol on endothelial cells of the developing semilunar heart valves in the chick embryo

Recent ultrastructural studies have revealed that there are differences in endothelial cell shape and cytoskeletal architecture between the arterial and ventricular faces of developing semilunar valves. In the present work we have analyzed valvular endothelial cell response to taxol in the chick embryo. Following taxol administration, abnormal mitotic cells appear in the endothelium of both faces of the cusps. Interphase cells show few structural alterations. No differential response of the valvular endothelium to the drug was observed in the arterial or ventricular faces of the cusps.     

Extracellular matrix organized in embryonic cavities during induction of the embryonic axis in chick embryo

Extracellular matrix (ECM) is detected as short, disorganized fibrils in the forming embryonic extracellular spaces shortly prior to the first morphogenetic cellular movements and interactions in the early chick embryo. As development progresses, the ECM is organized into an intricate network spanning the embryonic cavities. This dynamic entity undergoes relatively rapid changes in its organization pattern during the developmental period from morula to the induction of the neural plate. The ECM seems to preserve the exquisite architecture of the embryo and could guide migrating cells into defined pathways in the early embryo.     

The extracellular matrix of normal chick embryo fibroblasts: its effect on transformed chick fibroblasts and its proteolytic degradation by the transformants

Extracellular matrix (ECM), prepared from chick embryo fibroblasts, contains fibronectin as the major structural protein along with collagen and other polypeptides as less abundant protein components. When Rous sarcoma virus-transformed chick embryo fibroblasts are cultured on the ECM in the presence of the tumor promoter tetradecanoyl phorbol acetate, the transformed cells lose their characteristic rounded morphology and align on and within the ECM fibrillar network. This restrictive aspect of ECM is only temporary, however, and with time (24-72 h) the transformed cells progressively degrade the ECM fibers and resume their rounded appearance. The matrix degradation can be monitored by employing biosynthetically radiolabeled ECM. The addition of purified chicken plasminogen to the Rous sarcoma virus- transformed chick embryo fibroblast cultures enhances the rate and extent of ECM degradation, due to the elevated levels in the transformed cultures of plasminogen activator. Plasminogen-dependent and -independent degradation of ECM has been characterized with regard to sensitivity to various natural and synthetic protease inhibitors and to the requirement of cell/ECM contact. Plasminogen-dependent degradation of ECM occurs rapidly when ECM and cells are in contact or separated, whereas plasminogen-independent degradation is greatly reduced when ECM and cells are separated, which suggests that cell surface-associated proteolytic enzymes are involved. A possible role in ECM degradation has been indicated for cysteine proteases, metallo enzymes, and plasminogen activator, the latter as both a zymogen activator and a direct catalytic mediator.     

Effects of colchicine administration on the endothelial cells of the developing semilunar heart valves of the chick embryo

Summary Recent ultrastructural studies have revealed that differences exist in endothelial cell shape and cytoskeletal architecture between the arterial and ventricular faces of developing semilunar valves. In the present work we analyzed the morphologic response of the valvular endothelial cells of chick embryos to colchicine by light microscopy, scanning electron microscopy and transmission electron microscopy. The results show that colchicine administration during the stages of valve morphogenesis causes a very conspicuous disruption of the endothelial layer of the arterial face of the valves. The cells appear rounded and show massive surface blebbing. These alterations were not present in the endothelial cells on the ventricular face of the valves at the same stages. On the basis of these results we suggest that a difference in the degree of cell differentiation exists between the endothelial cells of the arterial and ventricular faces of the cusps and that this difference may have morphogenetic significance.     

N-glycosylated proteins interfere with the first cellular migrations in early chick embryo.

Cell adhesion and migration properties which are known to play a crucial role in developmental events seem to be modulated by variations in glycosylation of glycoproteins. In the chick embryo, the extracellular matrix (ECM) appears as a loose meshwork of fibrillar material in the space between the epiblast and the hypoblast shortly before the first major cell migrations start. Chick embryos treated with tunicamycin (TN), a specific inhibitor of N-linked glycosylation of proteins, show little or no ECM, diminished cell adhesion and a dramatic alteration in the architecture of the epiblast and of the hypoblast. The first major cell migrations which signal the onset of PS and gastrula formation are inhibited irreversibly in these embryos. Tunicamycin induces a substantial change in the labeling pattern with change in mobility of some polypeptides and with the induction or marked accentuation of multiple charged species (isoforms) of polypeptides different from these already present in the control blastoderm. The N-linked glycosylation of protein(s) that are synthesized during the interaction of the epiblast and of the hypoblast seem to play a critical role in cell adhesion and in the morphogenetic movements of gastrulation in the early chick embryo.     

Appearance and distribution of entactin in the early chick embryo

Abstract. Entactin is a sulfated glycoprotein of basement membranes and recent data indicate that it may play a major role in extracellular matrix (ECM) assembly and in modulating the activities of the other molecular components. We investigated the time of appearance and subsequent distribution of entactin during the earliest stages of morphogenesis and its involvement in the first major cellular migrations and interactions in the chick embryo. Entactin is first detected in the epiblast and in the hypoblast at the blastula stage. The accumulating ECM displays intense presence of entactin in the space between the epiblast and the hypoblast at late blastula. Entactin is increasingly abundant in the neural plate and in the ECM and also at least transiently in many mesodermal tissues such as the notochord, the developing heart and somites in the early chick embryo. Immuno-gold labeling revealed a punctate pattern of entactin distribution in the ECM during the gastrula, neurula and at later stages and at all levels within the embryo. Because of its early appearance in more than one germ layer, entactin may be important in the formation of most embryonic structures. Entactin is detected at the same developmental time and co-localizes with laminin. Antibodies to entactin do not interfere with triggering of the first major cell movements but perturb directional migration of these cells. It would seem that entactin plays a functional role in the directed migration of cells and does not seem to affect cell adhesion during the period of the first morphogenetic events in the early chick embryo.     

Appearance and distribution of entactin in the early chick embryo

Abstract. Entactin is a sulfated glycoprotein of basement membranes and recent data indicate that it may play a major role in extracellular matrix (ECM) assembly and in modulating the activities of the other molecular components. We investigated the time of appearance and subsequent distribution of entactin during the earliest stages of morphogenesis and its involvement in the first major cellular migrations and interactions in the chick embryo. Entactin is first detected in the epiblast and in the hypoblast at the blastula stage. The accumulating ECM displays intense presence of entactin in the space between the epiblast and the hypoblast at late blastula. Entactin is increasingly abundant in the neural plate and in the ECM and also at least transiently in many mesodermal tissues such as the notochord, the developing heart and somites in the early chick embryo. Immunogold labeling revealed a punctate pattern of entactin distribution in the ECM during the gastrula, neurula and at later stages and at all levels within the embryo. Because of its early appearance in more than one germ layer, entactin may be important in the formation of most embryonic structures. Entactin is detected at the same developmental time and co-localizes with laminin. Antibodies to entactin do not interfere with triggering of the first major cell movements but perturb directional migration of these cells. It would seem that entactin plays a functional role in the directed migration of cells and does not seem to affect cell adhesion during the period of the first morphogenetic events in the early chick embryo.     

Localization and somatotopy of sensory cells innervating the extraocular muscles of lamb, pig and cat. Histochemical and electrophysiological investigation

The localization of sensory cells innervating the extraocular muscles (EOMs) was studied in the lamb, pig and cat in which horseradish peroxidase (HRP) was injected into each EOM. Electrophysiological techniques were also used to search for EOM stretch sensitive units in the semilunar ganglion. In lamb and pig labeling was observed in the semilunar ganglion only, while in cat labeled neurons were present in both the semilunar ganglion and mesencephalic trigeminal nucleus. In the semilunar ganglion of all these species a clear somatotopic organization of EOM afferents was observed. The histochemical somatotopic pattern of EOM afferents in the semilunar ganglion of lamb and pig was substantially in agreement with the electrophysiological arrangement. The responses recorded to EOM stretch in the semilunar ganglion of the pig were characterized by a low threshold and a slow adaptation as previously found in the lamb; on the contrary, in the semilunar ganglion of the cat only a few units were found, which showed high stretch threshold and quick adaptation.     

Monensin inhibits the first cellular movements in early chick embryo

Summary In early chick blastoderm at stage XIII, the interaction of the hypoblast with the epiblast triggers on the epiblast the first extensive cellular migrations, which result in formation of the primitive streak, the source of the axial mesoderm. During this period, extracellular material (ECM) is secreted and assembled into an organized network in the extracellular spaces and is implicated in regulating the behaviour of the cells that contact it. The first cellular migrations and inductions are inhibited when early chick blastoderm is treated with the glycosylation-perturbing ionophore monensin. The difference in amount and in organization of ECM between monensin-treated embryos and control embryos is striking. Even blastoderms at stage X, which are essentially free of ECM, show extensive ECM after monensin treatment. Monensin produces a substantial change in the polypeptide pattern with the induction or marked accentuation of multiple charged species (isoforms) of polypeptides different from those present in the control embryos. The interference of monensin with the migration and induction mechanisms is permanent in embryos before the primitive streak (PS) stage, and it seems that the respective signals or the sensitivity of the epiblast/hypoblast cells to them must be very stage specific. Monensin-treated embryos probably secrete abnormal ECM that does not provide the proper conditions for the hypoblast to interact with the epiblast cells.     

Patterns of expression of a 15K beta-D-galactoside-specific lectin during early development of the avian embryo

We have determined, by immunohistochemical and biochemical techniques, the distribution of an endogenous beta-D-galactoside-binding lectin between the early primitive streak stage and the 5th day of embryonic development of the chick.The lectin, which was purified from the pectoral muscle of 16-day-old chick embryos, migrates on SDS-PAGE as a single polypeptide of relative molecular mass 15 x 10(3). Antibodies to this pure lectin interact with the 15K (K = 10(3) M(r)) polypeptide as well as with a 6.5K polypeptide; this second component appears to be antigenically related to the 15K lectin, as antibodies affinity purified on the 15K band recognize both polypeptides. In early stages of development, lectin immunoreactivity was present in most cells of the epiblast and hypoblast in the region of the primitive streak, while towards the edge of the area pellucida the epiblast was stained less intensely. During gastrulation, strong immunoreactivity was present also in migrating cells and in the mesoblast, while at the margin of the area pellucida the epiblast was negative. Up to the 10-somite stage, lectin immunoreactivity was present in the somites, neural tube and presumptive cardiac region; the non-neural ectoderm and the extracellular matrix were not labeled; the predominant immunoreactive component at this stage of development was the 6.5K polypeptide. Later in development, the lectin immunoreactivity gradually disappeared from the dermamyotome and nervous system to reappear conspicuously as soon as a differentiated myotome could be detected. Immunoreactivity was very high in the myotome, skeletal and cardiac muscles and transient in smooth muscles. The only region of the nervous system that continued to express the lectin throughout development was the trigeminal (semilunar) ganglion; in all regions of the nervous system, the lectin immunoreactivity disappeared early in development to be re-expressed only much later. The lining epithelium of the digestive tract and other endodermal derivatives expressed the lectin transiently. In the extraembryonic membranes, immunoreactivity to the lectin was observed in the yolk sac and in both layers of the amnion. The striking regulation of the expression of this endogenous lectin suggests that its functions are linked to cell proliferation and/or to the selective expression of a developmentally-timed cell phenotype.     

Localization of extracellular matrix receptors on the chondrocyte primary cilium.

A single primary cilium is found in chondrocytes and other connective tissue cells. We have previously shown that extracellular matrix (ECM) macromolecules such as collagen fibers closely associate with chondrocyte primary cilia, and their points of contact are characterized by electron-opaque plaques suggesting a direct link between the ECM and the cilium. This study examines the expression of receptors for ECM molecules on chondrocyte primary cilia. Embryonic chick sterna were fluorescently labeled with antibodies against alpha and beta integrins, NG2, CD44, and annexin V. Primary cilia were labeled using acetylated alpha-tubulin antibody. Expression of ECM receptors was examined on chondrocyte plasma membranes and their primary cilia using immunofluorescence and confocal microscopy. All receptors examined showed a punctate distribution on the plasma membrane. alpha2, alpha3, and beta1 integrins and NG2 were also present on primary cilia, whereas annexin V and CD44 were excluded. The number of receptor-positive cilia varied from 8/50 for NG2 to 43/50 for beta1 integrin. This is the first study to demonstrate the expression of integrins and NG2 on chondrocyte primary cilia. The data strongly suggest that chondrocyte primary cilia have the necessary machinery to act as mechanosensors, linking the ECM to cytoplasmic organelles responsible for matrix production and secretion.     

Development of extracellular matrix in chick paravertebral sympathetic ganglia

Alcian blue staining coupled with enzyme digestion or critical electrolyte staining revealed differences in the development of extracellular matrix (ECM) within sympathetic ganglia compared with the surrounding capsule. On day 5 of chick development (Hamburger-Hamilton stage 26) only hyaluronic acid (HA) could be detected in the ECM surrounding condensing primary ganglia. By day 7 (st 30) the ganglionic capsule contained HA, as well as sulfated glycosaminoglycans (GAGs), and this pattern continued into the adult stage. During the later stages of embryonic life (st 41-45) satellite cells appear, showing fine structural characteristics that point to their role in the secretion of intraganglionic ECM. Only during these stages could ECM be detected histochemically within ganglia, the same stages (days 15-19) when routine electron microscopic methods reveal collagen fibrils embedded in a granular ground substance. Thus, the intraganglionic environment appears as a separate compartment free of detectable amounts of GAG until late embryonic stages when ECM is secreted around satellite cells. This developmental pattern could represent a role of ECM in the histological stabilization of ganglia during the late stages of differentiation, since the appearance of intraganglionic ECM is correlated with the appearance of small dense-cored vesicles characteristic of adult neurons. The developmental pattern of ECM in differentiating sympathetic ganglia is compared with that of other tissues that undergo condensation and morphogenesis.     

An amino-terminal extension is required for the secretion of chick agrin and its binding to extracellular matrix

Agrin is an extracellular matrix (ECM) protein with a calculated relative molecular mass of more than 200 kD that induces the aggregation of acetylcholine receptors (AChRs) at the neuromuscular junction. This activity has been mapped to its COOH terminus. In an attempt to identify the functions of the NH2-terminal end, we have now characterized full-length chick agrin. We show that chick agrin encoded by a previously described cDNA is not secreted from transfected cells. Secretion is achieved with a construct that includes an additional 350 bp derived from the 5' end of chick agrin mRNA. Recombinant agrin is a heparan sulfate proteoglycan (HSPG) of more than 400 kD with glycosaminoglycan side chains attached only to the NH2-terminal half. Endogenous agrin in tissue homogenates also has an apparent molecular mass of > 400 kD. While the amino acid sequence encoded by the 350-bp extension has no homology to published rat agrin, it includes a stretch of 15 amino acids that is 80% identical to a previously identified bovine HSPG. The extension is required for binding of agrin to ECM. AChR aggregates induced by recombinant agrin that includes the extension are considerably smaller than those induced by agrin fragments, suggesting that binding of agrin to ECM modulates the size of receptor clusters. In addition, we found a site encoding seven amino acids at the NH2-terminal end of agrin that is alternatively spliced. While motor neurons express the splice variant with the seven amino acid long insert, muscle cells mainly synthesize isoforms that lack this insert. In conclusion, the cDNAs described here code for chick agrin that has all the characteristics previously allocated to endogenous agrin.     

Versican expression during synovial joint morphogenesis

The extracellular matrix (ECM) plays a critical role in governing cell behavior and phenotype during limb skeletogenesis. Chondroitin sulfate proteoglycans (Cspgs) are highly expressed in the ECM of precartilage mesenchymal condensations and are important to limb chondrogenesis and cartilage structure, but little is known regarding their involvement in formation of synovial joints in the embryonic limb. Matrix versican Cspg expression has previously been reported in the epiphysis of developing long bones and presumptive joint; however, detailed analysis has not yet been conducted. In the present study we immunolocalized versican and aggrecan Cspgs during chick elbow joint morphogenesis between HH st25-41 of development. In this study we show that versican and aggrecan expression initially overlapped in the incipient cartilage model of long bones in the wing, but versican was also highly expressed in the perichondrium and presumptive joint interzone during early stages of morphogenesis (HH st25-34). By HH st36-41 versican localization was restricted to the future articular surfaces of the developing joint and surrounding joint capsule while aggrecan localized in an immediately adjacent and predominately non-overlapping region of chondrogenic cells at the epiphyses. These results suggest a potential role for versican proteoglycan in development and maintenance of the synovial joint interzone.     

Butyric acid causes morphological changes in cultured chondrocytes through alterations in the extracellular matrix

Butyric acid induces characteristic changes in the morphology of chick embryo chondrocytes. Chick embryo chondrocytes when cultured in the absence of butyrate exhibit a spherical morphology and synthesize cartilage-specific chondroitin sulfate proteoglycan (CSPG). When these cultures are initiated and maintained in the presence of butyric acid, chondrocytes exhibit a mesenchymal morphology, a 90% reduction in the synthesis of CSPG, and a 75% reduction in DNA synthesis. The reduced synthesis of CSPG and DNA was shown not to be dependent on the morphological change. Chondrocytes require CSPG in order to express a spherical morphology, since including chondroitinase ABC in the culture media caused the cells to spread. In addition, the treatment of chondrocytes with purified CSPG prior to culture in media containing butyric acid resulted in spherical cells. The butyrate-induced spreading was shown to require either serum or fibronectin and could be prevented with antiserum against chick cell-surface fibronectin (cFn). Cell-surface fibronectin, which was present on both spherical and flattened chondrocytes, organized into fibrils beneath cells which spread. Increased fibronectin synthesis was not responsible for the butyrate-induced morphological change. From this evidence, it is concluded that the mechanism by which butyrate alters the morphology of these cells in culture involves inhibiting CSPG synthesis, thus preventing CSPG accumulation in the extracellular matrix (ECM). The absence of CSPG in the ECM allows fibronectin to mediate spreading of chondrocytes in culture.     

Effects of extracellular matrix components on the differentiation of chick embryo tail bud mesenchyme in culture

The mesenchymal cells of the chick tail bud comprise the remains of Hensen's node and the primitive streak after gastrulation. This mass of cells, situated at the caudal limit of the chick embryo, is morphologically homogeneous but pluripotent, with the ability to differentiate into a variety of tissues that are both ectoderm- and mesoderm-derived elsewhere in the embryo. These tissues include neuroectoderm, neurons, myoblasts and chondrocytes. As the factors regulating the differentiation of tail bud mesenchyme into so many cell types are unclear, and because the extracellular matrix (ECM) is known to have a profound effect on cellular differentiation in many embryonic systems, we studied the differentiation of tail bud mesenchyme explanted onto a variety of different ECM components as substrata. We report that the histogenetic potential of isolated tail buds in culture compares favourably with that in situ. Using various antibody markers, we have demonstrated that tail bud mesenchyme cultured upon different ECM components as substrata is able to differentiate into neurons, neuroepithelium, melanocytes, muscle and cartilage. Laminin and laminin-containing substrata (Matrigel) were found to promote the differentiation of neural crest derivatives (neurons and melanocytes) and neuroepithelial cells; type I collagen promoted both myogenesis and chondrogenesis; while type IV collagen promoted myogenesis only. We have therefore demonstrated that differentiation of tail bud mesenchyme in vitro is substratum-dependent.     

Cell interaction with the extracellular matrices produced by endothelial cells and fibroblasts

The extracellular matrices (ECM) produced by cultured bovine corneal endothelial cells and chick embryo fibroblasts were compared for their induction of cell attachment, proliferation and differentiation. The corneal endothelial ECM (cECM) induced a comparable and rapid attachment and flattening of both human Ewing's sarcoma and colon carcinoma cells which utilize fibronectin and laminin as adhesive glycoproteins, respectively. In contrast, the ECM produced by fibroblasts (fECM) readily supported the attachment and flattening of Ewing's sarcoma cells but had only a small effect on the carcinoma cells. Vascular endothelial cells were stimulated to proliferate by both types of matrices, but to a lesser extent by the fECM. In contrast, the formation of a closely apposed, non-overlapping and contact-inhibited endothelial cell monolayer was only dictated by the cECM. Vascular endothelial cells cultured on fECM grew on top of each other and incorporated [3H]thymidine even late at confluency. Neurite outgrowth (ciliary ganglion cells) and network formation (adult rat oligodendrocytes) were promoted by both types of matrices but in a more consistent manner with the cECM. It is likely that the small amounts of laminin deposited by chick embryo fibroblasts into their ECM are responsible for its efficient induction of neurite outgrowth and for the limited degree of carcinoma cell attachment and flattening. It is thus demonstrated that differences in chemical composition and supramolecular arrangement between cECM and fECM result not only in differences in the attachment, spreading and proliferative responses of cells but also in the expression of their characteristic morphological appearance and differentiated functions.     

Extracellular matrix assembly and 3D organization during paraxial mesoderm development in the chick embryo

The extracellular matrix (ECM) is a major player in the microenvironment governing morphogenesis. However, much is yet to be known about how matrix composition and architecture changes as it influences major morphogenetic events. Here we performed a detailed, 3D analysis of the distribution of two ECM components, fibronectin and laminin, during the development of the chick paraxial mesoderm. By resorting to whole mount double immunofluorescence and confocal microscopy, we generated a detailed 3D map of the two ECM components, revealing their supra-cellular architecture in vivo, while simultaneously retaining high resolution cellular detail. We show that fibronectin assembly occurs at the surface of the presomitic mesoderm (PSM), where a gradual increase in the complexity of the fibronectin matrix accompanies PSM maturation. In the rostral PSM, where somites form, fibronectin fibrils are thick and densely packed and some occupy the cleft which comes to separate the newly formed somite from the PSM. Our 3D approach revealed that laminin matrix assembly starts at the PSM surface as small dispersed patches, which are always localized closer to cells than the fibronectin matrix. These patches gradually grow and coalesce with neighboring patches, but do not generate a continuous laminin sheet, not even on epithelial somites and dermomyotome, suggesting that these epithelia develop in contact with a fenestrated laminin matrix. Unexpectedly, as the somite differentiates, its fibronectin and laminin matrices are maintained, thus initially containing both the epithelial dermomyotome and the mesenchymal sclerotome within the somite segment. Our analysis provides unprecedented details of the progressive in vivo assembly and 3D architecture of fibronectin and laminin matrices during paraxial mesoderm development. These data are consistent with the hypothesis that progressive ECM assembly and subsequent 3D organization are active driving and containing forces during tissue development.