Properties of extracellular adhesion-mediating particles in myoblast clone and its adhesion-deficient variant

NCAM-mediated adhesion of transfected cells to agrin

The vertebrate neural cell adhesion molecule NCAM mediates heterophilic adhesion to heparan sulfate proteoglycans in embryonic chick brain membranes. In this study, mouse L cells transfected with chicken NCAM were used to identify two of these ligands as agrin and the target of the 6C4 monoclonal antibody. A third heparan sulfate proteoglycan, perlecan, appeared not to support NCAM-mediated adhesion. Enzymatic degradation of chondroitin sulfates decreased adhesion in agrin-containing membrane fractions but increased adhesion if the agrin had previously been removed by immunoprecipitation, suggesting that interactions between heparan sulfate and chondroitin sulfate proteoglycans have important influences on adhesion. Our experiments support the view that NCAM can interact with multiple, but not with all, heparan sulfate and chondroitin sulfate proteoglycans in chick brain membranes in both positive and negative ways to influence cell adhesion.

Release of cell surface proteoglycans from differentiating colon cells proceeds by cleavage of lipophilic anchor peptides

Heparan sulphate proteoglycans are rapidly released from VACO 10MS colon cancer cells that are triggered with phorbol esters to undergo terminal differentiation. This lag-free temperature-sensitive process is correlated with a conversion of the lipophilic proteoglycans of the cell surface into non-lipophilic proteoglycans that accumulate in the culture medium. The released proteoglycans are very similar to their lipophilic precursors in size, buoyant density and glycosaminoglycan characteristics; however, they exhibit slightly smaller core proteins after chemical and enzymic deglycosylation. The lipophilicity of the larger-sized core proteins of the cell-associated proteoglycans is also correlated with the presence of an easily iodinatable domain; this domain is missing in the released proteoglycans. Exogenous proteases (i.e. chymotrypsin, V8, trypsin and proteinase K) readily cleave this segment from the larger protease-resistant region of the proteoglycan structure. It is also released intact by treatment of the isolated proteoglycans with methanolic HCl. This component appears to be peptide in character, in that proteases readily degrade it and release iodotyrosines when the precursor has been iodinated. No evidence for the presence of covalently attached fatty acids in the cell-associated proteoglycans was found. These results are consistent with the hypothesis that the altered proteoglycan metabolism that is associated with the phorbol-ester-induced terminal differentiation of certain human colon cancer cells ensues upon the activation of a membrane-localized protease that cleaves a lipophilic anchor segment from the cell surface proteoglycans.

Induction of an epithelial-mesenchymal transition by an in vivo adheron-like complex

The embryonic vertebrate heart consists of two epithelia: the myocardium and endothelium, separated by the myocardial basement membrane (MBM). The myocardium has been shown to induce endothelial transformation into prevalvular mesenchyme in a temporally and site restricted manner. Previously, we hypothesized that the myocardial-endothelial interaction is mediated in vivo by aggregates of 30-nm particles in the MBM which can be removed by EDTA extraction. These MBM extracts contain fibronectin and other lower Mr proteins and can initiate an epithelial-mesenchymal transition in the AV (atrioventricular canal) endothelium of embryonic chick heart in collagen gel culture. These and other data suggested that the 30-nm multicomponent particles are similar, structurally and compositionally, to multimolecular complexes, termed adherons, secreted by L6 muscle cells in culture. The purpose of this study was to (1) test whether the removal of the 30-nm particles from MBM extracts of embryonic chick hearts would remove the in vitro biological activity and (2) determine if the fractionated MBM extracts can cause AV endothelial cells to follow the same differentiation pathway observed in vivo by monitoring immunohistochemically the cell surface expression of N-CAM. Results showed that centrifugation of extract at 100,000g for 1 hr produced a supernatant fraction that was unable to initiate mesenchyme formation from AV endothelium. However, the resuspended pellet fraction did initiate differentiation of endothelium into mesenchyme. Conditioned medium from L6 skeletal muscle cultures could not substitute for the EDTA extract of embryonic heart. Endothelial cells undergoing the transition to form mesenchyme, both in vivo and in vitro, showed a concomitant decrease in N-CAM staining. This suggested that the pellet-induced formation of migrating cells in the collagen gels is not the result a novel in vitro phenomenon.

Specific configurations of fibronectin-containing particles correlate with pathways taken by neural crest cells at two axial levels

Although neural crest (NC) cells can potentially enter a number of intertissue spaces, they select a particular pathway that varies depending on the axial level. In the cranial region, NC cells enter the dorsal-lateral pathway (i.e., immediately subjacent to the ectoderm) and avoid the ventral pathway (i.e., pathway between the mesoderm and neural tube and within the mesodermal cell population), whereas in the trunk region, the majority of the NC cells enter the ventral pathway (i.e., between the somite and neural tube) and not the dorsal-lateral pathway. Our working hypothesis is that one determining factor in directing NC cell migration is the composition and/or intermolecular associations of the extracellular matrix (ECM) in these pathways. Histochemical staining, immunostaining, and lectin-binding studies on cryofixed and conventionally fixed tissue were conducted to initially characterize the ECM found in potential NC cell pathways prior to and during initial NC cell migration at two different axial levels. We found that, regardless of the axial level, the pathways into which NC cells eventually enter possessed a characteristic ECM arrangement. This arrangement included: 1) the presence of multicomponent, glycoprotein-containing spherical particles (0.1-0.5 micron in diameter); and 2) a low-sulfated ECM content. Although all particles contained fibronectin, only those in specific regions were able to bind to a monoclonal antibody directed to the cell-binding domain of fibronectin, suggesting that the conformation of fibronectin may be important in the expression of any in situ function of the molecule.

Prostaglandin binding does not require direct cell-cell contact during chick myogenesis in vitro

Myogenic differentiation in vitro involves at least three events at the cell surface: binding of prostaglandin to the cells, contact-mediated cell-cell recognition, and fusion of the myoblast membranes into myotubes. While the earlier events are thought to be necessary for subsequent fusion, the sequence of events has not been determined. A major impediment to determining the initial event has been the lack of synchrony of cell differentiation in vitro. To overcome this, we cultured chick embryo myoblasts as a suspension of single cells in gyratory rotation in medium without added Ca2+. Under these conditions, myoblasts exhibited characteristic prostaglandin binding at 34 h. Within 30 min, the cells began to aggregate. Because this occurred without change of medium or conditions of rotation, we termed the process autoaggregation. Within 8-10 h. cells within these autoaggregates began to fuse into syncytia. These results suggest that an early cell surface event in embryonic myogenesis is the characteristic binding of prostaglandin to the myoblasts. The results demonstrate that this binding precedes any direct cell-cell contact and suggest that it causes the subsequent change in myoblast cell-cell adhesion.

Myocardial specificity for initiating endothelial-mesenchymal cell transition in embryonic chick heart correlates with a particulate distribution of fibronectin

The early chick heart tube consists of myocardium and endothelium separated by a myocardially derived basement membrane (MBM). As development proceeds, the endothelium undergoes a transition into mesenchyme in a regionally specific manner; only the atrioventricular (AV) and outflow tract, but not the ventricular endothelium, is transformed into mesenchyme, the progenitor of heart septa and valves. Recent experiments have shown that an EDTA extract of MBM can initiate AV endothelium to form mesenchyme in an in vitro collagen gel culture system. Two-dimensional gel electrophoresis of AV region EDTA extracts showed potentially three isoelectric forms of fibronectin (Fn), while extracts from ventricle contained only two forms. The purpose of the present study was to further investigate the significance of these regional differences by testing of specific myocardial regions (AV vs ventricle) for their ability to induce endothelium to form mesenchyme in vitro, and to immunohistochemically determine if a regionally specific distribution of Fn exists in the MBM that can be correlated with previous electrophoretic data. Embryonic heart regions cultured on three-dimensional collagen gels showed that AV endothelium could only form mesenchyme if cocultured with AV myocardium. Coculture with ventricular myocardial explants did not initiate differentiation of AV endothelium. In contrast, ventricular endothelial cells did not form mesenchyme when cocultured with AV or ventricle myocardium. Immunohistochemical localization of Fn revealed three distinct morphological patterns of distribution in the AV-MBM, i.e., an intense lamina densa staining, diffuse staining in fibrils, and as particles. The Fn localized in particles (0.1 to 0.5 micron in diameter) appeared as a gradient of decreasing concentration extending from the myocardium toward the endothelium. In contrast, no particulate Fn staining was observed in the ventricular region. EDTA extraction selectively depleted the particulate form of Fn. Previous work has shown that this extract, which contains several lower Mr proteins in addition to Fn, is biologically active in initiating mesenchyme formation from AV endothelium in vitro. These results show that a regionally specific interaction of the myocardium with the endothelium is required to initiate the formation of prevalvular mesenchyme. This interaction may be mediated by a multicomponent complex involving Fn and other proteins which appear as a regionally distinct particulate only in areas of endothelial differentiation.

Genetic programming of development: a model

Genetic programming of the developmental processes in multicellular organisms is proposed to be so intricate and vitally important that a large set of genes is dedicated solely to this end. It is further proposed that this set can be compartmentalized into subsets on the basis of the changes in gene activities that occur during ontogenesis, and that the genes in each subset transiently control the epigenetic activities of a small group of cells. Automatic subset activation is achieved by the product of a gene in each subset that transfers activity specifically to the subset next in the developmental sequence. This device can generate a unidirectional series of activations that cascade hierarchically through development like toppling dominoes. The model provides a basis for developmental phenomena, such as pattern formation, morphogenesis, and regeneration, and it makes testable predictions at the molecular level.

Isolation and partial characterization of endothelial cell extracellular complexes

Human endothelial cells release components into the growth medium that stimulate cell-substratum adhesion. Several macromolecular components were isolated by ultracentrifugation of the endothelial cell conditioned medium. The components were heterogeneous, consisting of several sizes when examined by sedimentation velocity and gel filtration. When the extracellular components were evaluated by electron microscopy, structurally discrete particles were observed. The extracellular components and the complexes mediated cell-substratum adhesion to both human umbilical and arterial endothelial cells. The majority of the extracellular components that promote endothelial cell adhesion were pelleted by ultracentrifugation. Although the complexes contained fibronectin, antibodies to fibronectin did not inhibit cell adhesion to the complexes. Significant inhibition of endothelial cell adhesion was observed in the presence of heparin and heparan sulfate. The supernatant fraction following ultracentrifugation of the growth medium contained a component that suppressed endothelial cell adhesion to culture dishes coated with fibronectin, type I collagen, and endothelial cell complexes. SDS-polyacrylamide gel electrophoresis indicated that the complexes contained several components, and the majority of the large-molecular-weight components were pelleted by ultracentrifugation. The conditioned medium from human endothelial cells contains specific complexes that promote cell-substratum adhesion and components that suppress cell-substratum adhesion.

Chondronectin interactions with proteoglycan

We have investigated whether proteoglycans are involved in the attachment of embryonic chick chondrocytes to type II collagen. Chondroitin sulfate proteoglycan, when added exogenously, promotes the binding of chondronectin, the chondrocyte attachment factor, to type II collagen substrates and thereby stimulates chondrocyte adhesion. Blockage of endogenous proteoglycan synthesis with beta-xylosides prevents chondronectin-mediated chondrocyte attachment, confirming that proteoglycan is required. The intact proteoglycan must be present since chondroitin sulfate glycosaminoglycans did not promote chondronectin-mediated cell attachment but, rather, inhibited it in a dose-dependent manner. This inhibition, however, could be overcome with excess exogenous proteoglycan. Consequently, chondronectin interacts with proteoglycan and then the complex interacts with the collagen substrate and with the cell surface to promote cell adhesion. Further evidence for a direct interaction of chondronectin with the glycosaminoglycan portion of the proteoglycan is the selective binding of chondronectin to dextran-Sepharose, dextran having been shown to inhibit attachment to an extent similar to that of chondroitin sulfate.

Prostaglandin binding activity and myoblast fusion in aggregates of avian myoblasts

Myoblast aggregates provide a system for studying cell interactions which have several advantages over standard, stationary cultures. In gyrotory rotation, aggregate size can be controlled and is independent of cell migration. In muscle aggregates, fibroblasts are excluded, yet myoblast differentiation and fusion occur in a highly synchronous fashion. Specific PG binding occurs in chick or quail myoblast aggregates: in chick the peak of binding is at 35-36 hr. Aggregation is complete 16 hr before PG binding activity appears. This suggests either that gyrotory aggregation is not identical to myoblast recognition, or that PG binding activity occurs subsequent to myoblast recognition. Myoblast aggregates begin to release PG before 18 hr. The amount detected remains constant until binding begins at 34 hr when PG binding to the aggregates begins. Thus, both the release of PG and PG receptor activity are characteristics of the myoblasts and release of prostaglandin precedes appearance of the binding activity. As a first step in identifying the PG receptor and determining its appearance on the myoblast cell surface, we have prepared antisera against myoblast surfaces which blocks receptor-ligand interaction and have absorbed it against both peripheral and intrinsic membrane fractions. The results indicate that the PG receptor is a myoblast peripheral membrane macromolecule.

Characterization of toposomes from sea urchin blastula cells: a cell organelle mediating cell adhesion and expressing positional information

Cell adhesion in the sea urchin blastula is mediated by a 22S genus-specific glycoprotein complex consisting initially of six 160-kDa subunits that are processed proteolytically as development proceeds. Noncytolytic removal of the 22S particle from the surface with either 2.5% butanol or trypsin renders dissociated cells reaggregation incompetent, and addition restores reaggregation and development. Polyclonal antibodies against the 22S complex prevent reaggregation in a genus-specific manner while monoclonal antibodies stain cell surface structures in a pattern consistent with a code that specifies the position of a cell in the embryo by a unique combination of subunits in its cell adhesion particles. The existence of similar particles in Drosophila and amphibian embryos suggests that these glycoprotein complexes are a general class of organelles, the toposomes, that in the embryo mediate cell adhesion and express positional information.

Isolation of an adhesion-mediating protein from chick neural retina adherons

Adherons are high molecular weight glycoprotein complexes which are released into the growth medium of cultured cells. They mediate the adhesive interactions of many cell types, including those of embryonic chick neural retina. The cell surface receptor for chick neural retina adherons has been purified, and shown to be a heparan sulfate proteoglycan (Schubert, D., and M. LaCorbiere, 1985, J. Cell Biol., 100:56-63). This paper describes the isolation and characterization of a protein in neural retina adherons which interacts specifically with the cell surface receptor. The 20,000-mol-wt protein, called retinal purpurin (RP), stimulates neural retina cell-substratum adhesion and prolongs the survival of neural retina cells in culture. The RP protein interacts with heparin and heparan sulfate, but not with other glycosaminoglycans. Monovalent antibodies against RP inhibit RP-cell adhesion as well as adheron-cell interactions. The RP protein is found in neural retina, but not in other tissues such as brain and muscle. These data suggest that RP plays a role in both the survival and adhesive interactions of neural retina cells.

Isolation of a cell-surface receptor for chick neural retina adherons

Embryonic chick neural retina cells release glycoprotein complexes, termed adherons, into their culture medium. When absorbed onto the surface of petri dishes, neural retina adherons increase the initial rate of neural retina cell adhesion. In solution they increase the rate of cell-cell aggregation. Cell-cell and adheron-cell adhesions of cultured retina cells are selectively inhibited by heparan-sulfate glycosaminoglycan, but not by chondroitin sulfate or hyaluronic acid, suggesting that a heparan-sulfate proteoglycan may be involved in the adhesion process. We isolated a heparan-sulfate proteoglycan from the growth-conditioned medium of neural retina cells, and prepared an antiserum against it. Monovalent Fab' fragments of these antibodies completely inhibited cell-adheron adhesion, and partially blocked spontaneous cell-cell aggregation. An antigenically and structurally similar heparan-sulfate proteoglycan was isolated from the cell surface. This proteoglycan bound directly to adherons, and when absorbed to plastic, stimulated cell-substratum adhesion. These data suggest that a heparan-sulfate proteoglycan on the surface of chick neural retina cells acted as a receptor for adhesion-mediating glycoprotein complexes (adherons).

Early differentiation of vertebrate spinal neurons in the absence of voltage-dependent Ca2+ and Na+ influx

The development of the action potential and responses to neurotransmitters have been described for a population of embryonic spinal neurons developing in vivo. A comparable pattern is seen for spinal neurons developing in dissociated cell culture. The impulse appears very early in this developmental sequence, and the action potential involves a large inward Ca2+ current. Since Ca2+ is a ubiquitous intracellular regulator, we questioned whether a large influx of Ca2+ is necessary for the subsequent differentiation of membrane properties. Embryonic Xenopus neurons grown in normal culture medium do not make Ca2+- or Na+-dependent action potentials in their cell bodies in a Ca2+-free saline containing tetrodotoxin (TTX). To achieve a chronic blockade of impulse activity, neurons were grown in a medium in which Ca2+ was replaced by Mg2+, and to which 1 mM EGTA was added. In some instances TTX was present. Neurons grown in these experimental culture media extend neurites more rapidly than controls. Action potentials cannot be elicited from neurons when examined in experimental medium. However, examination in saline reveals that the change in the ionic dependence of the impulse is indistinguishable from that observed in neurons grown in normal medium. Furthermore, the time of onset of responses to GABA is unaffected by this experimental treatment. Thus the expression of Ca2+- and Na+-dependent action potentials seems not to play a part in the early differentiation of these membrane properties. However, the later development of GABA sensitivity is reduced.

Neurite-promoting factors and extracellular matrix components accumulating in vivo within nerve regeneration chambers

The outgrowth of neurites from cultured neurons can be induced by the extracellular matrix glycoproteins, fibronectin and laminin, and by polyornithine-binding neurite-promoting factors (NPFs) derived from culture media conditioned by Schwann, or other cultured cells. We have examined the occurrence of fibronectin, laminin and NPFs during peripheral nerve regeneration in vivo. A previously established model of peripheral nerve regeneration was used in which a transected rat sciatic nerve regenerates through a silicone chamber bridging a 10 mm interstump gap. The distribution of fibronectin and laminin during regeneration was assessed by indirect immunofluorescence. Seven days after nerve transection the regenerating structure within the chamber consisted primarily of a fibrous matrix which stained with anti-fibronectin but not anti-laminin. At 14 days, cellular outgrowths from the proximal and distal stumps (along which neurites grow) had entered the fibronectin-containing matrix, consistent with a role of fibronectin in promoting cell migration. Within these outgrowths non-vascular as well as vascular cells stained with anti-fibronectin and anti-laminin. Within the degenerated distal nerve segment, cell characteristic of Bungner bands (rows of Schwann cells along which regenerating neurites extend) stained with anti-fibronectin and laminin. The fluid surrounding the regenerating nerve was found to contain NPF activity for cultured ciliary ganglia neurons which markedly increased during the period of neurite growth into the chamber. In previous studies using this particular neurite-promoting assay, laminin but to a much lesser extent fibronectin also promoted neurite outgrowth.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of a 140Kd cell surface glycoprotein involved in myoblast adhesion

Two monoclonal antibodies that cause changes in the morphology of cultured chick myogenic cells have been described previously [8]. In this paper, these antibodies are shown to interact with the same 140Kd protein. The 140Kd protein has been further characterized as a cell-surface glycoprotein by lactoperoxidase-catalyzed iodinations and lectin affinity chromatography. The protein is resistant to digestion by trypsin and collagenase and has been shown to be unrelated to fibronectin by immunoprecipitation studies and by peptide mapping. A second protein, of approximately 170Kd MW, is also immunoprecipitated by the monoclonal antibodies. This protein is probably unrelated to the 140Kd protein since the peptide maps are quite distinct.

A role for adherons in neural retina cell adhesion

Embryonic chick neural retina cells release glycoprotein complexes, termed adherons, into their culture medium. When absorbed onto the surface of petri dishes, neural retina adherons increase the initial rate of neural retina cell adhesion; they also stimulate the rate of cell-cell aggregation. Adheron-stimulated adhesion is tissue specific, and the spontaneous aggregation of neural retina cells is inhibited by monovalent Fab' fragments prepared from an antiserum against neural retina adherons. Therefore cell surface antigenic determinants shared with adherons are involved in normal cell-cell adhesions. The particles from the heterogeneous neural retina population contain many proteins and several glycosaminoglycans. The adherons migrate as a symmetrical 12S peak on sucrose gradients and are predominantly 15-nm spheres when examined by electron microscopy. Finally, the specific activity of neural retina adherons increases from embryonic days 7 through 12 and then declines. These results suggest that glycoprotein particles may be involved in some of the adhesive interactions between neural retina cells and between the cells and their environment.