A comparison of fibronectin, laminin, and galactosyltransferase adhesion mechanisms during embryonic cardiac mesenchymal cell migration in vitro

Embryonic hearts contain a homogeneous population of mesenchymal cells which migrate through an extensive extracellular matrix (ECM) to become the earliest progenitors of the cardiac valves. Since these cells normally migrate through an ECM containing several adhesion substrates, this study was undertaken to examine and compare three ECM binding mechanisms for mesenchymal cell migration in an in vitro model. Receptor mechanisms for the ECM glycoproteins fibronectin (FN) and laminin (LM) and the cell surface receptor galactosyltransferase (GalTase), which binds an uncharacterized ECM substrate, were compared. Primary cardiac explants from stage 17 chick embryos were cultured on three-dimensional collagen gels. Mesenchymal cell outgrowth was recorded every 24 hr and is reported as a percentage of control. Migration was perturbed using specific inhibitors for each of the three receptor mechanisms. These included the hexapeptide GRGDSP (300–1000 μg/ml), which mimics a cell binding domain of FN, the pentapeptide YIGSR (300–1000 μg/ml), which mimics a binding domain of LM, and α-lactalbumin (1–10 mg/ml), a protein modifier of GalTase activity. The functional role of these adhesion mechanisms was further tested using antibodies to avian integrin (JG22) and avian GalTase. While the FN-related peptide had no significant effect on cell migration it did produce a rounded cellular morphology. The LN-related peptide inhibited mesenchymal migration 70% and α-lactalbumin inhibited cell migration 50%. Antibodies agasinst integrin and GalTase inhibited mesenchymal cell migration by 80 and 50%, respectively. The substrate for GalTase was demonstrated to be a single high molecular weight substrate which was not LM or FN. Control peptides, proteins and antibodies demonstrated the specificity of these effects. These data demonstrate that multiple adhesion mechanisms, including cell surface GalTase, are potentially functional during cardiac mesenchymal cell migration. The sensitivity of cell migration to the various inhibitors suggests that occupancy of specific ECM receptors can modulate the activity of other, unrelated, ECM adhesion mechanisms utilized by these cells.     

Molecular mechanisms of avian neural crest cell migration on fibronectin and laminin

We have examined the molecular interactions of avian neural crest cells with fibronectin and laminin in vitro during their initial migration from the neural tube. A 105-kDa proteolytic fragment of fibronectin encompassing the defined cell-binding domain (65 kDa) promoted migration of neural crest cells to the same extent as the intact molecule. Neural crest cell migration on both intact fibronectin and the 105-kDa fragment was reversibly inhibited by RGD-containing peptides. The 11.5-kDa fragment containing the RGDS cell attachment site was also able to support migration, whereas a 50-kDa fragment corresponding to the adjacent N-terminal portion of the defined cell-binding domain was unfavorable for neural crest cell movement. In addition to the putative "cell-binding domain," neural crest cells were able to migrate on a 31-kDa fragment corresponding to the C-terminal heparin-binding (II) region of fibronectin, and were inhibited in their migration by exogenous heparin, but not by RGDS peptides. Heparin potentiated the inhibitory effect of RGDS peptides on intact fibronectin, but not on the 105-kDa fragment. On substrates of purified laminin, the extent of avian neural crest cell migration was maximal at relatively low substrate concentrations and was reduced at higher concentrations. The efficiency of laminin as a migratory substrate was enhanced when the glycoprotein occurred complexed with nidogen. Moreover, coupling of the laminin-nidogen complex to collagen type IV or the low density heparan sulfate proteoglycan further increased cell dispersion, whereas isolated nidogen or the proteoglycan alone were unable to stimulate migration and collagen type IV was a significantly less efficient migratory substrate than laminin-nidogen. Neural crest cell migration on laminin-nidogen was not affected by RGDS nor by YIGSR-containing peptides, but was reduced by 35% after addition of heparin. The predominant motility-promoting activity of laminin was localized to the E8 domain, possessing heparin-binding activity distinct from that of the N-terminal E3 domain. Migration on the E8 fragment was reduced by greater than 70% after addition of heparin. The E1' fragment supported a minimal degree of migration that was RGD-sensitive and heparin-insensitive, whereas the primary heparin-binding E3 fragment and the cell-adhesive P1 fragment were entirely nonpermissive for cell movement.(ABSTRACT TRUNCATED AT 400 WORDS)     

Embryonic heart mesenchymal cell migration in laminin

Laminin, a large glycoprotein and major component of basement membranes, influences cell adhesion, migration, morphology, and differentiation. A peptide sequence, YIGSR, from the B1 chain of laminin has been found to correspond to an active site for cell adhesion. We report here that cardiac mesenchymal cells migrate vigorously within three-dimensional gels of laminin and that the YIGSR peptide will completely abolish this migratory activity. In contrast, migration of the mesenchymal cells into three-dimensional gels composed of collagen or collagen + laminin is not effected by YIGSR or other peptides (GRGDS, GRGDTP) reported to mediate cellular adhesion.     

wing blister, a new Drosophila laminin alpha chain required for cell adhesion and migration during embryonic and imaginal development

We report the molecular and functional characterization of a new alpha chain of laminin in Drosophila. The new laminin chain appears to be the Drosophila counterpart of both vertebrate alpha2 (also called merosin) and alpha1 chains, with a slightly higher degree of homology to alpha2, suggesting that this chain is an ancestral version of both alpha1 and alpha2 chains. During embryogenesis, the protein is associated with basement membranes of the digestive system and muscle attachment sites, and during larval stage it is found in a specific pattern in wing and eye discs. The gene is assigned to a locus called wing blister (wb), which is essential for embryonic viability. Embryonic phenotypes include twisted germbands and fewer pericardial cells, resulting in gaps in the presumptive heart and tracheal trunks, and myotubes detached from their target muscle attachment sites. Most phenotypes are in common with those observed in Drosophila laminin alpha3, 5 mutant embryos and many are in common with those observed in integrin mutations. Adult phenotypes show blisters in the wings in viable allelic combinations, similar to phenotypes observed in integrin genes. Mutation analysis in the eye demonstrates a function in rhabdomere organization. In summary, this new laminin alpha chain is essential for embryonic viability and is involved in processes requiring cell migration and cell adhesion.     

PEGylated human plasma fibronectin is proteolytically stable,supports cell adhesion,cell migration,focal adhesion assembly,and fibronectin fibrillogenesis

Delayed wound healing in many chronic wounds has been linked to the degradation of fibronectin (FN) by abnormally high protease levels. We sought to develop a proteolytically stable and functionally active form of FN. For this purpose, we conjugated 3.35 kDa polyethylene glycol diacrylate (PEGDA) to human plasma fibronectin (HPFN). Conjugation of PEGDA to HPFN or HPFN PEGylation was characterized by an increase of approximately 16 kDa in the average molecular weight of PEGylated HPFN compared to native HPFN in SDS‐PAGE gels. PEGylated HPFN was more resistant to α chymotrypsin or neutrophil elastase digestion than native HPFN: after 30 min incubation with α chymotrypsin, 56 and 90% of native and PEGylated HPFN respectively remained intact. PEGylated HPFN and native HPFN supported NIH 3T3 mouse fibroblast adhesion and spreading, migration and focal adhesion formation in a similar manner. Fluorescence microscopy showed that both native and PEGylated HPFN in the culture media were assembled into extracellular matrix (ECM) fibrils. Interestingly, when coated on surfaces, native but not PEGylated HPFN was assembled into the ECM of fibroblasts. The proteolytically stable PEGylated HPFN developed herein could be used to replenish FN levels in the chronic wound bed and promote tissue repair. © 2013 American Institute of Chemical Engineers Biotechnol. Prog., 29: 493–504, 2013     

Differential effects of cellular fibronectin and plasma fibronectin on ovarian cancer cell adhesion, migration, and invasion

Summary The main form of fibronectin (FN) encountered by tumor cells in vivo is cellular FN (cFN), which differs structurally and functionally from the commonly used plasma FN (pFN). We compared the effects of cFN and pFN on the ovarian carcinoma lines OVCAR-3 and SKOV-3 and on cultures of normal ovarian surface epithelium, which is the precursor of the epithelial ovarian carcinomas. Ovarian surface epithelial cells and SKOV-3 cells attached and spread faster on cFN than on pFN. On cFN, SKOV-3 migration was enhanced compared with pFN or plastic. In a matrigel transfilter assay, cFN strongly inhibited SKOV-3 invasion, whereas pFN did not. In contrast to SKOV-3, OVCAR-3 cells adhered faster on FN than on plastic but did not discriminate between cFN and pFN, and they did not migrate or invade matrigel either with or without FN. In both carcinoma lines, proliferation was unaffected by either FN. The results show profound differences in the responses to cFN and pFN by two invasive ovarian carcinoma lines. Because cFN is the main type that cancer cells encounter in vivo, extrapolations from culture data to in vivo events should preferably be based on studies using this form of FN.     

Functionally distinct laminin receptors mediate cell adhesion and spreading: the requirement for surface galactosyltransferase in cell spreading

The molecular mechanisms underlying cell attachment and subsequent cell spreading on laminin are shown to be distinct form one another. Cell spreading is dependent upon the binding of cell surface galactosyltransferase (GalTase) to laminin oligosaccharides, while initial cell attachment to laminin occurs independent of GalTase activity. Anti-GalTase IgG, as well as the GalTase modifier protein, alpha-lactalbumin, both block GalTase activity and inhibited B16-F10 melanoma cell spreading on laminin, but not initial attachment. On the other hand, the addition of UDP galactose, which increases the catalytic turnover of GalTase, slightly increased cell spreading. None of these reagents had any effect on cell spreading on fibronectin. When GalTase substrates within laminin were either blocked by affinity- purified GalTase or eliminated by prior galactosylation, cell attachment appeared normal, but subsequent cell spreading was totally inhibited. The laminin substrate for GalTase was identified as N-linked oligosaccharides primarily on the A chain, and to a lesser extent on B chains. That N-linked oligosaccharides are necessary for cell spreading was shown by the inability of cells to spread on laminin surfaces pretreated with N-glycanase, even though cell attachment was normal. Cell surface GalTase was distinguished from other reported laminin binding proteins, most notably the 68-kD receptor, since they were differentially eluted from laminin affinity columns. These data show that surface GalTase does not participate during initial cell adhesion to laminin, but mediates subsequent cell spreading by binding to its appropriate N-linked oligosaccharide substrate. These results also emphasize that some of laminin's biological properties can be attributed to its oligosaccharide residues.     

The role of murine cell surface galactosyltransferase in trophoblast: laminin interactions in vitro

Implantation of the mouse embryo involves the invasion of the secondary trophoblast giant cells of the ectoplacental cone (EPC) into the uterine decidua. The mechanisms of this event are poorly understood. The putative substrate molecules found in the decidua which could support trophoblast invasion include laminin, fibronectin, and collagen type IV. EPCs dissected from Day 7.5 embryos were cultured on all three matrices. Galactosyltransferase (GalTase) was localized by immunolabeling on trophoblast cell surfaces when grown on laminin but not the other matrices. Perturbations of the enzyme:substrate complex with alpha-lactalbumin, uridine diphosphogalactose, anti-GalTase, and pregalactosylation of the matrix did not affect rates of EPC attachment. However, decreased rates of migration or altered morphologies of spreading cells were observed. Laminin, and not fibronectin or collagen type IV, could be galactosylated with both exogenous GalTase or EPC outgrowths. Digests of galactosylated laminin produced a glycoconjugate substrate with a molecular weight of less than 10K. The results suggest that invasive secondary trophoblast cells possess a GalTase-mediated migration system that is functional on laminin.     

Dermatopontin promotes adhesion,spreading and migration of cardiac fibroblasts in vitro

Dermatopontin (DPT), an extracellular matrix (ECM) protein, has been previously shown to be upregulated in the infarct zone of experimentally induced myocardial infarction (MI) rats. However, the accurate role that DPT exerts in the ventricular remodeling process after MI remains poorly understood. In this study, we evaluated the expression pattern of DPT mRNA and protein as well as its secretion in cultured neonatal rat cardiomyocytes (CMs) and cardiac fibroblasts (CFs) under conditions of hypoxia and serum deprivation (hypoxia/SD). Further, we tested the possible roles of DPT in CFs adhesion, spreading, migration and proliferation, which greatly promote the ventricular remodeling process after MI. Results showed that hypoxia/SD stimulated DPT expression and secretion in CMs and CFs and that DPT promoted adhesion, spreading and migration of CFs whereas had no effect on CFs proliferation. In addition, functional blocking antibodies specific for integrin α3 and β1 significantly reduced CFs adhesion and migration that DPT induced, suggesting that integrin α3β1 is at least one receptor for CFs adhesion and migration to DPT. These results implicated that DPT participates in the ventricular remodeling process after MI and may act as a potential therapeutic target for ventricular remodeling.     

Role of collagen and fibronectin in neural crest cell adhesion and migration

Cultured neural crest cells which are freshly trypsinized require serum or purified fibronectin to attach to collagen substrates of types I–V. Furthermore, neural crest cells migrate in a Boyden chamber in response to fibronectin, and a “checkerboard” analysis demonstrates that fibronectin is both chemotactic and chemokinetic for these cells. It is proposed that collagen serves as a substrate for neural crest cells as they migrate in the early embryo. By mediating the cells' attachment to collagen, fibronectin may influence the movement of the cells. Local differences in fibronectin concentration or availability in the matrix could affect the degree of attachment of the cells to the collagen substrate and could also direct their migration by serving as a chemoattractant.     

Substrate adhesion of rat hepatocytes: a comparison of laminin and fibronectin as attachment proteins

In previous studies rat hepatocytes have been shown to adhere to substrates composed of collagen or fibronectin. In the present communication, the basement membrane protein laminin is reported to mediated the attachment and spreading of hepatocytes. The cell attachment-mediating activity of laminin was compared with that of fibronectin. The activity of fibronectin was heat sensitive, whereas laminin retained its activity after boiling. On the other hand, reduction and alkylation or periodate oxidation of the proteins affected only the cell attachment activity of laminin. Preincubation of cells with soluble fibronectin inhibited initial cell attachment to fibronectin but not to laminin substrates, and, reversely, soluble laminin selectively inhibited cell attachment to laminin. These results suggest that attachment of cells to substrates of the two proteins involves different cellular receptors recognizing distinct and nonidentical structures in the proteins.     

Biosynthesis of laminin and fibronectin by rat satellite cells during myogenesis in vitro

The biosynthesis of fibronectin and laminin was studied in satellite cells cultured from adult rat muscles before (day 4) and after fusion and formation of myotubes (day 14) using (35S) methionine as a tracer. The kinetics of incorporation into immunoprecipitable fibronectin and laminin were recorded at intervals from 1.5 to 24 hours of incubation with the tracer from the cells, the pericellular matrix and the culture medium. The rate of synthesis of fibronectin and laminin expressed as dpm/microgram DNA were constant from the mononucleated cell to the myotube state. Both glycoproteins were detected in the cells and in the pericellular matrix. When the results were expressed as the percentage of incorporation into total protein, major changes could be observed in the early phase of the kinetic studies in the cells and the pericellular matrix. Both showed an increase from the mononucleated myoblast to myotube, suggesting that an increasing fraction of total protein biosynthesis is directed towards these two extracellular matrix glycoproteins. At the same time, there was a decrease in the secretion into the medium of freshly synthesized radiolabeled fibronectin and laminin. Our results confirm the synthesis of varying ratios of both extracellular matrix macromolecules by undifferentiated mononucleated myogenic cells as well as myotubes.     

A fibronectin-related synthetic peptide, Pro-Ala-Ser-Ser, inhibits fibronectin binding to the cell surface, fibronectin-promoted cell migration in vitro, and cell migration in vivo

The biological activity of the amino acid sequence consisting of the immediate carboxyl terminus side of the Arg-Gly-Asp-Ser (RGDS) amino acid sequence in the cell-binding domain of intact fibronectin (FN) molecules was examined using synthetic peptides [RGDS, Gly-Arg-Gly-Asp-Ser-Pro (GRGDSP), Arg-Gly-Asp-Ser-Pro-Ala-Ser-Ser-Lys-Pro (RGDSPASSKP), Pro-Ala (PA), Pro-Ala-Ser (PAS), Pro-Ala-Ser-Ser (PASS), and Pro-Ala-Ser-Ser-Lys (PASSK)]. These peptides were applied to the primary mesenchyme cells (PMCs) of the sea urchin, Clypeaster japonicus. In vitro immunohistochemistry indicated that the binding of exogenous FN to the PMC surface was inhibited by the peptides RGDSPASSKP and PASS, but not by RGDS, GRGDSP, PA, or PAS. PASS and RGDS introduced into the blastocoel also inhibited PMC migration in vivo. FN-promoted PMC migration in vitro was also inhibited by PASS and RGDS. The present results indicate that the PASS peptide inhibits FN binding to the PMC surface and promotes PMC migration, suggesting that the FN molecule uses the PASS amino acid sequence to bind to the PMC surface and to promote PMC migration in the blastocoel.     

Sphingosine-1-phosphate inhibits cell migration and endothelial to mesenchymal cell transformation during cardiac development

Sphingosine-1-phosphate (S1P) is a biologically active sphingolipid metabolite that exerts important effects on numerous cellular events via cell surface receptors, S1P(1-5). S1P influences differentiation, proliferation, and migration during vascular development. However, the effects of S1P signaling on early cardiac development are not well understood. To address this issue, we examined the expression of S1P regulatory enzymes and S1P receptors during cardiac development. We observed that enzymes that regulate S1P levels, sphingosine kinase and sphingosine-1-phosphate phosphatase, are expressed in the developing heart. In addition, RT-PCR revealed that four of the five known S1P receptors (S1P(1-4)) are also expressed in the developing heart. Next, effects of altered S1P levels on whole embryo and atrioventricular (AV) canal cultures were investigated. We demonstrate that inactivation of the S1P producing enzyme, sphingosine kinase, leads to cell death in cardiac tissue which is rescued by exogenous S1P treatment. Other experiments reveal that increased S1P concentration prevents alterations in cell morphology that are required for cell migration. This effect results in reduced cell migration and inhibited mesenchymal cell formation in AV canal cushion tissue. These data indicate that S1P, locally maintained within a specific concentration range, is an important and necessary component of early heart development.     

Integrating adhesion, protrusion, and contraction during cell migration

Cell migration is fastest when the strength of the adhesion between the cell and the substrate is neither too strong nor too weak. In this issue of Cell, reveal how adhesion and cytoskeletal dynamics are integrated to optimize migration speed.     

Developmental modulation of embryonic cardiac myocyte adhesion to cardiac collagens in vitro.

The goal of this investigation is to identify molecules that mediate embryonic cardiac myocyte adhesion during chick cardiac morphogenesis. The assay used employs culturing embryonic myocytes on substrata containing embryonic heart proteins separated by molecular weight. This assay shows that embryonic myocytes from 10- to 14-day-old embryos will bind to 140,000 and 128,000 Da proteins present in embryonic hearts and do not require Mg2+ or Ca2+ for adhesion. Myocytes from embryos younger than 10 days or older than 14 days display little or no binding. Embryonic heart fibroblasts collected at these same ages do not bind to these proteins. The 140- and 128-kDa proteins were found to copurify in extraction procedures for procollagens. Amino acid analysis shows that both proteins contain high glycine and hydroxyproline, indicating that they are collagens. However, glycine and imino acid levels are low relative to other known collagens, indicating a nonhelical domain present in each molecule and most closely resembled levels present in procollagens. Immunoblots show that antisera to chick collagen type I recognizes the 128-kDa protein while anti-collagen type III recognizes the 140-kDa protein. Monoclonal antibodies to the amino terminal propeptide of collagen type I recognize the 128-kDa protein in immunoblotting procedures. Embryonic chick myocytes bind to 140/128 kDa proteins present in extracts of sympathetic trunk, although they do not bind to 140/128 kDa proteins in embryonic tendon. The findings thereby indicate that forms of type III and type I collagens in embryonic heart support direct adhesion of embryonic myocytes for a restricted period of cardiac myogenesis and that these proteins differ from collagen types I and III present in other tissues and from fully processed collagen types I and III.