Clonal segregation of multiple and overlapping matrix adhesive responses in dorsal root neuronal derivative cells

Clones of F11 hybrid (neuroblastoma X dorsal root neuron) cells have been tested for adherence and neurite outgrowth on three different substrata on which the parental cells display some competence--plasma fibronectin (pFN) with its multiple receptors, cholera toxin subunit B(CTB) as a model ganglioside GM1-binding substratum, and platelet factor-4 (PF4) as a model proteoglycan-binding substratum. This paradigm tests for independently segregating and overlapping mechanisms of neuritogenesis via transmembrane processes in pluripotent hybrid cells based on random loss of chromosomes contributed by the parent neural cells. For the nine clones tested, attachment was significantly lower on CTB but much higher on PF4 for all clones when compared to their attachment on pFN. Supplementation of cells with GM1 stimulated attachment of only two clones (on all three substrata). Neurite outgrowth was observed in a substratum-specific pattern and varied from 0 to greater than 60% on pFN; on CTB and PF4 substrata, the patterns were similar to each other but differed markedly from the pattern on pFN. In contrast, PF4- and CTB-directed neurites differed morphologically from each other while sharing some characteristics with neurites on pFN. Supplementation with GM1 or GT1b, but not GD1a, was inhibitory for neurite outgrowth in certain clones. Cycloheximide pretreatment distinguished several classes of clones based on inhibition of neuritogenesis. While most clones on pFN were unaffected, all clones on CTB and PF4 displayed significant and comparable degrees of inhibition, suggesting the sharing of some protein intermediate(s) on these substrata. Exposure to cycloheximide only during the active period of neuritogenesis generated higher percentages and longer neurites for all clones, indicating a widely-used negative regulation mechanism. Based on substratum type and cycloheximide protocols, these data have resolved six or more different transmembrane signalling processes for generating different classes of neurites. Some mechanisms have been segregated into individual clones while others overlap in other clones, providing cell systems for biochemical and molecular biological dissection of these processes.     

Multiple and alternative adhesive responses on defined substrata of an immortalized dorsal root neuron hybrid cell line

Attachment and neurite extension processes have been evaluated for an immortalized derivative cell of a rat dorsal root neuron after fusion with a mouse neuroblastoma cell (the clonal F11 hybrid cell line) and these processes compared with previous studies of neuroblastoma cells, since both cell types may be derived from the neural crest of the developing embryo. Biochemically defined substrata were provided by human plasma fibronectin (pFN), the heparan sulfate-binding protein platelet factor-4 (PF4), and the ganglioside GM1-binding protein cholera toxin B subunit (CTB). While some attachment of unsupplemented cells was noted on CTB substrata, GM1 supplementation permitted F11 cells to attach as well on CTB as on pFN or PF4. On PF4, very few neurite processes were observed while on pFN two morphologically distinct types of neurites could be identified: short, linear processes in a low percentage of cells resembling those of neuroblastoma cells and long, irregular and narrow processes in a higher percentage of cells resembling those of dorsal root neurons. On CTB, neurites of the latter class were even more prominent; however, cell bodies on CTB failed to spread by cytoplasmic extension as commonly observed in F11 cells on pFN and, to some extent, on PF4. The formation of both neurite classes on either pFN or CTB was completely inhibited by low concentrations of an RGDS (Arg-Gly-Asp-Ser) peptide in the medium of cultures, indicating the significance of pFN's binding to cell surface integrin or ganglioside GM1's possible interaction with integrin for mediating the differentiative process. In contrast, neurite formation of neuroblastoma cells is refractile to the soluble peptide as reported previously. Neurite extensions of F11 cells on either pFN or CTB were comparably sensitive to low concentrations of cytochalasin D, revealing the mediation of microfilament reorganization in these processes. Treatment of F11 cells with cycloheximide failed to inhibit neurite extension on pFN but did partially inhibit extension on CTB; this contrasts with the very high sensitivity of neurite formation by neuroblastoma cells on CTB substrata reported previously.(ABSTRACT TRUNCATED AT 400 WORDS)     

Ganglioside-dependent adhesion events of human neuroblastoma cells regulated by the RGDS-dependent fibronectin receptor and proteoglycans

Human neuroblastoma cells (Platt and La-N1) adhere and extend neurites on a ganglioside GM1-binding substratum provided by cholera toxin B (CTB). These adhesive responses, similar to those on plasma fibronectin (pFN), require the mediation of one or more cell-surface proteins [G. Mugnai and L. A. Culp (1987) Exp. Cell Res. 169, 328]. The involvement of two pFN receptor molecules in ganglioside GM1-mediated responses on CTB have now been tested. In order to test the role of cellular FN binding to its glycoprotein receptor integrin, a soluble peptide containing the Arg-Gly-Asp-Ser (RGDS) sequence was added to the medium. It did not inhibit attachment on CTB but completely inhibited formation of neurites; in contrast, the RGDS peptide minimally inhibited attachment or neurite formation on pFN. Once formed, neurites on CTB became resistant to the peptide. In order to test the role of cell-surface heparan sulfate proteoglycan (HS-PG), two approaches were used. First, the HS-binding protein platelet factor-4 (PF4) was used to dilute CTB or pFN on the substratum or, alternatively, added to the medium. Diluting the substratum ligand with PF4 had no effects on attachment on either CTB or pFN. However, neurite formation on CTB was readily inhibited and on pFN partially inhibited; the effects of PF4 were far greater than a similar dilution with nonbinding albumin. When PF4 was added to the medium of cells, attachment on either substratum was unaffected as was neurite outgrowth on pFN, revealing differences in PF4's inhibition as the substratum-bound or medium-borne component. In contrast, PF4 in the medium at low concentrations (1 microgram/ml) was highly inhibitory for neurite formation on CTB. The second approach utilized the addition of bovine cartilage dermatan sulfate proteoglycan (DS-PG), shown to bind to pFN as well as to substratum-bound CTB by ELISA, or cartilage chondroitin sulfate/keratan sulfate proteoglycan (CS/KS-PG) to the substratum or to the medium. At low concentrations, DS-PG but not CS/KS-PG actually stimulated neurite formation on CTB while at higher concentrations DS-PG completely inhibited attachment and neurite formation. While DS-PG partially inhibited attachment on pFN, it had no effect on neurite formation of the attached cells. Neuroblastoma cells adhered to some extent to substrata coated only with DS-PG, indicating "receptors" for PGs that permit stable interaction.(ABSTRACT TRUNCATED AT 400 WORDS)     

Cooperativity of ganglioside-dependent with protein-dependent substratum adhesion and neurite extension of human neuroblastoma cells

The potential involvement of gangliosides in the adherence and neurite extension of human neuroblastoma cells (Platt and La-N1) was investigated on tissue culture substrata coated with the ganglioside GM1-binding protein, cholera toxin B (CTB) subunit, for comparison with similar processes on plasma fibronectin (pFN)-coated substrata. Cells attached with reduced efficiency on CTB substrata as compared with pFN substrata and required a much longer time to form neurite processes for a small percentage of cells on CTB. The specificity of these processes for GM1 binding was tested in a variety of ways. Supplementation of the cells with exogenous GM1, but not GD1a, identified a larger population of cells adherent on CTB (comparable to pFN-adherent cells) and dramatically increased the proportion of cells capable of forming neurites without reducing the time requirement. In ultrastructural studies using the scanning electron microscope (SEM) and immunofluorescence (IF) analyses to discriminate microtubule distributions, neurites of GM1-supplemented cells on CTB were virtually identical with pFN-adherent neurites, whereas unsupplemented cells on CTB generated processes with fine-structural differences. Treatment of cells during the GM1 supplementation period with cycloheximide completely abolished the ability of cells to generate neurites on CTB and decreased the adhesive capacity of cells as well; a similar treatment of cells had no adverse effect on adherence or neurite extension on pFN. The importance of one or more proteins in GM1-dependent processes was further confirmed by demonstrating the trypsin sensitivity of a cell surface component(s) required to achieve maximal attachment on CTB; in contrast, adherence and neurite extension on pFN were much more resistant to this treatment process. Therefore, these experiments demonstrate (a) that certain cell surface gangliosides are capable of mediating adherence and neurite outgrowth of human neuroblastoma cells on a suitable ganglioside-binding substratum; (b) this ganglioside dependence is cooperative with one or more cell surface proteins which can now be analysed. These results are discussed in light of the identification in ref. [16] (Exp cell res 169 (1987) 311) of a second ‘cell-binding’ domain on the pFN molecule competent for adherence and neurite extension of these neuroblastoma cells, as well as the potential role of pFN binding to a complex ganglioside on the surface of these neural tumor cells in these processes.     

Neurite extension by neuroblastoma cells on substratum-bound fibronectin''s cell-binding fragment but not on the heparan sulfate-binding protein, platelet factor-4

Human and rat neuroblastoma cells extend neurites over plasma fibronectin (pFN)-coated substrata. For resolution of which fibronectin binding activities (the cell-binding domain (CBD), the heparan sulfate-binding domains, or a combination of the two) are responsible for neurite outgrowth, CBD was prepared free of heparan sulfate-binding activity as described by Pierschbacher et al. (Cell 26 (1981) 259-267). Neuroblastoma cells attached and extended neurites as stably and as effectively on CBD-coated substrata as on intact pFN, while cytoplasmic spreading was more extensive on pFN-coated substrata. The structures of growth cones on CBD or pFN were virtually identical. On substrata coated with the model heparan sulfate-binding protein, platelet factor 4 (PF4), cells attached and spread somewhat but never extended neurites. When cells were challenged with substrata coated with various ratios of CBD and PF4, PF4 was found to be an effective inhibitor of CBD-mediated neurite extension. Similarly, cells grown on substrata coated at different locations with CBD or PF4 in order to evaluate topographical dependence of growth cone formation extended neurites only onto the CBD-coated region or along the interface between these two proteins, but never onto the PF4 side of cells that bridged the interface. These studies indicate that (a) the CBD activity of pFN, and not its heparan sulfate-binding activity, is the critical determinant in neurite extension of these neural tumor cells from the central nervous system; (b) under some circumstances, heparan sulfate-binding activity can be antagonistic to neurite extension; (c) the chemical nature of the substratum controls the direction of neurite extension; (d) these neuroblastoma cells respond to these binding proteins very differently than fibroblasts or neurons from the peripheral nervous system.     

A second cell-binding domain on fibronectin (RGDS-independent) for neurite extension of human neuroblastoma cells

Human neuroblastoma cells (Platt and La-N1) have previously been shown to adhere and extend neurites on tissue-culture substrata coated with a 120K chymotryptic cell-binding fragment (CBF) of plasma fibronectin (pFN), a fragment which lacks heparan sulfate- and collagen-binding activities, and to adhere to—but not extend neurites on—substrata coated with the heparan sulfate (HS)-binding protein, platelet factor-4 (PF4) ([3.]). The mechanisms of these processes on CBF, on the intact pFN molecule, or on heparin-binding fragments of pFN have been tested using a heptapeptide (peptide A) containing the Arg---Gly---Asp---Ser (RGDS) sequence which recognizes a specific ‘receptor’ on the surface of a variety of cells or a control peptide with a single amino acid substitution. Adherence and neurite extension were completely inhibited on the 120K CBF by peptide A but not by control peptide; these results indicate that the RGDS-dependent ‘receptor’ is solely responsible for adhesive responses to the 120K CBF-containing region of the pFN molecule. When peptide A was added to cells on CBF which had already formed neuntes to test reversibility, retraction of all neurite processes was induced by 1 h and cells eventually detached. In contrast, on intact pFN, peptide A had very limited effects on either initial adherence or neurite extension, revealing a second ‘cell-binding’ domain on the fibronectin molecule outside of the 120K region competent for neurite differentiation; addition of peptide A at later times to pFN-adherent, neurite-containing cells could induce only a small subset of neurites to retract, thus supporting evidence for the presence of this second domain. A second ‘cell-binding’ domain was further confirmed by quantitation of neurite outgrowth on these substrata and by analyses of cells on substrata coated with mixtures of CBF/PF4. When substrata coated with chymotrypsin-liberated HBF were tested in a similar fashion, adherence was rapid but neurite outgrowth required much longer times and was completely sensitive to RGDS peptides; supplementation of cells with the complex ganglioside GT1b could not induce RGDS-resistant neurites on heparin-binding fragments (HBF). These latter results indicate that neurite extension on HBF is a consequence of a low concentration of RGDS-dependent activity in HBF (but not to HS-binding activity as characterized by Tobey et al. [3]) and that the second ‘cell-binding’ domain is sensitive to chymotrypsin digestion of pFN during the liberation of HBF. Possible candidate molecules for this second activity as well as its preliminary location in the pFN molecule are discussed and evidence, is provided in ref. [37] ([37.]) for the potential role for one class of molecules as a ‘receptor’. These neural tumor cells therefore have multiple and alternative mechanisms of adherence and differentiation on fibronectin matrices.     

Modulation of fibronectin adhesive functions for fibroblasts and neural cells by chemically derivatized substrata

Adhesion responses of fibroblasts (Balb/c 3T3 cells) and human neuron-derived (Platt neuroblastoma) cells have been examined with plasma fibronectin (pFN) adsorbed to glass surfaces derivatized with an alkyl chain and six chemical end groups interfacing with the bound pFN to test regulation of pFN function. Using new derivatization protocols, the following surfaces have been tested in order of increasing polarity: [CH3], [C = C], [Br], [CN], [Diol], [COOH], and underivatized glass [( SiOH]). For all substrata, pFN bound equivalently using either a supersaturating amount of pFN or a subsaturating amount in competition with bovine albumin. Attachment of both cell types was also equivalent on all substrata. However, spreading/differentiation responses varied considerably. F-actin reorganization was tested in 3T3 cells with rhodamine-phalloidin staining. While stress fibers formed effectively on pFN-coated [SiOH] and [Br] substrata, only small linear bundles of F-actin and a few thin stress fibers were observed on the [COOH], [Diol], and [CN] substrata; the hydrophobic substrata [( CH3] and [C = C]) gave an intermediate response. When a synthetic peptide containing the Arg-Gly-Asp-Ser sequence required for integrin binding to FNs was included in the medium as an inhibitor, additional differences were noted: Stress fiber formation was completely inhibited on [SiOH] but not on [Br] and stress fiber formation was very sensitive to inhibition on the hydrophobic substrata while the F-actin patterns on the [CN] and [COOH] substrata were unaffected. Evaluation of neurite outgrowth by neuroblastoma cells on these substrata revealed both qualitative and quantitative differences as follows: [Diol] = [COOH] greater than [SiOH] much greater than [CN] = [Br] greater than [CH3] = [C = C]. While there was poor cytoplasmic spreading and virtually no neurites formed on the hydrophobic surfaces when pFN alone was adsorbed, neurite formation could be "rescued" if a mixture of pFN with an excess of bovine albumin was adsorbed, demonstrating complex conformational interactions between substratum-bound pFN and adhesion-inert neighboring molecules. In summary, these studies demonstrate that different chemical end groups on the substratum modulate pFN functions for cell adhesion, principally by affecting the conformation of these molecules rather than the amounts bound. Furthermore, these studies confirm multiple-receptor interactions with the FN molecules in cell type-specific adhesion patterns.(ABSTRACT TRUNCATED AT 400 WORDS)     

Substratum contacts and cytoskeletal reorganization of BALB/c 3T3 cells on a cell-binding fragment and heparin-binding fragments of plasma fibronectin

BALB/c 3T3 cells make both close contacts and tight-focal contacts (with associated microfilament stress fibers) on plasma fibronectin (pFN)-coated substrata. To resolve the importance of the heparan sulfate-binding or cell-binding activities of the pFN molecule in these adhesive responses, a cell-binding fragment (120K) (CBF) free of any heparan sulfate-binding activity was prepared from human pFN by chymotrypic digestion and isolated as described by Pierschbacher et al. (Cell 26 (1981) 259). These adhesive responses to CBF were also compared to those of the model heparan sulfate-binding protein, platelet factor-4 (PF4), or heparin-binding fragments (HBF) of pFN. On intact pFN, greater than 70% of the cells formed tight-focal contacts and associated stress fibers by 4 h, the latter staining with NBD-phallacidin. In contrast, cells spread differently on CBF and failed to form tight-focal contacts; staining with NBD-phallacidin was localized to spiky projections at the cell margin with no detectable stress fiber formation. On PF4 or HBF, cells failed to form tight-focal contacts but did spread well and formed long microfilament bundles in peripheral lamellae. Spreading on CBF, HBF, or PF4 was paralleled by formation of close contacts. Spreading and to some extent attachment of cells on CBF was inhibited with a small peptide containing the Arg-Gly-Asp-Ser sequence; responses on HBF were unaffected by this peptide. When mixtures of CBF and PF4 were tested, cells still failed to form tight-focal contacts and stress fibers. These results demonstrate that the binding of CBF to its probable receptor under conditions routinely used to assay spreading activity results in an incomplete adhesive response compared with intact pFN. While this partial response may result from quantitative differences in the density of active cell-binding domains on the substratum, the pattern of microfilament reorganization produced by the binding of PF4 to cell surface heparan sulfate proteoglycans suggests that the ability of pFN to promote formation of tight-focal contacts and stress fibers may reside in the coordinate interaction of two or more binding activities in the intact molecule.     

Cholera toxin binds to lipid rafts but has a limited specificity for ganglioside GM1

Lipid rafts and the formation of an immunological synapse are crucial for T-cell activation. Binding of cholera toxin B subunit (CTB) to ganglioside GM1 is a marker to identify lipid rafts. Primary human T cells were isolated from healthy donors and were stimulated with superantigen staphylococcus enterotoxin B (SEB) and stained with cholera toxin B-fluorescein isothiocyanate (CTB-FITC). An optimized staining procedure is required to stain lipid rafts exclusively on the cell surface. Unstimulated T cells show a few CTB binding spots on the cell surface. The size and number of CTB-binding lipid rafts are strongly upregulated during T-cell activation in SEB-stimulated CD4(+) T cells. However, our data show that the specificity of CTB for GM1 ganglioside is limited, because the binding capacity is partly resistant to inhibition of ganglioside synthesis and sensitive to trypsin digestion. Our results indicate that the binding of FITC-labeled CTB can be divided into at least three different categories: a specific binding of CTB to ganglioside GM1, a nonspecific binding of CTB probably to glycosylated surface proteins and a nonspecific binding of FITC to the cell surface.     

Engagement of endogenous ganglioside GM1a induces tyrosine phosphorylation involved in neuron-like differentiation of PC12 cells

Using the cholera toxin B subunit (CTB) that specifically binds to ganglioside GM1a on the plasma membrane, we investigated intracellular signaling mediated by endogenous GM1a involved in neuronal differentiation of PC12 cells. The treatment with CTB induced morphological alternations of PC12 cells, such as augmentation of the cell body, neurite extension, and branched spikes of tips of neurites. The neurite extension induced with CTB was strongly suppressed by the pretreatment of tyrosine kinase inhibitors in a dose-dependent manner. Western blotting analysis showed that CTB induced tyrosine phosphorylation of several cellular proteins with molecular masses around 120, 70, and 45-40 kDa in PC12 cells. Some of the proteins identified were extracellular-signal regulated kinase (ERKs) (ERK1 and ERK2). The peak activation of ERKs lasted for 60-90 min and gradually decreased thereafter. Immunoprecipitation analysis demonstrated that the intracellular events induced with CTB are not related with the activation of Trk proteins, suggesting that signals evoked by ligation of endogenous GM1a are unique and distinct from those induced with exogenous GM1a. Although the presence of a tyrosine kinase inhibitor, genistein, at a concentration of 10 microM diminished the neurite extension of PC12 cells induced with CTB, ERK activation was still observed. However, pretreatment with a MEK inhibitor, PD98059, abolished the activation of ERKs induced with CTB in a dose-dependent manner and only attenuated the morphological alternations of PC12 cells. Considered together, we concluded that tyrosine phosphorylation induced with CTB was responsible for neuron-like differentiation of PC12 cells and that the MEK-ERK cascade is part of the biological signals mediated by endogenous ganglioside GM1a on PC12 cells.     

Cell surface heparan sulfate mediates some adhesive responses to glycosaminoglycan-binding matrices, including fibronectin

Proteins with affinities for specific glycosaminoglycans (GAC's) were used as probes for testing the potential of cell surface GAG's to mediate cell adhesive responses to extracellular matrices (ECM). Plasma fibronectin (FN) and proteins that bind hyaluronate (cartilage proteo-glycan core and link proteins) or heparan sulfate (platelet factor 4 [PF4]) were adsorbed to inert substrata to evaluate attachment and spreading of several 3T3 cell lines. Cells failed to attach to hyaluronate-binding substrata. The rates of attachment on PF4 were identical to those on FN; however, PF4 stimulated formation of broad convex lamellae but not tapered cell processes fibers during the spreading response. PF4-mediated responses were blocked by treating the PF4-adsorbed substratum with heparin (but not chondroitin sulfate), or alternatively the cells with Flavobacter heparinum heparinase (but not chondroitinase ABC). Heparinase treatment did not inhibit cell attachment to FN but did inhibit spreading. Cells spread on PF4 or FN contained similar Ca2+-independent cell-substratum adhesions, as revealed by EGTA-mediated retraction of their substratum-bound processes. Microtubular networks reorganized in cells on PF4 but failed to extend into the broadly spread lamellae, where fine microfilament bundles had developed. Stress fibers, common on FN, failed to develop on PF4. These experiments indicate that (a) heparan sulfate proteoglycans are critical mediators of cell adhesion and heparan sulfate-dependent adhesion via PF4 is comparable in some, but not all, ways to FN-mediated adhesion, (b) the uncharacterized and heparan sulfate-independent "cell surface" receptor for FN permits some but not all aspects of adhesion, and (c) physiologically compatible and complete adhesion of fibroblasts requires binding of extracellular matrix FN to both the unidentified "cell surface" receptor and heparan sulfate proteoglycans.     

Dermal fibroblasts from Down''s syndrome patients share a cycloheximide-induced deficiency in collagen adhesion responses with normal aging cells

Human skin fibroblasts from three different Down's syndrome patients (trisomy 21) of very different ages have been tested for their adhesion responses on tissue culture substrata coated with type I collagen, fibronectin (FN), and their combination after or during treatment of cells with cycloheximide to evaluate limitations in specific responses. It was shown previously that in vitro-aged papillary and reticular dermal fibroblasts from normal individuals do not generate F-actin stress fibers when pretreated with cycloheximide on collagen substrata but do so on FN substrata, a deficiency linked to limiting amounts/function of collagen-specific receptors in aging cells. In these studies, all three Down's fibroblast populations demonstrated a similar deficiency in stress fiber formation, evaluated by rhodamine-phalloidin staining, upon cycloheximide treatment at all passage levels. They remained competent for stress fiber formation on FN substrata and for reorganization of microtubule and intermediate filament networks on all substrata, demonstrating the specificity for the collagen matrix and for the F-actin cytoskeleton in this deficiency. The cycloheximide-induced deficiency could be readily reversed in all three cell populations by further incubation of cells in drug-free medium and, in some cases, by prior growth of cells in ascorbate-supplemented medium to stimulate collagen and possibly collagen receptor production. However, several pieces of evidence indicate that reduced amounts of FN and collagen synthesized by fibroblasts do not contribute to the cycloheximide-induced deficiency, including the inability to reverse the effect by treatment of cells with TGF beta. Several conclusions are suggested from these studies: (a) Down's dermal fibroblasts become deficient in collagen-specific receptor(s) upon cycloheximide treatment, which leads to altered transmembrane signaling and inability to reorganize F-actin into stress fibers; (b) Down's dermal fibroblasts at all passage levels have matrix adhesive phenotypes similar to those of aging fibroblasts from normal individuals; and (c) these studies provide further support for cells from Down's patients as a genetic model of aging in normal populations.     

Fibronectin-mediated adhesion of fibroblasts: inhibition by dermatan sulfate proteoglycan and evidence for a cryptic glycosaminoglycan-binding domain

Dermatan sulfate proteoglycans (DS-PGs) isolated from bovine articular cartilage have been examined for their effects on the adhesive responses of BALB/c 3T3 cells and bovine dermal fibroblasts on plasma fibronectin (pFN) and/or type I collagen matrices, and compared to the effects of the chondroitin sulfate/keratan sulfate proteoglycan monomers (CS/KS-PGs) from cartilage. DS-PGs inhibited the attachment and spreading of 3T3 cells on pFN-coated tissue culture substrata much more effectively than the cartilage CS/KS-PGs reported previously; in contrast, dermal fibroblasts were much less sensitive to either proteoglycan class unless they were pretreated with cycloheximide. Both cell types failed to adhere to substrata coated only with the proteoglycans; binding of the proteoglycans to various substrata has also been quantitated. While a strong inhibitory effect was obtained with the native intact DS-PGs, little inhibitory effect was obtained with isolated DS chains (liberated by alkaline-borohydride cleavage) or with core protein preparations (liberated by chondroitinase ABC digestion). In marked contrast, DS-PGs did not inhibit attachment or spreading responses of either 3T3 or dermal fibroblasts on type I collagen-coated substrata when the collagen was absorbed with pFN alone, DS-PGs alone, or the two in combination. These results support evidence for (a) collagen-dependent, fibronectin-independent mechanisms of adhesion of fibroblasts, and (b) different sites on the collagen fibrils where DS-PGs bind and where cell surface "receptors" for collagen bind. Experiments were developed to determine the mechanism(s) of inhibition. All evidence indicated that the mechanism using the intact pFN molecule involved the binding of the DS-PGs to the glycosaminoglycan (GAG)-binding sites of substratum-bound pFN, thereby inhibiting the interaction of the fibronectin with receptors on the cell surface. This was supported by affinity chromatography studies demonstrating that DS-PGs bind completely and effectively to pFN-Sepharose columns whereas only a subset of the cartilage CS/KS-PG binds weakly to these columns. In contrast, when a 120-kD chymotrypsin-generated cell-binding fragment of pFN (CBF which has no detectable GAG-binding activity as a soluble ligand) was tested in adhesion assays, DS-PGs inhibited 3T3 adherence on CBF more effectively than on intact pFN. A variety of experiments indicated that the mechanism of this inhibition also involved the binding of DS-PGs to only substratum-bound CBF due to the presence of a cryptic GAG-binding domain not observed in the soluble CBF.(ABSTRACT TRUNCATED AT 400 WORDS)     

Promotion of Neuritogenesis in Mouse Neuroblastoma Cells by Exogenous Gangliosides. Relationship Between the Effect and the Cell Association of Ganglioside GM1

Ganglioside GM1 promoted neuritogenesis of neuroblastoma cells, neuro-2a clone, in monolayer culture. GM1 bound to neuro-2a cells in three distinct forms, one removable by treatment with serum-containing solutions, one serum-resistant and labile to trypsin treatment, and one resistant to serum and trypsin treatments. The proportions among the three forms of cell-associated GM1 varied in relation to duration of exposure to ganglioside, ganglioside concentration in the medium, and number of cells in culture. The form removable by serum was predominant at the initial stages of association and at the highest ganglioside concentrations (over 10(-6)M); the trypsin-labile and -stable forms tended to increase with increasing cell number and decreasing ganglioside concentration. The neuritogenic effect of GM1 was higher when neuro-2a cells were incubated for 24 h in the presence of GM1 and fetal calf serum. Under this condition the percentage of neurite-bearing cells increased from 11% of control to 62% at the optimal ganglioside concentration of 10-4M. The effect was still present, although to a lower extent (from 11% to 28% of neurite-bearing cells), when cells were first exposed for only 2 h to GM1, then washed and incubated for 24 h in the presence of fetal calf serum. The trypsin-labile and -stable forms of cell-associated GM1 had a fundamental role in the effect, whereas the form removable by serum was not involved. The preparation of GM1 used was extremely pure (99%) and, in particular, had a peptide contamination, if any, less than 1:20,000-1:50,000.(ABSTRACT TRUNCATED AT 250 WORDS)     

Adhesive responses of fibroblast and neuroblastoma cells to substrata coated with polyvalent or monoclonal antibody to fibronectin

Both polyvalent and hybridoma-produced antibodies to fibronectin (Fn) were used to ‘map’ the immunoaccessible subsets of cell surface fibronectin on virus-transformed murine fibroblast SVT2 and rat neuroblastoma B104 cells. As one approach to this end, attachment and spreading responses of cells were measured on tissue culture substrata coated with antibody or with plasma fibronectin to compare their adhesive responses. Both SVT2 and B104 cells adhere poorly to polyvalent anti-Fn-coated substrata over short time intervals, but within several hours changes occur which permit cells to attach and spread as well on anti-Fn as on Fn (post-adsorption of the anti-Fn with Fn also generates a maximal response). This adhesive response could be completely prevented by predigesting the cells with Flavobacterium heparanase, but not with chondroitinase ABC, indicating that the cell surface Fn responsible for antibody-mediated adhesion is associated with heparan sulfate proteoglycans on the cell surface. The compositions of the substratum-attached material (left bound after EGTA-mediated detachment of cells) from cells attaching to anti-Fn or Fn were analysed by SDS-PAGE and found to be identical within the same cell type for the two different substrata. Three hybridoma-produced antibodies, which recognize different determinants on Fn, generated different adhesive responses for SVT2 or B104 cells when adsorbed to the substratum. SVT2 cells adhered well to antibody no. 32-coated substrata but poorly to antibodies 92 or 136; on the other hand, B104 cells responded similarly to all three antibodies over short times of attachment but much better to no. 32 after a several hour incubation. These experiments indicate that (1) much of the cell surface fibronectin is complexed with heparan sulfate proteoglycan and is initially inaccessible to bind to polyvalent antibody on the substratum to promote adhesion; (2) the surface of neuroblastoma cells contains a fibronectin-like molecule which is important in their substratum adhesion; and (3) monoclonal antibodies are valuable tools in ‘mapping’ the orientation of cell surface molecules like fibronectin by measuring adhesive responses to antibody-coated substrata.     

Effects of plant lectins on the adhesive properties of baby hamster kidney cells

We studied the effects of different lectins on the adhesive properties of baby hamster kidney (BHK) cells. The purpose of these studies was to learn more about the cell surface receptors involved in cell adhesion. Three adhesive phenomena were analyzed: 1) the adhesion of BHK cells to lectin-coated substrata; 2) the effects of lectins on the adhesion of cells to substrata coated by plasma fibronectin (pFN); and 3) the effects of lectins on the binding of pFN-coated beads to cells. Initial experiments with fluorescein-conjugated lectins indicated that concanavalin A (Con A), ricinus communis agglutinin I (RCA I), and wheat germ agglutinin (WGA) bound to BHK cells but peanut agglutinin (PNA), soybean agglutinin (SBA), and ulex europaeus agglutinin I (UEA I) dod not bind. All three of the lectins which bound to the cells promoted cell spreading on lectin substrata, and the morphology of the spread cells was similar to that observed with cells spread on pFN substrata. Protease treatment of the cells, however, was found to inhibit cell spreading on pFN substrata or WGA substrata more than on Con A substrata or RCA I substrata. In the experiment of cells with Con A or WGA inhibited cell spreading on pFN substrata, but RCA I treatment had no effect. Finally, treatment of cells with WGA inhibited binding to cells of pFN beads, but neither Con A nor RCA I affected this interaction. These results indicate that the lectins modify cellular adhesion in different ways, probably by interacting with different surface receptors. The possibility that the pFN receptor is a WGA receptor is discussed.     

Complementary adhesive responses of human skin fibroblasts to the cell-binding domain of fibronectin and the heparan sulfate-binding protein, platelet factor-4

Plasma fibronectin (pFN) contains binding domains for an unidentified receptor on the surface of fibroblasts and for heparan sulfate chains of proteoglycans on these same cells. A series of experiments were designed to assess the relative importance of these activities in mediating substratum adhesion of human skin fibroblasts (strain 4449) grown in the absence of ascorbate (asc-) or in its presence (asc+) to minimize or maximize collagen production-maturation, respectively. The cell-binding fragment (CBF) of pFN was purified from chymotryptic digests free of any heparan sulfate-binding activity. The responses of cells to CBF were then compared with those mediated by the heparan sulfate-binding protein, platelet factor-4 (PF4). At early time points when cells had spread effectively on pFN, both asc- or asc+ cells extended spiky projections on PF4 and long projections on CBF with actively ruffling membranes at their tips. By 4 h, asc+ cells had spread much more effectively on CBF than asc+ cells on PF4 or asc- cells on either binding activity. Mixtures (w/w) of CBF:PF4 between 1:1 and 9:1 generated a more physiologically normal response than to either of the binding proteins alone, particularly for asc+ cells. Examination of cytoskeletal reorganization by fluorescence analysis with an antibody to 7S tubulin (for microtubules) and NBD-phallacidin (for F-actin) revealed condensations of microfilaments at the ruffling edges of asc- cells on CBF or on PF4 and for asc+ cells on PF4; in contrast, asc+ cells on CBF generated long bundles of microfilaments in their spreading lamellae within 4 h. Microtubule networks reorganized very well on CBF but only partially on PF4 with either cell type. Microfilament reorganization was comparable to that on intact pFN with CBF:PF4 mixtures of 1:1 and 9:1 for asc+ cells, whereas asc- cells generated condensations of microfilaments but little bundling. These studies reveal that the adhesive responses to mixtures of these two binding activities are significantly greater than to the individual activities and that the responses of asc+ cells approach the properties of cells on intact pFN, whereas asc- cells remain incapable of forming stress fiber-like bundles of microfilaments under all conditions.     

The Effect of the B Subunit of Cholera Toxin on the Action of Nerve Growth Factor on PC12 Cells

Abstract: Exogenous gangliosides, especially ganglioside GM1 (GM1), seem to potentiate the action of nerve growth factor (NGF). We have examined the possible regulation of the NGF signaling pathway in PC12 cells by the B subunit of cholera toxin (CTB), which binds to endogenous GM1 specifically and with a high affinity. CTB treatment (1 μg/ml) enhanced NGF-induced neurite outgrowth from PC12 cells, NGF-induced activation of ribosomal protein S6 kinase, and NGF-induced stimulation of trk phosphorylation. CTB plus NGF also caused a greater inhibition of [³H]-thymidine incorporation into DNA than did NGF alone. These enhancing effects of CTB were blocked by the presence of cytochalasin B in the culture medium but were not affected by the presence of colchicine or by the depletion of Ca²⁺ in the medium. ¹²⁵I-NGF binding experiments revealed that CTB treatment did not affect the specific binding of NGF to the cells. These results strongly suggest that the binding of cell surface GM1 by CTB modulates the pathway of intracellular signaling initiated by NGF and that the association of CTB with a cytoskeletal component is essential for these effects.     

Contact formation by fibroblasts adhering to heparan sulfate-binding substrata (fibronectin or platelet factor 4)

The process of cell-substratum adhesion of BALB/c 3T3 fibroblasts on fibronectin (FN)-coated substrata was compared with that of cells adhering to substrata coated with the heparan sulfate (HS)-binding protein, platelet factor four (PF4). FN has binding domains for HS and an unidentified cell surface receptor, whereas PF4 binds to only HS on the surface of the cell. The attachment and early spreading sequences of cells on either substratum were similar as shown by scanning electron microscopy (SEM). Within 2 h of spreading, cells on FN developed typical fibroblastic morphologies, whereas those on PF4 lacked polygonal orientations and formed numerous broadly spread lamellae. Interference reflection microscopic analysis indicated that PF4-adherent cells formed only close adhesive contacts, whereas FN-adherent cells formed both close contacts and tight focal contacts. Cells on either substratum responded to Ca2+ chelation with EGTA by rounding up, but remained adherent to the substratum by relatively EGTA-resistant regions of the cell's undersurface, demonstrating that cell surface HS by binding to an appropriate substratum is capable of initiating a Ca2+-dependent spreading response. The EGTA-resistant substratum-attached material on PF4 was morphologically similar to that on FN, the latter of which was derived from both tight focal contacts and discrete specializations within certain close contacts. These studies show that heparan sulfate proteoglycans on the surface of these cells can participate in the formation of close contact adhesions by binding to an appropriate substratum and suggest that sub-specializations within close contact adhesions may evolve into tight focal contacts by the participation of an unidentified cell surface receptor which binds specifically to fibronectin but not to PF4. In addition, the functional role of FN in tight focal contact formation is demonstrated.     

Adhesion sites of murine fibroblasts on cold insoluble globulin-adsorbed substrata

The attachment and detachment behavior of three mouse fibroblast cell lines adhering to plastic tissue culture substrata coated with the serum protein cold-insoluble globulin (CIg) resembles that seen on the usual serumcoated substrata. The transformed cell line SVT2 spreads more extensively on the CIg-coated than on the serum-coated substratum, while the nontransformed Balb/c 3T3 line and concanavalin A-selected “revertant” of SVT2 are equally well spread on both substrata. In all three cases, immunofluorescence microscopy using antibodies to CIg suggests that the cells are more tightly apposed to the CIg-coated substratum than to the serum-coated substratum. Substrate-attached material (SAM), which contains cell-substratum adhesion sites and which is left after EGTA-mediated detachment of cells, is enriched for cell surface fibronectin and glycosaminoglycans (GAG). When cells are seeded onto CIg-coated substrata rather than serum-coated substrata, there is an increased deposition of GAG but a comparable deposition of cellular proteins. The protein distribution of the two types of SAM are identical as analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis, including fibronectin content. This indicates that substratum-bound CIg cannot functionally substitute for cell surface fibronectin in these adhesion sites. Analysis of the GAG deposited on CIg-coated substrata reveals that hyaluronate and the chondroitins are increased to a much greater extent than heparan sulfate; however, the ratio of hyaluronate to the various chondroitin species is invariant. These data provide further evidence that hyaluronate and the chondroitins are deposited in adhesion sites in well-defined stoichiometric proportions, possibly as supramolecular complexes, and that CIg may mediate adhesion of cells in the serum layer by binding to GAG-containing proteoglycans.