Specificity of cell adhesion: differences between normal and hybrid sea urchin cells.

The adhesive specificity of embryonic sea urchin cells from two species, and the two hybrid crosses between these species was examined by a cell-aggregate collection assay. Cells of normal Lytechinus or Tripneustes embryos were found to adhere to homospecific cell aggregates at a much higher rate than they would adhere to heterospecific aggregates. Hybrid cells adhered to collecting aggregates at an intermediate rate. The observed pattern of hybrid cell adhesion suggested that paternal gene products are capable of modifying cell surface adhesive sites as early as the mesenchyme blastula stage.     

A requirement for trypsin-sensitive cell-surface components for cell-cell interactions of embryonic neural retina cells

A quantitative assay was used to measure the rate of collection of a population of embryonic neural retina cells to the surface of cell aggregates. The rate of collection of freshly trysinized cells was limited in the initial stages by the rate of replacement of trypsin-sensitive cell- surface components. When cells were preincubated, or "recovered," and then added to cell aggregates, collection occurred at a linear rate and was independent of protein and glycoprotein synthesis. The adhesion of recovered cells was temperature and energy dependent, and was reversibly inhibited by cytochalasin B. Colchicine had little effect on collection of recovered cells. Antiserum directed against recovered cell membranes was shown to bind to recovered cells by indirect immunofluorescence. The antiserum also was shown to inhibit collection of recovered cells to aggregates, suggesting that at least some of the antigens identified might be involved in the adhesion process. The inhibitory effect of the antiserum was dose dependent . Freshly trypsinized cells absorbed neither the immunofluorescence activity nor the adhesion-inhibiting activity. Recovered cells absorbed away both activities. In specificity studies, dorsal neural retina cells adhered to aggregates of ventral optic tectum in preference to aggregates of dorsal optic tectum. The adhesive specificity of the dorsal retina cells was less sensitive to trypsin than the adhesive specificity of ventral retina cells which adhered preferentially to dorsal tectal aggregates only after a period of recovery.     

Intercellular adhesive selectivity. I. An improved assay for the measurement of embryonic chick intercellular adhesion (liver and other tissues)

An improved assay for measuring intercellular adhesive selectivity of embryonic chick liver cells is described. Three major improvements over earlier procedures are noted: (a) enhanced reproducibility of liver cell-liver cell aggregate adhesion (homotypic adhesion) was achieved; (b) 25-70% of the input cells adhered to the collecting aggregates during the course of routine experiments as compared to the 0.25% in earlier assays. This increase in cellular adhesion suggests that the observed cell pick-up is a characteristic of the majority of the dissociated liver cell population; (c) the rate of intercellular adhesion was increased 1,000-fold. The main feature of the assay is that it measures the tissue adhesive selectivities of the dissociated cell population. Studies were undertaken on three embryonic chick tissues (liver, neural retina, and mesencephalon) to determine the tissue selectivity of intercellular adhesion of these dissociated cell types. Some general properties of liver cell homotypic adhesion have been studied and are reported.     

Requirements for the Ca2+-independent component in the initial intercellular adhesion of C2 myoblasts

Using a sensitive and quantitative adhesion assay, we have studied the initial stages of the intercellular adhesion of the C2 mouse myoblast line. After dissociation in low levels of trypsin in EDTA, C2 cells can rapidly reaggregate by Ca2+-independent mechanisms to form large multicellular aggregates. If cells are allowed to recover from dissociation by incubation in defined media, this adhesive system is augmented by a Ca2+-dependent mechanism with maximum recovery seen after 4 h incubation. The Ca2+-independent adhesion system is inhibited by preincubation of cell monolayers with cycloheximide before dissociation. Aggregation is also reduced after exposure to monensin, implicating a role for surface-translocated glycoproteins in this mechanism of adhesion. In coaggregation experiments using C2 myoblasts and 3T3 fibroblasts in which the Ca2+-dependent adhesion system was inactivated, no adhesive specificity between the two cell types was seen. Although synthetic peptides containing the RGD sequence are known to inhibit cell-substratum adhesion in various cell types, incubation of C2 myoblasts with the integrin-binding tetrapeptide, RGDS, greatly stimulated the Ca2+-independent aggregation of these cells while control analogs had no effect. These results show that a Ca2+- independent mechanism alone is sufficient to allow for the rapid formation of multicellular aggregates in a mouse myoblast line, and that many of the requirements and perturbants of the Ca2+-independent system of intercellular myoblast adhesion are similar to those of the Ca2+-dependent adhesion mechanisms.     

Calcium-dependent adhesion of Drosophila embryonic cells

Summary By using an in vitro functional assay, we have shown that Drosophila embryonic cells possess Ca²⁺-dependent adhesive sites, which resemble in many respects those described for vertebrate cells and tissues. The cells, obtained by mechanical disruption of gastrulastage embryos, form aggregates within 30 min when maintained under constant rolling. The aggregation is completely dependent on the presence of Ca²⁺ in the medium. In its absence, the cells remain dispersed but the process is reversible by readdition of Ca²⁺. In addition the aggregation is temperature-dependent. No aggregation occurs at 4° C but it can be restored by raising the temperature to 25° C. These properties are characteristic of these cells: established cell lines do not aggregate under the same conditions and mixing of cell lines and embryonic cells does not result in chimeric aggregates, thus pointing towards cell-type selectivity with respect to aggregability. Observations in electron microscopy have shown that the embryonic cells in the aggregates tightly adhere to one another and form, as early as after 30 min, maculae adherens junctions. Drosophila embryonic cells have adhesion sites that are protected from trypsin proteolysis in the presence of Ca²⁺ and sensitive in its absence. The cells' aggregation can be inhibited by a mouse antiserum directed against cell-surface components and a good correlation exists between neutralization of the inhibitory activity of the antiserum and the presence of trypsin-sensitive sites on the cells. These data are in favour of cell-cell adhesion mediated by specific adhesion proteins.     

Specificity of cell-cell interactions in sea urchin embryos: Appearance of new cell-surface determinants at gastrulation

Studies on normal and hybrid sea urchin embryos show that, beginning at gastrulation, hybrid cells express cell-surface antigens specific to both species. The appearance of these antigens is shown to be correlated with a change in the adhesive specificity of hybrid cells: Beginning at gastrulation, hybrid cells recognize and adhere to embryonic cells of both normal genotypes. Prior to gastrulation, hybrid cells adhere to cells of the maternal genotype only. Two adhesion assays demonstrate these adhesive preferences. (i) When cell aggregates are placed together in a dish, Lytechnius aggregates fuse together, and Tripneustes aggregates fuse together, but aggregates of the two species do not fuse with each other. Hybrid cell aggregates, if they are past the beginning of gastrulation, fuse to both Tripneustes and Lytechinus aggregates. (ii) In a collection assay, midgastrula cells of the hybrid embryos are collected at a high rate to aggregates of either species. Pregastrula hybrid cells collect at a high rate to aggregates of the maternal species only. This change in adhesive preference is temporally correlated with the appearance of new cell surface antigens. Antiserum was prepared in rabbits against membranes from Lytechinus gastrulae. Indirect immunofluorescence tests show that hybrid cells of the cross (T♀ × L♂) express Lytechinus-specific antigens at the cell surface beginning at gastrulation. Furthermore, an apparent relationship between the new cell-surface antigens and adhesion exists in that Lytechinus cell adhesion is inhibited specifically after binding Fab fragments of the Lytechinus antiserum. The antiserum has no effect on Tripneustes adhesion. The Lytechinus adhesion-inhibiting activity can be removed by absorption of the antiserum with Lytechinus cells.     

Inhibition of intercellular adhesion by concanavalin A is associated with concanavalin A-mediated redistribution of surface receptors

The inhibition of adhesion between aggregates and layers of embryonic retinal cells by concanavalin A (Con A) and Con A-mediated rearrangements of Con A receptors on retinal cells were studied. A short incubation of aggregates and layers with 10 micrograms/ml Con A substantially reduced aggregate-to-layer adhesion in a subsequent assay without soluble lectin present. This effect of Con A was dose-dependent, temperature-sensitive, involved events subsequent to Con A binding, and was reduced by cytochalasin B. The inhibition produced by succinylated Con A was substantially increased by incubation with antibody to Con A. Visualization of ConA- receptor complexes by fluorescence microscopy revealed that binding of Con A induced clearing of Con A receptors from filopodia, flattened regions of growth cones, and the edges of axons. This clearing reaction was prevented by the same agents that reduced Con A's inhibition of cell adhesion: low temperature, succinylation of Con A, or cytochalasin B. Aggregate-layer adhesion was restored by releasing Con A at 37 degrees C. Inhibitors of protein and ATP synthesis did not prevent recovery of ability to make adhesions. However, release of Con A at lowered temperatures did not prevent recovery. The results suggest that intercellular adhesion is inhibited by events associated with redistribution of Con A-receptor complexes on retinal cells.     

Some effects of trypsin dissociation on the inhibition of reaggregation among embryonic chicken neural retina cells by cycloheximide

The effects of cycloheximide on the reaggregation of trypsin-dispersed, embryonic chicken, neural retina cells were investigated. The cells were used either immediately after isolation (F-cells), or after 24 hr prior culture under conditions not permitting reaggregation (V-cells). The parameters of aggregation used were the size of aggregates formed in gyrotatory shaker cultures, and the concentration of single cells in these cultures. At both 24 and 48 hr, following treatment with cycloheximide, the mean diameters of the aggregates of F-cells showed a greater reduction than the V-cells, when compared with their corresponding controls. In addition, cycloheximide resulted in a higher concentration of single cells, that is less cell/cell adhesion, than in comparable controls. A higher proportion of single cells were present in the F-cell cultures in the presence of cycloheximide than in the V-cell cultures. Thus, the degree of inhibition of cell adhesion by one inhibitor of protein synthesis differed in F-cells and V-cells. These experiments may serve to focus attention on some secondary effects of tryptic dissociation, which is an often overlooked factor in subsequent studies of reaggregating embryonic cells, particularly in those experiments involving the use of metabolic inhibitors.     

Intercellular adhesive selectivity. III. Species selectivity of embryonic liver intercellular adhesion

A species difference in the intercellular adhesive selectivity of mixtures of embryonic liver cells is reported. This is first quantitative assessment of species differences in the intercellular adhesive properties of embryonic cells. A collecting aggregate assay, a new double-label assay procedure, and histological and autoradiographic procedures were used to elucidate the intercellular adhesive selectivity of developing mammalian and avian liver cells. Evidence is presented that the reported adhesive differences are not due to the different cell types composing the respective embryonic mammalian and avian livers. Finally, such heterolgous-homotypic selectivity of adhesion is not a property of all tissues, since it is shown that developing brain cells (mesencephalon) do not exhibit the avove intercellular adhesive selectivity (mammalian vs. avian). These findings provide further support for the hypothesis that generic identity as well as cell type may play an important part in determining the intercellular adhesive behavior of heterologous-homotypic mixtures of embryonic cells. A possible evolutionary divergence of morphogenetic mechanisms is discussed.     

An analysis of the recovery of tetrahymena from effects of cycloheximide

When cycloheximide (0.2 μg per ml) was added to synchronized cultures of Tetrahymena pyriformis GL-C, the initial rate of incorporation of ¹⁴C-leucine was reduced to about 20% of the rate observed in control cells. After one hour, the rate increased fairly abruptly to about 60% of the control rate. The cells in cycloheximide underwent synchronous division about three hours after addition of cycloheximide. A second addition of cycloheximide had little effect on either the rate of incorporation or on the time of cell division in the drug. The medium in which cells had recovered brought about full inhibition of ¹⁴C-leucine incorporation in fresh cells, indicating that recovery was not accompanied by appreciable degradation of the cycloheximide. It was therefore concluded that during recovery the cells were either adapting to the cycloheximide or excluding it. The recovery process shows some specificity, since cells which had recovered from cycloheximide, and had become insensitive to a second dose of this drug, still retained full sensitivity to another drug, colchicine. Conversely, cells recovering in colchicine became insensitive to fresh colchicine but remained sensitive to cycloheximide.     

Cell-to-cell adhesion of dissociated embryonic brain cells; the effects of metabolic inhibitors and temperature

Brain cells from 16 to 18-day-old mice embryos were dissociated by mild trypsinization and rotated for 120 min. The area and density of of the adhesive complexes formed were registered using the method described previously. The adhesiveness of dissociated embryonic brain cells (measured during the 120 min of rotation) was diminished in the presence of inhibitors of protein synthesis (puromycin, cycloheximide and inhibition of mRNA synthesis actinomycin D). The inhibition was, however, not distinct, because 1 microgram/ml of cycloheximide and actinomycin was without any significant effect, and the degree of inhibition evoked by 10 micrograms/ml and 25 micrograms/ml of puromycin bordered on significance. However, protein synthesis inhibitors in long-term aggregation experiments had a pronounced inhibitory effect and/or induced destruction of the aggregates. Metabolic inhibitors (KCN and NaN3) caused an inhibition at the lowest level of significance (p less than 0.05) 10(-3) mol/l KCN reduced the final adhesive product significantly. Cells rotated at room temperature and at +5 degrees C adhere to the same extent as in control experiments (37 degrees C). The adhesion was significantly inhibited at +60 degrees C and also after freezing at -80 degrees C with subsequent thawing. The adhesion of cells exposed for 30 min to between +80 degrees C and 100 degrees C was completely abolished. The process of embryonic brain cell adhesion requires a low energy supply, and is relatively independent of biosynthetic processes and of temperature changes between +5 degrees C and +50 degrees C.     

Can retinal adhesion mechanisms determine cell-sorting patterns: a test of the differential adhesion hypothesis

Embryonic chick neural retina cells possess two classes of adhesion mechanism, one Ca2+-independent, one Ca2+-dependent, responsible for short-term cell aggregation. This study investigates the role of these mechanisms in the long-term cell sorting potentially relevant to in vivo histogenesis. Retina cells are prepared either with both (E cells) or with only one mechanism (TC cells, CD; LTE cells, CI), respectively. The two types of cell preparations are differentially labelled using fluorescein or rhodamine isothiocyanate, mixed and allowed to aggregate in the presence or absence of cycloheximide at 0.5 microgram ml-1 to retard metabolic recovery of the removed adhesive mechanism. When observed by fluorescence and phase-contrast microscopy, the aggregates formed in cycloheximide show cell sorting, the cells with both mechanisms assuming a more interior position relative to those with a single adhesion mechanism. In parallel hanging-drop experiments, preformed aggregates of cells with a single adhesion mechanism are seen to spread upon aggregates of cells with both mechanisms. No sorting occurs amongst cells from a given stage prepared using any single dissociation protocol. The observed cell sorting would thus seem to derive exclusively from differential cell adhesiveness dependent upon the different dissociation conditions and maintained in the presence of cycloheximide. The experiments support the hypothesis that the dual CI and CD adhesion mechanisms in question can play a central role in governing cell-sorting behaviour during normal histogenesis.     

Acquisition of synchronous beating between embryonic heart cell aggregates and layers

Synchronous beating between chick embryonic heart cell aggregates and heart cell layers was used to study the relationship between intercellular adhesion and ionic coupling. Adhesion was measured by counting the proportion of aggregates which were not to be removed from cell layers by gentle washing after a 30 min incubation. Synchrony between bound aggregates and contiguous layers was assessed by phase microscopy. The first evidence of synchrony was seen 1.5 h after addition of aggregates to layers, following which there was an increase in the percentage of aggregates beating synchronously, reaching over 50% at 7 h and slowly increasing to a maximum of 65% by 24 h. Scanning electron microscopy and autoradiography of thymidine-labeled cells suggest that synchrony does not depend on cell movement at the interface between aggregate and layer. Acquisition of synchrony can be prevented completely by inhibiting protein synthesis, although pulsation of aggregates and layers continues in proportions unchanged from controls. After reversal of protein synthesis inhibition, synchrony is acquired at a rate and to an extent closely resembling that of newly adherent controls. These data indicate that ionic coupling is neither an inevitable nor an immediate consequence of adhesion. Since ionic coupling has been shown to correlate with the presence of gap junctions, the findings suggest that gap junctions are not involved in the initial events responsible for intercellular adhesion in vitro and that their formation following adhesion in this system may depend upon protein synthesis.     

Intercellular adhesive selectivity. II. Properties of embryonic chick liver cell-cell adhesion

Studies directed at understanding the molecular basis of liver cell homotypic adhesion are presented. An assay which measures the rate of adhesion of isotopically labeled (32PO4) embryonic chick liver cells to liver cell aggregates, described in a companion paper, has been used to investigate the problem of intercellular adhesive selectivity. Cation requirements, the effects of various inhibitors of metabolism and protein synthesis, of chelators (EDTA and EGTA), and the effects of temperature on liver cell adhesion are reported. Two mechanisms of inhibition of liver intercellular adhesion are suggested. One involves destruction of cell-surface adhesion receptors (sensitivity to proteases); the other is an energy-dependent step which may involve alterations in plasma membrane conformation and/or membrane fluidity. Finally, a model is suggested for liver cell-cell adhesion that incorporates the early tissue selectivity of intercellular adhesion previously reported, followed by a multistep process which leads to histogenic aggregation.     

Multiple influences of a heparin-binding growth factor on neuronal development

Heparin-binding growth factor-2 (HBGF-2; also known as basic fibroblast growth factor) is mitogenic for most anchorage-dependent cells. It is shown here that HBGF-2 stimulates cell-substratum adhesion and neurite extension in the sympathetic nerve cell line PC12. When HBGF-2 is adsorbed to artificial extracellular matrices consisting of heparin or chondroitin sulfate, it causes the formation of cellular aggregates or circles of cells, respectively. HBGF-2 is also a nerve cell survival molecule, for it potentiates the survival of primary cultures of embryonic chick ciliary ganglion cells but not of embryonic neural retina cells. Finally, a series of synthetic peptides from the HBGF-2 sequence is described that selectively alter the biological effects of HBGF-2. The amphiphilic nature of one of these peptides is discussed with respect to its ability to stimulate cell adhesion.     

A rapid assay for fusion of embryonic chick myoblasts

A rapid and sensitive assay for measuring myoblast fusion in suspension cultures of embryonic chick pectoral myoblasts is described. Fusion-competent cells are generated by growth in suspension using a low calcium medium. Fusion-promoting levels of calcium are added, and the suspensions incubated for 1–6 h. The cells are then trypsinized to disperse cellular aggregates and sized in a Coulter particle counter. This assay minimizes many of the artifacts inherent in measurements of fusion in monolayer cultures, and is designed for the rapid screening of agents for their effects on fusion.     

Intercellular adhesion

Summary A quantitative procedure for determining the early kinetics of cell aggregation (adhesion) is described. The cells used for this study were obtained by dissociation of 8-day-old embryonic chicken neural retina with crude trypsin. The method is based on determining the decrease in single cells in an aggregating population with the Coulter electronic particle counter. A variety of experiments show that the method is reproducible and capable of detecting relatively small changes in the rate of aggregation. Using a number of criteria, the loss of single cells from the population with increasing time of incubation was shown to result from the formation of aggregates, and not from other phenomena such as cell death or changes in cell permeability. The intercellular adhesions formed under these conditions were stable to mechanical shear and to ethylenediaminetetraacetate, and were partially resistant to crude trypsin. The logarithm₁₀ of the number of single cells in the population was found to be directly related to the time of incubation. The slope of the resultant straight lines could be used as a measure of the rate of aggregation. No lag in aggregation was demonstrable under the standard assay conditions. the rate was affected by the initial cell density, speed of rotation during aggregation, temperature, and by Ca²⁺ and Mg²⁺. It was not affected by inhibitors of protein synthesis, metabolic inhibitors, ATP, ADP, cyclic-AMP, or horse serum at 37 °C. The quantitative method for determining the initial rate of adhesion should be applicable to studies on the chemistry of this process.Contribution No. 557 from the McCollum-Pratt Institute.     

Developmental control of 2-aminoisobutyric acid transport by 7-and 14-day chick heart cell aggregates. Roles of insulin and amino acids.

Cell aggregates cultured from 7-day embryonic avian heart showed a spontaneous increase in A-system 2-aminoisobutyric acid transport when placed in protein-free and amino acid-free buffer for 3 hr. The apparent V_max increased from 4.0 to 9.9 nmoles/μl of intracellular fluid volume/10 min in 3 hr. l-Proline (5 mM), an amino acid transported primarily by the A system, prevented this rise, but l-phenylalanine, primarily an L-system substrate, had no effect. Actinomycin, puromycin, and cycloheximide (55 μM) also prevented the time-dependent increase in transport. In contrast, cell aggregates cultured from 14-day embryonic heart exhibited a decrease in apparent V_max during the 3-hr incubation, from 8.3 to 3.3 nmoles/μl of intracellular volume/10 min. l-Proline, but not l-phenylalanine, enhanced this decrease in A-system transport. The percentage proline inhibition of transport was reduced by actinomycin or cycloheximide (55 μM) at both ages. Insulin stimulated A-system transport at identical half-maximal concentrations of 18 nM at 7 and 14 days of embryonic development. In the presence of cycloheximide at 7 days of age, insulin prolonged the half-life of transport activity twofold. However, at 14 days, cycloheximide reduced the insulin response by 88% [Elsas, L. J., Wheeler, F. B., Danner, D. J., and DeHaan, R. L. (1975). J. Biol. Chem.250, 9381–9390]. l-Proline or actinomycin reduced both basal and insulin-stimulated transport by 7-day cell aggregates, but neither reduced the percentage insulin stimulation. We conclude that inherent developmental control(s), A-system amino acids, and insulin regulated the maximal velocity of A-system transport by controlling the biological turnover of transport protein(s). l-Proline decreased the existing synthesis of transport protein(s) at both ages. The predominant effect of insulin shifted from a posttranslational level at 7 days to a synthetic level by 14 days of embryonic development. Seven-day cell aggregates spontaneously increased synthesis in the absence of A-system amino acids, but 14-day cell aggregates required hormonal stimulation to shift the balance from degradation to synthesis of transport protein(s).     

Cell-substratum adhesion strength as a determinant of hepatocyte aggregate morphology

Cultured hepatocytes typically form multicellular aggregates which are either monolayered or spheroidal in morphology. We propose that the aggregate morphology resulting from a particular cell-substratum interaction has a biophysical basis: when cell contractile forces are greater than cell-substratum adhesion forces, spheroidal aggregates form; when cell contractile forces are weaker than cell-substratum adhesion forces, cells remain essentially spread and form monolayered aggregates. We tested this hypothesis by systematically varying the morphology of hepatocellular aggregates formed on substrata coated with a series of different concentrations of Matrigel, and correlating aggregate morphology with the cell-substratum adhesion strength measured in a shear flow detachment assay. Aggregate morphology was binary-spheroidal aggregates formed at low Matrigel concentrations and monolayered aggregates formed at high Matrigel concentrations. Cell-substratum adhesion strength was similarly binary, with low adhesion strengths correlated with spheroidal aggregates and high adhesion strengths correlated with formation of monolayered aggregates. (c) 1997 John Wiley & Sons, Inc. Biotechnol Bioeng 53: 415-426, 1997.     

Adhesive specificity of developing cerebellar cells on lectin substrata

Ten lectins, each with a different carbohydrate-binding specificity, have been coupled to tissue culture substrata with carbodiimide [1-cyclohexyl-3-(2-morpholinoethyl)-carbodiimide-metho-p-toluene sulfonate] and assayed for their efficacy as substrates for the carbohydrate-specific adhesion of cells dissociated from mouse cerebellum at embryonic Day 13 and postnatal Days 0 and 7. On surfaces treated with concanavalin A, succinyl-concanavalin A, Lens culinaris agglutinin, and wheat germ agglutinin, both embryonic and early postnatal cerebellar cells formed a monolayer. On surfaces coupled with Ricinus communis_I agglutinin (120,000 daltons) both embryonic and postnatal cells formed cellular aggregates with extensive fiber outgrowth. On surfaces treated with peanut agglutinin, Dolichos bifloris agglutinin, Wistaria floribunda agglutinin, soybean agglutinin, or Ulex europaeus_I agglutinin, embryonic cerebellar cells formed cellular aggregates with a cell viability of 25–35% and little or no fiber outgrowth. Postnatal cerebellar cells, in contrast, formed cellular aggregates with a cell viability of 60–70% and extensive fiber outgrowth. On surfaces treated with Ulex europaeus_I agglutinin, cells from postnatal Day 7 formed limited areas of monolayer in addition to cellular aggregates. After 12 hr in vitro the specific attachment of cerebellar cells to lectin-derivatized substrata was inhibited 60–80% by the inclusion of free hapten carbohydrate (50–100 mM) in the growth medium. The addition of soluble concanavalin A or Ricinus communis_I agglutinin (100 μg/ml) was toxic. These studies suggest the presence of glycoconjugate-binding sites for concanavalin A, Lens culinaris agglutinin, and wheat germ agglutinin which promote cerebellar cellular adhesion.