Redistribution and shedding of flagellar membrane glycoproteins visualized using an anti-carbohydrate monoclonal antibody and concanavalin A

Two carbohydrate-binding probes, the lectin concanavalin A and an anti-carbohydrate monoclonal antibody designated FMG-1, have been used to study the distribution of their respective epitopes on the surface of Chlamydomonas reinhardtii, strain pf-18. Both of these ligands bind uniformly to the external surface of the flagellar membrane and the general cell body plasma membrane, although the labeling is more intense on the flagellar membrane. In addition, both ligands cross-react with cell wall glycoproteins. With respect to the flagellar membrane, both concanavalin A and the FMG-1 monoclonal antibody bind preferentially to the principal high molecular weight glycoproteins migrating with an apparent molecular weight of 350,000 although there is, in addition, cross-reactivity with a number of minor glycoproteins. Western blots of V-8 protease digests of the high molecular weight flagellar glycoproteins indicate that the epitopes recognized by the lectin and the antibody are both repeated multiple times within the glycoproteins and occur together, although the lectin and the antibody do not compete for the same binding sites. Incubation of live cells with the monoclonal antibody or lectin at 4 degrees C results in a uniform labeling of the flagellar surface; upon warming of the cells, these ligands are redistributed along the flagellar surface in a characteristic manner. All of the flagellar surface-bound antibody or lectin collects into a single aggregate at the tip of each flagellum; this aggregate subsequently migrates to the base of the flagellum, where it is shed into the medium. The rate of redistribution is temperature dependent and the glycoproteins recognized by these ligands co-redistribute with the lectin or monoclonal antibody. This dynamic flagellar surface phenomenon bears a striking resemblance to the capping phenomenon that has been described in numerous mammalian cell types. However, it occurs on a structure (the flagellum) that lacks most of the cytoskeletal components generally associated with capping in other systems. The FMG-1 monoclonal antibody inhibits flagellar surface motility visualized as the rapid, bidirectional translocation of polystyrene microspheres.     

The effect of diabetes on hepatocyte plasma membrane fluidity and concanavalin A-induced agglutination

The techniques of fluorescence polarization and lectin-induced agglutination have been utilized to investigate the effects of the diabetic state on some of the dynamic properties of cell membranes. Hepatocyte plasma membranes from streptozotocin-induced diabetic rats exhibited a significant decrease in cholesterol and sialic acid with no alteration in phospholipid content. This membrane system also exhibited a decrease in fluorescence polarization, using the fluorescent probe, 1,6-di-phenyl-1, 3,5-hexatriene, suggesting an increase in membrane fluidity over the value observed in normal hepatocytes. When normal hepatocytes were incubated in the presence of the lectin, concanavalin A (ConA), no significant agglutination was observed. In contrast, hepatocytes from diabetic rats which exhibited a slightly decreased lectin-binding capacity underwent extensive agglutination. In addition, normal hepatocytes which were pretreated with 0.1 mM tetracaine also underwent extensive agglutination with no measurable increase in lectin-binding capacity. These results suggest that altered membrane lipid fluidity and/or cytoskeletal organization may have a profound effect on cell surface dynamics and could result in the uncoupling of the insulin receptor complex from the membrane-associated effector system(s), a defect which may play a role in the problem of insulin resistance observed in some forms of diabetes.     

A lectin on the hemocyte membrane of the oyster (Crassostrea virginica)

Using antisera produced against a serum lectin we have shown by employing immunocytofluorescence that hemocytes from the oyster, Crassostrea virginica, possess a lectin which is situated on the external surface of the cell membrane. The antisera block the binding of hemocyte microsomes to protease-treated vertebrate erythrocytes, thus confirming that the hemocyte membrane lectin is serologically related to the serum lectin. The major serum lectin has an apparent mass of 34,000. Flow cytometry has revealed that the distribution of the surface lectin on hemocytes represents a heterogeneous expression on a population basis, but no discrete cell subpopulations can be identified.     

Coxsackievirus B3 infection alters plasma membrane of neonatal skin fibroblasts.

Replication of coxsackievirus B3 occurred for days in cultures of murine neonatal skin fibroblasts in the absence of cytopathology and resulted in alteration of the plasma membrane. Dual immunofluorescence studies showed that the lectin Ulex europaeus agglutinin I bound only to cells producing viral capsid antigens. Cultures of coxsackievirus B3-inoculated murine neonatal skin fibroblasts showed maximum binding of this lectin at 72 h postinoculation. These data show that in a nonlytic infection a picornavirus can alter the surface of an infected cell.     

Modulation of thymocyte membrane potential by concanavalin A.

Binding of convanavalin A, a potent mitogenic lectin, to thymocyte surface membrane causes depolarization of membrane potential. The effect is suppressed by alpha-methyl-D-glucoside, a haptenic inhibitor of this lectin, or by low temperature. Colchicine and cytochalasin B aslso suppress the change. These data indicate that perturbation of thymocyte surface membrane receptors induced by concanavalin A might be linked to change in the functional state of cellular cytoskeletal systems in turn causing depolarization of thymocyte surface membrane. The initial event generated by receptor-ligand interaction on the outer surface could be translated into cellular interior action only under highly fluid conditions of membrane lipid. Depolarization of thymocyte plasma membrane may be involved in the triggering mechanism of metabolic burst associated with blastoid transformation.     

Expression profiling of lymphocyte plasma membrane proteins

The physicochemical properties of plasma membrane proteins of mammalian cells render them refractory to systematic analysis by two-dimensional electrophoresis. We have therefore used in vivo cell surface labeling with a water-soluble biotinylation reagent, followed by cell lysis and membrane purification, prior to affinity capture of biotinylated proteins. Purified membrane proteins were then separated by solution-phase isoelectric focusing and SDS-PAGE and identified by high-pressure liquid chromatography electrospray/tandem mass spectrometry. Using this approach, we identified 42 plasma membrane proteins from a murine T cell hybridoma and 46 from unfractionated primary murine splenocytes. These included three unexpected proteins; nicastrin, osteoclast inhibitory lectin, and a transmembrane domain-containing hypothetical protein of 11.4 kDa. Following stimulation of murine splenocytes with phorbol ester and calcium ionophore, we observed differences in expression of CD69, major histocompatibility complex class II molecules, the glucocorticoid-induced TNF receptor family-related gene product, and surface immunoglobulin M and D that were subsequently confirmed by Western blot or flow cytometric analysis. This approach offers a generic and powerful strategy for investigating differential expression of surface proteins in many cell types under varying environmental and pathophysiological conditions.     

An analysis of concanavalin A-mediated agglutination in two Chinese hamster ovary subclones whose surface phenotypes respond to maintenance in medium supplemented with dibutyryl cyclic AMP. V. Biochemical composition of the plasma membrane.

We have used two Chinese hamster ovary subclones whose surface phenotype has been extensively investigated with regard concanavalin A-mediated cell-cell agglutination and concanavalin A-induced receptor site clustering to investigate what changes in membrane composition, if any, can be correlated with the concanavalin A-detected changes in surface phenotype. These cell clones are uniquely disposed for this purpose since maintenance of the cells under different growth conditions produces changes in agglutinability and receptor site mobility in one cell clone (H-7W) but not the other (K-1). After extensive characterization of the surface membranes of these two subclones we have been unable to identify any change in the membrane peptides, glycopeptide, cholesterol, or fatty acid composition which can be directly correlated with the concanavalin A-detected surface phenotypes. It is of particular interest to note that we have been unable to correlate the presence or absence of the large external transformation-sensitive glycoprotein with the relative mobility of the lectin receptors or with the degree of concanavalin A-mediated cell agglutination. Furthermore we have been unable, in this system, to corroborate earlier data suggesting a role for cholesterol in determining the relative mobility of the lectin receptors. Thus using a cell system consisting of genetically matched cell clones, we have been unable to identify any changes in the biochemical composition of the plasma membrane which might be associated with the surface phenotypes detected by concanavalin A.     

Lectin binding sites in Paramecium tetraurelia cells. I. Labeling analysis predominantly of secretory components

Though all three lectins tested (ConA, RCA II, WGA) bound to the entire cell membrane, none bound selectively to the docking site of secretory organelles (trichocysts); the same results were achieved with FITC-conjugates, or, on the EM level, with peroxidase- or gold-labeling. Only WGA triggered the release of trichocysts and none of the lectins tested inhibited AED-induced synchronous exocytosis. When exocytosis was triggered synchronously in the presence of any of these three lectins (FITC-conjugates), the resulting ghosts trapped the FITC-lectins and the cell surface was immediately afterwards studded with regularly spaced dots (corresponding to the ghosts located on the regularly spaced exocytosis sites). These disappeared within about 10 min from the cell surface (thus reflecting ghost internalization with a half life of 3 min) and fluorescent label was then found in approximately 6-10 vacuoles, which are several microns in diameter, stain for acid phosphatase and, on the EM level, contain numerous membrane fragments (otherwise not found in this form in digesting vacuoles). We conclude that synchronous massive exocytosis involves lysosomal breakdown rather than reutilization of internalized trichocyst membranes and that these contain lectin binding sites (given the fact free fluorescent probes did not efficiently stain ghosts). Trichocyst contents were analyzed for their lectin binding capacity in situ and on polyacrylamide gels. RCA II yielded intense staining (particularly of "tips"), while ConA (fluorescence concentrated over "bodies") and WGA yielded less staining of trichocyst contents on the light and electron microscopic level. Only ConA- and WGA-staining was inhibitable by an excess of specific sugars, while RCA II binding was not. ConA binding was also confirmed on polyacrylamide gels which also allowed us to assess the rather low degree of glycosylation (approximately 1% by comparison with known glycoprotein standards) of the main trichocyst proteins contained in their expandable "matrix". Since RCA II binding could be due to its own glycosylation residues we looked for an endogenous lectin. The conjecture was substantiated by the binding of FITC-lactose-albumin (inhibitable by a mixture of glucose-galactose). This preliminary new finding may be important for the elucidation of trichocyst function.     

Mass isolation of cell surface membrane fragments from pigeon heart.

Cell surface membrane fragments were isolated and purified by successive rate zonal and isopycnic centrifugation of calcium oxalate-loaded pigeon heart microsomes in sucrose density gradients. The most highly purified cell membrane fraction sediments at a buoyant density of 1.105 g/ml. Some of the membrane pieces are present as open fragments and leaky vesicles, while others form tightly sealed vesicles of both inside-in and inside-out membrane orientation. The pigeon heart cell membrane preparation exhibits high (Na+ + K+ + Mg2+)-ATPase and adenylate cyclase activities. Additional activity of these enzymes is uncovered by sodium dodecyl sulfate and alamethicin, respectively. Electron microscopic inspection of the cell surface membrane preparation revealed (a) a predominance of thick-walled vesicles with smooth surfaces on negative staining and (b) binding of concanavalin A to the bulk of isolated membrane pieces following their incubation with the lectin.     

Effects of local anesthetics on membrane properties. II. Enhancement of the susceptibility of mammalian cells to agglutination by plant lectins.

Treatment of untransformed mouse and hamster cells with the tertiary amine local anesthetics dibucaine, tetracaine and procaine increases their susceptibility to agglutination by low doses of the plant lectin concanavalin A. Agglutination of anesthetic-treated untransformed cells by low doses of concanavalin A is accompanied by redistribution of concanavalin A receptors on the cell surface to form patches, similar to that occurring in spontaneous agglutination of virus-transformed cells by concanavalin A. Immunofluorescence and freeze-fracture electronmicroscopic observations indicate that local anesthetics per se do not induce this redistribution of concanavalin A receptors but modify the plasma membrane so that receptor redistribution is facilitated on binding of concanavalin A to the cell surface. Fluorescence polarization measurements on the rotational freedom of the membrane-associated probe, diphenylhexatriene, indicate that local anesthetics produce a small increase in the fluidity of membrane lipids. Spontaneous agglutination of transformed cells by low doses of concanavalin A is inhibited by colchicine and vinblastine but these alkaloids have no effect on concanavalin A agglutination of anesthetic-treated cells. Evidence is presented which suggests that local anesthetics may impair membrane peripheral proteins sensitive to colchicine (microtubules) and cytochalasin-B (microfilaments). Combined treatment of untransformed 3T3 cells with colchicine and cytochalasin B mimics the effect of local anesthetics in enhancing susceptibility to agglutination by low doses of concanavalin A. A hypothesis is presented on the respective roles of colchicine-sensitive and cytochalasin B-sensitive peripheral membrane proteins in controlling the topographical distribution of lectin receptors on the cell surface.     

Evidence that a membrane bound lectin mediates fusion of L6 myoblasts.

The external membranes of L₆ myoblasts are shown to posses lectin activity which resides in protein molecules. Thiodigalactoside blocks agglutination of formalinized, trypsin treated rabbit red blood cells caused by the lectin. Thiodigalactoside at a concentration which neither inhibits cell division nor decreases cell yield prevents fusions of myoblasts. It is suggested that this protein which has lectin activity also is an essential participant in the membrane events which cause fusion of myoblasts to form myotubes.     

Biophysics of sphingolipids II. Glycosphingolipids: An assortment of multiple structural information transducers at the membrane surface

Glycosphingolipids are ubiquitous components of animal cell membranes. They are constituted by the basic structure of ceramide with its hydroxyl group linked to single carbohydrates or oligosaccharide chains of different complexity. The combination of the properties of their hydrocarbon moiety with those derived from the variety and complexity of their hydrophilic polar head groups confers to these lipids an extraordinary capacity for molecular-to-supramolecular transduction across the lateral/transverse planes in biomembranes and beyond. In our opinion, most of the advances made over the last decade on the biophysical behavior of glycosphingolipids can be organized into three related aspects of increasing structural complexity: (1) intrinsic codes: local molecular interactions of glycosphingolipids translated into structural self-organization. (2) Surface topography: projection of molecular shape and miscibility of glycosphingolipids into formation of coexisting membrane domains. (3) Beyond the membrane interface: glycosphingolipid as modulators of structural topology, bilayer recombination and surface biocatalysis.     

Developmentally-related changes in surface membrane glycopeptides of murine haemopoietic cells.

We have carried out a comparative study of mature murine granulocytes with two immature haemopoietic cell lines (multipotential cells, FDCP-Mix, and granulocyte progenitor cells, FDCP-2) with respect to the structure and composition of their surface membrane glycopeptides. The glycopeptides were labelled biosynthetically by incubation of the cells for 1-3 days with [3H]glucosamine. Cell-associated glycopeptides were released by treatment with trypsin and the trypsin extract was exhaustively digested with Pronase to remove most residual peptide. Radiolabelled materials were fractionated by chromatography on lectin affinity columns connected in the series: lentil lectin (LCA), concanavalin A (Con A) and wheat germ agglutinin (WGA). Lectin-binding glycopeptides were eluted with appropriate competing sugars and further analysed by gel filtration, base/borohydride elimination and susceptibility to degradation by glycosidases including endo-beta-galactosidase. Abundant quantities of N-linked polylactosamine-type glycopeptides, which bound only to the WGA columns, were identified on mature granulocytes but the molecules were highly-branched (i.e. resistant to endo-beta-galactosidase). In contrast, there seemed to be very little branching in the polylactosamine chains from FDCP-2 cells, whilst corresponding carbohydrates from multipotential FDCP-Mix cells gave evidence for both linear and branched domains in the same, large complex glycans. O-Linked tetrasaccharides of general structure: NeuAc-Gal-(NeuAc)-GalNAc were found in clusters on WGA-binding glycopeptides from all cell types, these components being especially prominent on mature granulocytes. FDCP-2 cells were distinguished by the presence of monosialylated and non-sialylated counterparts of the foregoing tetrasaccharides. The relative amount of LCA-binding glycopeptides was low on FDCP-Mix cells by comparison with FDCP-2 cells and mature granulocytes. Our findings therefore demonstrate that notable differences in gross composition and molecular fine structure of surface membrane glycopeptides are detectable in haemopoietic cells at different stages of development. The relationship of these differences to the biological properties of cell surfaces remains to be established.     

Platelet plasma membrane lectin activity

The lectin activity of human platelet and erythrocyte membranes was evaluated using trypsinized, formalinized erythrocytes from eight species. Platelet membranes had the greatest lectin activity against cow erythrocytes, but also had significant activity against human, sheep, electric eel, and rabbit erythrocytes. In contrast, erythrocyte membranes only had low lectin activity against electric eel erythrocytes with no activity against the other types of erythrocytes tested. The platelet membrane lectin activity was found to reside in protein molecules on the external surface of the platelet plasma membrane. The lectin activity of platelet membranes was inhibited by amino sugars and some basic amino acids: N-acetylated amino sugars and other neutral sugars were without effect. These results demonstrate that the external surface of the platelet plasma membrane has a specific lectin activity.     

Solubilization and enrichment of boar sperm membrane proteins

Boar sperm membranes are rather resistent to the solubilizing effect of some detergents. Deoxycholate, an ionic detergent, was efficient in solubilizing sperm proteins but some nonionic detergents like Triton X-100 displayed relatively poor capacity in rendering membrane proteins soluble. This may be due to sperm proteins being attached to submembraneous structures through bonds involving divalent cations, since mixtures of Triton X-100 and ethylenediamine tetraacetic acid (EDTA) were almost as efficient as deoxycholate in solubilizing membrane proteins. Since intact spermatozoa were directly treated with detergents the solubilized proteins comprised a mixture of intracellular and membrane components. To enrich for membrane proteins, affinity chromatography on columns containing different lectins was carried out. SDS polyacryiamide gel electrophoresis of sperm glycoproteins desorbed from the various lectin columns demonstrated that each lectin bound a unique set of components although most glycoproteins were recovered from two or more columns. Columns containing Lens culinaris hemagglutinin yielded more sperm glycoproteins than any of the other lectin columns examined. The predominant amount of the sperm proteins recovered from the Lens culinaris lectin column was membrane derived, as the majority of the proteins were integrated into liposomes. It is concluded that sperm membrane proteins are efficiently solubilized by detergent in the presence of a chelator and that most of the membrane glycoproteins can easily be enriched by affinity chromatography on a lectin column. Proteins obtained in this way should serve as excellent starting material for the isolation of individual sperm membrane proteins.     

Effects of local anesthetics on membrane properties II. Enhancement of the susceptibility of mammalian cells to agglutination by plant lectins

Treatment of untransformed mouse and hamster cells with the tertiary amine local anesthetics dibucaine, tetracaine and procaine increases their susceptibility to agglutination by low doses of the plant lectin concanavalin A. Agglutination of anesthetic-treated untransformed cells by low doses of concanavalin A is accompanied by redistribution of concanavalin A receptors on the cell surface to form patches, similar to that occurring in spontaneous agglutination of virus-transformed cells by concanavalin A. Immunofluorescence and freeze-fracture electronmicroscopic observations indicate that local anesthetics per se do not induce this redistribution of concanavalin A receptors but modify the plasma membrane so that receptor redistribution is facilitated on binding of concanavalin A to the cell surface. Fluorescence polarization measurements on the rotational freedom of the membrane-associated probe, diphenylhexatriene, indicate that local anesthetics produce a small increase in the fluidity of membrane lipids. Spontaneous agglutination of transformed cells by low doses of concanavalin A is inhibited by colchicine and vinblastine but these alkaloids have no effect on concanavalin A agglutination of anesthetic-treated cells. Evidence is presented which suggests that local anesthetics may impair membrane peripheral proteins sensitive to colchicine (microtubules) and cytochalasin-B (microfilaments). Combined treatment of untransformed 3T3 cells with colchicine and cytochalasin B mimics the effect of local anesthetics in enhancing susceptibility to agglutination by low doses of concanavalin A. A hypothesis is presented on the respective roles of colchicine-sensitive and cytochalasin B-sensitive peripheral membrane proteins in controlling the topographical distribution of lectin receptors on the cell surface.     

Monoclonal antibodies to endogenous galactose-specific tumor cell lectins.

A monoclonal antibody, 5D7, was obtained after immunization of syngeneic mice with B16 melanoma cell extracts enriched for endogenous lectin activity and screening for inhibition of lectin-mediated hemagglutination. Binding of this antibody to affinity-purified B16 melanoma galactoside-specific lectin was revealed by solid-phase radioimmunoassay and binding to the surface of viable B16 cells was demonstrated by indirect immunofluorescence. Inhibition of lectin activity and cell surface labeling by 5D7 antibody were also found with several types of cultured human and murine cells including melanoma, sarcoma and carcinoma. This monoclonal antibody should be useful for evaluating the role of tumor cell surface lectins in intercellular interactions and metastasis.     

High-resolution electron microscopical study of cyst walls of Entamoeba spp

Knowledge of the fine structural organization, molecular composition and permeability properties of the cell surface of intestinal protozoan cysts is important to understand the biologic basis of their resistance. Recent studies on the biology of the cyst walls of Entamoeba histolytica and Entamoeba invadens have considerably advanced knowledge on the cellular processes involved in the transport and surface deposition of the main cyst wall components. Using transmission electron microscopy, cytochemistry, scanning electron microscopy and freeze-fracture techniques, we have obtained new information. In mature cysts the permeability of Entamoeba cysts is limited to small molecules not by the cyst wall, but by the plasma membrane, as demonstrated with the use of ruthenium red as an electron-dense tracer. Cell walls of E. histolytica cysts are made up of five to seven layers of unordered fibrils 7-8 nm thick. Alcian blue stains a regular mesh of fibrils approximately 4 nm thick, running perpendicularly to the cyst wall. In addition, abundant ionogenic groups are seen in cyst walls treated with cationized ferritin. In the mature cysts of E. histolytica and E. invadens small cytoplasmic vesicles with granular material were in close contact with the plasma membrane, suggesting a process of fusion and deposition of granular material to the cell wall. The plasma membrane of mature cysts is devoid of intramembrane particles when analyzed with the freeze-fracture technique. When viewed with scanning electron microscopy the surface of E. histolytica cysts clearly differs from that of Entamoeba coli and E. invadens.     

Antitumor and proapoptotic effect of Abrus agglutinin derived peptide in Dalton's lymphoma tumor model

Abrus agglutinin peptide fractions obtained from 10 kD molecular weight cut off membrane permeate (10 kMP), was shown to have selective antiproliferative activity on several tumor cell lines with induction of apoptosis through mitochondrial pathway. The present study was designed to evaluate acute general toxicity and in vivo therapeutic effectiveness of 10 kMPP in Dalton's lymphoma (DL) mice model. The acute toxicity like body weight, peripheral blood cell count, lympho-hematological and biochemical parameters remained unaffected with 1mg/kg body weight and lower of 10 kMPP. The in vivo antitumor study indicated that there were 27%, 58.5% and 84.5% reduction in DL cell survival in 100, 200 and 500 microg/kg body weight of 10 kMPP, respectively. Analysis of the growth inhibitory mechanism in DL cells revealed nuclear fragmentation and condensation with appearance of the sub G0/G1 peak is indicative of apoptosis. Further, the Western blotting showed apoptosis was mediated by reduction in ratio of Bcl-2 and Bax protein expression, and activation of caspase-3 through release of cytochrome-c in DL cells. Kaplan-Meier survival analysis showed an effective antitumor response (53 ILS%) with dose of 500 microg/kg body weight. Our result showed that the novel peptides present in Abrus agglutinin possess potent antitumor properties which need to be further explored.     

Adhesivity and rigidity of erythrocyte membrane in relation to wheat germ agglutinin binding

Binding of the plant lectin wheat germ agglutinin (WGA) to erythrocyte membranes causes membrane rigidification. One of our objectives has been to directly measure the effects of WGA binding on membrane rigidity and to relate rigidification to the kinetics and levels of WGA binding. Our other objective has been to measure the strength of adhesion and mechanics of cell separation for erythrocytes bound together by WGA. The erythrocyte membrane rigidity was measured on single cells by micropipette aspiration. The slope of the suction pressure-length data for entry into the pipette provided the measure of the membrane extensional modulus. Data were collected for cells equilibrated with WGA solutions in the range of concentrations of 0.01- 10 micrograms/ml. Erythrocyte-erythrocyte adherence properties were studied by micropipette separation of two-cell aggregates. First, a "test" cell was selected from a WGA solution by aspiration into a small micropipette, then transferred to a separate chamber that contained erythrocytes in WGA-free buffer. Here, a second cell was aspirated with another pipette and maneuvered into close proximity of the test cell surface, and adhesive contact was produced. The flaccid cell was separated from the test cell surface in steps at which the force of attachment was derived from the pipette suction pressure and cell geometry. In addition, we measured the time-dependent binding and release of fluorescently labeled WGA to single erythrocytes with a laser microfluorometry system. The results showed that the stiffening of the erythrocyte membrane and binding of fluorescently labeled WGA to the membrane surface followed the same concentration and time dependencies. The threshold concentration for membrane stiffening was at approximately 0.1 microgram/ml where the time course to reach equilibrium was close to 1 h. The maximal stiffening (almost 30-fold over the normal membrane elastic modulus) occurred in concentrations greater than 2 micrograms/ml where the time to reach equilibrium took less than 1 min. The WGA binding also altered the normal elastic membrane behavior into an inelastic, plastic-like response which indicated that mechanical extension of the membrane caused an increase in cross-linking within the surface plane. Similar to the stiffening effect, we observed that the membrane adhesivity of cells equilibrated with WGA solutions greatly increased with concentration greater than 0.1 microgram/ml.(ABSTRACT TRUNCATED AT 400 WORDS)