A comparison of ligand-induced redistribution of surface immunoglobulins, alloantigens, and concanavalin A receptors on mouse lymphoid cells

Redistribution of surface immunoglobulins (Ig), H-2^b, Thy-1.2 and TL. 1,2,3 alloantigens, and concanavalin A (Con A) receptors on mouse thymus, lymph node and spleen cells into “caps” induced by bivalent antibodies or ligands was compared by immunofluorescence. Surface Ig was capped rapidly following attachment of anti-Ig antibody at 37°. Capping of alloantigens and Con A receptors occurred very slowly following attachment of alloantibody or Con A, but much more rapidly after addition of a secondary bivalent antibody. An inverse relationship between the number of surface component sites per cell and the extent of capping of that component was observed. Capping of alloantigens sparsely represented on the cell surface was not inhibited by high concentrations of alloantibody, in contrast to capping of alloantigens present in greater quantities. These results suggest that factors in addition to molecular cross-linking may be involved in ligand-induced redistribution of cell surface components.     

Ligand-loaded but not free complement receptors for C3b/C4b and C3d co-cap with cross-linked B cell surface IgM and IgD

We have performed experiments to investigate possible physical interactions between C receptors (CR) and surface Ig (sIg) on the B cell plasma membrane. These molecules were found to be independent, non-linked, B cell surface structures, because capping CR1, CR2, sIgM, or sIgD with a specific antibody did not affect the distribution of the remainder of these molecules. Both CR1 and CR2, if bound by antibodies that did not independently cap CR, however, became associated with cross-linked sIg because CR that have been bound by intact anti-CR antibodies or their Fab fragments co-capped with sIgM or sIgD that had been bound by divalent anti-IgM or anti-IgD antibody. CR1 that had bound C3b similarly co-capped with sIg when sIg was cross-linked. Ligand-bound or even cross-linked CR did not associate with non-cross-linked sIg because sIgD, bound by a univalent Fab fragment of anti-IgD antibody, did not co-cap with CR that had been cross-linked by a sandwich of mouse anti-CR antibody and goat anti-mouse Ig. Other surface molecules, such as B1 and HLA-DR Ag, when bound by specific antibodies, did not cap with cross-linked sIg, and sIgD, when bound by a univalent Fab fragment of anti-IgD antibody, did not co-cap with cross-linked sIgM. Interactions between CR and sIg were not mediated by an association with IgG FcR because co-capping of CR and sIg was observed when F(ab')2 fragments of both anti-CR and anti-Ig antibodies were used. These results demonstrate that B cell surface CR can become associated with sIg, but only if sIg is cross-linked and CR is bound by anti-CR antibody or has bound its natural ligand.     

Polymerization of additional actin is not required for capping of surface antigens in B-lymphocytes

CH12 is a murine B-cell lymphoma whose surface immunoglobulin (sIg) and concanavalin A (Con A) receptors patch and cap readily. Actin may be involved in CH12 patching and capping, since fodrin and F-actin collect under the cap, and cytochalasin D inhibits sIg capping. We have examined the state of the actin cytoskeleton during patching and capping. A wide range of concentrations of rabbit anti-mouse antibody (RAM) and Con A were used to patch or cap CH12 cells. G-actin was quantitated by DNase I inhibition, F-actin was quantitated by fluorescence-activated cell sorter analysis of fluorescent phalloidin staining, and actin nucleation sites were measured by pyrene actin polymerization. None of these methods detected any significant changes in actin when compared to control cells or untreated cells, leading us to conclude that increased actin polymerization is not necessary for capping to occur. The significance of these data to the membrane flow and cytoskeletal models of capping is discussed.     

FACTORS AFFECTING THE REDISTRIBUTION OF SURFACE-BOUND CONCANAVALIN A ON HUMAN POLYMORPHONUCLEAR LEUKOCYTES

Human neutrophil polymorphonuclear leukocytes (PMN) were studied to determine the influence of cellular locomotion upon the redistribution and capping of concanavalin A (Con A). Con A was detected by fluorescence (using Con A conjugated to fluorescein isothiocyanate [Con A-FITC]), or on shadow-cast replicas (using Busycon canaliculatum hemocyanin as a marker for Con A). After labeling with Con A 100 µg/ml at 4°C and warming to 37°C, locomotion occurred, and the Con A quickly aggregated into a cap at the trailing end of the cell. When locomotion was inhibited (with cytochalasin B, or by incubation in serum-free medium at 18°C) Con A rapidly formed a cap over the central region of the cell. Iodoacetamide inhibited capping. PMN labeled with FITC, a monovalent ligand, developed caps at the tail only on motile cells; FITC remained dispersed on immobilized cells. PMN exposed to Con A 100 µg/ml at 37°C bound more lectin than at 4°C, became immobilized, and showed slow central capping. The Con A soon became internalized to form a perinuclear ring. Such treatment in the presence of cytochalasin B resulted in the quick formation of persistent central caps. Colchicine (or prior cooling) protected PMN from the immobilizing effect of Con A, and tail caps were found on 30–40% of cells. Immobilization of colchicine-treated cells caused Con A to remain in dispersed clusters. Thus, capping on PMN is a temperature- and energy-dependent process that proceeds independently of cellular locomotion, provided a colchicine-sensitive system is intact and the ligand is capable of cross linking receptors. On the other hand, if the cell does move, it appears that ligands may be swept into a cap at the tail whether cross-linking occurs or not.     

Correlation between movement of concanavalin A membrane receptors and cytolysis. A scanning electron microscopy study

The present study was undertaken to test whether cytolysis induced by Concanavalin A (Con A) requires lateral mobility of membranal lectin receptor sites into caps. Treatment of interphase murine mastocytoma cells with 10(-4) M colchicine promoted cap formation by Con A in about 30% of the cells, followed by cytolysis. Pretreatment of the cells with NaN3, low temperature, or glutaraldehyde decreased the degree of capping and, to the same extent, the degree of cytolysis. The addition of antibodies to cells bound with Con A increased the appearance of capping and cytolysis. A linear relationship with a high correlation coefficient exists between the degree of capping and cytolysis, suggesting that lateral mobility of membrane Con A receptors is required for cytolysis by the lectin. The process of cap formation by Con A up to the stage of cytolysis was followed by scanning electron microscopy.     

Isolation and initial biochemical characterisation of caps of two major rat thymocyte glycoproteins: evidence for the involvement of a 205 K Con A binding protein and cytoskeletal components in capping

Two major rat thymocyte surface glycoproteins, the leucocyte-common (L-C) antigen and the leucocyte sialoglycoprotein (LSGP), were induced to cap independently, using the specific monoclonal antibodies OX-1 and W3/13, respectively, and an appropriate fluorescently labeled second antibody layer. The caps were subsequently isolated from detergent extracted cells by a procedure involving gentle shearing. TRITC-phalloidin staining of the isolated caps demonstrated the presence of F-actin within these structures, and lectin-affinity staining after fractionation on SDS polyacrylamide gels revealed the presence of a concanavalin A (Con A) binding protein of relative molecular weight (Mr) 205,000, gp205, in both the L-C antigen and LSGP caps, but absent from the detergent-insoluble residue isolated from unchallenged cells. These results suggest that gp205 may be involved in the association of cross-linked glycoproteins with the cytoskeleton during capping.     

Two distinct mechanisms for redistribution of lymphocyte surface macromolecules. II. Contrasting effects of local anesthetics and a calcium ionophore

In the previous study, lymphocyte surface molecules were separated into two subsets depending on whether capping was associated was associated with redistribution of cytoplasmic myosin. In the present study, the effects of the local anesthetic chlorpromazine and of the Ca2+ ionophore {"type":"entrez-nucleotide","attrs":{"text":"A23187","term_id":"833253","term_text":"A23187"}}A23187 were compared. Both drugs affected the surface redistribution of immunoglobulin (Ig), Fc receptors, and the TL antigen- -molecules that appear to cap by association with microfilaments--but had no effect on the Thy.1 (theta) and H2 antigens--molecules that cap slowly, apparently unlinked to microfilament function. The capping of Ig, Fc receptor, and TL was inhibited while that of H2 and theta was not. Both drugs reversed the Ig Fc receptor, and TL caps but not the H2 and theta caps. In the former group, the reversal of caps was accompanied by a parallel reversal of the myosin segregated to the cap area. The appearance of myosin after drug treatment varied: chlorpromazine resulted in a diffuse pattern similar to that of normal lymphocytes, whereas {"type":"entrez-nucleotide","attrs":{"text":"A23187","term_id":"833253","term_text":"A23187"}}A23187 produced an array of aggregates and coarse filaments. The results are compatible with the view that two mechanisms for capping exist in the lymphocyte. The Ca2+ ionophore may affect capping of microfilament-dependent caps by producing a systemic activation of contractile proteins while chlorpromazine may act by disrupting a Ca2+-dependent link between surface complexes and the contractile proteins.     

Ligand-induced changes in the location of actin, myosin, 95K (alpha- actinin), and 120K protein in amebae of Dictyostelium discoideum

In this study we investigated concanavalin A (Con A) induced changes in the locations of actin, myosin, 120K, and 95K (alpha-actinin) to determine the extent to which actin and myosin are reorganized during capping and the roles that 120K and 95K might play in this reorganization. We observed the location of each protein by indirect immunofluorescence using affinity purified antibodies. Four morphological states were distinguished in vegetative Dictyostelium amebae: ameboid cells before Con A binding, patched cells, capped cells, and ameboid cells with caps. The location of each protein was distinct in ameboid cells both before and after capping Actin and 120K were found in the cell cortex usually associated with surface projections, and myosin and 95K were diffusely distributed. Myosin was excluded from surface projections in ameboid cells. During patching, all four proteins were localized below Con A patches. During capping, actin, myosin, and 95K protein moved with the Con A patches into the cap whereas 120K protein was excluded from the cap. During the late stages of cap formation actin and myosin were progressively lost from the cap, and 120K became concentrated in new actin-filled projections that formed away from the cap. However, 95K remained tightly associated with the cap. Poisoning cells with sodium azide inhibited capping but not patching of ligand. In azide-poisoned cells, myosin and 95K did not co-patch with Con A, whereas copatching of 120K and actin with Con A occurred as usual. Our results support the hypothesis that capping is an actomyosin-mediated motile event that involves a sliding interaction between actin filaments, which are anchored through the membrane to ligand patches, and myosin in the cortex. They are also consistent with a role for 120K in the formation of surface projections by promoting growth and/or cross-linking of actin filaments within projections, and with a role for 95K in regulating actomyosin-mediated contractility, earlier proposals based on the in vitro properties of these two proteins (Condeelis, J., M. Vahey, J. M. Carboni, J. DeMey, S. Ogihara, 1984, J. Cell Biol., 99:119s-126s).     

The capping of lymphocytes and other cells, studied by an improved method for immunofluorescence staining of frozen sections.

Experiments have been carried out on the capping by lectins and antibodies of surface receptors of mouse splenic T and B lymphocytes and other cells, in which the surface distribution of the lectin or antibody, and the intracellular distribution of myosin or actin, were determined on the same cells by a double fluorescence technique. For this purpose, a general method for intracellular staining was developed which is intended to preserve sensitive antigens and fragile ultrastructural elements. The method involves mild formaldehyde fixation of the cells or tissues, infusion with concentrated sucrose, rapid freezing, and the preparation of frozen sections thinner than 1 micrometer thickness. The immunofluorescent or other appropriate fluorescent reagents are then applied to the thawed section. In the present experiments, intracellular actin was detected using a fluorescent staining method based on the interaction of F-actin with heavy meromyosin, while intracellular myosin was detected by an indirect immunofluorescence procedure. Our findings were that the formation of a cap by each of the lectins or antibody reagents was always accompanied by a concentration of myosin and actin directly under the cap. These and other results suggest that capping is an active process in which actin and myosin participate directly in the formation of all caps. This proposal carries important new implications for the molecular mechanism of capping.     

Nonuniform distribution of concanavalin-A receptors and surface antigens on uropod-forming thymocytes

Uropods can form spontaneously in a variable fraction of mouse thymocytes incubated for 30--60 min in vitro at temperatures between about 8 degrees and 37 degrees C. The majority of the cells with a typical uropod are medium and large thymocytes. The "normal" distribution of concanavalin-A receptors and antigens recognized by a rabbit anti-mouse thymocyte serum was studied on these cells by electron microscopy using ferritin-conjugated lectin or antibodies. The cells were fixed with glutaraldehyde or formaldehyde before labeling. The distribution was essentially uniform on spherical cells. On the contrary, on cells which had formed a uropod the labeled receptors and antigens appeared to be preferentially concentrated around the nucleus, and depleted over the uropod, and especially over the constriction at the base of the uropod. Uropod formation and inhomogeneous distribution were inhibited or reversed by cytochalasin B, but not by vinblastine or colchicine. When the same ligands were applied to unfixed cells, the labeled and cross-linked components capped normally towards the cytoplasmic pole of the cell. These observations are described in relation to the ability of receptors and antigens to interact with an intracellular mechanical structure, and to the mechanism of capping.     

Capping of saccharides on the plasma membrane of lymphocytes as studied by fluorescein-labelled lectins

The capping of saccharides on the plasma membrane of rat splenic lymphocytes was studied by means of fluorescein-labelled lectins. Treatment of unfixed splenic lymphocytes with any one of the three lectins, concanavalin A (Con A), Ricinus communis agglutinin (RCA) and wheat germ agglutinin (WGA) led to the formation of caps of each saccharide receptor on the plasma membrane. Treatment of unfixed lymphocytes with Con A was found to result in the formation of caps of saccharide receptors for RCA, whereas cap formations were never noted in such double treatment of the cells with all other combined uses of two lectins. These results are taken to indicate that the saccharide receptors for Con A are associated with those for RCA in the plasma membrane of rat splenic lymphocytes.     

The role of microfilaments in the capping of epidermal growth factor receptor in A431 cells

Capping of the EGF receptor (EGF-R) on the surface of suspended and adherent epidermoid carcinoma cells, A431, is studied. It was induced at 20 degrees C after treating cells with monoclonal antibody to the EGF receptor followed by the second antibody conjugated with FITC. Accumulation of cortical actin under the caps was detected by rhodamine-phalloidin. Destruction of the actin stress-fiber-like bundles was observed during incubation of cells with the ligands at 0 degrees C. Two processes appear to take place at 20 degrees C: redistribution of the EGF-R with cortical actin into the caps within 15-30 min and reconstruction of cytoplasmic actin bundles over 45-60 min. Dihydrocytochalasin B prevented cap formation in adherent cells, but small patches of EGF-R colocalized with actin aggregates under plasma membrane were observed. The function of different actin-containing cytoskeleton structures in the process of capping is discussed.     

Distribution of concanavalin A in fibroblasts: direct endocytosis versus surface capping.

Indirect immunofluorescence of intact or acetone-extracted cells has allowed us to distinguish concanavalin A (Con A) which is associated with the plasma membrane of CHO cells from Con A which has been interiorized. We find that Con A is directly endocytized by these cells with no intervening stage of plasma membrane aggregation. The lectin accumulations observed by direct fluorescence are actually cytoplasmic collections of pinosomes which contain Con A. Only in a small fraction of CHO cells are true plasma membrane aggregates, or caps, found. This predominance of direct pinocytic interiorization over capping was not affected by dibutyryl cAMP or by treatments which can disrupt microtubules, including cold shock or exposure of the cells to anti-mitotic agents. Cytochalasin B, however, inhibited the uptake of Con A and at the same time promoted the formation of large surface aggregates of the lectin, or minicaps. Capping may reflect a competition between aggregation in the plane of the membrane and direct interiorization of bound lectin. Surface cap formation may be a characteristic process of cells with very low endocytic rates, such as lymphocytes.     

Interactions of lyophilised and rehydrated mouse spleen lymphocytes with phytohaemagglutinin (PHA) and concanavalin A (Con A)

Rehydrated lymphocytes freeze-dried in the presence of polyvinyl-pyrrolidone (PVP) and foetal calf serum (FCS) have been shown to retain plaque forming activity (5) but were unable to respond to plant mitogens (6) or to bind to immobilised phytohaemagglutinin (PHA) or Concanavalin A (Con A) (16).Studies with fluorescein conjugated and radio iodinated antibody to PHA and Con A showed that the ability of the cells to bind the lectins was undiminished. However, agglutination by lectin and capping of lectin-anti-lectin were impaired by freeze-drying, suggesting a defect in membrane fluidity, perhaps resulting from damage to the microfilament and microtubule apparatus of the cell.     

The redistribution of membrane surface immunoglobulin induces the rearrangement of some membrane integral proteins

We investigated whether the redistribution of surface membrane receptors is associated with rearrangement of integral membrane proteins. Using a newly developed process, which combines histochemical analysis with an immunofluorescence or immuno-electron microscopy-staining technique, we studied the redistribution of two membrane-bound enzymes, 5'-nucleotidase and ATPase, on mouse splenic lymphocytes and B lymphoma cells induced by anti-mouse immunoglobulin antibodies. Labeling and capping of the membrane surface immunoglobulin induced a similar rearrangement of both 5'-nucleotidase and ATPase from uniform distribution at 4 degrees C into 'patches' and caps at 37 degrees C.     

Capping of cholera toxin-ganglioside GM1 complexes on mouse lymphocytes is accompanied by co-capping of alpha-actinin

We used cholera toxin, which binds exclusively and with a high affinity to the ganglioside GM1, as a probe to investigate the distribution of this glycolipid on the surface of mouse lymphocytes. When lymphocytes are incubated with cholera toxin (or its B subunit) and then sequentially with horse anti-toxin and FITC-swine anti-horse Ig at 37 degrees C, the cholera toxin-ganglioside GM1 complex is redistributed to a cap at one pole of the cell. The capping of cholera toxin-GM1 complexes is slower than the capping of surface-Ig complexes, requires two antibodies, and is inhibited at high toxin concentrations. Cholera toxin-GM1, like surface-Ig capping, is an energy-dependent process and is inhibited by sodium azide, low temperatures, or cytochalasin B, but is unaffected by demecolcine. An affinity-purified antibody against alpha-actinin was used to examine the distribution of this cytoskeletal component during the capping process. 88% of the cells that had a surface Ig cap displayed a co-cap of alpha-actinin, and 57% of the cells that had a cholera toxin-GM1 cap displayed a co-cap of alpha- actinin. Time course studies revealed similar kinetics of external ligand cap formation and the formation of alpha-actinin co-caps. We conclude that capping of a cell-surface glycolipid is associated with a reorganization of the underlying cytoskeleton. The implications of such an association are discussed in the context of current models of the mechanism of capping.     

Mycoplasma contamination of membrane associated measles antigens. Inability to demonstrate in vitro lymphocyte responsiveness to measles.

A marked suppression of protein synthesis including IgA was demonstrated in BALB/c mouse thymocytes incubated in short-term tissue culture in the presence of anti-mouse α chain antibodies. In C57BL mouse thymocytes a suppression of protein synthesis including IgM was obtained by incubating the cells in tissue culture containing anti-mouse μ chain antibodies. The association of anti-α chain antibodies or anti-κ chain antibodies, at 4 °, to the Ig subunits on the surface of BALB/c mouse thymocytes was demonstrated following radioiodination of the antibody treated cells. The anti-mouse Ig antibodies attached to the surface α chains or κ chains at 4 ° were radioiodinated on the cell surface, rendering the corresponding surface mouse Ig subunits inaccessible to radioiodination by lactoperoxidase. The α chains or κ chains complexed with their specific antibodies were independently removed from the cell surface upon heating to 37 °. However, it was found that each of the antibodies attached first to its Ig subunit on the cell surface interferes with the subsequent binding of antibodies to the second subunit. The antibody-surface Ig complexes, although cleared from the cell membrane at 37 °, were not released into the culture medium, leading to the conclusion that these complexes were endocytosed.     

IL-2 production by B cells stimulated with a specific antigen

The ability of a specific antigen (Ag) to stimulate B cells to produce IL-2 was examined with a murine B lymphoma line, A20-HL, which expressed surface IgM specific for trinitrophenyl (TNP). The culture supernatant of A20-HL cells stimulated with TNP3.9-ovalbumin (-OVA) or anti-IgM goat IgG contained an activity which supported the proliferation of an IL-2-dependent T cell line, CTLL-2. Neither TNP3.9-OVA nor anti-IgM antibody stimulated the parent line, A20.2J, which did not bear TNP-specific sIg, whereas anti-mouse Ig rabbit IgG F(ab)2 did stimulate both A20-HL cells and A20.2J cells. The active material in the culture supernatant was identified as IL-2 based on the experiments in which the activity was inhibited by anti-IL-2 mAb, and IL-2 mRNA was expressed in A20-HL cells stimulated with TNP3.9-OVA or anti-IgM antibody. These results support the conclusion that a specific Ag can stimulate A20-HL cells to produce IL-2. For IL-2 production, TNP receptors on A20-HL cells have to be appropriately cross-linked, inasmuch as either TNP3.9-OVA or TNP6.7-OVA was much more effective than TNP1.2-OVA and TNP22.9-OVA in the induction of IL-2 production by A20-HL cells.     

Role of the cytoplasmic domains of viral glycoproteins in antibody-induced cell surface mobility.

We have investigated the role of the cytoplasmic domains of the influenza virus hemagglutinin (HA) and the parainfluenza virus type 3 (PI3) fusion (F) glycoproteins as a determinant of their ability to undergo antibody-induced redistribution on plasma membranes. The viral envelope genes were truncated in their cytoplasmic domains by using oligonucleotide-directed mutagenesis and expressed by using recombinant vaccinia viruses. In HeLa cells, the truncated HA (HAt), like the full-length HA, did not cap in response to specific antibody. In CV-1 cells, HAt showed patchy surface immunofluorescence with few caps, whereas full-length HA exhibited capping in many cells in response to bivalent antibody. Quantitation of cap formation indicated a sevenfold decrease in the frequency of capping of HAt in comparison with full-length HA. Similarly, truncated F also exhibited a significant decrease in cap formation in comparison with full-length F. These results indicate that the ability of influenza virus HA and PI3 F to undergo redistribution in response to bivalent antibody has been altered by truncation of the viral glycoproteins and suggest that capping may involve interactions between the cytoplasmic domain of the viral glycoproteins and host cell components.     

Biochemical analysis of ligand-induced receptor patching and capping using a novel immunolactoperoxidase iodination technique

A novel approach for the analysis of membrane proteins involved in ligand-induced surface receptor patching and capping is described. The technique is based on the use of immunolactoperoxidase (immuno-LPO) conjugates which catalyze the iodination of those surface proteins with available tyrosine groups that are located in the immediate vicinity of the patch or cap of a particular antigen. We have used the patching and capping of the H-2 (histocompatibility) antigen on mouse thymocytes to illustrate this method. However, this technique should be generally applicable to any cell surface proteins which can be induced to form patches or caps by a specific ligand. Cytochemical analysis indicates that the immuno-LPO conjugates induce the same patching and capping of the H-2 antigen as does the unconjugated antibody. Biochemical analysis of the 125I-labeled proteins by SDS polyacrylamide gel electrophoresis indicates that a large membrane protein (mol wt of approximately 200,000 daltons) is closely associated with H-2 patches and caps. Since a number of other prominent membrane proteins are not labeled by this procedure, selective redistribution of certain surface proteins must be occurring during H-2 antibody-induced patching and capping.