The expression and localization of surface neoantigens in transformed and untransformed cultured cells infected with avian tumor viruses

The presence and localization of neoantigens induced in cultured cells, infected or transformed with avian tumor viruses (ATV), were studied ultrastructurally on carbon platinum replicas of cell surfaces. The use of antibody, labeled with hemocyanin molecules, provided sensitive detection and analysis of cell surface antigen distribution. The subgroup-specific antigens of the viral envelope were found in considerable amount in the plasma membranes of ATV-infected chick embryo fibroblasts. The distribution of these antigens over the cell surface, evaluated on cells which were prefixed with glutaraldehyde, was found to be diffuse with a greater density on the cell processes in some cells. Reaction of antibody to viral envelope antigens with living ATV-infected cells resulted in a number of patterns of redistribution of membrane antigen-antibody complexes (AAC). Redistribution occurred in symmetrical or asymmetrical modes. The former consisted of randomly oriented aggregates (patches) of AAC over the cell surface. The latter included: (a) linear accumulation of AAC at cell margins; and (b) condensation of complexes into one or more centers of coalescence. These observations could be made on chick embryo cells infected (but not transformed) by avian leukosis virus, or on cells oncogenically transformed by avian sarcoma virus. The regions of coalescence were suggestive of the “capping” phenomenon seen in other systems, and their formation was temporally correlated with endocytosis of labeled AAC and the gradual loss of AAC from the surface. The effects of several biologically perturbing substances on the processes of redistribution were investigated in ALV-infected fibroblasts. Sodium azide, puromycin, actinomycin D, and colchicine had no effect on either form of asymmetrical redistribution. Cytochalasin B (CB) and iodoacetic acid (IAA) appeared to have some effect on the marginal redistribution, and to completely prevent the condensation into foci of coalescence (FC). When treated with these compounds, reacted with antibody at low temperature, washed free of unbound antibody, and warmed at 37° C, cells rapidly cleared their surfaces of AAC. This was not accompanied by formation of FC or endocytosis. In some of these cells, a distribution was observed which suggested a possible centrifugal flow of antigenic sites – perhaps an alternate route for disposal of AAC. None of the drugs tested affected symmetrical redistribution. Repeated attempts at detection and topographical analysis of a tumor-specific antigen on the surface of Rous sarcoma virus-transformed chicken and rat cells have provided no evidence for antibody to such an antigen in the serum of immunized animals. Autochthonous, homologous, and heterologous immunizations of chickens and rats did not produce a detectable antibody response to a virus-specific tumor surface antigen. Preliminary results, however, suggest the expression of an individual-specific (unique) tumor antigen on the surface of Rous sarcoma cells.     

The dynamics of antibody-induced redistribution of viral envelope antigens in the plasma membranes of avian tumour virus-infected chick embryo fibroblasts.

Avian tumour virus-infected chick embryo fibroblasts express new antigens, identical with the viral envelope antigens, in their plasma membranes. Electron-microscopic examination of carbon-platinum replicas of cells labelled with haemocyanin-marked antibody has shown the distribution of these antigens to be diffuse over the cell surface with an increased concentration on peripheral cell processes. However, antigen-antibody complexes (AAC), resulting from reaction with specific antibody, may be redistributed into a variety of patterns. Observation of the time course of antibody-induced antigen mobility revealed a rapid and a delayed phase of redistribution. During the rapid phase (10 min or less) some of the antigen-bearing cells reorganized AAC into patches, while the remainder maintained a diffuse distribution. A fraction of the cells with either diffuse or patchy distribution also redistributed AAC into a pattern of 'marginal redistribution (MR)', consisting of linear aggreagation of AAC, at the cell edge. During the 'late' phase of redistribution (after about 20 min), AAC began to condense into one or more foci of coalescence (FC) on each cell. As the number of cells with FC increased with time, the fraction of cells which were labelled decreased. Electron-microscopic observation of thin sections of ferritin-labelled specimens indicated that AAC were lost by endocytosis and that this process was probably related to FC formation. Inhibitors of oxidative phosphorylation, protein synthesis, RNA synthesis, or microtubule assembly had no significant effect on the patterns or the course of redistribution. Iodoacetic acid (IAA), which depletes cellular ATP, and cytochalasin B (CB), which is believed to depolymerize microfilaments, partially inhibited MR and completely prevented FC formation and endocytosis. Paradoxically, IAA or CB-treated cells lost AAC very rapidly by some alternate mechanism not involving FC formation but which may entail a centrifugal migration of complexes to the cell extremities during the process of AAC disposal.     

Pathogenesis of passive Heymann glomerulonephritis: chlorpromazine inhibits antibody-mediated redistribution of cell surface antigens and prevents development of the disease

Two hypotheses were tested: first, that in LEW rats the interaction of sheep (or rabbit) anti-brush border antibodies with antigens (Heymann antigens) expressed on the plasma membrane of glomerular visceral epithelial cells is characterized by initial redistribution of immune complexes on the cell surface and by subsequent shedding of immune complexes in the subepithelial part of the capillary wall; and secondly, that this interaction is inhibited by chlorpromazine, a drug that displaces calcium ions from binding sites linking the plasma membrane to the cytoskeleton, and which blocks the redistribution of IgG on the surface of B lymphocytes exposed to anti-IgG antibodies. The studies were performed in vitro on cultured LEW glomerular epithelial cells and in vivo in LEW rats. In cultured glomerular epithelial cells exposed at 37 degrees C to anti-brush border IgG, chlorpromazine prevented, in a dose-dependent manner, the redistribution ("capping") of Heymann antigens and the fixation of complement. The renal glomeruli of chlorpromazine-treated LEW rats examined 6 and 48 hr after transfer of anti-brush border antibodies had punctate and, later, punctate and diffuse deposits of sheep (or rabbit) IgG on glomerular epithelial cells, but not similar deposits of rat C3. Moreover, granular subepithelial deposits of sheep (or rabbit) IgG and rat C3, characteristic of passive Heymann glomerulonephritis, did not develop, although deposits of sheep IgG were detected by immunoelectron microscopy on the microvilli of glomerular epithelial cells. Comparative studies on rats with similar reductions in glomerular filtration rates, produced by high doses of chlorpromazine or with renal artery stenosis, showed that the findings were not the consequence of insufficient delivery of antibody to glomerular epithelial cells. The results are consistent with the interpretation that Heymann glomerulonephritis is induced by mechanisms of redistribution of cell surface antigens comparable to those that govern the interaction of surface antigens (or receptors) with appropriate ligands in B lymphocytes and other classical in vitro systems.     

Association of mouse adenovirus-induced cell surface antigen(s) with histocompatibility antigens

The topological relationship on the mouse adenovirus (M-Ad)-infected cell surface between virus-induced specific cell surface(s) antigens and serologically defined major histocompatibility antigens (H-2) was analyzed by the cap formation technique. Rhodamine-isothiocyanate (RITC)-labeled anti-S serum failed to stain the surface of virus-infected lymphoid cells which were pretreated with anti-H-2 serum and fluorescein isothiocyanate (FITC)-labeled anti-mouse immunoglobulin serum (anti-M-Ig) to cap the appropriate H-2 antigens. Conversely, the capping of the S antigens by pretreatment with anti-S followed by FITC anti-M-Ig serum induced cocapping of H-2 antigens. The β₂ microglobulins (β₂m) were also shown to be cocapped with S antigens by anti-β₂m or by anti-S serum. The S antigens, however, did not cocap with mouse-immunoglobulins or Thyl. 2 antigens on virus-infected B or T lymphocytes, respectively. To further elucidate the molecular relationship between S and H-2 antigens, radio-iodinated virus-infected cells were solubilized with Nonidet P40 (NP40) and S antigens were precipitated with anti-S serum. When the precipitates were analysed with sodium dodecyl sulfate Polyacrylamide gel electrophoresis, two major peaks were seen at positions of molecules of about 45,000 and 12,000 daltons both of which corresponded with molecules which were observed when NP40 extracts of virus-infected or uninfected cells were precipitated with anti-H-2 serum. Sequential immunoprecipitation analysis of infected cell extracts showed that S antigens were coprecipitated with either H-2K or H-2D antigens. These results suggest that the S antigens are somehow associated with H-2K or H-2D antigens separately.     

Independence of H-2 and viral antigens on the cell surface and absence of H-2 antigens on murine leukemia virus and mouse mammary tumor virus particles

By indirect immunoelectron microscopy we tested for the presence of H-2 antigens on murine mammary tumor virus (MMTV) and murine leukemia virus (MuLV) particles. The association of H-2 antigens and viral antigens on the virus-infected cell surface was investigated with antibody-induced redistribution. Mammary tumor cells and leukemia cell lines with different H-2 genotypes and carrying different MuMTV or MuLV were used. No H-2 antigens could be demonstrated on the envelope of MMTV and MuLV particles, even after the permeabilization of their envelopes with saponin. On the surface of virus-infected cells antibody-induced patching or capping of the viral antigens did not result in copatching or cocapping of the H-2 antigens. In the reciprocal tests no co-redistribution of viral antigens with H-2 antigens was seen. Our experiments failed to show any physical association between H-2 antigens and MMTV or MuLV antigens on the cell surface.Abbreviations used in this paper MMTV mammary tumor virus - MuLV murine leukemia virus - MHC major histocompatibility complex - IEM immunelectron microscopy     

Murine T lymphoma cells express a novel membrane-associated antigen with unique features

A novel membrane-associated antigen expressed on various murine T lymphoma cells has been detected by a rat monoclonal antibody. The antibody YE6/6 initially produced against Moloney leukemia virus-transformed T lymphoma line MBL-2, reacted with several other lymphoma lines including non-T lymphoma lines as well as thymocytes from leukemic AKR mice, but it did not show significant reactivities with resting or mitogen-activated normal lymphocytes by flow cytometric analysis. The antibody did not bind to some Abelson leukemia-transformed cells, which express Moloney virus antigens, suggesting that the antigen is unlikely to be encoded by Moloney virus genome. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the antigen molecules immunoprecipitated by the antibody revealed three major polypeptides. Two of the polypeptides, with approximate m.w. of 95,000 and 35,000, can be labeled by the cell surface iodination and, therefore, seem to be exposed on the cell surface. The third polypeptide, with approximate m.w. of 65,000, is not labeled by the surface iodination but it is readily detected by [35S]methionine labeling. The third polypeptide was labeled with [32P]orthophosphate indicating that it is a phosphoprotein. Western blot analysis showed that YE6/6 antibody primarily reacts with 35,000 m.w. polypeptide. Furthermore, the same 35,000 m.w. protein was also detected in concanavalin A-activated spleen cells at a low level by Western blot, but normal resting lymphocytes were negative. These results suggest that the antigen detected by YE6/6 antibody may be a cell proliferation-associated antigen and its expression is highly elevated on transformed lymphoma cells as compared to normal mitogen-activated lymphocytes.     

Antibody-induced capping of measles virus antigens on plasma membrane studied by electron microscopy.

Antibodies specific for measles virus could redistribute ("cap") virus antigens on infected HeLa cells as shown by transmission and scanning electron microscopy. Using an indirect immunoperoxidase technique, infected cells showed diffuse, circumferential distribution of virus antigens over the cell surface when mixed with antibody at 4 C. At 37 C, virus-coated microvilli concentrated on one pole of the cell, leaving the remainder of the plasma membrane devoid of both viral antigens and microvillus projections. Whereas extreme polar displacement of virus-antibody complexes frequently occurred, endocytosis was rarely seen. The findings indicate that antiviral antibodies can move and cluster virus on plasma membranes and suggest that virus-antibody complexes are stripped and shed from the cell surface.     

Epstein-Barr virus superinduces a new human B cell differentiation antigen (B-LAST 1) expressed on transformed lymphoblasts

We have developed a monoclonal antibody that detects the first human B-cell-specific differentiation antigen expressed on transformed B lymphoblasts. The antigen is termed B-LAST 1 and is found on B cells transformed in vitro with Epstein-Barr virus (EBV) and pokeweed mitogen; in vivo with EBV and antigen; and on neoplastic B cells from chronic lymphocytic leukemia and poorly differentiated lymphoma. The antigen has a molecular weight of 45,000 and was not found on cells of T, null or myeloid lineage, whether obtained from peripheral blood, lymph nodes, neoplasms or cell lines. The antigen is expressed at a much higher level on EBV-infected cells than on any other cell type studied, but does not appear to be virally encoded. The significance of this antigen in the process of viral and nonviral transformation and its possible role as a target for T-cell-mediated immunity against virus-infected cells is discussed.     

Expression of idiotype on the surface of human B cells producing anti-DNA antibody

We analyzed the idiotype (Id) expression on the surface of human anti-DNA antibody-producing cells. Murine monoclonal anti-Id antibodies with a specificity for determinants associated with the antigen-binding sites of human monoclonal anti-DNA autoantibodies were prepared. One anti-Id antibody reacted only with surface Id on anti-ssDNA-producing cells, but not with those on anti-dsDNA-producing B cell clones. Another anti-Id antibody did bind the surface Id on anti-dsDNA clones, but not those on anti-ssDNA clones. The interaction between anti-Id and surface Id was inhibited by pretreatment of the clones with DNA or appropriate polynucleotide antigens, or by preabsorption of anti-Id antibodies with free anti-DNA antibodies. Surface IgM and IgD expressed the same Id as the antibody secreted from the clones. The treatment of Id-positive clones by anti-Id antibody induced the redistribution of surface Id on the cells, indicating that these cells serve as targets for the regulatory action of anti-Id antibody.     

Localized surface antigens of guinea pig sperm migrate to new regions prior to fertilization

We have previously defined distinct localizations of antigens on the surface of the guinea pig sperm using monoclonal antibodies. In the present study we have demonstrated that these antigen localizations are dynamic and can be altered during changes in the functional state of the sperm. Before the sperm is capable of fertilizing the egg, it must undergo capacitation and an exocytic event, the acrosome reaction. Prior to capacitation, the antigen recognized by the monoclonal antibody, PT-1, was restricted to the posterior tail region (principle piece and end piece). After incubation in capacitating media at 37 degrees C for 1 h, 100% of the sperm population showed migration of the PT-1 antigen onto the anterior tail. This redistribution of surface antigen resulted from a migration of the surface molecules originally present on the posterior tail. It did not occur in the presence of metabolic poisons or when tail-beating was prevented. It was temperature-dependent, and did not require exogenous Ca2+. Since the PT-1 antigen is freely diffusing on the posterior tail before migration, the mechanism of redistribution could involve the alteration of a presumptive membrane barrier. In addition, we observed the redistribution of a second surface antigen after the acrosome reaction. The antigen recognized by the monoclonal antibody, PH-20, was localized exclusively in the posterior head region of acrosome-intact sperm. Within 7-10 min of induction of the acrosome reaction with Ca2+ and A23187, 90-100% of the acrosome-reacted sperm population no longer demonstrated binding of the PH-20 antibody on the posterior head, but showed binding instead on the inner acrosomal membrane. This redistribution of the PH-20 antigen also resulted from the migration of pre-existing surface molecules, but did not appear to require energy. The migration of PH-20 antigen was a selective process; other antigens localized to the posterior head region did not leave the posterior head after the acrosome reaction. These rearrangements of cell surface molecules may act to regulate cell surface function during fertilization.     

Antibody-induced changes on rabbit sperm surface inhibit gamete interaction

Interaction of specific ligands with cell surface molecules may induce reorganization of surface components. A monoclonal antibody (B-12) against sperm surface antigens of 40kDa size induced molecules on the plasma membrane overlying the acrosome of rabbit sperm to cluster in small aggregates at 0°C (patching). At an elevated temperature of 37°C these clusters of antigen antibody complexes collected into a large aggregate on one pole of the cell forming a cap (capping). This cap-like structure showed a reduction in size over a period of time and eventually disappeared from the sperm surface. Inhibition of capping by sodium azide indicated that it is an energy-dependent process. Patching of antigens did not require energy. Involvement of sperm head cytoskeleton in the process of capping was evident from potentiation of cap formation by cytoskeleton disrupting agents like cytochalasin B and D. Patching of antigen antibody complexes was not affected by either of the agents. The loss of antigen antibody complexes from sperm surface was mainly due to shedding of the complexes in the surrounding media. Sperm with patches of antigen antibody complexes did not adhere to oocytes. Sperm from the group where a majority of the sperm were denuded of the antigen antibody complexes also did not bind to oocytes. © 1994 Wiley-Liss, Inc.     

Differences in HLA antigen recognition by human influenza virus-immune cytotoxic T cells.

The specificity of in vitro induced human influenza-immune cytotoxic effector cells was analyzed with respect to recognition of HLA-A and -B-linked gene products. The influenza-immune cytotoxic activity observed on panels of virus-infected targets demonstrated that virus-immune effectors preferentially lyse targets with which they share HLA-A or -B specificities. Virus-immune effectors from certain donors recognized virus in conjunction with some, but not all, of their self HLA-A and -B antigens. Among donors who share a given HLA antigen (such as A2 or B7), there are differences in the ability of their virus-immune T cells to recognize the shared antigen. Virus-infected target cells from HLA-A2 or -B7 "nonresponder" donors could be lysed by virus-immune T cells obtained from other donors who shared only the HLA-A2 or -B7 antigen with these target cells. These observations suggest that the absence of cytotoxic T cell responses by some donors to influenza virus in conjunction with HLA-A2 or -B7 is not due to control by the structural genes that code for these HLA antigens, but rather may result from control by regulatory genes that act at the level of the responder and/or stimulator cell. The results are discussed in the context of Ir gene regulation of human T cell responses.     

A high-throughput hybridoma selection method using fluorometric microvolume assay technology

Monoclonal antibodies (mAb) are not only useful reagents but also represent a promising type of therapeutics due to their high affinity and exquisite specificity for their antigens. A critical step in mAb generation is to identify antigen-specific antibodies. Although enzyme-linked immunosorbent assay (ELISA) has been broadly applied for antibody selection against secreted antigens, an inherent disadvantage for ELISA is the difficulty in identifying antibodies that recognize the native conformation of cell surface antigens. To overcome this drawback, the authors have developed a high-throughput cell-based antibody binding assay using fluorometric microvolume assay technology (FMAT). This method offers a homogeneous assay for detection of antibody binding to its antigen on the cell surface. To distinguish antibodies that bind to antigen on the cell surface from those that bind nonspecifically to cells, the binding is assessed using both antigen-expressing cells and related cells devoid of the antigen expression. This assay can detect antibodies at a concentration as low as 5 ng/mL and cell surface antigen as low as 9000 copies per cell. Results demonstrate that the FMAT method provides a sensitive and homogeneous assay to detect antibody binding to cell surface antigens and is amenable for high-throughput hybridoma selection.     

Human monoclonal antibodies against surface antigens of Langerhans cells from lymphocytes of diabetics transformed by Epstein-Barr virus

Human monoclonal antibody against islet cell surface antigens was generated from a pre-diabetic patient's peripheral blood lymphocytes transformed with Epstein-Barr virus. Reactivity of these transformed lymphocytes was evaluated using indirect immunofluorescence on rat islet cell suspensions and frozen sections of human pancreas. Several lymphoblastoid cell lines that react with islet cell surface were obtained. Preliminary immunoblots with enriched rat islet cell membrane antigens suggest a reactivity toward a 64 kdalton antigen.     

Anchoring a secreted plasmodium antigen on the surface of recombinant vaccinia virus-infected cells increases its immunogenicity.

We show that the subcellular location of foreign antigens expressed in recombinant vaccinia viruses influences their effectiveness as immunogens. Live recombinant viruses induced very poor antibody responses to a secreted repetitive plasmodial antigen (the S-antigen) in rabbits and mice. The poor response accords with epidemiological data suggesting that S-antigens are poorly immunogenic. Appending the transmembrane domain of a membrane immunoglobulin (immunoglobulin G1) to its carboxy terminus produced a hybrid S-antigen that was no longer secreted but was located on the surface of virus-infected cells. This recombinant virus elicited high antibody titers to the S-antigen. This approach will facilitate the use of live virus delivery systems to immunize against a wide range of foreign nonsurface antigens.     

Cell surface antigens expressed by subsets of pre-B cells and B cells

A large number of monoclonal antibodies, produced by immunizing rats with mouse pre-B cell lines, have been analyzed for their ability to define cell surface antigens expressed by B cells at early stages of differentiation. Whereas many antibodies recognized antigens on pre-B cell lines, only two clones detected cell surface antigens that were distinguished by their restricted distribution among a panel of continuous cell lines and cells from various tissues. Monoclonal antibody clone AA4.1 recognized a cell surface antigen found on all pre-B lymphomas and on one of three B lymphomas tested. This antigen was found on cells at highest frequency in the bone marrow. Adult spleen and fetal liver also have detectable numbers of AA4.1+ cells. Cells that did not express this antigen include plasmacytomas, two of three B lymphomas, T lymphomas, a stem cell line, adult liver, brain, thymus, and lymph node cells. Clone GF1.2 detected an antigen on some pre-B cell lines, one of three B lymphomas tested, and a small fraction of cells from adult bone marrow, spleen, lymph node, and fetal liver. Plasmacytomas, some pre-B lymphomas, two B lymphomas, T lymphomas, adult liver, brain, and thymus cells were negative. In adult bone marrow, AA4.1 bound to all cytoplasmic IgM+ pre-B cells, whereas GF1.2 detected one-half of these cells. Both antibodies recognized approximately 50% of surface IgM+ (sIgM+) bone marrow cells. A small population of bone marrow cells lacking any detectable Ig (surface or cytoplasmic) also reacted with these antibodies. Depletion of AA4.1 or GF1.2 antigen-bearing cells from bone marrow reduced the ability of bone marrow B cells to respond to LPS by 50 to 65%. Experiments with a cloned pre-B lymphoma demonstrate that AA4.1+ pre-B cells become sIgM+ GF1.2+ B cells after activation with LPS. These antibodies recognize cell surface determinants with restricted distribution among the B lymphocyte lineage because they detect antigens displayed by normal and transformed immature B lymphocytes.     

A fluorescence study on the mobility of surface antigens of untreated tumor cells and of tumor cells undergoing cell-mediated lysis

Heterologous (rabbit) antibodies were raised against murine P-815 mastocytoma cells of DBA/2 origin. Antisera and IgG preparations were highly cytotoxic, whereas Fab fragments thereof lost all activity. Fab fragments also showed a much lower avidity than IgG, both for tumor and normal DBA/2 and C57 spleen cells as measured by the release of iodinated Fab and IgG. Both preparations bound specifically to P-815 cells since they were capable of inhibiting T cell-mediated target cell lysis. The binding of IgG and monovalent Fab fragments was studied by fluorescence. Rhodamine-coupled IgG bound homogeneously in the cold and quickly formed patches upon warming but did not form caps even after prolonged incubation at 37 degrees C. Rhodamine-coupled Fab fragments also bound homogeneously. Their distribution was unaltered after incubation at 37 degrees C even when tumor cells formed uropod-like tails. Fab fragments, however, could be induced to cap with a second and third antibody layer. P-815 cells labeled with rhodamine-coupled Fab fragments were incubated with cytolytic T cells (CTL). The conjugates formed between CTL and fluorescent target cells were observed. No gross redistribution of surface antigens on target cells was observed even at late stages of the lytic process. CTL, therefore, do not seem to operate via a redistribution of surface antigens.     

Participation of membrane skeleton proteins in aggregation of epidermal growth factor receptors in A431 cells.

Polyclonal antibody against alpha-spectrin of chicken erythrocytes was prepared. This antibody as well as anti-vinculin and anti-annexin I and II, were used for localization of the antigens in A431 cells during translocation of epidermal growth factor receptors (EGF-Rs) on cell surface. During aggregation of EGF-Rs only spectrin and actin aggregates colocalized with the "capped" receptors in adherent as well as in suspended cells. Physiological implication of spectrin involvement in EGF-Rs redistribution in A431 cells is discussed.     

Demonstration of a tumor-associated surface antigen in Marek's disease.

Surface antigenic markers were detected on three classes of Marek's disease (MD) tumor cells, i.e., MD lymphoma cells, cultured cells of the MSB-1 lymphoblastoid cell line, and JMV lymphoblastic leukemia cells, by indirect membrane immunofluorescent staining with serum from chickens immunized with JMV cells or from rabbits immunized with MSB-1 cells. This surface antigen was not detected on normal chicken lymphocytes, RPL-16 tumor cells (tranedormed by an avian RNA virus, or MD virus-infected fibroblasts that were positive for viral membrane antigen (MA). Furthermore, the surface antigen appeared unrelated to embryonic or histocompatibility antigens. This antigen is provisionally designated as a Marek's disease tumor-associated surface antigen (MATSA). The MATSA's on JMV, MSB-1 and MD lymphoma cells were related but not identical as demonstrated by antiserum titration, absorption and blocking tests with homologous and heterologous systems.     

Monoclonal antibodies: use to detect developmentally regulated antigens on D. discoideum amebae

We have used monoclonal antibodies to detect developmentally regulated cell surface antigens on D. discoideum amebae. A study of an antigen detected using an antibody produced by a hybridoma line implicates a previously undescribed component in the process of cell aggregation. This antigen (consisting of a doublet of 69,000 and 73,000 molecular weight) is first detected during the early hours of cell starvation and is present until cells begin slug formation. The developmental appearance of the antigen is not controlled by cAMP pulses and is distinct from that of Contact A sites. Fab fragments directed against the antigen are potent inhibitors of aggregation but do not inhibit the differentiation of cells to aggregation competence.