Identification of mobile and fixed antigens on the plasma membrane of rat spermatozoa using monoclonal antibodies

We have used monoclonal antibodies to study the mobility and distribution of three different antigens on the cell surface of rat spermatozoa. We classified two of the antigens (designated 2B1 and 2D6) as 'mobile', since when detected by indirect immunofluorescence they were situated over the entire sperm flagellum and were susceptible to antibody-induced patching. Patching was critically dependent upon antibody concentrations and was much reduced at 4 degrees C. Patching of the 2B1 antigen was not induced by the 2B1 monoclonal antibody alone. Thus, 2B1 antibody labelled directly with fluorescein bound with a uniform distribution over the sperm flagellum, but this uniform fluorescence was made patchy on subsequent incubation in an unlabelled second antibody layer of anti-mouse IgG anti-serum. By 'Western blotting', the 2B1 antigen was found to be located to a 40 kD molecular weight polypeptide. The remaining 'fixed' antigen (designated 1B6) was not susceptible to antibody-induced patching, and was restricted to a discrete domain on the post-acrosomal region of the sperm surface. We discuss the relationship between mobility of sperm surface antigens and their segregation to discrete domains on the plasma membrane.     

Antigen binding to lymphoid cells from unimmunized mice: IV. Shedding and reappearance of multiple antigen binding Ig receptors of T- and B-lymphocytes

Patterned antigen-binding cells (ABC) can bind two antigens and show “islands” of Ig receptor with mixed specificity. However, these cells, when unfixed, lose most of their bound fluorescent antigen within minutes upon warming above 0 °C. Residual antigen moves to one pole of the cell forming a “cap” within 5 min at room temperature. If such patterned ABC are capped with a single antigen, receptors to a second antigen can be detected on a portion of the capped cells, but only in the cap. The frequency of capped, “double” ABC approximated the frequency of patterned “double” ABC originally present.If lymphoid cells are mixed with fluorescent antigens at 0 °C and then incubated for 4 hr at 37 °, no ABC are found. When the cells are then fixed and the fluorescent antigens readded, new antigen-binding Ig receptors can be shown to have reappeared on the cell surface during the 4-hr incubation. The reappearance of antigen receptor could be inhibited by prior addition of either 10^?2M sodium azide or 50 μg/ml cycloheximide, implying that the receptors were actively synthesized by the cell. These inhibitors did not prevent shedding, but azide did inhibit the capping process. Both B-cells (bone marrow or spleen cells) and T-cells (splenic T-cells or 99.5% pure cortisone-resistant T-cells) were shown to regenerate multispecific ABC to the frequency found prior to incubation.     

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.     

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.     

Use of a monoclonal antibody to evaluate integrity of the plasma membrane of stallion sperm

Transmission electron microscopy was used to confirm that a monoclonal antibody (F79.3E2; class IgGlK) was specifically localized to an antigen in the acrosomal ground substance of stallion sperm. This antibody was used to develop and validate an indirect immunofluorescent procedure to evaluate integrity of the plasma-acrosomal membranes of stallion sperm. The concept was that primary monoclonal antibody would be “shielded” from its acrosomal antigen by an intact plasma membrane. Conversely, sperm with damaged plasma-acrosomal membranes would exhibit green acrosomal fluorescence when viewed with an epifluorescence microscope. A lipophilic counterstain (red fluorescence) was used to insure that all sperm were visualized. Sperm in fresh-extended or frozen-thawed semen were incubated with hybridoma supernatant containing monoclonal antibody for 30 min at 37°C, then a second antibody (rabbit anti-mouse IgG-FITC) was added for 30 min at 37°C. Unbound antibody was removed by dilution and centrifugation. Sperm were resuspended in phosphate-buffered saline containing Evan's blue as a counterstain. All sperm fluoresced bright red, regardless of the status of cell membranes, except that in cells with damaged plasma-acrosomal membranes, the green fluorescence associated with antibody was overriding for the rostral portion. By counting fluorescent and nonflourescent “acrosomes”, the percentage of sperm with intact plasma-acrosomal membranes was easily determined. Evaluation of five mixtures of undamaged and damaged sperm by this procedure gave a correlation of 0.91 between the percentage of damaged sperm in a mixture and the percentage of sperm with a fluorescent acrosome. Intra- and interassay coefficients of variability were < 6%.     

Two distinct mechanisms for redistribution of lymphocyte surface macromolecules. I. Relationship to cytoplasmic myosin

A detailed kinetic analysis of the distribution of cytoplasmic myosin during the capping of various lymphocytic surface molecules revealed two distinct capping mechanisms. (a) Some cell surface molecules, including immunoglobulin, Fc receptor, and thymus leukemia antigen, all cap spontaneously in a small fraction of lymphocytes during locomotion. Cytoplasmic myosin becomes concentrated in the cytoplasm underlying these spontaneous caps. Exposure to specific antibodies causes all three of these surface molecules to cap rapidly with a concomitant redistribution of cytoplasmic myosin to the area of the cap. These antibodies also stimulate cell locomotion. (b) Other lymphocyte surface molecules, including H2 and Thy.1, do not cap spontaneously. Moreover, exposure to antibodies to these molecules causes them to cap slowly without a redistribution of cytoplasmic myosin or stimulation of cell locomotion. Exposure to concanavalin A gives a response intermediate between these two extremes. We believe that the first type of capping is active and may involve a direct link between the surface molecules and the cytoplasmic contractile apparatus. The second type of capping appears to result simply from aggregation of cross-linked molecules in the plane of the membrane.     

Antibody-induced redistribution of normal and tumor associated surface antigens

Redistribution (capping) of normal and tumor-associated surface antigens was studied on murine and human cells by the indirect membrane immunofluorescence (MIF) technique. The capping of H-2 isoantigens was compared on normal mouse T-lymphocytes and on YAC cells, a Moloney leukemia virus (MLV) induced lymphoma. H-2 and Moloney virus induced cell surface antigen (MCSA) capping was compared on three YAC lines with different MCSA concentrations. H-2 and tumor-associated surface antigen capping was compared on two polyoma induced sarcoma lines and five methylcholanthrene induced sarcoma lines. In the human system, IgM-capping was compared on normal lymphocytes and on the Burkitt lymphoma derived Daudi line. Capping of HL-A and the Epstein-Barr virus (EBV) determined membrane antigen (MA) was compared on the Burkitt lymphoma derived line Maku and on EBV-superinfected Daudi cells. H-2 antigens on normal murine cells capped more promptly and on a larger fraction of the cell population on the various tumor cells. Surface associated IgM showed a better capping on normal lymphocytes than on Daudi cells. All tumor associated antigens except MCSA, showed good capping. MCSA was almost completely refractory to capping. Increasing concentrations of MCSA appeared to inhibit the capping of H-2 on the YAC sublines with different concentrations of MCSA. The polyoma induced ascites sarcoma (SEWA) did not cap either with regard to H-2 or the polyoma determined surface antigen.     

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.     

Surface and internal antigens of rat spermatozoa distinguished using monoclonal antibodies

Fluorescent antibody labeling techniques are frequently used to investigate the topography of antigens on spermatozoa. It is generally assumed that these procedures detect molecules only on the sperm surface but we now show that this assumption is not always valid. Using monoclonal antibodies that recognize either surface or internal antigens we demonstrate how spurious conclusions can be made, and we suggest simple procedures for assigning the position of an antigen to the cell surface or to an intracellular organelle. Antibodies against plasma membrane antigens should stain 100% of normal intact spermatozoa, but this proportion should be greatly reduced if the spermatozoa have previously been demembranated. If ? 100% of spermatozoa are stained but the proportion increases following permeabilization, then the possibility should be considered that the antigens are intracellular. We conclude that assignment of an antigen to a regional domain on the sperm surface using fluorescent antibody techniques should be validated by a demonstration that the antigen is actually located on the cell surface.     

Concanavalin A receptors, immunoglobulins, and theta antigen of the lymphocyte surface. Interactions with concanavalin A and with Cytoplasmic structures

The effect of concanavalin A (Con A) on the capping of mouse lymphocyte surface immunoglobulin (surface Ig), cross-linked by rabbit anti-mouse Ig antibody, and on the capping of mouse thymocyte theta antigen, cross- linked by anti-theta alloantibody and rabbit anti-mouse Ig antibody, has been studied by immunofluorescence, using fluorescein conjugated Con A and rhodamine-conjugated anti-mouse Ig antibody, and by electron microscopy, using native or fluorescein-conjugated Con A and ferritin- conjugated anti-mouse Ig antibody. Prior incubation of the cells with Con A inhibited only partially capping os surface Ig, whereas it blocked almost completely capping of theta antigens. Both on cells with rings and on cells with caps the staining for surface Ig or theta antigen was superimposed to the staining for Con A. When Con A receptors on spleen cells were capped by Con A at concentrations of 10 mug/ml or higher, and the distribution of surface Ig was examined under noncapping conditions, all detectable surface Ig were found in the caps. As shown by electron microscopy, surface Ig remained dispersed in a layer of Con A. The ability of Con A to cap surface Ig was not altered by the presence of cohchicine or vinblastine. These results suggest that surface Ig are cross-linked by Con A to other Con A receptors. In these conditions surface Ig behave essentially as Con A receptors, as for example, in their sensitivity to cytochalasin B during inhibition or reversal of capping induced by this drug. The behavior of surface Ig parallels that of Con A receptors also in the presence of vinblastine. It is concluded that in the presence of Con A, antimitotic drugs do not modify directly the interaction between Con A receptors and surface Ig, but probably influence the capping ability of the Con A receptors or, more in general, affect the ability to elicit movements over the cell surface. The role in capping of cytochalasin- sensitive and vinblastine-sensitive structures is discussed. Both types of structures appear to play an active role in the formation of a cap, although the former probably corresponds to the main mechanical system responsible for the active displacement of cytoplasmic and surface material.     

Capping of immune complexes by sporozoites of Eimeria tenella

Sporozoites of Eimeria tenella were incubated for 10, 20, or 30 min with parasite-specific monoclonal IgG antibody 3D3II from mice and then rinsed in a Tris-buffered glucose saline solution (TBGS). Some sporozoites were then incubated for 10, 20, or 30 min with ferritin- or colloidal gold-conjugated goat anti-mouse IgG antibody and then fixed in 2.5% glutaraldehyde and prepared for transmission (TEM) or scanning (SEM) electron microscopy. Other sporozoites that had been previously exposed to monoclonal antibody were prefixed with 0.25% glutaraldehyde, incubated with ferritin- or colloidal gold-conjugated anti-mouse IgG antibody and then fixed and prepared for TEM or SEM. Control preparations consisted of sporozoites exposed only to TBGS, monoclonal antibody 3D3II or to ferritin- or colloidal gold-conjugated anti-mouse IgG antibody. Capping of immune complexes occurred only on the surface of those sporozoites exposed to monoclonal antibody 3D3II followed by ferritin- or gold-conjugated antibody. Immune complexes moved laterally and posteriorly on the outer surface of the parasite plasma membrane to form a cap at the posterior end of the sporozoite. Capping did not occur in TBGS controls nor in sporozoites treated with monoclonal antibody 3D3II and prefixed in 0.25% glutaraldehyde before exposure to ferritin- or gold-conjugated antibody. Thus, capping of surface antigens did not occur in the presence of monoclonal 3D3II antibody only, whereas specimens exposed to both monoclonal and ferritin- or colloidal gold-conjugated antibodies were able to cap immune complexes.     

A Possible role of the nucleus in cytochalasin B-Induced capping

The possible influence of the nucleus on Cytochalasin B (CB)-induced capping of antibodies to surface antigens on L cells SV40-3T3 and NRK La 334 cells was studied. The cap formation induced by CB, was generally localized opposite the nucleus which was displaced against the cell periphery. To be able to observe the nuclear membrane in relation to the capping process we have taken advantage of an antiserum specific for antigens in the nuclear membrane but lacking reactivity to the plasma membrane and intranuclear antigens. This approach indicated that the CB-induced capping caused an accumulation of nuclear membrane antigens in the area of the nucleus facing the cap. The CB-induced local accumulation of nuclear membrane antigens required intact cells and could not be induced by binding of antibodies to the nuclear membrane followed by exposure to CB. Whatever the basis for the CB-induced altered reactivity of the anti-nuclear membrane antibodies (folding of the nuclear periphery, for example) this result indicated that the nuclear membrane was affected by CB capping. The possible role of the nucleus in the CB-induced capping process was further investigated in enucleated cells. The results obtained indicate that such cells both when enucleated in suspension and adherent to a surface did not exhibit CB capping. This disappearance of CB capping did probably not reflect decreased cell viability, previous exposure of the cells to CB during the enucleation procedure or a decreased capacity of the enucleated cells to bind CB.     

Restriction of a sperm surface antigen's mobility during capacitation.

Fluorescent Fab¹ [immunoglobulin G (IgG) fragment with antigen binding capacity from papain digestion of IgG] antibody fragments and globulin from antisera prepared against a single rabbit sperm surface membrane glycoprotein antigen (MGP) were used to study surface antigen mobility. Epididymal and ejaculated spermatozoa exhibited a redistribution of MGP surface antigen over the acrosomal region when labeled at 4°C and warmed to 37°C. Following in vivo capacitation, spermatozoa did not exhibit MGP surface antigen redistribution over the acrosome. The restricted mobility of this surface antigen implies a physiological change in plasma membrane fluidity, which may be a necessary preliminary to the acrosome reaction. Furthermore, it is suggested that the presence or absence of specific peripheral membrane proteins may control the positional relationship between mobile and nonmobile integral membrane components.     

Physiology of receptor capping induced by erythrocyte surface antigens

The capping of antigen-binding cell receptors by bound sheep erythrocytes (SRC) demonstrates that antigen mounted on a cell surface can generate a signal leading to the capping reaction. SRC-induced capping of ABC is: (a) highly dependent on both aerobic and anaerobic glycolysis, (b) unaffected by agents altering intracellular cyclic nucleotide concentrations, (c) slightly more vigorous in strain A than in CBA mice, (d) inhibited by calcium ionophore, (e) inhibited by the local anesthetic dibucaine and the tranquillizer chlorpromazine, (f) dependent on cytoskeletal activity (i.e., inhibited by the simultaneous presence of colchicine and cytochalasin B), (g) not dependent on the membrane ATPases inhibited by ouabain, (h) not dependent on motility, in that agents which inhibit motility (cytochalasin B alone) or stimulate motility (carbachol) do not alter capping behavior. These properties represent similarities between the capping of surface Ig by the cellular antigens on SRC and by proteins such as anti-Ig. SRC-induced capping is much slower than anti-Ig-induced capping, and only engages 30–40% of ABC, indicating that the nature of the crosslinking agent can influence the kinetics and extent of capping. But SRC cap with the rapid kinetics typical of anti-Ig-induced capping if the surface membrane of the ABC is first cleared of other glycoproteins with trypsin. The removal of negatively charged sialic acid residues by neuraminidase has no such effect. It is probable that the compression of bound SRC into a small area of the membrane requires more energy than does the capping of protein ligands, and that some cells cannot muster enough energy to achieve it.     

The retention of 125I-labeled plasma membrane proteins in bovine spermatozoa cryopreserved in egg-yolk citrate extender

Cryopreservation of bovine sperm in egg-yolk citrate extender (EYC) usually maintains fertility. Since plasma membrane proteins are important for the fertilizing potential of sperm, the possible loss of membrane proteins from sperm subjected to cryopreservation in EYC was evaluated. Sperm were washed and labeled with ¹²⁵I without significantly reducing motility. Radiolabeled sperm were a) held for 2 hr at 22°C in N-2-hydroxyethylpiperazine-N'-ethanesulfonic acid (HEPES)-buffered saline containing 1% polyvinyl alcohol, b) cooled to 5 °C in glycerol-free EYC and held for 3 hr, or c) frozen-thawed in EYC containing 7% glycerol. Sperm were solubilized and proteins were separated by electrophoresis under denaturing conditions. Freeze-thawing dislodged most egg-yolk proteins from the spermatozoal plasma membrane that were bound to and retained by sperm that only were cooled to 5 °C. Autoradiography resolved 11-18 bands of ¹²⁵I polypeptides. There was no difference (P > 0.05) in the amount of ¹²⁵I protein retained by frozenthawed and cooled sperm. However, the radioactivity in two polypeptide bands (MW = 105 K and 24.2 K) was less (P < 0.05) for sperm held at 22 °C in HEPES-buffered saline. Thus, holding sperm in buffered saline at 22 °C resulted in a greater loss of ¹²⁵I proteins from the plasma membrane than did cryopreservation of sperm in EYC. Cryopreservation did not induce greater loss of ¹²⁵I proteins from the plasma membrane than simply cooling sperm to 5 °C in EYC.     

Membrane phase behavior during cooling of stallion sperm and its correlation with freezability

Abstract

Stallion sperm exhibits great male-to-male variability in survival after cryopreservation. In this study, we have investigated if differences in sperm freezability can be attributed to membrane phase and permeability properties. Fourier transform infrared spectroscopy (FTIR) was used to determine supra and subzero membrane phase transitions and characteristic subzero membrane hydraulic permeability parameters. Sperm was obtained from stallions that show differences in sperm viability after cryopreservation. Stallion sperm undergoes a broad and gradual phase transition at suprazero temperatures, from 30–10°C, whereas freezing-induced dehydration of the cells causes a more severe phase transition to a highly ordered gel phase. Sperm from individual stallions showed significant differences in post-thaw progressive motility, percentages of sperm with abnormal cell morphology, and chromatin stability. The biophysical membrane properties evaluated in this study, however, did not show clear differences amongst stallions with differences in sperm freezability. Cyclodextrin treatment to remove cholesterol from the cellular membranes increased the cooperativity of the suprazero phase transition, but had little effects on the subzero membrane phase behavior. In contrast, freezing of sperm in the presence of protective agents decreased the rate of membrane dehydration and increased the total extent of dehydration. Cryoprotective agents such as glycerol decrease the amount of energy needed to transport water across cellular membranes during freezing.     

Effect of culture pH on recombinant antibody production by a new human cell line, F2N78, grown in suspension at 33.0 °C and 37.0 °C

The human host cell line, F2N78, is a new somatic hybrid cell line designed for therapeutic antibody production. To verify its potential as a human host cell line, recombinant F2N78 cells that produce antibody against rabies virus (rF2N78) were cultivated at different culture pH (6.8, 7.0, 7.2, 7.4, and 7.6) and temperatures (33.0 °C and 37.0 °C). Regardless of the culture temperature, the highest specific growth rate was obtained at a pH of 7.0–7.4. Lowering the culture temperature from 37.0 °C to 33.0 °C suppressed cell growth while allowing maintenance of high cell viability for a longer period. However, it did not enhance antibody production because specific antibody productivity did not increase at 33.0 °C. The highest maximum antibody concentration was obtained at 37.0 °C and pH 6.8. The N-linked glycosylation of the antibody was affected by the culture pH rather than the temperature. Nevertheless, G1F was dominant and G2F occupied a larger portion than G0F in all culture conditions. Compared to the same antibody produced from recombinant CHO cells, the antibody produced from rF2N78 cells has more galactose capping and was more similar to human plasma IgG. Taken together, the results obtained here demonstrate the potential of F2N78 as an alternative human host cell line for therapeutic antibody production.     

A novel antigenic cell surface protein associated with T200 is involved in the post-activation stage of human NK cell-mediated lysis

A monoclonal antibody, 9.1C3, was used to investigate the mechanism of natural killer (NK) cell-mediated lysis. In addition to blocking NK cell function, the antibody blocked antibody-dependent cellular cytotoxicity against the K562 target cell at the effector cell level. The stage at which 9.1C3 antibody inhibited cytolysis was established with a Ca++ pulse technique, whereby it was shown that the antibody inhibited killing at a discrete step after the Ca++-dependent programming for lysis. The 9.1C3 antigen appeared to be associated with the T200 glycoprotein complex. Thus the 66 and 77 Kd proteins detected by 9.1C3 were also precipitated with a monoclonal antibody to T200, and in sequential immunoprecipitations, 9.1C3 antibody removed these bands from immunoprecipitates with antibody to T200. Also, in co-modulation studies, it was found that antibody to T200 co-capped the 9.1C3 antigen but that capping with 9.1C3 antibody did not induce co-modulation of the T200 antigen. Expression of the 9.1C3 and T200 antigens on different cell types, however, was not identical, and the 9.1C3 antibody did not immunoprecipitate high m.w. proteins in the region of 200 Kd. Functionally, in NK cell killing studies, the antibody to T200 used alone did not block but was synergistic with the 9.1C3 antibody. The differential effect of the enzymes pronase and trypsin on the cell surface expression of the 9.1C3 and T200 antigens reflected the ability of these enzymes to inhibit NK cell killing. These data suggest that the 9.1C3 antigen participates in a late event in the cytolytic pathway.     

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.