Quantification of the strength of cell-cell adhesion: the capture of tumor cells by activated murine macrophages proceeds through two distinct stages

The binding of tumor cells by macrophages activated with Bacillus Calmette-Guerin is a necessary step toward destruction of those cells. Although several characteristics of the interaction have been defined, little is known of how the actual binding process develops. We used a technique to quantify the forces required to disrupt cell-cell interactions. Over a range of applied relative centrifugal forces, the majority of targets that bound to the activated macrophages fell on two distinct plateaus. Approximately 90% of added targets were bound to the monolayers of macrophages over the range of 1 to 100 X G; 25 to 30% remained bound from 1200 X G to 1500 X G. Two strengths of binding, termed weak and strong binding, respectively, were thus defined on the basis of these curves. Strong binding developed only between activated macrophages and tumor cells. By contrast, weak interactions occurred between either activated or nonactivated macrophages and neoplastic or non-neoplastic target cells. The strong binding required time (60 to 90 min), metabolic activity by the macrophages, and trypsin-sensitive surface structures on the macrophages for development, whereas the weak interaction occurred rapidly and required none of these. Additional evidence indicated the weak binding developed into strong when activated macrophages bound neoplastic cells. This stabilization increased the strength of force to separate tumor cells from the macrophages at least approximately 15 fold (i.e., from approximately 16 mu dynes/cell to approximately 240 mu dynes/cell). Of note, the development of strong binding of antibody-coated targets had distinct requirements for establishment. Taken together, the data suggest the stabilization of binding (i.e., the development of weak into strong binding) leading to effective cell-cell interaction is a complex and dynamic process that may vary depending upon the recognition system involved.     

The cytolytic function of mononuclear phagocytes. II. Factors that determine the binding and lysis of tumor cells by activated macrophages

The effects of various modifiers upon the interaction of LPS- and BCG-activated macrophages with cells of mastocytoma P815 have been investigated. The efficiency of binding and lysis of the tumor cells is to a great extent determined by activation of the effector-cells, expression of the trypsin-sensitive receptors on the surface of macrophages, and by the type of target-cells. Introduction into the analytical system (effector-target) of unlabeled tumor cells or membrane preparations obtained from them inhibits substantially both binding and lytic activity of cytotoxic macrophages. If nontransformed cells or their membranes are applied, no significant changes in the investigated processes can be detected. Trypsinization of tumor cells as well as of activated but not resident macrophages modifies considerably the interaction of effectors with targets. The quantity of tumor cells bound with macrophages does not depend on the fact, which of the partners is subject to trypsinization, but it is much less than that of target-cells bound in the control. The incubation of activated macrophages with actinomycin D results in a substantial suppression of their lytic activity, whereas treatment of tumor cells with this inhibitor of protein synthesis leads to a considerable decrease in stability of the targets against lytic activity of the factor activated by effectors. The obtained data reveal the ways of selective binding and effective lysis of transformed targets by activated macrophages.     

The effects of activated macrophages on tumor target cells: Escape from cytostasis

In contrast to normal mouse peritoneal macrophages, activated macrophages almost totally inhibit [³H]TdR uptake by tumor target cells 24 hr after challenge. However, when the period of observation was extended to 48 or 72 hr, renewed [³H]TdR uptake by target cells was often, but not always, observed in the presence of activated macrophages. This apparent escape of target cells from the cytostatic effects of activated macrophages was not due to a subpopulation of resistant target cells, and autoradiographic studies revealed that target cells, inhibited from incorporating [³H]TdR by activated macrophages at 24 hr, were subsequently able to renew DNA synthesis and multiply. These results suggest that in the presence of activated macrophages, the almost total cytostasis of target cells does not necessarily mean that these cells are irreversibly damaged or killed.Escape from or maintenance of cytostasis was not peculiar to any of the target cells (L cells, EMT-6, Bladder 4934) or mouse strains (SW, C57BL, BALB/c) employed nor was it consistent with any of the forms of stimulation used for obtaining activated macrophages (Toxoplasma or Besnoitia infection; C. parvum treatment). However, the results suggest that when escape of target cells from the cytostatic effects of activated macrophages occurred, it may have been due to a qualitative or quantitative inadequacy of the population of macrophages employed.     

Enhancement of selective tumor cell binding by activated murine macrophages in response to phorbol myristate acetate

The fundamental biology of how stable cell-cell bonds develop between activated macrophages and tumor cells, although essential to lysis of the neoplastic targets, remains poorly understood. To investigate whether this phenomenon could be pharmacologically manipulated, we analyzed the effect of phorbol diesters on tumor cell binding by macrophages. Activated murine peritoneal macrophages, treated in vitro with as little as 1 ng/ml of phorbol myristate acetate (PMA), bound significantly more tumor cells than did untreated macrophages. The effect was induced rapidly by PMA (i.e., maximum enhancement was seen within 15 min) and resulted in an average approximately twofold increase in the number of targets bound. The interaction between PMA-treated activated macrophages and tumor cells was completed much more rapidly than by untreated macrophages. The enhanced binding was seen only in macrophages treated with biologically active phorbol esters. Only the selective interaction between activated macrophages and tumor cells was affected (i.e., PMA treatment had no effect on nonselective interactions between activated macrophages and non-neoplastic targets or between nonactivated macrophages and any type of target). Pretreatment of activated macrophages with PMA apparently altered the requirements for microfilaments and microtubules in establishing binding, because cytochalasin B and colchicine, which inhibited control binding, as well as phagocytosis, had no effect on PMA-enhanced binding. PMA treatment did not alter energy requirements for binding, however, because low temperature (4 degrees C) or inhibitors of glycolysis and oxidative phosphorylation blocked both control and PMA-enhanced binding. The enhancement of binding apparently was not due to large quantities of secreted oxygen metabolites but did correlate closely with increased spreading and surface area of the macrophages. PMA treatment resulted in enhanced expression of trypsin-sensitive tumor-cell binding sites on the macrophage surface. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of macrophage membrane proteins labeled with 125I by the lactoperoxidase method revealed at least four trypsin-sensitive cell surface proteins that were re-expressed after PMA treatment. The data suggest that rearrangement and/or induced expression of surface binding sites may be an important step in the binding of tumor cells and indicate that PMA is a useful pharmacologic probe in dissecting the establishment of such binding into discrete steps.     

Increased binding of tumor cells by macrophages activated in vitro with lymphocyte mediators.

Following incubation in vitro with lymphocyte mediators, activated macrophages become capable of binding more tumor cells than nonactivated macrophages. Increased binding occurs rapidly (within 1 hr), does not require the presence of serum in the medium, and is inhibited by treatment with trypsin. The increased binding by activated macrophages is quantitatively selective for tumor cells. Incubation with lymphocyte mediators of cell types other than macrophages does not increase the binding of tumor cells to such monolayers. These results indicate that the binding of tumor cells by activated macrophages results from the stimulation of a specific macrophage function during the process of macrophage activation.     

Increasing the sensitivity of in vitro transformed hamster embryo cells (STHE strain) to cytolysis by resident and activated macrophages

The sensitivity of low-malignant spontaneously in vitro transformed hamster embryo cells (STHE strain) to cytolysis of both resident and activated macrophages has been examined with cytolytic 3H-thymidine release assay. Activated macrophages were obtained from Syrian hamster peritoneal exudate cells 5 days following priming with 3% thioglycollate-broth and subsequent in vitro activation with proper-myl, levan, LPS, MDP, 1,4-dihydropyridine-derivate PP-256 and PMA. It has been shown that the STHE strain cells were sensitive to cytolysis by only fully activated macrophages. Both resident and non-activated (Thioglycollate-elicited) macrophages have not developed significant levels of the cytolytic activity against STHE cell targets. Short-term treatment of STHE cells with actinomycin D result in augmentation of their sensitivity to cytolysis by resident and activated macrophages.     

Demonstration of YAC target cell lysis by murine granulated metrial gland cells

Granulated metrial gland (GMG) cells are a consistently observed but poorly understood feature of the murine uterus during successful pregnancy. From morphological studies and antibody phenotyping it has been suggested that GMG cells may be members of the natural killer (NK) cell lineage. However, lysis of murine NK cell targets by GMG cells has not been observed although lysis of freshly dissociated trophoblast cells by GMG cells has been recorded using timelapse video. We failed to demonstrate significant interactions between migrating GMG cells, collected from explant cultures under previously reported cultures conditions, and YAC target cells. However, YAC cell lysis did occur if hrIL-2 was present throughout the periods of explant culture and lysis assay. Furthermore, lysis was enhanced if the pregnant females were treated with the interferon inducer poly I.C. 24 hr before metrial gland collection. GMG cells expressed perforin and serine protease mRNA. Consistent with the lysis experiments, expression of these genes was enhanced when the cells were incubated with hrIL-2. Our data provide further support for a relationship between GMG cells and NK cells, but do not establish a relationship of identity since hrIL-2, a growth factor sufficient for the culture of NK cells, cannot support growth or prolong survival of GMG cells.     

Antibody-dependent cell lysis by NK cells is preserved after sarcoma-induced inhibition of NK cell cytotoxicity

Osteosarcoma and Ewing’s sarcoma tumor cells are susceptible to IL15-induced or antibody-mediated cytolytic activity of NK cells in short-term cytotoxicity assays. When encountering the tumor environment in vivo, NK cells may be in contact with tumor cells for a prolonged time period. We explored whether a prolonged interaction with sarcoma cells can modulate the activation and cytotoxic activity of NK cells. The 40 h coculture of NK cells with sarcoma cells reversibly interfered with the IL15-induced expression of NKG2D, DNAM-1 and NKp30 and inhibited the cytolytic activity of NK cells. The inhibitory effects on receptor expression required physical contact between NK cells and sarcoma cells and were independent of TGF-β. Five days pre-incubation of NK cells with IL15 prevented the down-regulation of NKG2D and cytolytic activity in subsequent cocultures with sarcoma cells. NK cell FcγRIIIa/CD16 receptor expression and antibody-mediated cytotoxicity were not affected after the coculture. Inhibition of NK cell cytotoxicity was directly linked to the down-regulation of the respective NK cell-activating receptors. Our data demonstrate that the inhibitory effects of sarcoma cells on the cytolytic activity of NK cells do not affect the antibody-dependent cytotoxicity and can be prevented by pre-activation of NK cells with IL15. Thus, the combination of cytokine-activated NK cells and monoclonal antibody therapy may be required to improve tumor targeting and NK cell functionality in the tumor environment.     

Characterization of the recognition of target cells sensitive to or resistant to cytolysis by activated macrophages: II. Competitive inhibition of macrophage-dependent tumor cell killing by mitogen-induced,nonmalignant lymphoblasts

We have previously reported that tumoricidal rat macrophages can distinguish quiescent normal lymphocytes from concanavalin A (Con A)-stimulated lymphocytes and thymic lymphoma cells on the basis of their ability to compete for the macrophage-dependent cytolysis of a sensitive tumor cell line. The present study was undertaken to determine (a) whether recognition was related to the proliferative response induced by Con A stimulation and (b) whether the competition of cytolysis was dependent upon the binding of sensitive target cells to activated macrophages. These possibilities were tested by examining Con A-treated lymphocytes in different functional stages of the Con A response with respect to their ability to compete either for cytolysis or binding of a tumor cell line susceptible to both activities. The results show that the ability to compete for either function was acquired coincidentally with the Con A-induced proliferative response. This competitive activity was not due solely to the presence of Con A in the culture medium nor to culture of unstimulated lymphocytes but rather required a blastogenic response to the mitogen. Blast-transformed nonproliferative cells (96 hr post-Con A stimulation) were as competitive as cells which had been stimulated to reinitiate DNA replication by treatment with Interleukin 2. Thus, competition for cytolysis is a consequence of blastogenesis rather than proliferation per se and operates mechanistically by competing for the binding of target cells to activated macrophages, an event known to be a necessary prerequisite to cytolysis.     

Both tumor necrosis factor and nitric oxide participate in lysis of simian virus 40-transformed cells by activated macrophages.

SV40 transformation of rodent fibroblasts generally produces cells that are highly sensitive to killing by activated macrophages. The cell line SV-COL-E8 (E8) is typical of SV40-transformed mouse fibroblasts in that it is readily lysed when exposed to activated macrophages. This killing is not due solely to TNF, because soluble TNF alone is incapable of lysing these cells. TNF is, however, necessary for lysis since antibodies to TNF will prevent macrophage-mediated lysis. Similarly, E8 is not sensitive to nitric oxide (NO); however, NO is also necessary for lysis since inhibition of NO generation (by coincubation with the arginine analogue NG-monomethyl-1-arginine) with Fe(II)) blocks lysis of E8 by activated macrophages. Cytolysis by macrophages is contact dependent, suggesting that the cell-associated TNF precursor may be involved in mediating cytolysis. However, transfected cell lines bearing cell-associated TNF precursor do not mediate killing of E8. Thus, killing of E8 either involves both TNF and NO in addition to a third, as yet unidentified, lytic mechanism, or killing requires the contact-dependent delivery of TNF and NO from the macrophage to its target.     

Generation of EPR-detectable nitrosyl-iron complexes in tumor target cells cocultured with activated macrophages.

After immunostimulation, murine macrophages oxidize L-arginine into nitric oxide (NO) which acts as an effector molecule. In this study, we attempted to establish whether activated macrophage-derived NO forms paramagnetic complexes in tumor target cells which do not express by themselves the L-arginine:NO pathway. Accordingly, murine L1210 leukemia cells were cocultivated with activated peritoneal macrophages from Bacillus-Calmette-Guérin-infected mice, or activated in vitro with interferon-gamma. In control experiments, macrophages were prevented from producing nitrogen oxides by incubation with NG-monomethyl-L-arginine, a specific inhibitor of the L-arginine:NO pathway. After coculture, L1210 cells were removed from adherent macrophage monolayers and analyzed by electron paramagnetic resonance at 77 K. In the L1210 cells cultured with activated macrophages, we detected a signal typical of nitrosyl-iron-sulfur complexes, with g values of 2.041 and 2.015. This signal was not present when L1210 cells were either cultured alone or cocultured with activated macrophages in the presence of NG-monomethyl-L-arginine. Mitochondria from activated macrophage-injured L1210 cells also exhibited the signal with g values of 2.041 and 2.015. These results show that when tumor target cells undergo cell-to-cell contact with activated macrophages during culture, the macrophages promote target cell nitrosylation in compartments like mitochondria.     

Role of tumor necrosis factor-alpha in E1A oncogene-induced susceptibility of neoplastic cells to lysis by natural killer cells and activated macrophages

NIH-3T3 cells transfected with adenovirus E1A oncogene cDNA were found to exhibit cytolytic susceptibility to murine NK cells and activated macrophages associated with a threshold level of oncogene product expression exceeding that required for morphological transformation. A similar correlation was observed between threshold levels of E1A gene product expression and target cell susceptibility to direct cytotoxicity by rTNF. Inhibition of splenic NK cell and peritoneal macrophage cytolysis by antisera specific for murine rTNF confirmed the importance of E1A-induced TNF susceptibility as one determinant of target cell cytolytic susceptibility. Anti-TNF antibody was, however, unable to block killing of E1A-expressing targets by the NK cell line, NKB61A2. These results suggest a direct link between the functions of E1A oncogene products and cellular mechanisms of action of TNF elaborated by host effector cells and indicate that E1A expression also affects target cell susceptibility to TNF-independent cytolytic mechanisms.     

Latent murine gamma-herpesvirus infection is established in activated B cells, dendritic cells, and macrophages

Intranasal infection of mice with the murine gamma-herpesvirus MHV-68 results in an acute lytic infection in the lung, followed by the establishment of lifelong latency. Development of an infectious mononucleosis-like syndrome correlates with the establishment of latency and is characterized by splenomegaly and the appearance of activated CD8+ T cells in the peripheral blood. Interestingly, a large population of activated CD8+ T cells in the peripheral blood expresses the V beta 4+ element in their TCR. In this report we show that MHV-68 latency in the spleen after intranasal infection is harbored in three APC types: B cells, macrophages, and dendritic cells. Surprisingly, since latency has not previously been described in dendritic cells, these cells harbored the highest frequency of latent virus. Among B cells, latency was preferentially associated with activated B cells expressing the phenotype of germinal center B cells, thus formally linking the previously reported association of latency gene expression and germinal centers to germinal center B cells. Germinal center formation, however, was not required for the establishment of latency. Significantly, although three cell types were latently infected, the ability to stimulate V beta 4+CD8+ T cell hybridomas was limited to latently infected, activated B cells.     

Evidence against expression of an endogenous murine leukemia virus causing cellular resistance to lysis by activated macrophages

In previous studies we observed that resistance of murine SV40-transformed fibroblast cell lines to cytolysis by activated macrophages was frequently associated with cellular expression of the gp70 of an endogenous ecotropic murine leukemia virus (MuLV). The work described here was initiated to test directly for a causative relationship between MuLV expression and resistance to lysis by macrophages. Northern blot analysis revealed that macrophage-resistant cells contain full length retroviral RNA. A panel of mAb which distinguish among host-range classes of MuLV detected only a non-recombinant ecotropic gp70 in these cells. The ecotropic MuLV from two independently derived macrophage resistant cells were isolated by limiting dilution cloning on Mus dunii fibroblasts. These viruses were then used to infect macrophage-sensitive cell lines and the resultant MuLV-positive cells tested for sensitivity to macrophage cytolysis. The MuLV-infected lines remained highly sensitive to macrophage lysis despite their high levels of cell surface gp70 and release of infectious MuLV. Thus, although we cannot rule out the possibility that MuLV or a product thereof is necessary for development of macrophage resistance in transformed cells, expression of MuLV per se is not sufficient to create the resistant phenotype.     

Yersinia protein kinase YopO is activated by a novel G-actin binding process

Pathogenic bacteria of the genus Yersinia employ a type III secretion system to inject effector proteins (Yops) into host cells. The Yops down-regulate host cell functions through unique biochemical activities. YopO, a serine/threonine kinase required for Yersinia virulence, is activated by host cell actin via an unknown process. Here we show that YopO kinase is activated by formation of a 1:1 complex with monomeric (G) actin but is unresponsive to filamentous (F) actin. Two separate G-actin binding sites, one in the N-terminal kinase region (amino acids 89-440) and one in the C-terminal guanine nucleotide dissociation inhibitor-like region (amino acids 441-729) of YopO, were identified. Actin binding to both of these sites was necessary for effective autophosphorylation of YopO on amino acids Ser-90 and Ser-95. A S90A/S95A YopO mutant was strongly reduced in substrate phosphorylation, suggesting that autophosphorylation activates YopO kinase activity. In cells the kinase activity of YopO regulated rounding/arborization and was specifically required for inhibition of Yersinia YadA-dependent phagocytosis. Thus, YopO kinase is activated by a novel G-actin binding process, and this appears to be crucial for its anti-host cell functions.     

Nucleosome-dependent escape of tumor cells from natural-killer-mediated lysis: nucleosomes are taken up by target cells and act at a postconjugation level

 Our previous data suggested that chromatin fragments released from dead cells into the extracellular medium could be involved in the impairment of natural-killer (NK)-mediated cytotoxicity reported in cancer patients. In the present study, an inhibition of the NK-mediated lysis was obtained in vitro by nucleosome addition to different tumor target cells, independently of their sensitivity to NK-mediated lysis. We observed a rapid endocytosis and degradation of nucleosomes by K562 tumor target cells and (although to a much lesser extent) a binding to a subpopulation of lymphocytes. Nucleosomes impaired neither the conjugation step nor the expression of adhesion molecules at the effector (CD11a, CD18, CD2) or target (CD54, CD58) cell surface. On the contrary, flow-cytometry analysis of the conjugation suggested that nucleosomes might stabilize the conjugates. Investigations of the killing process showed that nucleosomes decreased the NK cytotoxic potential without modifying Ca²⁺-dependent lethal-hit-delivery kinetics. The cytotoxic potential was not restored by increasing the available magnesium and calcium concentrations in the extracellular medium. Taken together, the results suggest that the inhibition of NK-mediated lysis by nucleosomes may result from alterations of the NK mechanism at the postconjugation level and after lethal-hit delivery. Hence, the inhibition could involve a delay in the recycling of effector cells, or a resistance of tumor target cells to NK cells. Received: 7 October 1996 / Accepted: 12 November 1996     

Virus-mediated induction in human lymphocytes of antibody-independent cytotoxicity (VDCC) and enhancement of antibody-dependent cytotoxicity (ADCC) against natural killer-resistant tumor target cells

The effect of Parotis virus on the in vitro cytotoxicity of human lymphocytes against NK-resistant mouse mastocytoma cells was studied. In the ⁵¹Cr-release assay, treatment of lymphocytes with virus induced a rapid cytotoxicity in the absence of anti-P8 15 antibody (virus-dependent cellular Cytotoxicity, VDCC) and strongly enhanced antibody-dependent cytotoxicity (ADCC). At the effector cell level, virus treatment was found to increase the frequency of target-binding cells (TBC) as well as the proportion thereof mediating VDCC and/ or ADCC, indicating recruitment of active effector cells. The recruited cells were heterogeneous but contained a major fraction bearing the T-cell-associated antigen T3. Virus was found to decrease rather than to increase the recycling capacity of the cytotoxic lymphocytes, suggesting that VDCC induction and ADCC enhancement were due to a virus-mediated improvement of effector cell-target cell interactions. VDCC and ADCC enhancement may be of protective importance in early phases of virus infection as well as for the production of nonspecific tissue injuries associated with viral disease.     

Mechanism of inducer expulsion in Streptococcus pyogenes: a two-step process activated by ATP.

The mechanism of methyl-beta-D-thiogalactoside-phosphate (TMG-P) expulsion from Streptococcus pyogenes was studied. The expulsion elicited by glucose was not due to exchange vectorial transphosphorylation between the expelled TMG and the incoming glucose since more beta-galactoside was displaced than glucose taken up, and the stoichiometry between TMG and glucose transport was inconstant. Instead, two distinct and sequential reactions, intracellular dephosphorylation of TMG-P followed by efflux of free TMG, mediated the expulsion. This was shown by temporary accumulation of free TMG effected by competitive inhibition of its efflux and by the aid of arsenate, which arrested dephosphorylation of TMG-P but did not affect efflux of free TMG formed intracellularly before arsenate addition. The competitive inhibition of TMG efflux by its structural analogs suggests that a transport protein facilitates the expulsion. Iodoacetate or fluoride prevented TMG-P dephosphorylation and its expulsion. However, provision of ATP via the arginine deiminase pathway restored these activities in the presence of the glycolytic inhibitors and stimulated expulsion in their absence. Other amino acids tested did not promote this restoration, and canavanine or norvaline severely inhibited it. Arginine without glucose neither elicited the dephosphorylation nor evoked the expulsion of TMG-P. Ionophores or ATPase inhibitors did not prevent the expulsion as elicited by glucose or its restoration by arginine. The results suggest that activation of the dephosphorylation-expulsion mechanism occurs independently of a functional glycolytic pathway, requires ATP provision, and is possibly due to protein phosphorylation controlled by a yet unknown metabolite. The in vivo phosphorylation of a protein (approximate molecular weight - 10,000) under the conditions of expulsion was demonstrated.     

In vitro interactions of murine peritoneal macrophages and sarcoma cells. I. Promotion of tumor cells proliferation by macrophages

An ascites subline (AA) of the murine sarcoma MC1M grows in vivo in the peritoneal cavity but dies in vitro when cultured on glass or collagen. The viability of AA cells in vitro is not influenced in cocultures with fibroblast cell line L929, and is diminished in cocultures supplemented with macrophage culture supernatant or in cocultures with non-adherent peritoneal cells. However, AA cells proliferate in vitro on glass or collagen when cocultured with syngeneic, semisyngeneic, and allogeneic peritoneal macrophages. This was demonstrated by tritiated thymidine incorporation assay, by AA cell number counting, and by measuring AA cell protein content. Proliferation also occurs when AA cells are separated from the macrophage monolayer by millipore filters.     

Modulation of the recognition and lysis of EL4 tumor target cells by cytotoxic T lymphocytes

When the EL4 targets were harvested from the peritoneal cavity (in vivo), they had less than half as much cell-surface sialic acid as EL4 cells harvested from tissue culture (in vitro), apparently due to the presence of a neuraminidase activity in the peritoneal cavity. Both the recognition and the lysis of either EL4 in vivo or EL4 in vitro target cells by allogeneically primed cytotoxic T lymphocytes were enhanced upon removal of cell-surface sialic acid by neuraminidase treatment. However, even after neuraminidase treatment, there still remained a difference in the lytic profile when using EL4 targets that were harvested in vivo versus in vitro. Both conjugate formation between the target and the T cells and anti-H-2D^b adsorption by the target cells were unaffected by the culture conditions of the target line. However, antibody-induced capping and exocytosis of vesicles differed between the differently cultured target cells, suggesting that there was a membrane organizational difference between them that was detected by the cytotoxic T cells. These data are consistent with the idea that cell surface sialic acid as well as the membrane organization can influence T-cell recognition and lysis of target cells.