Protection from experimental autoimmune thyroiditis conferred by a monoclonal antibody to T cell receptor from a cytotoxic hybridoma specific for thyroglobulin.

A clonotypic mAb, AG7, has been prepared from splenocytes of CBA/J mice immunized with a cytotoxic T cell hybridoma, HTC2, specific for a pathogenic epitope of the thyroglobulin molecule in association with class I MHC Ag. AG7 binds to HTC2 cells but not to the other T cell hybridomas tested. Moreover, when used in functional studies, AG7 blocks the HTC2 capacity of specific target lysis. It also reacts with a determinant that comodulates with the CD3 Ag present on the surface of HTC2 cells. Immunoprecipitation of 125I-labeled solubilized HTC2 membranes demonstrated two bands located at 90 and 72 kDa under nonreducing conditions, which became a 46-kDa band under reducing conditions. Finally, when AG7 is injected into CBA/J mice, on day -1 before immunization with the pathogenic tryptic fragments of the thyroglobulin molecule, experimental autoimmune thyroiditis is abrogated. Thus, one of the multiple potential mechanisms of the protective immunity against EAT induced by HTC2 cells that we previously proposed, i.e., the generation of anti-clonotypic antibodies to HTC2 TCR, seems apparent.     

Arsonate-specific murine T cell clones. IV. Properties of I-E- and I-A-restricted clones

The T cell antigen L-tyrosine-p-azobenzenearsonate is unique in being a simple determinant that can be presented in the context of both I-A and I-E. I-E-restricted T cell clones derived from B10.A(5R) mice were found to fall into three groups: Type I clones recognized antigen only in the context of syngeneic apcs, Type II clones recognized antigen with the same highly specific major histocompatibility complex restriction but in addition proliferated in response to allogeneic stimuli; Type III clones were "degenerate" in their major histocompatibility complex-restricted recognition of antigen and proliferated when antigen-presenting cells bearing Eb beta Ek alpha (syngeneic), Ek beta Ek alpha, or Ed beta Ed alpha were used. These observations allow some conclusions to be drawn about sites on the I-E molecule that may be functionally significant in the presentation of this antigen. By using the B cell hybridoma LK35.2 as target cells, some of these T cell clones act as cytotoxic cells in the Class II-restricted manner predicted from the results of proliferative assays. Class II-restricted cytotoxicity can therefore be controlled by both I-A and I-E mouse Ir gene loci.     

Rat cytotoxic T lymphocytes against human T-lymphotropic virus type 1-infected cells recognize gag gene and env gene encoded antigens

T cell immune responses in syngeneic WKA/H rats were analyzed by using lymphoid cell lines, TARS-1, TART-1, and TARL-2, infected with human T-lymphotropic virus type 1 (HTLV-1). Spleen cells of rats in which these cell lines had been rejected were sensitized in vitro with the same cell lines, and cells cytotoxic to these HTLV-1+ cell lines, and cells cytotoxic to these HTLV-1+ cell lines were generated. The effector cells were CTL of the CD5+ CD8+ phenotype and showed restriction of MHC class I Ag. Direct tests as well as cold target cell inhibition tests with an array of cell populations showed that these CTL reacted only with syngeneic HTLV-1+ cell lines. When xenogeneic HTLV-1+ cell lines were similarly utilized for in vitro sensitization, rat CTL specific for syngeneic HTLV-1+ cells were generated. They were not, however, reactive with xenogeneic HTLV-1+ cells used for sensitization. Syngeneic rat cells selectively expressing gag, env, or pX gene coded Ag were prepared by infection of recombinant vaccinia viruses. In cold target cell inhibition tests of anti-HTLV-1 CTL with thus prepared cells, cytotoxicity against the syngeneic HTLV-1+ cells line, TARS-1, was inhibited by syngeneic cells expressing gag gene or env gene coded Ag. Inhibition was, however, more consistent and more dominant by cells with gag gene than those with env gene. Syngeneic cells with pX gene and MHC class I incompatible cells with gag, env, or pX gene did not inhibit cytotoxicity.     

H-2 antigen expression and sensitivity of BL6 melanoma cells to natural killer cell cytotoxicity

The sensitivity of H-2b-high and H-2b-low variants of BL6 melanoma to the cytotoxic action of NK and lymphokine-activated killer cells was investigated. BL6 mouse melanoma cells lack detectable H-2Kb and had low levels of expression of H-2Db Ag. The BL6T2 variant cells, obtained after treatment of BL6 cells with mutagen N-methyl-N-nitro-N'-nitro-soguanidine, had relatively high levels of expression of class I H-2b Ag. Poly(I:C)-stimulated spleen cells of nude mice were highly cytotoxic for BL6T2, whereas H-2b-low BL6 cells were less sensitive to NK activity in an 18-h 51Cr-release assay. Similar results were obtained after 4-h incubation of radio-labeled tumor cells with IL-2-activated effector cells. In contrast, both lines were equally sensitive to lysis by purified granules derived from rat large granular lymphocytes (LGL) or by macrophages. By using various clones selected from BL6 or BL6T2 cells, it was found that BL6 or BL6T2 clones with low H-2b Ag expression were less sensitive to lysis by NK cells than H-2b-high clones. After IFN treatment of either BL6 or BL6T2, the target cells became more resistant to lysis by either NK cells or by purified LGL granules. IFN-treated BL6 cells had substantially increased expression of H-2b Ag and in this respect became similar to untreated BL6T2. However, IFN-treated BL6 cells were more resistant than BL6T2 cells to lysis by NK cells and LGL granules, suggesting that augmentation of H-2b Ag expression and NK resistance could be two independent IFN-induced effects. With a cold target inhibition assay, it was found that BL6T2 or its H-2 positive clones were highly competitive and inhibited the cytotoxic activity of NK and lymphokine-activated killer cells against radiolabeled YAC-1 and BL6T2, whereas BL6 cells or H-2-negative clones of BL6T2 and BL6 lines showed poor competitive ability. Thus, our data indicate that the NK resistance of H-2-low BL6 cells may be due to a paucity of NK recognizable determinants. N-Methyl-N-nitro-N'-nitroguanidine treatment of BL6 melanoma cells was associated with an increase in class I H-2b Ag expression and NK sensitivity, suggesting the involvement of class I MHC Ag in the sensitivity of tumor cells to NK cell-mediated cytotoxicity.     

Generation of class I MHC-restricted T-T hybridomas

In this report we describe a system for the generation of functional, class I MHC-restricted, T-T hybridomas. The BW5147 cell line was transfected with the CD8 gene. BW5147 transfectants were obtained that stably expressed CD8 and this expression was maintained after somatic cell hybridization with activated T lymphocytes. To determine whether the stable expression of CD8 would facilitate the generation of class I MHC-specific T-T hybridomas, the transfected cells were fused with alloreactive T cells and the resultant hybrids were screened for their ability to produce lymphokines in response to antigenic stimulation. Somatic cell hybridizations with BW5147-CD8 transfectants give rise to a much higher frequency of class I MHC-specific T-T hybridomas relative to parallel fusions with BW5147. To determine whether the BW5147-CD8 transfectants would also support the generation of Ag-specific, class I MHC-restricted T-T hybridomas, they were fused with OVA-specific CTL. Several T-T hybrid clones were identified that produced lymphokines after stimulation with a transfected APC that was synthesizing OVA, or with a tryptic digest of OVA in the presence of syngeneic APC. The stimulation by Ag was MHC-restricted and mapped to the Kb molecule. An anti-CD8 mAb inhibited the stimulation of these hybridomas by Ag plus APC, whereas their stimulation by mitogen was unaffected. Cytolytic activity was not detected when several of the OVA-specific or alloreactive hybridomas were tested for their ability to kill target cells bearing the appropriate Ag. These results demonstrate that the BW5147-CD8 transfectants allow the generation of class I MHC-restricted T-T hybridomas. The potential utility of this system is discussed.     

Introduction of soluble protein into the class I pathway of antigen processing and presentation

In order to investigate how peptides associate with class I major histocompatibility complex (MHC) glycoproteins intracellularly, we generated cytotoxic T lymphocytes (CTL) specific for a readily available soluble protein in association with class I. C57BL/6 (H-2b) mice immunized against a syngeneic tumor cell transfected with chicken ovalbumin (OVA) cDNA gave rise to H-2Kb-restricted CTL specific for the OVA258-276 peptide. This synthetic peptide and CNBr fragments of OVA (242-285 and 242-273) were able to target H-2b cells for lysis by the CTL in a 3 hr assay. Cells incubated with native OVA for up to 24 hr did not become sensitized for recognition and lysis. However, when OVA was introduced directly into the cytoplasm of cells by the osmotic lysis of pinosomes, the Kb restricted determinant formed readily.     

Alloreactive bovine T lymphocyte clones: an analysis of function, phenotype, and specificity

A bovine alloreactive cell population was subjected to complement-dependent lysis with monoclonal antibody (mAb) IL-A11. The original population and the population depleted of cells bearing the determinant recognized by mAb IL-A11 were cloned. Parent cultures and 21 clones were examined for cytolytic function and for expression of determinants recognized by mAb IL-A11 and two additional mAb, IL-A12 and IL-A17. Clones could be classified according to maximal achievable levels of cytolysis by using Theileria parva-infected bovine lymphoblastoid target cells. In this way, three groups were identified--one capable of high level cytolysis, one of intermediate levels, and one group comprising apparently noncytolytic clones. The clones in the first group reacted with mAb IL-A17; those in the second and third groups, with mAb IL-A11 and IL-A12. It was shown that cytotoxicity effected by IL-A17+ clones could be inhibited by this mAb and also by a mAb directed to MHC class I determinants on target cells. Conversely, cytotoxicity effected by IL-A11+/IL-A12+ clones could be inhibited by mAb IL-A11 and by a mAb directed to MHC class II determinants on target cells. The levels of expression of class I and class II determinants on target cells correlated with the levels of killing by clones of the IL-A17+ phenotype and clones of the IL-A11+/IL-A12+ phenotype, respectively. The results indicate that cytotoxic bovine T lymphocyte clones specific for class I MHC antigens and both cytotoxic and noncytotoxic clones specific for class II MHC antigens can be obtained. Further, their specificity for class I or class II antigens can be determined by phenotyping with mAb.     

Synergy between subpopulations of normal mouse spleen cells in the in vitro generation of cell-mediated cytotoxicity specific for "modified self" antigens.

Responding lymphoid cells cultured in vitro with irradiated trinotrophenyl (TNP)-modified syngeneic spleen cells develop direct cell-mediated cytotoxicity which is specific for target cells bearing both the TNP moiety and histocompatibility determinants of the modified sensitizing cell. Two subpopulations of normal mouse spleen cells have been shown to synergize in the in vitro generation of specific cell-mediated cytotoxicity to these "modified self" antigens. The synergizing populations are nylon wool column-adherent and column-nonadherent fractions of normal mouse spleen. When mixtures of these two cell populations are cultured in vitro with irradiated TNP-modified syngeneic spleen cells, greater cytotoxicity is generated in the two populations sensitized separately. The synergizing cell in the column-adherent population is resistant to lysis by rabbit anti-mouse brain serum, is distinct from the cytotoxic effector T lymphocyte, and is unresponsive to phytohemagglutinin; its synergizing function could not be replaced by peritoneal cells. These results suggest that it is a non-T cell which may be distinct from the macrophage.     

Ultrastructural changes during lysis of L929 target cells by class II-restricted influenza virus-specific murine cytotoxic T-lymphocyte clones

Lysis of virus-infected L929 target cells transfected with the H-2 class II IAk gene by class II-restricted influenza virus-specific murine cytotoxic T lymphocyte (CTL) clones was studied by electron microscopy and compared with lysis of L929 cells by class I-restricted CTL clones. T lymphocytes predominantly approached the basal surface of target cells grown on a plastic dish and also approached uninfected L929 target cells, although virus maturation exhibited no polarity with respect to the cell surface site. After incubation for 30 min, the target cell nuclei began to change: chromatin became irregularly redistributed and aggregated, and the nuclei appeared swollen. Later, electron-dense and -light areas of nuclei became segregated, and the cytoplasm became disorganized with many vacuoles. The ultrastructural changes of target cells during lysis by class I- and class II-restricted CTL clones appeared to be similar. These findings and other cytotoxicity data of class I and class II CTLs are discussed.     

Functional heterogeneity in allospecific cytotoxic T lymphocyte clones. II. Development of syngeneic cytotoxicity in the absence of specific antigenic stimulation

Two out of four long-term murine allospecific cytotoxic T lymphocyte (CTL) clones tested could develop high levels of cytotoxicity against syngeneic target cells when cultured under appropriate conditions. All CTL clones maintained strict allospecificity so long as they were cultured with both appropriate allogeneic stimulator cells and growth factor (supernatant from secondary mixed lymphocyte cultures). In two of the clones, syngeneic reactivity rapidly developed when the allogeneic stimulator cells were replaced with syngeneic or third party stimulator cells, and when the supernatant from EL4 thymoma cells stimulated with phorbol ester was used as growth factor. In addition to killing the appropriate allogeneic target, clones with syngeneic reactivity could kill both syngeneic C57BL/6 targets and H-2-congenic BALB.B targets but not third party unrelated targets, suggesting that the self structure recognized was coded for within the major histocompatibility complex. Such clones did not kill the natural killer (NK) target YAC. The results obtained from cold target inhibition and from subcloning at limiting dilution of clones with syngeneic reactivity suggested that both allogeneic and syngeneic reactivity could be expressed by the same individual cell in the CTL clone. The specificity for syngeneic H-2 as opposed to third party H-2 and NK-sensitive target cells, and the observation that both allospecific and syngeneic killing could be partially blocked by anti-Lyt-2 antibody treatment of the CTL, strongly suggested that different recognition structures are involved in CTL-mediated syngeneic cytotoxicity and NK cytotoxicity.     

Major histocompatibility complex-unrestricted cytolytic activity of human T cells. Analysis of precursor frequency and effector phenotype

The frequency and phenotype of human T cells that mediate major histocompatibility complex (MHC)-unrestricted cytolysis were analyzed. T cell clones were generated by culturing adherent cell-depleted peripheral blood mononuclear cells at a density of 0.3 cell/well with phytohemagglutinin, recombinant interleukin 2 (rIL-2), and irradiated autologous peripheral blood mononuclear cells and/or Epstein-Barr virus-transformed lymphoblastoid cell lines. These conditions were shown to expand a mean of 96% of cells cultured. All of the 198 clones generated by this method were T cells (CD2+, CD3+, CD4+ or CD2+, CD3+, CD8+) that possessed potent lytic activity against K562, an erythroleukemia line sensitive to lysis by human natural killer cells, and Cur, a renal carcinoma cell line resistant to human natural killer activity. Cytolysis was MHC-unrestricted, since the clones were able to lyse MHC class I or class II negative targets, as well as MHC class I and class II negative targets. In addition, the activity was not inhibited by monoclonal antibodies directed against class I or class II nonpolymorphic MHC determinants. Killing, however, was inhibited by soluble monoclonal antibodies against the CD3 complex. Although the clones produced tissue necrosis factor/lymphotoxin-like molecules, lysis of Cur or K562 was not mediated by a soluble factor secreted by the clones. Some of the clones retained their cytotoxic activity when grown in rIL-2 alone for 4 to 6 wk, whereas others exhibited markedly diminished cytotoxicity after maintenance in this manner. Clones that exhibited diminished or no cytotoxic activity after prolonged maintenance in rIL-2 could be induced to kill by stimulation with immobilized but not soluble monoclonal antibodies to CD3 in the absence of lectin. All of the clones examined expressed NKH1 and CD11b but none were CD16 positive. The degree of cytotoxicity of resting or activated clones could not be correlated with expression of these markers. These data indicate that the capacity for MHC-unrestricted tumoricidal activity and expression of NKH1 and CD11b, but not CD16, are properties common to all or nearly all human peripheral blood-derived T cell clones regardless of CD4 or CD8 phenotype.     

Syngeneic sensitization of mouse lymphocytes on monolayers of thyroid epithelial cells. VII. Generation of thyroid-specific cytotoxic effector cells

During primary syngeneic sensitization of lymphocytes on monolayers of thyroid epithelial cells (TEC), lymphoblasts are generated as assessed by thymidine uptake. When these thyroid-sensitized lymphoblasts are deposited onto 51Cr labeled TEC used as target cells, syngeneic cytotoxicity (SC) occurs after 5 hr. The effector cell of this SC is a T lymphocyte, belonging to the Lyt-2 T-cell subset. Moreover, blocking experiments demonstrated that SC involves class I major histocompatibility complex and thyroglobulin (Tg) antigens. These data demonstrate that SC can be compared to the classical hapten or virus self-mediated cytotoxicity, but in this case Tg plays the role of these agents. The in vivo relevance of this SC is discussed.     

MHC-restricted cytotoxic response of chicken T cells: expression, augmentation, and clonal characterization

Major histocompatibility complex (MHC)-restricted cytotoxicity of chicken lymphocytes was studied by using three reticuloendotheliosis virus (REV)-transformed cell lines as targets in 51Cr-release assays. The cell lines, designated RECC-UG5, RECC-UG6, and RECC-UG8, were developed from bone marrow cells of REV-infected line G-B1, line G-B2, and (G-B1 X G-B2)F1 chickens respectively. Effector cells were obtained from spleens of G-B1, G-B2, F1, and F2 chickens 7 days after inoculation of REV. The inbred G-B1 (MHC genotype B13/B13) and G-B2 (MHC genotype B6/B6) lines originate from a common partially inbred line. Initial studies with effector cells from G-B1 and G-B2 chickens showed that significant cytotoxicity occurred only with syngeneic target cells. The degree of cytotoxicity was markedly enhanced by neonatally treating effector cell donors with cyclophosphamide (CY) and delaying virus challenge until the birds were 4 wk old. Augmentation of cytotoxicity was presumed to be due to elimination of bursal-dependent suppressor T cells by CY. The results with spleen cells from REV-inoculated F2 birds clearly showed that cytotoxicity was MHC restricted; i.e., significant lysis only occurred if effector cells and target cells had a common B system antigen. Lysis of RECC-UG5 targets was three to four times higher than lysis of RECC-UG6 targets when effector cells were from heterozygous (B6/B13)F1 and F2 birds. Because these two target cell lines generally showed a similar degree of lysis by effector cells from syngeneic B homozygous birds, the differences obtained with effector cells from B heterozygous birds was most likely due to differences in the number of effector cells with specificity for each target line. Evidence for an additive cytotoxic effect, considered to be due to the lytic activity of two separate T cell clones, was obtained when F1 effector cells were tested with the F1-derived RECC-UG8 targets. The results of other experiments indicated that the effector cells were of T cell lineage and that their activity was probably directed against virus-induced antigens on the transformed target cells.     

Antigen presentation by Toxoplasma gondii-infected cells to CD4+ proliferative T cells and CD8+ cytotoxic cells

Cytotoxic cells specific for Toxoplasma gondii-infected cells were detected in the peripheral blood leukocytes from a patient with acute toxoplasmosis. The cytotoxicity was mediated by CD5+, CD4-, CD8+ cells. The cytotoxic T cells lysed Toxoplasma-infected target cells with HLA class I restriction. Two types of T cell clones were established from peripheral blood leukocytes of a patient with chronic toxoplasmosis; one was a CD5+, CD4-, CD8+ cytotoxic cell specific for Toxoplasma-infected cells, and the other was a CD5+, CD4+, CD8- proliferative cell that responded to Toxoplasma antigen. Toxoplasma-infected cell-specific cytotoxic cloned T cells recognize the infected target cells in the context of the HLA class I molecules, and the CD8 molecule was involved in the cytotoxicity. Toxoplasma antigen-specific proliferative cloned T cells were stimulated by Toxoplasma antigen-pulsed or Toxoplasma-infected cells in conjunction with HLA-DR molecule on the target cells. Thus, antigen presentation by Toxoplasma-infected cells for activation of both cytotoxic and proliferative T cells has been demonstrated.     

CT hybridomas: tumor cells capable of lysing virally infected target cells

By fusing primed murine lymphocytes with a syngeneic T cell lymphoma, we have been able to select for H-2-restricted, virus-specific cytotoxic T cell hybridomas (CTH). These T cell hybrids, which replicate in ordinary tissue culture medium or in ascites, are capable of lysing virally infected target cells, and their activity is facilitated by the presence of lectins in the assay medium. Unlike cells mediating lectin nonspecific lysis, these hybridomas are H-2 restricted and specific for single viral proteins. The ability to maintain these cells in culture for over 18 mo and to pass them in vivo without loss of activity or specificity indicates that they will provide sufficient material for the analysis of surface proteins and genetic information required for the recognition and lysis of virally infected cells by killer T cells.     

Evidence for an involvement of T4+ cytotoxic T cells in tumor immunity

Cell-mediated immunity against cancer cells primarily involves class I major histocompatibility complex (MHC)-restricted cytotoxic T cells and natural killer (NK) cells. To investigate whether T4+ cytotoxic T cells also have a role in tumor-specific immunity, mice were immunized with a B cell lymphoma. T cell hybridomas were constructed from the immune spleen cells and analyzed for their cytotoxic ability against the immunizing lymphoma. A T4+, Lyt-1+ hybridoma cell line was developed (103L2) which specifically killed the immunizing tumor cells but not normal B cells or a range of other tumor cells of B or non-B origin. This cytotoxic hybridoma cell line differed from Lyt-2+ cytotoxic T lymphocyte cells and NK cells, commonly identified with cytotoxicity, in a number of important ways. First, the cells were class II MHC restricted; second, interleukin-2 was released from activated effector cells; and finally but most importantly, innocent nonparticipating bystander cells were also killed. The significance of this observation was that normal cells were protected, although a broad range of tumor cell types, including tumor antigen-negative mutants, were killed. It is therefore conceivable that T4+ cytotoxic T cells might play an important role in tumor immunity through the direct recognition and lysis of tumor cells while any tumor variants, arising due to antigen loss, would remain susceptible through the bystander killing effect and normal cells would remain unaffected. These results strongly suggest that tumor-reactive T4+ cytotoxic T cells belong to a new category of effector cells with an important role in tumor-specific immunity.     

Alloantigen-induced cytotoxicity against syngeneic tumor cells: analysis at the clonal level

It has been shown that peritoneal exudate cells (PEC) from BALB/c mice immunized with minor histocompatibility antigens presented by DBA/2 or B10.D2 spleen cells are capable of lysing syngeneic YC8 tumor cells in a 4-hr 51Cr-release assay. In this study, we employed limiting dilution analysis to determine the frequency of CTL precursors (CTL-P) reactive against both the specific DBA/2 (or P815) target and the syngeneic tumor YC8. The mean frequency of anti-DBA/2 CTL-P in PEC from BALB/c mice immunized with DBA/2 was 1/302. Between one-third and one-fifth of limiting dilution microcultures that exhibited lytic activity against DBA/2 lymphoblasts (or P815) were also able to lyse YC8. No lysis of YC8 was observed in the absence of a parallel lysis on DBA/2 lymphoblasts or P815 target cells. T cell clones, derived by micromanipulation from microcultures selected for cytotoxic activity against YC8 and/or P815, maintained either the specific anti-allogeneic or the doubly reactive ( antiallogeneic plus anti-syngeneic tumor) phenotype. Fourteen clones (six specific and eight doubly reactive) were tested for cytotoxic activity on a panel of target cells with different haplotypes. All showed H-2-restricted specificity for minor histocompatibility antigens shared by DBA/2 and B10.D2. The restriction element for some of the clones mapped in the K region of the H-2 complex, whereas for other clones the restriction element mapped in the D region; both K- and D-restricted clones were able to lyse YC8. When the clones that exhibited lysis on YC8 were tested on two other BALB/c tumor targets, LSTRA, a Moloney virus induced lymphoma, and RL male-1, a radiation induced lymphoma, two of seven were found to lyse all three syngeneic tumor targets equally well, but not syngeneic BALB/c blasts. These clones were functionally categorized as conventional CTL because they were unable to proliferate when cultured with antigen in the absence of exogenous lymphokines, and were unable to produce lymphokine with IL 2 activity when stimulated by the appropriate splenocytes. When tested in vivo in a Winn assay, a strong anti-tumor activity against YC8 was exerted by the anti-DBA/2 clones DY4 -3 and DY16 -3. These clones lysed both YC8 and the immunizing target cells in vitro. No in vivo effect in neutralizing YC8 tumor growth was observed with clone D2-1, a clone that lysed DBA/2 targets but not YC8 in vitro.     

Studies on the specificity of in vitro-induced lymphocytotoxicity to methylcholanthrene-induced fibrosarcoma cell lines

Cytotoxic effector lymphocytes were induced by in vitro immunization of lymph node and spleen cells from CS7B16(H2^b) and Balb/c(H2^d) mice to syngeneic or allogeneic methylcholanthrene-induced fibrosarcoma (MCAF) cell lines. The T cell-dependent cytotoxicity was specific to target cell lines to which the lymphocytes were immunized in vitro. Normal fibroblasts as stimulator cells did not induce lymphocytotoxicity to syngeneic MCAF cells or to normal syngeneic fibroblasts. The results indicate that the in vitro-immunized lymphocytes recognize individual specific tumor-associated antigens of the MCAF cells. In experiments in which the lymphocytes were immunized in vitro to allogeneic MCAF cells, cytotoxic reactions to alloantigens, but not to tumor-associated antigens, were detected. Incubation with phytohemagglutinin (PHA) during the sensitization period modified the specificity of the cell-mediated lysis of MCAF cells: Allogeneic as well as syngeneic target cells were destroyed by these effector cells. PHA induced a nonspecific cytotoxic effect which increased the specific lysis of target cells. The cytotoxicity of the in vitro-immunized lymphocytes was inhibited by incubation with membrane protein preparations from the syngeneic MCAF cell lines. In contrast to the specificity of the cytotoxic effect to the different syngeneic cell lines, the membrane extract of one individual syngeneic MCAF cell line was able to inhibit the lymphocytotoxicity to all other syngeneic cell lines. Membrane protein preparations from allogeneic MCAF cells or from normal syngeneic fibroblasts were not inhibitory. The in vitro-immunized cytotoxic lymphocytes did not impair the tumor growth in vivo as could be demonstrated by passive transfer of the lymphocytes in a Winn assay.     

Differential recognition of tumor-derived and in vitro Epstein-Barr virus-transformed B-cell lines by fetal calf serum-specific T4-positive cytotoxic T-lymphocyte clones

Two interleukin-2 (IL-2)-dependent cytotoxic T-cell clones were obtained by limiting dilution from a lymphocyte culture stimulated in vitro with the autologous Epstein-Barr virus-transformed lymphoblastoid cell line (LCL) in the presence of fetal calf serum (FCS). Both clones uniformly had a T3+, T4+, Dr+ phenotype and lysed autologous B blasts, the autologous LCL, and allogeneic B cell lines sharing major histocompatibility complex (MHC) class II antigens. The cytotoxic function was triggered by FCS-derived components. There was no killing if the sensitive targets were cultured in serum-free medium or in medium supplemented with human serum. Sensitivity to lysis could be restored by exposing the targets to FCS for at least 6 hr at 37 degrees C. Monoclonal antibodies directed to T-cell-specific surface antigens and MHC class II antigens inhibited lysis with different efficiencies depending on the target cell origin. Killing of Burkitt's lymphoma (BL)-derived cell lines was blocked more easily than killing of LCLs. LCLs but not BL lines induced proliferation of the T-cell clones in the absence of exogenous IL-2. The differences were not related to quantitative variations in the expression of MHC class II antigens, indicating that BL lines differ from LCLs in other cell membrane properties that may influence antigen presentation. The results suggest that the affinity of effector/target binding, which is probably influenced by the concentration of antigenic determinants expressed on the target cell membrane, determines whether proliferative responses or cytotoxicity are induced in the antigen-recognizing T cells.     

Processing of exogenous liposome-encapsulated antigens in vivo generates class I MHC-restricted T cell responses.

Acid-sensitive liposomes have been developed for cytosolic delivery of encapsulated substances. We now demonstrate delivery of liposome-encapsulated Ag into the class I MHC Ag processing pathway in peritoneal macrophages in vitro using several types of acid-sensitive liposomes, including those composed of dioleoylphosphatidylethanolamine (DOPE)/palmitoylhomocysteine, DOPE/cholesterol hemisuccinate, DOPE/dioleoylsuccinylglycerol, and DOPE/dipalmitoylsuccinylglycerol. Our previous studies showed that acid-resistant liposomes (dioleoylphosphatidylcholine/dioleoylphosphatidylserine) did not engender class I-mediated presentation in vitro. However, in vivo immunization with OVA encapsulated in acid-resistant as well as acid-sensitive liposomes generated class I MHC-restricted T cell responses, as determined by subsequent in vitro cytotoxicity assays using OVA-transfected target cells. Target lysis by these cells was OVA- and class I MHC (Kb)-specific. This response was not generated by immunization with equivalent amounts of soluble OVA. Thus, a pathway for in vivo class I processing of Ag encapsulated in acid-resistant liposomes has been missed in vitro, perhaps because it is dependent on specific populations of APC or interactions between cells that have not been reconstituted in vitro. This pathway may explain the ability of many exogenous particulate Ag (liposomes, bacteria, parasites, and mammalian cells) to generate class I MHC-restricted T cell responses.