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.     

In vitro sensitization of human lymphoid cells to antigens on cultured melanoma cells: II. Sensitization against melanoma-associated antigens

Peripheral blood lymphoid cells from patients with malignant melanoma can be sensitized on allogeneic or autochthonous melanoma monolayers. Peak cytotoxicity occurred after 5 days of sensitization. Sensitization appeared to be directed against melanoma-associated antigens, as judged by the pattern of cytotoxic reactivity. Sensitized cells were cytotoxic against autochthonous or allogeneic melanoma cells, but not against autochthonous fibroblasts or allogeneic tumor cells of different histologic types. Sensitization of responder lymphoid cells from melanoma patients on allogeneic melanoma cells usually resulted in more pronounced cytotoxicity against autochthonous melanoma target cells than did sensitization on autochthonous melanoma monolayers. These results indicate that cell cultures of human malignant melanoma contain tumor-associated antigens which can sensitize human peripheral blood lymphoid cells in vitro. These results also support the concept that there are cross-reactive tumor-associated antigens in human malignant melanomas.     

Adoptive transfer of cells sensitized in vitro into mice in a skin allograft assay

In these experiments we investigated the ability of adoptively transferred in vitro-sensitized cells to cause an accelerated rejection of skin allografts. The survival of B10.BR or B10.D2 skin grafts on B6AF1 mice was measured. It was determined that 5 × 10⁷in vitro-sensitized cells were required for a consistent accelerated skin allograft rejection. Attempts to optimize sensitization using syngeneic mouse serum were unsuccessful. In vitro-sensitized lymphocytes were specific in their activity toward skin allografts, but were nonspecific in their lysis of tumor targets. Inadvertant transfer of alloantigen with in vitro-sensitized cells was not responsible for accelerated graft rejection. This work demonstrates that cells sensitized in vitro can cause specific accelerated skin allograft rejection in normal mice.     

Functional characteristics of T cell receptors during sensitization against histocompatibility antigens in vitro

Using the mixed leukocyte culture (MLC) reaction as a model system for the generation of cytotoxic effector lymphocytes, we have examined changes which occur in recognition-binding function during T cell sensitization. Properties of recognition-binding units on normal and immune T lymphocytes were assessed through the ability of T cells to bind to specific cellular immunoadsorbants at various stages of in vitro sensitization. While antigen-specific recognition-binding function was readily detected on fully cytotoxic effector cells, we were unable to detect functionally specific binding of unsensitized lymphocytes to cellular immunoadsorbants. The ability of cells undergoing sensitization in MLC to bind specifically to target cell monolayers appeared congruent in time with cytotoxic function. These results suggest that a fundamental membrane-associated change occurring during T cell sensitization may be the development of a strong and specific target-cell binding function.     

Cytotoxicity of allogeneic lymphocytes sensitized against H-2 antigens in vitro

A system is described in which C57/Bl lymphocytes can be sensitized in vitro against H-2 alloantigens of DBA/2 fibroblasts. Cytotoxicity of sensitized lymphocytes was measured by ⁵¹Crrelease from DBA/2 mastocytoma cells which were used as sensitive target cells. During the sensitization period one can observe lymphoid blast transformation and proliferation to start from the third day. Optimal cytotoxic effect of sensitized lymphocytes is reached on the fifth day. C57/Bl lymphocytes sensitized on C₃H fibroblasts were found not to be cytotoxic to DBA/ 2 mastocytoma cells.     

Immunological Potential of the in vitro Mixed Skin Cell-Leukocyte Reaction

THE mixed skin cell-leukocyte reaction (MSLR) is an in vitro reaction between dissociated skin cells and allogeneic peripheral blood leukocytes. It is similar in its immunological implications to the reaction between allogeneic leukocytes, commonly known as the mixed leukocyte reaction (MLR) or the mixed lymphocyte interaction (MLI). In the latter, immunological recognition between lymphocytes from genetically disparate donors can be detected and measured either by blastoid transformation, enhanced mitotic rate or induction of DNA synthesis^1–4. This system has been useful in the study of the transfer of transplantation immunity in vivo by lymphocytes sensitized in vitro⁵ and also in the identification of tissue incompatibility between donor and recipient^{6, 7}. In studies with inbred strains of rats the proliferative phase of the MLR has been shown to possess characteristics required for an immunological response; that is, selectivity and specificity^{8, 9}. Furthermore, mouse peripheral lymphocytes sensitized in mixed culture with allogeneic lymphocytes have been shown to engender immunospecific destruction of target cells¹⁰, an event which is directly associated with allograft rejection.     

Biological characterization of T and B lymphocytes separated from normal mouse spleen by a physical adherence column method

The capacity of spleen cell populations enriched for T and B lymphocytes by a physical adherence column method to respond in vitro to phytomitogens and allogeneic lymphocytes was determined. Column filtrate cells (T lymphocytes) responded well to phytohaemagglutinin- and mitomycin-C-treated allogeneic spleen cells, but poorly to pokeweed mitogen. Adherent cell populations from the column (B and some T lymphocytes) responded well to pokeweed mitogen, but poorly to phytohaemagglutinin- and mitomycin-C-treated allogeneic cells.Purified peripheral T lymphocytes prepared from normal mouse spleen by the column method reconstituted the depleted in vitro antibody response to the thymic-dependent SRBC antigen of all B lymphocyte sources tested, namely, spleen cells from congenitally athymic mice, neonatally thymectomized mice, and adult thymectomized mice which had been reconstituted with bone marrow, and a lymphocyte population prepared by incubating spleen cells with anti-θ serum and complement. When transferred with sheep erythrocytes to congenitally athymic mice, purified peripheral T cells restored the in vivo IgM and IgG responses of these animals. These results confirm that the column filtrate is a thymus derived subpopulation of cells capable of cell-mediated immunity and cooperation with B lymphocytes in humoral immunity both in vitro and in vivo.     

Generation of suppressor lymphocytes during sensitization in culture against a syngeneic tumor: affinity chromatography on insolubilized histamine

We investigated the effect of depletion of histamine-binding lymphoid cells on immunological properties of lymphocytes sensitized in culture against tumor cells. C57BL/6 spleen cells that were sensitized in vitro on monolayers of the syngeneic Lewis lung carcinoma (3LL) became cytotoxic to the tumor cells in vitro after 3 to 5 days of sensitization. Sensitized cells harvested after 4 days of sensitization occasionally enhanced tumor growth in vivo. Fractionation of the sensitized lymphocytes over insolubilized histamine-rabbit serum albumin-Sepharose (HRS) columns decreased or abolished the enhancing activity in vivo and specifically increased the in vitro cytotoxic activity of the depleted lymphocytes. A similar increase in the cytotoxic activity of HRS-fractionated cells was observed in an allogeneic combination of C57BL spleen cells sensitized against C3H fibroblasts. The effect of HRS chromatography on the in vitro cytotoxic activity increased with prolonged incubation of the depleted effector cells with the target cells.     

Transfer of cell-mediated hyperacute rejection reaction: The role of active sensitization

The transfer of lymph node cells draining graft sites of allogeneic murine skin results in adoptive immunization of syngeneic recipients, as per hyperacute rejection of allogeneic test skin grafts. The transfer of spleen cells from mice sensitized by i.p. injection of allogeneic cells does not have this result unless the cells undergo a secondary in vitro sensitization. The resultant hyperacute rejection is due in part to adoptive immunization via the spleen cells primed during the in vivo sensitization and rendered transfer effective by the in vitro exposure; in part it is due to active sensitization by carried-over antigen from the in vitro exposure. It follows that the transfer effect of spleen cells sensitized in vivo and in vitro is only in part abrogated by exposure to α-Thy. 1 serum and complement.     

Recruitment of effector lymphocytes by initiator lymphocytes. Recruited lymphocytes are immunospecific and include graft-versus-host-reactive lymphocytes.

We have shown previously that initiator T lymphocytes (ITL), sensitized in vitro against fibroblast antigens, recruit effector T cells in vivo. After injection into hind footpads of syngeneic recipients, sensitized ITL migrated to the draining popliteal lymph nodes (PLN) and activated a trapping mechanism by which circulating lymphocytes were recruited in the PLN. This paper reports experiments designed to test the immunospecificity of these recruited T lymphocytes (RTL). We found that immunospecific RTL were depleted from other lymphoid organs during recruitment in the PLN. However, immunospecific ITL were not depleted from spleens during PLN recruitment. Thus ITL and RTL are functionally distinguishable. We show that specific GVH reactive lymphocytes were also lost from spleens and distal lymph nodes during trapping of RTL in the PLN. Thus, the trapping phase of the recruitment response is immunospecific, as are the sensitization and effector phases. The trapped RTL are antigen-specific, and include the pool of GVH-reactive-lymphocytes committed to the same alloantigen. Thus, it appears that GVH-reactive cells respond to syngeneic ITL sensitized against allogeneic fibroblasts.     

Differential cytotoxicity of activated lymphocytes on allogeneic and xenogeneic target cells. I. Activation by tuberculin and by Staphylococcus filtrate

Normal lymphocytes activated by mitogens such as phytohemagglutinin (PHA), by Staphylococcus filtrate (SF), or lymphocytes from sensitized individuals stimulated by antigen (PPD, etc.) are cytotoxic to tissue culture cells of different origins. In this and the following paper, the results of a detailed quantitative analysis of the specificity of this cytotoxic reaction are presented. Effector cells were human or mouse lymphocytes, activated by PHA, SF, PPD, or serum factors in the culture medium. Cells from established cell lines of human, mouse, hamster, or rabbit origin, or primary human or rat embryonic fibroblasts were used as target cells. Lysis was quantitated by release of ⁵¹Cr from labeled target cells.Purified human blood lymphocytes, activated by PPD, SF, or otherwise, preferentially damaged allogeneic target cells. Lysis of xenogeneic target cells was weak or did not occur. A close correlation was noted between target cell destruction and blastoid transformation of the lymphocytes, but the slope of the regression lines of xenogeneic cytotoxicity was much smaller than that of allogeneic cytotoxicity when plotted as a function of blastoid transformation.Lymph node or spleen cells from CBA mice were stimulated by PPD to transformation and DNA synthesis. CBA lymphocytes also showed an increased degree of blast transformation in medium containing fetal calf serum or certain batches of fresh human serum. Mouse lymphocytes activated in these ways damaged allogeneic L cells but had no effects on xenogeneic Chang cells.These results indicate that lymphocytes activated by various means preferentially damage target cells from their own species. The recognition mechanisms which determine the specificity of the reactions are not known.     

The effect of hydrocortisone on lymphocyte-mediated cytolysis

This paper reports the results of experiments designed to analyze the mechanism by which hydrocortisone suppresses the cell-mediated cytolysis produced by sensitized lymphocytes. We used an in vitro system in which rat lymph node cells were sensitized to, and caused cytolysis of mouse fibroblasts.We found that hydrocortisone probably suppresses cytolysis by preventing the primary activation of the cytolytic mechanism by target cell antigens. Suppression was most efficient when hydrocortisone was added at the beginning of the cytolytic reaction. The cytolytic mechanism itself appeared to remain intact, and could be activated by the lectin concanavalin A (con A) despite the presence of hydrocortisone.Suppression of cytolysis could not be related to any general inhibition of DNA, RNA, or protein synthesis. The influence of hydrocortisone on cytolysis was not modified by vitamin A (retinol), an agent which antagonizes the effect of hydrocortisone on lysosome membranes.Hydrocortisone was found to be less effective in suppressing the activity of lymphocytes that had been sensitized initially in the presence of hydrocortisone.     

Cellular immunity in the mouse. I. In vitro lymphocyte reactivity

The mixed lymphocyte culture (MLC) and antigen-mediated proliferative response represent important correlates to the in vivo phenomena of allograft rejection and delayed hypersensitivity. This study defines an in vitro model to measure mouse lymphocyte responsiveness to allogeneic cells, antigen (tuberculoprotein), and nonspecific mitogens. Results describe optimal cells concentration, time and conditions of culture. Optimal conditions include the use of high cell concentration, flat-bottomed vials, RPMI-1640 medium, and fresh human serum. Peripheral blood lymphocytes demonstrated greater proliferation than lymph node lymphocytes, which in turn demonstrated greater activity than splenic lymphocytes. Significant proliferation occurred in serum-free media, dialyzed against fresh serum and supplemented with hydrocortisone and carrier protein. The MLC response in the mouse appears dependent on multiple subpopulations of cells and on soluble substances produced by them.     

The induction of cellular immunity with soluble murine histocompatibility antigens

Soluble transplantation antigens have been prepared from various lymphoid organs of the mouse strains A and C57BL. These preparations have been partially characterized by gel filtration on Sephadex G-200 and G-100. The distribution of various antigenic activities, such as precipitation with rabbit antisera, inhibition of the cytotoxic reactions of heterologous antisera and of alloantibodies, differed considerably among the chromatographic fractions. The soluble antigen preparations retained their antigenic and immunogenic properties, as demonstrated by their ability to block the cytotoxic reactions of alloantisera and to modify tumor growth in immunized recipients. Immunization of normal recipients with the immunogenic transplantation antigen preparations led to the production of sensitized lymphocytes, capable of destroying allogeneic target cells in vitro. Sensitized lymphocytes appeared in the regional lymph nodes after a single injection of 200–300 μg of the antigen preparation, reaching a peak level between 9 and 12 days. On reimmunization, the cytolytic activity of lymph node cells increased considerably and sensitized lymphocytes also appeared in the spleens of immunized animals.     

Correlation between Production of Inflammatory Substances and Generation of Effector T Cells Mediating Delayed-Type Hypersensitivity in Mice

In vitro exposure to human serum albumin (HSA) of splenic lymphocytes from mice sensitized for delayed-type hypersensitivity (DTH) against HSA resulted in the release of substances that could induce a footpad inflammatory reaction with a maximum 6 hr after injection into normal mice. The substances were fractionated mainly in a molecular weight range of 30,000 to 70,000 daltons on Sephadex G-200. The ability of sensitized lymphocytes to produce the substances was dependent on T cells, was antigen specific, and correlated well with the ability of the lymphocytes to mediate DTH reactions. Moreover, the substances were produced efficiently by the DTH effector cell population generated in the in vitro culture system and also by the effector cell-enriched fractions on discontinuous bovine serum albumin gradients. These results suggest that the substances are produced by DTH-effector cells.     

The human LT system. V. A comparison of the relative lytic effectiveness of various MW human LT classes on 51Cr-labeled allogeneic target cells in vitro: enhanced lysis by LT complexes associated with Ig-like receptor(s).

The present studies examine the in vitro cell-lytic capacity of various molecular weight (MW) human lymphotoxin (LT) classes obtained from lectin-activated normal or immune lymphocytes on allogeneic target cells. The findings reveal that the high-MW complex class of LT is up to 100 times more effective than the smaller MW LT forms (α, β, and γ) in causing lysis of various allogeneic cell types including lymphoid cells in vitro. Moreover, the data suggest that lectin-stimulated alloimmune cells (MLC sensitized) release complex LT forms in association with a specific antigen-binding receptor(s), and that these complexes are from 3 to 10 times more effective on the sensitizing target cell than complexes obtained from lectin-stimulated nonimmune cells. Positive evidence that complex-induced lysis involved LT was indicated by the finding that lysis was completely neutralized by incubation with heterologous antisera directed against a refined human α₂-LT subclass (anti-α₂) and partially neutralized with anti-human Fab₂′ serum. These findings support the concept that LT molecules may represent a system of related cell-lytic molecules. While the smaller MW forms are only weakly lytic by themselves, they can be assembled into highly lytic complexes which may be focused or directed by an antigen-binding receptor(s).     

Cytotoxicity of autosensitized lymphocytes restricted to the H-2K end of targets

Lymphocytes from rodents cultured on syngeneic fibroblasts become cytotoxic against syngeneic but not against allogeneic target cells. We investigated whether known antigens are involved in the phenomenon and the data indicate that H-2 antigens must be shared between sensitizing fibroblasts and responder lymphocytes to generate autocytotoxic cells. Furthermore, the cytotoxicity of autosensitized lymphocytes is restricted to target cells identical with respect to theK and/orI regions. F₁ hybrid lymphocytes cultured on parental fibroblasts develop cytotoxicity towards sensitizing cells. In contrast, parental lymphocytes cultured on F₁ hybrid fibroblasts will not damage the F₁ cells, although they are cytotoxic against both syngeneic and allogeneic parental cells. In addition, parental or F₁ hybrid lymphocytes cultured on parental fibroblasts are not cytotoxic against F₁ hybrid target cells. Fibroblasts heterozygous for theK end only, are also resistant to the cytotoxic action of such lymphocytes. Thus it seems that H-2 antigens, specifically theK end, antigens have a significant role in the phenomenon of autosensitization.     

Reversible Inhibition of Lymphocyte-mediated Cytotoxicity by Cytochalasin B

ALLOGRAFT immunity is characterized by the appearance of sensitized lymphocytes which are specifically able in vitro to destroy target cells carrying the sensitizing alloantigens. These cytotoxic lymphocytes represent thymus-derived effector cells^1,2 and are quite distinct from alloantibody-producing cells, which are also formed during induction of allograft immunity³. Although contact between viable cytotoxic lymphocytes and target cells is necessary for destruction, the events which lead to target cell lysis are still unknown⁵.     

Thymus-dependent and thymus-independent effector functions of mouse lymphoid cells. Comparison of cytotoxicity and primary antibody formation in vitro

We have compared two effector functions, antibody formation and cytotoxic capacity in vitro, of mouse cells of various origin with special reference to the T lymphocyte dependence of these processes. We have used addition of PHA and coating of target chicken erythrocytes (CRBC) with antibody as the two means of inducing cytotoxicity. Antibody formation in vitro has been studied both against thymus-dependent sheep erythrocytes (SRBC) and thymus-independent (E. coli) antigens. Spleen cells from thymectomized, lethally irradiated bone marrow-, or fetal liver-repopulated mice were deprived of phagocytic cells by uptake of colloidal iron. They did perform better than normal spleen cells in the antibody-induced cytotoxicity and were also induced to cytotoxicity by PHA. PHA did not induce increased DNA synthesis in these T cell-deprived spleen cell preparations, which could not make primary antibodies to SRBC but were able to do so against E. coli antigens. Fresh bone marrow and fetal liver cells, deprived of phagocytic cells, were also induced into a highly efficient cytotoxicity by anti-CRBC as well as by PHA. Pretreatment of spleen cells with an alloantiserum (θ) against T lymphocytes reduced but did not abolish the PHA-induced cytotoxicity. In contrast, it did not affect the antibody-induced cytotoxicity. Such treated cells could not make antibodies to SRBC but could do so against E. coli. Pretreatment of spleen cells with a heteroantiserum (MBLA) against mouse B lymphocytes completely abolished all cytotoxic- and antibody-forming abilities of the cells, although experiments with combinations of θ-treated and MBLA-treated cells suggested that the MBLA treatment had left behind a significant portion of helper T cells needed for the in vitro antibody response. From these data we conclude, as have others, that the antibody-induced cytotoxicity is independent of T lymphocytes. It can be induced in immature precursor cells from fetal liver or bone marrow, and these cells may also become cytotoxic on interaction with PHA. However, in normal spleen cells, at least part of the PHA-induced cytotoxicity is T cell dependent. Some preliminary data suggest that this PHA-induced cytotoxicity of normal spleen cells may be a joint process between T lymphocytes and other cells.     

Induction of an antibody response in vitro against synthetic antigens in guinea pigs. I. Culture and assay conditions

Guinea pig spleen and lymph node cells were found to produce anti-2,4-dinitrophenyl (Dnp) oligolysine PFC in vivo against 2,4-dinitrophenyl-β-alanyl glycyl glycyl (Dagg-SRBC) but not against trinitrophenyl-SRBC target indicator cells. Furthermore, when sensitized spleen cells or their purified B-cell fractions were cocultured with primed peritoneal exudate lymphocytes (PEL) but not splenic T cells they were able to generate a secondary PFC response in vitro to the synthetic antigens, Dnp oligolysines. PFC were not induced in vitro if these same cultures were pulsed with short-chain peptides (five lysines) or the complex antigen, dinitrophenyl-bovine γ-globulin (DnpBGG). Con A was able to substitute for PEL in triggering spleen cells to mount a secondary in vitro PFC response to homologous Dnp oligolysines. More importantly, the Con A-aided spleen cell cultures were not induced above background values when challenged in vitro with heterologous Dnp oligolysines. This study suggests that spleen cells may lack a nonspecific signal for the development of a secondary in vitro PFC response.