Correlation of cytotoxicity with experimental allergic encephalomyelitis.

Cytotoxicity of immune lymph node cells in experimental allergic encephalomyelitis (EAE) was maximal 9 days after injection of encephalitogenic emulsion. The ability of these cells to passively transfer EAE was also maximal at this time. Immune spleen cells were more cytotoxic than lymph node cells 9 days after injection; however, these cells did not passively transfer EAE. Twelve days after injection of encephalitogenic emulsion immune spleen cells passively transferred EAE with resulting mild histopathologic lesions. At this time the spleen cells were 50% more cytotoxic than comparable lymph node cells. Cyclophosphamide suppressed the development of clinical EAE and the development of cytotoxic lymphoid cells. It also reduced clinical signs and cytotoxic activity of lymph node cells. Spleen cell cytotoxic activity was enhanced by Cyclophosphamide. It was concluded that cytotoxic activity of lymph node and spleen cells was correlated with the ability of these cells to produce EAE. Lymph node cell populations differed qualitatively and/or quantitatively from immune spleen cell populations in EAE. Capacity to passively transfer EAE coincided with the maximal Cytotoxicity of the lymphoid cells from each tissue.     

Murine T-cell hybridomas that produce lymphokine with macrophage-activating factor activity as a constitutive product

Responder spleen cells primed to alloantigens in vivo could generate high degree of cytotoxicity against low- or nonimmunogenic stimulators such as thymocytes or uv light-treated spleen cells in vitro. However, a removal of adherent cells from primed responder cells remarkably reduced the cytotoxicity after stimulation with such low-immunogenic stimulators. Adding a small number of peritoneal adherent cells (PACs) also suppressed the cytotoxic activity of unseparated responders against low-immunogenic stimulators. These suppressive effects by PACs were blocked by indomethacin. By adding prostaglandin E₂, cytotoxic T lymphocyte (CTL) generation of primed unseparated responders against low-immunogenic stimulators was suppressed; however, cytotoxic activity against mitomycin C-treated stimulators was not suppressed. These results suggested that prostaglandins released from PACs selectively inhibited the function of splenic adherent cells that were required for CTL generation of primed responder spleen cells against low-immunogenic stimulators in vitro.     

Analysis of changes in natural cytostatic and cytotoxic activity of mouse spleen cells after treatment with cyclophosphamide and alpha-interferon

Cytostatic and cytotoxic activity of mouse spleen cells against normal and tumour target cells has been studied. The comparative analysis of mouse spleen cell cytostatic and cytotoxic activity after exposure to cyclophosphamide has shown that the effectors of natural cytotoxic activity are highly sensitive to cyclophosphamide, while cytostatic effectors are heterogeneous in their sensitivity to cyclophosphamide. Pretreatment of spleen cells with alpha-interferon produced an increase in cytotoxic and cytostatic activity against tumour target cells. The cells of lymphoid organs (spleen, bone marrow, thymus) had greater distinctions in cytotoxic than in cytostatic activity against tumour target cells.     

Stimulatory cells in the generation of T-cell-mediated cytotoxicity: Potent stimulating activity of a small radioresistant spleen cell population (RSCs)

The combined effects of irradiation followed by cultivation on a total spleen cell population in order to study the evolution of the stimulating potential in the in vitro generation of allogeneic cytotoxic T lymphocytes (CTLs) were tested. Results revealed that, after 3 days and up to at least 7 days of cultivating irradiated (1000 rad) spleen cells, the remaining living cells (radioresistant spleen cells or RSC) have the same potential to generate CTLs as irradiated noncultivated spleen cells. RSC can resist a 5000-rad irradiation and induce a primary cytotoxic response pattern similar to that of total spleen cells; they act in primary as well as in secondary cultures with optimal responder to RSC ratios of about 100, but are still stimulatory at MLC ratios up to 1000 or 5000. They are lysed by specific allogeneic CTLs and readily inhibit the specific lysis of H-2-identical labeled targets by CTLs. RSCs do not express unusual levels of H-2 or Ia antigens and do stimulate purified T cells. Alloantisera anti-H-2 are able to completely block the RSC-induced generation of CTL. This RSC population may prove to be a good model to study non-H-2- or H-2-associated, nonserologically detectable determinants interacting in the generation of T-cell-mediated cytotoxicity.     

The effects of a macrophage-derived cytotoxin on the growth and metabolism of target cells.

Peritoneal macrophages obtained from Sarcoma I (SaI)-immune CS7BL/6 mice release a heat-labile cytotoxin, specific macrophage cytotoxin (SMC), following a two hour interaction with appropriate target cells. Specific macrophage cytotoxin specifically inhibits A/Jax spleen cells from mitogenically responding to concanavalin A, whereas syngeneic CS7BL/6 spleen cells are unaffected. Treatment of target cells with SMC results in early alterations in RNA and DNA metabolism. The uptake and incorporation of ³H-uridine was found to be initially elevated while intracellular levels of ³H-thymidine became markedly reduced. Furthermore, the cytotoxic action of SMC was found to be rapidly accelerated and amplified by low levels of actinomycin-D.     

A history of theories of acquired immunity

Alloimmune mouse spleen cells are capable of carrying out nonspecific cell-mediated cytolysis of syngeneic target cells when incubated in the presence of lectins such as Con A or PHA (lectin-dependent cell-mediated cytotoxicity). In the present study plant lectins from a variety of sources were examined for their ability to participate in alloimmune-LDCC. Reactivity was then compared to mitogenic activity and the ability to activate cytotoxic effector cells in vitro. Of the lectins tested only those reported to be T-cell mitogens were capable of participating in alloimmune-LDCC. Agglutinating but nonmitogenic lectins (e.g., WGA) or mitogens such as LPS or PWM failed to yield positive LDCC. Of the T-cell mitogens demonstrating positive reactivity in the alloimmune-LDCC assay, only a portion were able to generate cytolytic activity when incubated with normal spleen cells in vitro (Con A, GPA, lentil). Crude PHA, purified erythroagglutinin, or leukagglutinin failed to generate cytotoxic effector cells in this system even though these were mitogenic and demonstrated positive alloimmune-LDCC. The results suggest that T-cell mitogens interact with cytotoxic effector cells in a manner which specifically triggers cytolysis. The relationship of this interaction to other lymphocyte-lectin interactions is discussed.     

Potentiation of the in vitro cytotoxic response to syngeneic lymphoma cells by soluble products of tuberculin-sensitive lymphoid cells stimulated with PPD

Spleen cells from rats immunized with the syngeneic (C58NT)D Gross virus induced lymphoma have previously been shown to differentiate into cytotoxic effector cells following restimulation with tumor cells in vitro. Previous work has also demonstrated that the addition of PPD-primed syngeneic spleen cells and PPD to cultures of (C58NT)D-primed spleen cells will potentiate the in vitro cytotoxic response to tumor antigens. In the studies presented here, the potentiating effect was found to be mediated by a soluble factor(s) released by nonadherent cells from BCG-primed rats. The release of this immunopotentiating factor(IPF) required the presence of PPD and varied with the concentration of PPD added. IPF was produced by BCG-primed spleen, lymph node, and thymus cells. Maximal production of IPF in PPD-stimulated cultures was obtained after 6–12 hr of incubation. Supernatants obtained after 30 hr of incubation lacked apparent IPF activity when tested initially, but activity was recovered after mild heat treatment. Recovery of IPF activity after heat exposure is best explained by the presence of a heat-labile inhibitor. IPF itself is stable to heat treatment to 56 °C for 40 min. IPF was also shown to be capable of enhancing immune responses to histocompatibility antigens in vitro.     

The role of HLA-DR determinants in monocyte-macrophage presentation of herpes simplex virus antigen to human T cells

Spleen cell killing of target cells can manifest through spleen cell-target cell interaction in the presence of mitogenic lectin, lectin-dependent cell-mediated cytotoxicity (LDCC). Spleen cells from C57B1/6 mice immunized with C3H mouse cells were found to be capable of cytotoxicity against autologous and other C57B1/6 spleen cells in the presence of Con A. Thus, alloimmune spleen cells are capable of an anti-self cytotoxic response in the presence of mitogenic lectin, antiautologous LDCC. Antiautologous LDCC is blocked by preincubation of cytotoxic cells with colchicine, an inhibitor of the cytotoxic effector mechanism. Analysis of alloimmune spleen cell subpopulations suggests that the antiautologous LDCC cell is an immature alloimmune cytotoxic cell (prekiller cell). Potent LDCC was found in alloimmune spleen cell preparations depleted of alloimmune cytotoxic T cells (killer-depleted) by three passes on allogeneic cell monolayers genetically identical with the immunizing cell. However, some LDCC effectors were also found to adhere to the adsorbing target, suggesting that there is some maturational diversity among LDCC effectors.     

Detection of nonspecific cytotoxicity in graft-versus-host reaction as a function of target cell type

The cytotoxic activity of spleen cells from mice undergoing graft-versus-host (GVH) reaction on ⁵¹Cr-labeled target cells was studied under in vitro conditions. Among normal tissues used as target cells, skin fibroblasts proved to be most sensitive to the nonspecific cytotoxic effects of spleen cells from mice undergoing GVH reaction, whereas kidney cells or macrophages were insensitive to these nonspecific cytotoxic effects. Of the two murine neoplastic target cells used, Sarcoma 1 cells were susceptible to these nonspecific cytotoxic effects whereas mastocyoma cells were resistant. However, the target cells which were insensitive to the nonspecific cytolytic effects, were lysed specifically by the spleen cells from animals specifically sensitized. Therefore, both specific and nonspecific cytotoxic effects of spleen cells from mice undergoing GVH reaction could be detected with appropriate targets. These results provide a basis for reconciliation of several apparently contradictory results, reported in the literature, concerning the specificity of the cytotoxic effects of specifically sensitized lymphocytes.     

Suppressor factor from tumor-allosensitized spleen cells--its effect on in vitro proliferation of tumor cells and in vivo skin allograft survival

C57BL/6 mice are sensitized ip with allogeneic P-815 mastocytoma cells. Fifteen days later the spleen cells of the sensitized mice are used in the production of suppressor factor or treated with mitomycin and used as suppressor cells. Sensitized spleen cells incubated with the specific alloantigen (DBA/2 m-treated spleen cells) release suppressor factor (SF)² which inhibits cell proliferation in mixed lymphocyte culture (MLC) as well as the in vitro generation of cytotoxic cells (CML). SF is most effective when added eary during MLC. SF also inhibits mitogen responsiveness of normal spleen cells. In addition to inhibiting lymphocyte function in vitro, suppressor cells as well as SF inhibit the in vitro proliferation of tumor cells. This inhibition is specific for the tumor to which the suppressor cells are induced. The inhibition of tumor cell proliferation is not due to the presence of cytotoxic cells in the spleen of the tumor-allosensitized mice. Suppressor cells from neonatal mice do not inhibit the in vitro proliferation of tumor cells. SF injected iv into C57BL/6 mice decreases the mixed lymphocyte reactivity of the host spleen cells and decreases the ability of the host to reject skin allografts. We interpret these data to suggest that tumor-allosensitized spleen cells, and the SF they produce, not only affect lymphocyte function but also inhibit tumor cell proliferation. This dual effect of suppressor cells could be an important part of the immune surveillance against tumors.     

Generation of nonspecific murine cytotoxic T cells in vitro by purified human interleukin 2

Murine spleen cells developed into nonspecific cytotoxic cells within 72 hr of culture in the presence of highly purified sources of human interleukin 2. In whole spleen cell cultures, human interleukin 2 generated effector cells which were Thy 1.2⁺, Lyt 2.2⁺, resistant to γ irradiation (1000 R), and capable of lysing both H-2 compatible and incompatible targets. The effector cells generated in this manner were not restricted to classical natural killer cell-sensitive targets. If thymus-derived cells (T cells) were depleted from the spleen cell population before culture with human interleukin 2, the effector cells generated were enriched in effectors capable of lysing natural killer cell-sensitive targets. Interferon was not produced in interleukin 2-stimulated spleen cell cultures. In addition, heterologous antibody to murine -γ-interferon did not abrogate the generation of cytotoxic cells by human interleukin 2. These and additional data suggest that human interleukin 2 is capable of stimulating γ-irradiation-sensitive Thy 1.2⁺ cell(s) capable of lysing a variety of target cells regardless of inherent sensitivities to classical natural killer cells. Thy 1.2^? cells were also stimulated by human interleukin 2 and lysed only natural killer cell-sensitive targets. Human interleukin 2 caused some Thy 1.2^? cells to become susceptible to lysis by anti-Thy 1.2 serum and complement.     

Inhibition of rat mixed lymphocyte cultures by suppressor macrophages.

Normal rat spleens contain suppressor cells which can inhibit proliferative and cytotoxic responses of lymphocytes to alloantigens in vitro. The suppressor cells are adherent, phagocytic, resistant to treatment with ATS and C, radioresistant, resistant to treatment with mitomycin C, apparently absent from the thymus, and found in very high concentrations in peritoneal exudates. These characteristics indicate that the suppressor cell is a macrophages and not a T cell. When suppressor cells were removed from spleen cell suspensions, strong in vitro proliferative and cytotoxic responses to alloantigens could consistently be observed.     

Regulation of the In Vitro Secondary Cell-Mediated Cytotoxic Response against Syngeneic FBL-3 Leukemia by Macrophages

Depletion of macrophages from immune spleen cells by treatment with carbonyl iron and magnet or by in vivo treatment with carrageenan enhanced the in vitro secondary cell-mediated cytotoxic response against a syngeneic Friend virus-induced leukemia, FBL-3 cells of C57BL/6 mice. However, further depletion of macrophages by passing the carbonyl iron-treated immune spleen cells through a nylon wool column abrogated the cytotoxic response. The addition of splenic macrophage-enriched preparations from either FBL-3-immune or normal mice suppressed the cytotoxic response of immune spleen cells treated with carbonyl iron and magnet. This suppressive effect of splenic macrophages presented a marked contrast with the enhancing effect of normal peritoneal macrophages on the same cell-mediated cytotoxic response, indicating regulation of the generation of killer T cells against a syngeneic tumor by functionally distinct macrophages. The suppressed cell-mediated cytotoxic response against FBL-3 cells by immune spleen cells was augmented by the addition of indomethacin to the culture medium, and this augmentation with indomethacin was greatly decreased by depletion of phagocytic cells from the immune spleen by treatment with carbonyl iron and magnet. The mechanisms of regulation of the cell-mediated cytotoxic response with soluble factors released from macrophages are discussed.     

Phorbol myristic acetate enhances the production of Interleukin 2

Interleukin 2 is an antigen-nonspecific factor produced by Concanavalin A (Con A)-activated mouse spleen cells that has a number of biologic activities including the capacity to stimulate thymocyte proliferation, support the growth of continuous T cell lines, augment the antibody response of nude mouse spleen cells, and support the generation of antigen-specific cytotoxic T cells. In order to obtain increased amounts of Interleukin 2 for further purification and biologic studies, we have examined the use of Phorbol Myristic Acetate (PMA) as a costimulant. In this report we demonstrate that the addition of PMA to Con A-induced mouse spleen cell cultures results in a 5- to 20-fold increase in the production of Interleukin 2 activity under serum-containing and serum-free culture conditions.     

Alteration of allospecific t-cell receptors after differentiation from prethymic precursor cells in semiallogeneic environments

Murine bone marrow cells (strain A) have been allowed to differentiate in vivo in syngeneic (A) or semiallogeneic hosts (A × B) to produce mature splenic T lymphocytes. After stimulation of these cells with irradiated allogeneic (C) spleen cells in tissue cultures, the cytotoxic T-cell blasts (CTL) were purified by velocity sedimentation and used to immunize (A × C) F₁ hybrid mice, to produce antisera recognizing the receptor structure (for C) on the relevant A cytotoxic cells (and their precursors). Using these sera we have been able to show that the T-cell receptor for alloantigen C on strain A cytotoxic precursor lymphocytes (CTLp) seems to differ according to the host environment in which those T cells differentiate from immature bone marrow precursors.     

Antibody-dependent cytotoxicity of human and mouse mononuclear cells against Trypanosoma cruzi epimastigotes

Human peripheral mononuclear cells were cytotoxic to antibody-sensitized Trypanosoma cruzi epimastigotes. The cytotoxic effect depended on the concentration of effector cells and antiserum, and was progressive until 17 hr of incubation at 28 °C. After 3 hr of incubation the highest specific activity was achieved at a 50:1 effector to target cell ratio. A nonspecific cytotoxic effect in the absence of antiserum was observed at a 100:1 parasite to cell ratio or after 17 hr of incubation. When the human mononuclear cell population was depleted of adherent cells by Sephadex G-10 filtration or adsorption to glass, the cytotoxic effect was greatly reduced. Similar results were obtained using mouse spleen cells, indicating that only the adherent cells were cytotoxic to sensitized T. cruzi in both systems. When human mononuclear cells were incubated with amobarbital, cyanide, azide, or aminotriazole, an inhibition of cytotoxicity against sensitized T. cruzi was observed, suggesting that oxygen reduction products and myeloperoxidase were involved in the destruction of sensitized T. cruzi epimastigotes by normal human mononuclear cells.     

Intracellular localization of anti-tumor immune RNA.

Syngeneic spleen cells from normal, non-immune Fischer 344/N rats and allogeneic spleen cells from normal Wistar-Furth rats became cytotoxic, in vitro, to chemically induced Fischer rat sarcoma (MC3-R) target cells following incubation with xenogeneic Immune RNA (I-RNA) extracted from spleens of guinea pigs immunized with MC3-R tumor cells. I-RNA extracted from intact spleen cells or from the cytoplasmic fraction of spleen cells were equally active. RNA extracted from isolated spleen cell nuclei was inactive, as were all RNA fractions from spleen cells of nonspecifically immunized guinea pigs. Syngeneic I-RNA extracted from intact spleen cells or the cytoplasmic fraction of cells from spleens of Fischer rats bearing growing MC3-R transplants mediated cytotoxic reactions against MC3-R target cells when incubated with normal Fischer rat spleen cells. RNA from the nuclei of spleen cells of rats bearing MC3-R tumors was considerably less active. All RNA fractions from spleen cells of normal non-immune Fischer rats were inactive. The immunologically active component of xenogeneic and Syngeneic I-RNA, therefore, were found to be localized in the cytoplasm of specifically sensitized lymphoid cells.     

Asialo-GM1-positive T killer cells are generated in F1 mice injected with parental spleen cells

(C57BL/6 x DBA/2)F1 mice transplanted with parental C57BL/6 spleen cells become splenic chimeras, show donor antihost cytotoxic T cell activity, and lose their T cell-mediated, humoral, and natural immunity. Injection of anti-asialo-GM1 (ASGM1) into transplanted mice strongly suppresses splenic cytotoxic activity and causes a significant reduction of spleen cells expressing ASGM1, Thy-1, and Lyt-2. In vitro treatment of spleen cells from transplanted mice with antibody and complement shows that the cytotoxic effector cells are ASGM1+, Thy-1+, Lyt-2+, L3T4-, NK1.1-, and H-2d-, hence of donor origin. The cytotoxic effector cells are specific for H-2d targets and lack NK activity. In an attempt to explore whether in vivo elimination of the cytotoxic effector cells has any influence on splenic chimerism or humoral immunity, F1 mice injected with parental splenocytes were treated with anti-ASGM 1. Results show that this treatment eliminates a substantial proportion of cytotoxic effector cells but has no effect on splenic chimerism or restoration of humoral immunity. It therefore appears that cytotoxic effector cells are not primarily responsible for induction of chimerism or suppression of humoral immunity. In support of this injection of parental spleen cells with the nu/nu mutation induces killer cells in F1 mice but fails to induce splenic chimerism or immunosuppression. In contrast, injection of parental spleen cells with the bg/bg mutation generates both splenic chimerism and suppression of humoral immunity although their ability to generate cytotoxic effector cells in F1 hosts is seriously impaired and comparable to the cytotoxic potential of C57BL/6 nu/nu cells. It is concluded that the ASGM1 + cytotoxic T cells are not primarily responsible for splenic chimerism and suppression of humoral immunity and that the two effects are likely caused by parental cells with a different phenotype and function.     

Capacity of different cell types to prime in vivo for secondary in vitro cytotoxic T-cell responses against non-major-histocompatibility antigens

The capacity of several types of cell preparations to induce in vivo a state of memory for a secondary in vitro cytotoxic response against non-major-histocompatibility antigen was markedly reduced (on a per cell basis) by uv-irradiation. This indicated that memory induction requires metabolically active stimulator cells. An “adherent cell preparation” (AC) that was enriched for dendritic cells was among the most effective memory-inducing cell populations; but concanavalin A-activated nylon-wool-nonadherent spleen cells (Con A-NWT) or concanavalin A-activated unfractionated spleen cells (Con A-spl) were on the average equally effective. Normal unfractionated spleen cells (spl) or nonactivated nylon-wool-nonadherent cells (NWT) were markedly less effective on a per cell basis. This pattern of stimulatory activity was in line with the relative stimulatory activity of these cell types in primary cytotoxic responses in the presence of interleukin 2 (IL-2) and also in line with the relative capacity to induce IL-2-dependent proliferation in H-2D-incompatible T-cell populations (cf. W. Dröge et al., J. Immunol.132, 2749, 1984). These differences in the immunogenic potential and the requirement for metabolically active stimulator cells suggested that these cells stimulated the CTL system directly and not indirectly through antigen processing cells of the immunized host. Nevertheless, the secondary cytotoxic response after injection of low numbers of Con A-spl into H-2 heterozygous recipients, (BALB/c × BALB/b)F1, or into recipients with recombinant H-2 haplotype (A.J) was only preferentially but not exclusively restricted to the H-2 haplotype of the immunizing cell populations. Restriction was considerably more complete when AC were used for immunization.     

In situ effector pathways of allograft destruction. 1. Generation of the "cellular" effector response in the graft and the graft recipient

Inflammatory leukocytes of DA-to-WF rat renal allografts displayed significant cytolytic activity to natural killer (NK) target cells on Day 2 after transplantation. The NK activity, which was associated with large granular lymphocytes in discontinuous Percoll gradients, peaked on Day 4 and disappeared rapidly thereafter. Coincident with the presence of NK activity in the graft, a decrease in NK activity in the recipient spleen was observed. Low NK activity was also recorded in WF-to-WF autografts. The cells displaying direct cytotoxic activity to donor (but not to recipient) strain peritoneal exudate target cells (PEC) were associated with the T suppressor/killer lymphocytes in affinity chromatography. They appeared in the graft between Days 2 and 4, peaked between Days 6 and 8 and disappeared slowly thereafter. In the spleen the cytotoxic T lymphocyte (CTL) activity appeared later and it reached a maximum between Days 16 and 20 before decreasing. In the blood distinct CTL activity was seen only from Days 16-20 onwards, after the graft had been rejected. No CTL activity was recorded in the graft, blood, or spleen of an autograft recipient. Addition of donor-directed post-transplantation antibody (antibody-dependent cellular cytotoxicity, ADCC) had a slight enhancing effect on the cytotoxic activity of inflammatory leukocytes up to Day 5. After this time, added antibody had a blocking effect on direct CTL activity. No ADCC activity was recorded in the inflammatory population of an autograft. On the contrary, high levels of ADCC activity to donor strain PEC were recorded in the spleens of both autograft and allograft recipients throughout the period of follow-up. The results demonstrate that at least three cellular effector pathways exist in an allograft: a strong natural killer cell component, a strong cytotoxic T lymphocyte component, and (possibly) a weak cell component participating in an ADCC type of cytotoxicity.