Immunosuppression during viral oncogenesis. IV. Generation of soluble virus-induced immunologic suppressor molecules

We describe herein functional attributes and generation of immunologic suppressor activity elaborated in response to oncogenic virus infection. Malignant rabbit fibroma virus-induced immunologic suppressor factor (VISF) is a T cell product produced in peak quantities by spleen cells taken from infected rabbits 7 days after infection in vivo. Its production does not appear to require macrophage participation. VISF is highly labile, 3.5 to 12 kDa, and capable of suppressing both B and T lymphocytic responses. Indomethacin and the cyclic nucleotides cAMP and cGMP inhibit its generation. VISF activity is neither antigen nor species specific. It suppresses murine and leporine immune responses to antigens unrelated to the inducing virus. Comparable suppressor activity may be induced by infecting an apparently non-functional rabbit T lymphoma line, RL-5, with malignant rabbit fibroma virus. VISF is principally a suppressor-inducer factor: in vitro, lymphocytes exposed to VISF do not show decreased immunologic responsiveness until 4 days of culture. VISF induces T suppressor cell activity when normal spleen cells are exposed briefly to VISF. Thus, immunosuppressive consequences of malignant fibroma virus infection are partially mediated by a small, non-specific T cell-derived suppressor lymphokine with unique functional characteristics. Non-specific immunologic dysfunction that often attends virus infections may reflect the activity of such factors in humans as well.     

Immunosuppression in viral oncogenesis. III. Effects of virus infection on interleukin 1 and interleukin 2 generation and responsiveness

Malignant rabbit fibroma virus (MV) is an oncogenic immunosuppressive leporipoxvirus. We studied the effects of MV infection and MV-associated tumor-induced suppressor factor (TISF) on the production of and responsiveness to interleukins 1 and 2. Adherent cells from MV tumor-bearing rabbits elaborate adequate amounts of IL 1 in response to E. coli endotoxin. Neither live virus nor TISF alters the production or the responsiveness to IL 1. However, when we examined spleen cells from rabbits 7 days after MV inoculation, we noted that their ability to produce and respond to IL 2 is deficient. Despite their relatively poor capacity to produce IL 2, these spleen cells express receptor for IL 2 in normal amounts, as measured by the monoclonal antibody 7D4. TISF derived from T lymphocytes from MV tumor-bearing rabbits is by itself capable of inhibiting partially normal secretion of IL 2 and also the response of the cloned murine T cell line HT-2 to added IL 2. Full expression of the immunosuppressive capacity of spleen cells from MV tumor-bearing rabbits requires cell-cell contact, however, and cannot be replaced by either live virus or spleen cell supernatants. Such spleen cells inhibit normal mitogen responsiveness, a defect not remedied by adding exogenous IL 2. Immunologic dysfunction induced by MV infection is transient, and by 11 days after virus inoculation, actively mediated recovery from immunosuppression is observed. We found that spleen cells from rabbits studied 11 days postinoculation secreted IL 2 normally. Thus, immunologic dysfunction secondary to infection with malignant rabbit fibroma virus reflects deficiencies in both elaboration of and response to IL 2, and return of immune function later in the course of the infection is associated with return of the ability of lymphocytes to secrete IL 2.     

Immunologic dysfunction during viral oncogenesis. I. Nonspecific immunosuppression caused by malignant rabbit fibroma virus

Malignant rabbit fibroma virus (MV) is a potent oncogenic poxvirus that produces a rapidly progressive syndrome of disseminated myxosarcoma, immunosuppression, and fatal gram-negative infection. MV is probably a recombinant between Shope fibroma virus (SFV) and rabbit myxoma virus, and is capable of preventing or aborting the in vitro proliferative responses of rabbit lymphocytes to B and T lymphocyte mitogens. Proliferative responses to sheep erythrocytes (SRBC) are similarly affected, although MV does not alter ongoing antibody responses to SRBC. Splenic lymphocytes from MV tumor-bearing rabbits suppress antibody and proliferative responses to SRBC when added to lymphocytes from SRBC-primed rabbits. Finally, lysates of cultured splenic lymphocytes from rabbits given MV suppress both proliferative and antibody-forming responses to SRBC. When MV is removed from these lysates by UV inactivation or by centrifugation, the suppressive activity remains. We therefore conclude that MV induces immunologic unresponsiveness in rabbits by at least two mechanisms. First, a direct suppressive effect of added virus on in vitro lymphocyte proliferation is seen. There is no effect in this situation if an antibody response is already in progress. Second, spleen cells exposed to MV in vivo produce one or more soluble factors capable of suppressing both proliferative and antibody responses of normal lymphocytes.     

Reversal of virus-induced immune suppression

We studied the immunosuppressive capacity of splenic lymphocytes from rabbits at different stages of progressive myxosarcoma induced by malignant rabbit fibroma virus (MV). Spleen cells taken from rabbits 7 days after virus inoculation proliferate poorly in response to Con A, and suppress normal responses to the mitogen. Those from animals 11 days after virus injection have recovered partially from MV-induced suppression. Further, their Con A responses are no longer suppressed by day 7 spleen cells. Supernatants from cultures of spleen cells from rabbits given MV 7 days previously suppress both antibody-producing and proliferative responses to unrelated antigens. Comparable supernatants from rabbits receiving MV 11 days before sacrifice neither suppress nor augment such responses. Mixing cells from 7 or 11 day MV rabbits with normal spleen cells gives similar results. When supernatants from spleen cell of rabbits with tumors induced 7 and 11 days previously are mixed, the supernatants from rabbits with 11-day-old tumors inhibit the suppressive capacity of those from animals with 7-day-old tumors. Similarly, mixing spleen cells from rabbits given MV 7 and 11 days previously results in culture supernatants that do not suppress normal antibody and proliferative responses. The ability of cells from rabbits given MV 11 days before to inhibit the effects of cells from rabbits given MV 7 days previously does not involve the production of interferon. Thus, despite progressive tumor burden, immunologic recovery is observed in rabbits 11 days after tumor virus inoculation. One factor in this recovery may be the generation of active inhibitors of virus-induced immunosuppression. Similar mechanisms may apply to recovery of immunologic function in other virus infections as well.     

Lymphocyte-virus interactions. Identification of a restriction fragment permitting virus replication in lymphocytes

We are interested in understanding the effects of virus infection on lymphocyte function. To approach this question, we used a unique system of two genetically related leporipoxviruses to generate recombinants. One of these viruses, malignant fibroma virus (MV), replicates in many different cell types, including lymphocytes. The other, Shope fibroma virus (SFV), replicates principally in fibroblasts, but cannot replicate in lymphocytes. Fibroblasts infected with SFV received restriction fragments from MV by transfection. Recombinant viruses were selected in vitro for their ability to replicate in lymphocytes. By these means we have identified one restriction fragment, the 10.8-kb BamHI "C" fragment, capable of transferring from MV to SFV the ability to replicate in lymphocytes. A family of recombinants bearing different sized inserts of this restriction fragment has been isolated and is being characterized. Lymphocytotropic recombinants bearing portions of this restriction fragment produce colony morphology in vitro intermediate between MV's plaques and SFV's foci. On the basis of their ability to grow in and suppress mitogen responsiveness of lymphocytes, these recombinants may be classified into four different groups. Group 1 viruses are the most immunosuppressive, whereas those of group 4 are least. These traits correlate with ability to replicate in lymphocytes. Genetic analysis of recombinants indicates that the most immunosuppressive recombinants do not necessarily contain the most fragment C DNA. Therefore, we have identified a restriction fragment, one or more of the genes of which are sufficient to allow an otherwise nonlymphocytotropic virus to replicate in lymphocytes. Additional genetic and immunologic analysis should permit us to determine the structure and function of the protein responsible for this effect.     

Immunologic dysfunction during viral oncogenesis: II. Inhibition of cellular immunity to viral antigens by malignant rabbit fibroma virus

The ability of two related viruses—Shope fibroma virus (SFV) and malignant rabbit fibroma virus (MV)—to induce virus-specific immune responses in lymphocytes of recipient animals was studied. SFV produces a benign local tumor which regresses in 12–14 days. Using an assay for virus-induced lymphocyte blastogenesis lymphocytes reactive to SFV were detected, both in rabbits bearing SFV-induced tumors and in rabbits whose SFV-induced tumor had regressed. These virus-reactive cells were detected in peripheral blood and spleen, and in lymph nodes draining the primary tumor. In contrast, MV produces a disseminated tumor and eventual death. MV does not induce detectable blastogenic responses in lymphocyte populations. SFV and MV are antigenically cross reactive: rabbits immune to SFV do not develop MV-induced tumors, and antisera to each virus neutralize both equally. Lymphocytes from SFV-infected rabbits proliferate in vitro in response to MV that has been inactivated by ultraviolet light (uv/MV) but not to infectious MV. In contrast, lymphocytes from rabbits infected with MV do not respond to uv-inactivated MV or to SFV. Thus, infectious MV inhibits the development of normal blastogenic responses in vivo and prevents the expression of those responses in lymphocytes from MV-resistant, SFV-immune rabbits in vitro. The relevance of this impairment to the differences in the clinical courses of SFV- and MV-induced tumors is discussed.     

Suppressor T lymphocyte induction by a factor released from cultured blastocysts

For the analysis of immunologic escape mechanisms of embryos during the implantation period in mice, the effects of culture supernatant of blastocysts on in vitro responsiveness to alloantigen of mice was investigated. Blastocyst-cultured conditioned medium was prepared by culturing late blastocysts of outbred ICR mice for 5 days. The addition of culture supernatant containing four or eight blastocysts to allogeneic mixed lymphocyte culture inhibited both the MLR responses and the generation of cytotoxic T lymphocytes (CTL). Preincubation of the culture supernatant with lymphocytes syngeneic to the responder cells of MLR induced potent suppressor cell activity in the MLR. The supernatant did not inhibit the activity of CTL at the effector phase, but preinduced suppressor cells obtained by incubation of splenocytes with the supernatant showed almost complete suppression of CTL activity at the effector phase. Both of the suppressor cells, active on MLR and at the generation phase of CTL as well as active at the effector phase, had a surface phenotype of Thy-1+ and Ig-. The suppressive material could be extracted from the eight-cell stage of fertilized ova or blastocysts but not from unfertilized ova, indicating that the production of the factor(s) is dependent on the stages of early embryogenesis. These results suggest that the active induction of suppressor T lymphocytes by the factor(s) released from implanted embryos is one of the protective mechanisms from maternal immunologic attack.     

Modulation of cellular immune function in vitro by histamine receptor-bearing lymphocytes: mechanism of action.

When soluble histamine is added to guinea pig lymphocytes in vitro, antigen-induced cellular proliferation and the production of migration inhibitory factor is suppressed. The inhibitory effects that are produced by histamine have been shown to be mediated by the histamine-type 2 receptors of the involved cells, but the exact nature of this suppression has not been fully explored. The present studies have evaluated, following immunization, the effect of histamine on macrophage function in vitro, and affinity chromatography to delete a subpopulation of cells bearing histamine receptors. When we treated monolayers of peritoneal exudate cells with histamine (up to 10^?3M) we found that histamine did not interfere with antigen binding by macrophages, macro phage presentation of antigen to lymphocytes, nor the antigen-independent or antigen-dependent lymphocyte-macrophage rosetting. Columns containing insolubilized conjugates of histamine and rabbit serum albumin depleted a subpopulation of cells responsive to histamine i.e., the non-adherent cells made migration inhibitory factor and proliferated in the presence of histamine. The latter finding suggested that the retained cells might have suppressor function and if so, might mediate their effect through the release of a soluble factor. Preliminary data obtained in these studies supports this hypothesis. We conclude that cells bearing histamine receptors may serve a regulatory role in cellular immunity after their activation by histamine by producing a non-dialyzable factor with immunosuppressive properties.     

Suppression of antibody responses in allogeneic mice by products of lymphoid tissue. I. Allogeneic suppressive factor (ASF) from spleens repopulated with thymus cells.

A cellfree extract prepared from the spleen cells of C3H mice is capable of suppressing antibody responses to SRBC when extract material is exposed to alloantigens. The observed immunosuppression was attributed to a soluble factor in the extract. This allogeneic suppressive factor (ASF) was detected in extracts prepared from the spleen cells of unirradiated mice as well as those of irradiated mice repopulated with thymocytes, provided that mice were previously immunized with SRBC. Donors of actively suppressive ASF preparations did not need to be previously exposed to alloantigens. Extracts from thymus and marrow cells of unirradiated mice and the spleen cells of irradiated mice repopulated with marrow cells (or no cells) did not contain ASF. C3H thymocytes stimulated with SRBC generated more ASF activity in spleens of C3BF1 hosts than in those of C3H hosts, indicating that alloantigenic stimulation enhances the production or activity of ASF. Once produced, C3H ASF was able to suppress antibody responses in cell transfer experiments only if exposed to C3BF alloantigens of either donor lymphoid cells or irradiated hosts. Once exposed to alloantigens, ASF appears to be capable of suppressing antibody responses of syngeneic C3H or semi-allogeneic C3BF cells. When both donor lymphoid cells and hosts were syngeneic with the donor of the ASF, there was enhancement of antibody formation in cell transfer experiments. C3H ASF did not interfere with education of C3BF thymocytes to SRBC or with the generation of precursors of anti-SRBC antibody-forming cells by C3BF1 marrow cells. ASF may interfere with cellular cooperative events necessary for humoral immune responses or with terminal differentiation of B cells. Production of ASF could partially account for the suppression of antibody responses observed during graft-vs-host reactions.     

Therapeutic vaccine to control stromal tumor-induced immunosuppression in human uterine cervixc cancer.

Cancer cells may escape immune surveillance by secreting in their microenvironment soluble factors that may locally paralyze the stromal effector immune cells. In the human uterine cervix cancer, HPV-16 E7 protein, released in the stroma, should contribute to cancer cells immune escape since this protein inhibits the cellular immune response to recall antigens or alloantigens and strongly enhances the release of immunosuppressive cytokines by APCs. This prompted us to prepare a therapeutic vaccine triggering anti-E7 neutralizing Abs to antagonize the E7-induced stromal immunosuppressive effects and allow cellular immune reaction towards cancer cells including specific CTLs, induced by conventional vaccine, to be effective. Since HPV-16 is a mucosotropic virus, this therapeutic vaccine has been prepared to generate systemic as well as mucosal immunity.     

Interferon: effects on the immune response and the mechanism of activation of the cellular response.

The discovery of interferon in 1957 by Drs. Isaacs and Lindenmann led to major revisions in the concepts of man's defenses against viral infections. There are at least two types of interferon. Along with their antiviral properties, they have recently been shown to exert a suppressive effect on the humoral and cellular immune response; they affect both B and T lymphocytes. A variety of substances, including virus, polyribonucleotides, and mitogens for T lymphocytes, are good interferon inducers. T lymphocytes seem to be necessary for these inducers to exert their immunosuppressive effects. The immunosuppressive effects of interferon inducers suggests that interferons may be mediators of suppressor T lymphocyte effects. In the virus system, interferon does not exert its antiviral effects by direct action on the virus, but rather derepresses a cell gene that results in the production of an antiviral protein. This antiviral protein is probably the mediator of inhibition of virus replication. This is a complex sequence of events that results in the interaction of interferon with the cell membrane and the resulting production of the antiviral state in the cell. This review will examine the various steps of this involved process.     

Macrophage migration stimulation factor, migration inhibition factor and the role of suppressor cells in their production.

Guinea pig lymph node lymphocytes and human peripheral blood lymphocytes when stimulated by specific antigen or mitogen will release factors that affect in vitro macrophage migration. Migration inhibition factor production appears to be under the control of suppressor cells which are T lymphocytes. When suppressor cells are generated by stimulation with Con A for 4 days, migration stimulation factor (M.St.F.) activity is found. In other situations where M.St.F. is found this is thought to be due to increased suppressor cell activity. For example, young adults produce this lymphokine when stimulated with Con A, whereas aged individuals produce MIF. Concanavalin A appears to be the mitogen of choice for M.St.F. production, and phytohemagglutinin for MIF production. The release of this putative factor M.St.F. from suppressor T cells helps to explain some of the difficulties that have existed in studies of macrophage migration inhibition.     

Activation of Fc receptor-bearing lymphocytes by immune complexes. I. Stimulation of lymphokine production by nonadherent human peripheral blood lymphocytes

Activation of human peripheral blood lymphocytes by incubation with particulate immune complexes or aggregated human gamma-globulin was studied by measuring the release of leukocyte migration inhibitory factor (LIF) activity. LIF-active supernatants were consistently produced when nonadherent lymphocytes containing less than 1% surface immunoglobulin-bearing cells and less than 0.2% nonspecific esterase-positive monocytes were incubated in the presence of RBC sensitized with rabbit or human antibodies or with pooled heat-aggregated human gamma-globulin. This immune complex-induced lymphokine production (ICLP) was dependent on the presence of cells bearing receptors for the Fc portion of IgG (Fc gamma). ICLP could not be demonstrated with lymphocyte preparations enriched for B cells even though the latter showed vigorous LIF production in the presence of complement-sensitized erythrocytes. ICLP was dependent on the concentration of lymphocytes and of stimulant as well as on the duration of coincubation, and it required active metabolic processes and RNA and protein synthesis but not DNA synthesis. Ca++ but not Mg++ was obligatory. ICLP by non-B Fc gamma receptor-bearing lymphocytes may play a role in antibody-dependent protective inflammation and immunologic injury phenomena, which is similar to that of lymphokine release by antigen-activated T cells in delayed hypersensitivity responses.     

The biologic effects of allogeneic effect factor on T lymphocytes. I. The mitogenic activity and the autonomous induction of cytotoxic T lymphocytes by AEF

Studies presented herein illustrate the capacity of the soluble mediator, allogeneic effect factor (AEF), which is derived from histoincompatible cell interactions, to induce the in vitro differentiation of normal murine splenic lymphocytes into mature cytotoxic cells capable of exerting activity on H-2-identical target cells. This process requires the presence of T lymphocytes during the sensitization phase, and the lytic activity on tumor cells is mediated by cytotoxic T lymphocytes (CTL). The capacity of AEF to induce differentiation of such CTL does not require the presence of stimulating target cells in the sensitization phase. The induction of CTL requires the presence of AEF at the initiation of culture, although exposure to AEF as brief as 1 hr is sufficient to induce fresh spleen cells to differentiate into CTL during the subsequent 5 days in culture. In addition to its ability to induce CTL, AEF is highly mitogenic for T lymphocytes. However, the mitogenic and the CTL-inducing activities of AEF can be experimentally dissociated, indicating that different subpopulations of T lymphocytes may be involved in the response to AEF. In contrast to similar soluble helper factors derived from allogeneic cell interactions, AEF appears to be unique in its ability to autonomously induce a primary CTL response in vitro.     

Immunoregulatory factors from a human macrophage-like cell line. II. A human T-cell lymphokine-induced suppressor factor for lymphocyte proliferation

It has been demonstrated that the human histiocytic lymphoma-derived cell line U937, which has monocytoid characteristics, responds to a concanavalin A-induced T-cell-derived suppressor supernatant (T-SFS) with the release of a factor markedly suppressing mitogen-stimulated proliferation of normal peripheral blood lymphocytes. The suppressor material is not dialyzable, appears within 2 hr of exposure of U937 cells to the T-SFS, persists for at least 24 hr, and has a Mr of approximately 40,000 by gel chromatography. The suppressor factor does not affect the proliferation of continuous T- and B-lymphoid cell lines, distinguishing it from the inhibitor of DNA synthesis also released by U937, but appears to be specific for a stage of activation of normal lymphocytes that is independent of (a) utilization of interleukin-2 and (b) inhibition of production of interleukin-2.     

The role of regulatory components from resident T lymphocytes in polyclonal B cell activation

Resident T lymphocytes have been found to exert helper and suppressor regulatory influences with regard to polyclonal activation of murine splenic B lymphocytes elicited by lipopolysaccharide. In the normal adult spleen, only T cell helper influences are exercised over polyclonal B cell activation. This activity is a property of Lyt 1+2- T cells and does not appear to be subject to MHC restriction. Suppressive influence evidently is either latent or it exists at such a low level that its effects are difficult to detect. No regulatory activity can be recovered from the supernatants of T cells, cultured either with or without LPS. However, suppressor T cell function may be evoked by activating splenic T cells with Concanavalin A or by sonicating unstimulated splenic T cells in order to liberate a suppressive potential which is not expressed by these unstimulated cells when intact. The soluble fraction of resident splenic T cell sonicates exerts both helper and suppressor regulatory influences. The soluble helper activity is derived from Lyt l+2- T cells, whereas suppressor activity is generated from Lyt 1-2+ T cells. The suppressive activity of T cell sonicates is not restricted by the MHC gene complex. Helper and suppressor activities contained in splenic T cell sonicates were separated by gel chromatography; the suppressive activity was found to elute with a molecular weight between 68,000 and 84,000 daltons, and the helper activity eluted with a molecular weight between 15,000 and 23,000 daltons. The data indicate that helper and suppressor activities are distinct molecular entities derived from distinct splenic T lymphocyte subpopulations. The possibility that these molecules are precursors to or components of antigen-specific or nonspecific helper and suppressor factors described in the literature is discussed.     

T cells from naive mice suppress the in vitro cytotoxic response against endogenous Gross virus-induced tumor cells

Syngeneic normal lymphoid cells added in co-culture of immune lymphocytes and tumor cells reveal a suppressive activity inhibiting the generation of cytolytic T lymphocytes. The suppression was specific for the response directed against endogenous virus-induced or x-ray-induced tumor cells expressing endogenous C type virus antigens. Thymocytes, spleen cells, or lymph node cells from naive mice were able to express this suppressive activity. The same cells displayed no suppressive activity on killer cells directed against exogenous C type virus-induced tumor cells. The suppressor cells were Thy-1+, Lyt-1- 2+. Our results strongly suggested that the spontaneous suppressor cells exert their activity by interacting with an early step on the CTL response, probably at the level of the helper T cell function. The suppressive activity was mediated by soluble factor(s) that were antigen specific and possibly H-2 restricted. The possible implications of these spontaneous suppressor T lymphocytes in the development of endogenous virus-induced tumors and their possible implications in tolerance to self antigens are discussed.     

Histamine-induced suppressor factor inhibition of NK cells: reversal with interferon and interleukin 2

Culture supernatants of lymphocytes stimulated with 10(-3) to 10(-8) M histamine contain histamine-induced soluble suppressor factor (HISSF) that significantly inhibits the natural killer (NK) cell functions of allogeneic lymphocytes. Lymphocytes precultured with increasing concentrations of HISSF showed a dose-dependent suppressive effect on their NK activity. HISSF was not cytotoxic itself and produced suppressive effects on PBL, NK-enriched large granular lymphocytes (LGL), and isolated T cells. Suppression was evident throughout a range of effector:target cell ratios. Production of HISSF was specifically blocked by the H2 antagonist cimetidine, but not by the H1 antagonist clemastine fumarate. Furthermore, H1 and H2 antagonists themselves do not induce production of HISSF. Although HISSF could inhibit the cytotoxicity of LGL, LGL themselves do not produce HISSF. HISSF inhibition of NK activity could be completely reversed by treating effector lymphocytes with recombinant interferon-alpha (IFN) for 1 or 2 hr or culturing them with purified interleukin 2(IL 2) for 36 hr. Our data suggest that exogenous IFN and IL 2 may have therapeutic potential in the treatment of immunological diseases associated with histamine-induced suppressor cell activity.     

Active suppression of host-vs-graft reaction in pregnant mice. VI. Soluble suppressor activity obtained from decidua of allopregnant mice blocks the response to IL 2

The mammalian fetus expresses a variety of antigens against which the maternal immune system can react and which in an allogeneic mating bears paternal transplantation antigens. Although these antigens may be expressed on the fetal trophoblast cells that contact maternal uterine decidua, the "fetal allograft" is not usually rejected. Previous studies have demonstrated the presence of nonspecific non-thymus-derived suppressor cells in the lymph nodes draining the uterus and in decidua of laboratory mice undergoing first allogeneic pregnancy. These suppressor cells appeared to be small lymphocyte cells that inhibit the generation of cytotoxic T lymphocytes (CTL) in vitro and in vivo and elaborate a nonspecific non-MHC-restricted soluble suppressor activity when cultured for 48 hours at 37 degrees C in vitro. We now report that soluble suppressor activity obtained from the decidua (DS) of allopregnant C3H/HeJ mice inhibits both the primary and secondary (memory) CTL response in vitro but does not inhibit lysis of target cells by preformed CTL. DS did not suppress the proliferation of YAC lymphoma cells, P-815 cells, or a C3H placental trophoblastoma line. Suppressor activity was obtained from anti-thy-1.2 + complement-resistant cells in the decidua, could also be obtained from the decidua of allopregnant CD1 nu/nu mice, and was associated with a single peak of activity of approximately 100,000 daltons on Sephacryl 200 chromatography. Suppression could not be overcome by adding either crude or HPLC-purified IL 2 to the mixed lymphocyte cultures in vitro, and both crude and column-purified suppressor factor inhibited the IL 2-dependent proliferation of H-Y cells (a cloned T cell line with NK activity). Furthermore, DS inhibited the IL 2-dependent generation of cytotoxic effector cells in vitro in the absence of allogeneic stimulator cells. Thus, a soluble suppressor factor obtained from non-T cells present in the decidua of successfully allopregnant mice could block the response to IL 2 and inhibit the generation of both specific and nonspecific cytotoxic effector cells. The significance of this inhibition with respect to survival of the "fetal allograft" is discussed.