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.     

Lymphocyte function in experimental African trypanosomiasis. IV. Immunosuppression and suppressor cells in the athymic nu/nu mouse

The role of T cells in the development and expression of antigen-nonspecific immunosuppression in experimental African trypanosomiasis was addressed. Nude ($\text{nu}\text{nu}$) C57BL/ 6 NIH mice and their thymus-bearing ($\text{nu}\text{+}$) littermates were infected with Trypanosoma rhodesiense and examined for suppression of splenic B-cell responses in vitro to the mitogen LPS. All animals developed splenic unresponsiveness to LPS. Further, both nu/nu and nu/ + infected mice displayed suppressor cell activity in their spleen cell populations upon transfer to normal uninfected mouse spleen cell cultures. On the basis of these findings we suggest that both the generalized immunosuppression and the development of suppressor cell activity in the spleens of mice infected with T. rhodesiense are T-independent processes.     

Impairment of primary in vitro response of New Zealand mouse spleen cells to a thymic-dependent antigen.

New Zealand Black (NZB) and NZB by New Zealand White (NZW) F₁ hybrid ($\text{B}\text{W}$) mice develop clinical signs of autoimmune disease between 6 and 10 months of age but spleen cells from these strains have a greatly reduced in vitro response to sheep erythrocytes (SRBC) as early as 5–6 weeks of age. This hyporesponsiveness can be only partially restored with 2-mercaptoethanol, allogeneic macrophages or spleen cells, or allogeneic factor. The response of NZB and $\text{B}\text{W}$ spleen cells to the thymic independent antigen DNP-Ficoll is nearly normal. The reduced in vitro SRBC response was found to be attributable to splenic T and B cells rather than macrophages. Macrophages from NZB mice were found to function normally. The in vitro behavior of NZB lymphocytes is very similar to non-autoimmune mice infected with common murine viral pathogens. NZB and $\text{B}\text{W}$ mice may be making an active immune response as early as 5 weeks of age.     

Immunoregulation in MRL/Mp-lpr/lpr mice: evidence for decreased helper-T-cell and increased suppressor-T-cell function with age

In vivo and in vitro plaque-forming cell (PFC) responsiveness to sheep erythrocytes (SRBC) was used to assess immunoregulatory function in the autoimmune MRL mouse strain. MRL/Mp-lpr/lpr (MRL/l) mice had good primary and secondary IgM and IgG responses in vivo compared to MRL/Mp-+/+ (MRL/n) mice when young, but with age the MRL/l responses declined markedly. In vitro primary SRBC-specific PFC responses in MRL/l mice declined at the same time as in vivo responses, indicating that the in vivo autoimmune environment could not account for cellular dysfunction. When varied mixtures of T and B cells from MRL/l and MRL/n mice were cultured, abnormalities in MRL/l T-cell function became apparent. T-helper-cell (T_H) function declined rapidly with age, beginning by 2 to $\text{2}\text{1}\text{2}$ months of age. T cells from MRL/l mice 2 months of age and older also had increased suppressor activity when cultured with B cells and MRL/n T cells. The degree of suppressor activity increased with age. The correlation of these findings with results of previous studies by others and with autoimmune disease is discussed.     

Concanavalin A-induced suppressor cell activity for T-cell proliferative responses: Autologous and allogeneic suppression in aging humans

Peripheral blood mononuclear cells from 48 healthy subjects of ages varying from 20 to 94 years were evaluated for the ability to generate suppressor cell activity following in vitro incubation with concanavalin A. The suppression of proliferative responses by autologous and young, allogeneic lymphocytes to phytohemagglutinin was assessed using suppressor/ responder cell ratios ($\text{S}\text{R}$) of 2:1 and 1:1 and by using a summation index. Inducible suppressor cell activity for autologous responder cells was comparable between 24 aged (76.0 ± 10.9 years) and 20 young (26.8 ± 4.6 years) subjects. However, aged subjects exhibited a significant decrease in suppressor cell activity ($\text{S}\text{R}\text{= 1}$) when allogeneic responder cells were utilized. Our results indicate that autologous inducible suppressor cell activity is preserved in the aged population, whereas allogeneic activity is impaired.     

Soluble factors from BCG-induced suppressor cells inhibit in vitro PFC responses but not cytotoxic responses.

A macrophage-like suppressor cell is present in the spleens of BCG-infected C57BL/6 mice. This suppressor cell is capable of suppressing both in vitro cytotoxic and PFC responses of normal C57BL/6 spleen cells. Suppression was not caused by changes in the kinetics of the responses or in the quantities of antigen required for stimulation. Suppression of the in vitro cytotoxic response could not be linked to any soluble mediator. In contrast, supernatants obtained from BCG spleen cell cultures, which failed to inhibit alloantigen-induced cytotoxic responses, suppressed the in vitro PFC response to SRBC by normal C57BL/6 spleen cells. It is postulated that either BCG-induced macrophage-like suppressor cells inhibit these in vitro responses via different mechanism(s) or these responses are regulated by different suppressor cell subpopulations within the monocyte/macrophage compartment of BCG spleen cells.     

Proliferative and cytotoxic immune functions in aging mice. IV. Effects of suppressor cell populations from aged and young mice

The changes with age in three splenic suppressor cell populations were studied in C57BL/6 mice. Allospecific Ts cells and nonspecific non-T suppressor cells were both generated in vitro in allogeneic MLC. The presence of "pre-existing" suppressor cells in fresh spleen cells from normal mice was examined. Suppressor cell activities were assayed for their ability to suppress proliferation in a fresh allogeneic MLC after treatment to prevent their own proliferation. The ability to generate both specific and nonspecific suppressor cells decreased with age, whereas pre-existing suppressor cells were detected in spleens from the majority of the aged animals but not in spleens from young animals. The decrease in suppressor cell activity was not due to any requirement for age matching between donors of suppressor and target cells. The specific and nonspecific MLC-generated suppressor cells inhibited both the proliferative response in the assay MLC and the generation of cytotoxic cells. The pre-existing suppressor cells only suppressed the proliferative response and not the generation of cytotoxic cells. The changes seen with age in these suppressor cell populations suggest that the ability to generate suppression (both allospecific and nonspecific) to newly encountered Ag declines with age, whereas a resident splenic suppressor cell population accumulates over the lifetime of the animals.     

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.     

Allogeneic T-cytotoxic reactivity of senescent mice: affinity for target cells and determination of cell number

Experiments were performed to determine the cause(s) of the reduced T-cytotoxic-cell response observed in senescent mice. The cytotoxic cells studied developed in mixed lymphocyte cultures (MLC) of 6 × 10⁶ C57B1/6J (H-2^b) spleen cells from mice of various ages which were stimulated by doses of irradiated Balb/c (H-2^d) cells giving responder to stimulator ratios of 10:10 and 10:1. The cytotoxic response, as determined in a ⁵¹Cr-release assay against P815 (H-2^d) mastocytoma cells in culture, declines with age. This age-related decline is more pronounced with the lower dose of stimulator cells (10:1). The cytotoxic response developing in 10:10 and 10:1 MLC of spleen cells from young mice is comparable in magnitude, whereas the lower dose (10:1) is much less stimulatory in cultures of spleen cells from mice above 12 months of age. In order to better understand this age-dependent decline in cytotoxic response, the affinity of effector cells to their target and the percentage of cytotoxic cells which develop in the cultures of spleen cells from mice of various ages were determined. The affinity of cytotoxic cells developing in 10:10 MLC does not change with age. The affinity of cytotoxic cells developing in 10:1 MLC from young mice is significantly higher than the affinity of those developing in 10:10 MLC. This dose-dependent increase in affinity is not apparent in 20-month-old mice, which show equal affinity of cytotoxic cells in 10:10 and 10:1 MLC. The percentage of cytotoxic cells in the cultures was found to decrease with age. This decrease was more pronounced after 10:1 stimulation. Thus the decline with age in cytotoxic response can be attributed to a decrease in number of functional cytotoxic cells developing in MLC cultures, regardless of stimulator cell dose and a decrease in affinity for target cells at low stimulator cell doses.     

Further studies on suppressor cell activity in the spleen of neonatal mice.

Spleen cells from newborn BDF₁ and C57BL/6 mice are tested for suppressor activity in mixed lymphocyte culture. The added spleen cells, treated with mitomycin, suppress both cell proliferation and the generation of cytotoxic cells. Thymus cells from newborn mice have little suppressor activity. Suppressor cells act across an allogeneic barrier, are cortisone-resistant, XR-resistant, T-cells and their activity is inversely correlated to the MLC reactivity in the spleen of the young animal. Incubation of neonatal suppressor cells on macrophage monolayers reduces suppressor cell activity and points to the possible importance of the macrophage in controlling immunological maturation.     

Proliferative and cytotoxic immune functions in aging mice. II. Decreased generation of specific suppressor cells in alloreactive cultures

The ability of spleen cells from aged C57BL/6 mice to generate specific suppressor cells in mixed lymphocyte cultures (MLC) against allogeneic H-2 antigens was investigated. The suppressor cells from young and old mice were assayed in parallel for their ability to inhibit the proliferative response and the generation of cytotoxicity in fresh MLC. Suppressor cell generation was found to be significantly decreased in 41% of aged mice (23 to 28 mo) as compared to young controls (3-8 mo). The suppressor cells were H-2-specific, radiation-resistant (1000 R), and Thy-1+; they did not function by lysing the fresh stimulators or responder cells, or by absorbing the interleukin 2 in the fresh cultures. Suppression required very small numbers of cells to be effective. It was concluded that the effect of aging was less marked on specific suppressor cell generation than on generation of cytotoxic T cells in the MLC. However, a third type of response studied, the proliferative response, was affected earliest and most severely.     

Induction kinetics of human suppressor cells in the mixed lymphocyte reaction and influence of prednisolone on their genesis

The induction kinetics of human suppressor cells in mixed lymphocyte cultures (MLC) and the influence of prednisolone on the genesis of these suppressor cells is reported. We induced over 1 to 6 days suppressor cells in one-way MLC (MLC-1), the inhibitory activity of which was tested on a secondary MLC (MLC-2), and on responder cells alone, where lymphocytes were obtained from the same lymphocyte donors as for the MLC-1. In four experiments the degree of inhibition ($\text{x}\text{?}\text{±}\text{SE}$) when suppressor cells were induced for 2, 4, or 6 days was 38.5 ± 11.8, 79.5 ± 7, and 85 ± 6%, respectively, compared to 50.5 ± 9.4, 83.3 ± 7.8, and 85.3 ± 9.8% when 500 ng/ml prednisolone was added to the MLC-1. A similar inhibition pattern was observed when the generated suppressor cells were incubated with responder cells only. The inhibitory activity of these MLC-induced suppressor cells was abrogated by irradiation with 3000 R. Suppressor cells apparently are generated in MLCs between Days 1 and 4; furthermore, their genesis is not affected by usual therapeutic concentrations of prednisolone.     

Macrophages as effector cells of protective immunity in murine schistosomiasis: IV. Coincident induction of macrophage activation for extracellular killing of schistosomula and tumor cells

Peritoneal macrophages from Schistosoma mansoni-infected mice are activated both for nonspecific tumor cytotoxicity and for killing of skin-stage schistosomula in vitro. In the current study, mechanisms for induction of macrophage tumoricidal and schistosomulacidal activity have been compared. Examination of macrophages activated in vivo by BCG infection or C. parvum treatment, or in vitro by exposure to lymphokine prepared from antigen-stimulated BCG-immune spleen cells, showed that these effector functions were closely linked. Indeed, fractionation of lymphokine-rich supernatant fluids by Sephadex G-100 gel filtraction showed that activities responsible for induction of schistomula killing by inflammatory macrophages and for induction of tumoricidal activity cochromatographed as a single peak in the 50,000 MW region. Thus, development of macrophage-mediated cytotoxicity against these two extracellular (tumor cell or helminth) targets was coincident in several cell populations activated in vivo or in vitro. However, activation for tumoricidal and schistosomulacidal capacity appeared to be quantitatively dissociated in macrophages from mice with chronic schistosomiasis; those cells demonstrated low, yet significant, levels of larval killing ($\text{1}\text{3}$ to $\text{1}\text{5}$ those of BCG or lymphokine-activated cells) but maximal levels of tumor cell cytotoxicity. Furthermore, cytotoxicity by peritoneal cells from S. mansoni-infected mice was not increased in vitro by exposure to lymphokine. Identification of this functional alteration in S. mansoni-activated cells may help to clarify the role of macrophages in the partial immunity against challenge infection which is demonstrated by mice with chronic primary S. mansoni infection.     

The ability of hapten-conjugated cells to induce cell-mediated cytotoxicity is affected by the mode of hapten linkage

Spleen cells from C57 $\text{B}\text{1}\text{6}$ mice were modified with varying concentrations of several haptens coupled in different ways, then assayed for their ability to induce a cytotoxic response against hapten-modified target cells when cocultured with syngeneic spleen cells. Haptens such as TNBS, DNBS, Fl-NCS, and AB-NCS which couple via the ?-amino groups of lysine were all capable of generating high levels of cytotoxicity when tested against hapten-coupled syngeneic tumor. One hapten, DNBM, which coupled via -COOH groups was effective in generating cell-mediated cytotoxicity. By contrast, similar haptens such as ABA and DNBA which couple as diazonium salts via tyrosine and histidine groups were not found to generate cytotoxic responses over wide ranges of concentrations. Possible explanations are discussed.     

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.     

Alcohol toxicity in cell culture

The purpose of this investigation was to study the mechanism of tissue toxicity induced by ethanol, which neither is metabolized nor interacts chemically with cell components. In concentrations that may be found in blood and tissues of humans, alcohol stimulated at low and impaired at higher concentrations the $\text{invitro}$ incorporation of DNA precursors into mitogen-stimulated mouse spleen cells in suspension. The degree of impairment varied directly with ethanol concentrations and duration of incubation. The impairment was demonstrable with several different mitogens and also when ethanol was added to the culture 2 hours after exposure to the mitogen. The impairment was irreversible when ethanol was removed in later stages of incubation. Because the cells did not metabolize ethanol under the conditions of this experiment, a direct physical effect of ethanol $\text{per se}$ on cell membranes is inferred. This conclusion is supported further by the finding that chlorpromazine $\text{in vitro}$ counteracted both stimulatory and inhibitory effects of ethanol.     

Suppressor T cells and suppressor macrophages induced by Corynebacterium parvum

Corynebacterium parvum, injected intravenously into C57B1/6 mice (H-2^b) previously alloimmunized with P815 (H-2^d) mastocytoma cells, generated splenic suppressor cells that inhibited the development of primary cytotoxic lymphocytes in vitro. These suppressor cells differed from those generated by intravenous C. parvum injection of naive C57B1/6 mice. The former suppressor cells were effectively induced by administration of 700 μg of C. parvum whereas the latter suppressor cells were dependent upon higher doses (1400 μg) of adjuvant for their activation. Furthermore, suppressor cells generated in alloimmunized mice could only suppress C57B1/6 anti-P815 in vitro cytotoxic responses whereas suppressor cells generated in naive mice could suppress C57B1/6 anti-CBA (H-2^k) responses as well. Suppressor cells were not H-2 restricted in their action. Fractionation of spleens from alloimmunized, C. parvum-treated mice revealed the presence of suppressor T cells and suppressor macrophages. We were unable, however, to determine which cell was responsible for “antigen specificity” of suppression since the fractionation procedures seemed to trigger both suppressor cell types prior to adding them to the primary culture.     

Role of the H-2I region in the generation of an antiviral cytotoxic T-cell response in vitro

The participation of H-2I gene products in generating virus-specific proliferative and/or cytotoxic T-lymphocyte (CTL) responses was investigated. Spleen cells from mice infected with vaccinia virus were restimulated secondarily in vitro with syngeneic virus-infected peritoneal exudate cells (PEC) and then restimulated in tertiary cultures with virus-infected PEC from syngeneic and partially histoincompatible strains of mice. Based on the finding that comparable proliferative responses resulted when stimulating the responding cells were histocompatible at the H-2K, I, or D region of the major histocompatibility complex (MHC), the additively enhanced, but not potentiated, proliferation caused by identity at two or three H-2 regions was analyzed. Enhancement of proliferation followed when the H-2K/D components plus virus and the H-2I components plus virus were either on the same, or alternatively on two, stimulating cells. This suggests that H-2K, D, and I plus virus trigger distinct T-cell subsets. A virus-specific CTL response was generated in vitro when spleen cells from virus-primed mice and even unprimed mice were stimulated with cells sharing only H-2K and/or H-2D of the MHC. Identity at the H-2I region did not stimulate a CTL response, nor did it influence the magnitude of the $\text{K}\text{D}$ restricted response. Nevertheless, the presence of anti-Ia antiserum in cultures of syngeneic stimulators and responders inhibited the cytotoxic response to a great extent. Therefore, H-2I region products seem to participate in the generation of virus-specific CTL in vitro.     

Expression of subregion and haplotype preference for H-2Kk restricted cytotoxic T-cell responses in vivo and at the level of the precursor frequencies

Several strains of mice bearing the H-2K^k allele were found to generate in vivo strong CTL responses against TNP-haptenated syngeneic cells, while several other strains of mice were found to generate comparably weak or no responses. C3H × DBA/2)F1 mice (H-2^k × H-2^d) and A/J mice with the recombinant haplotype $\text{H-2}{}^{\mathrm{<mtext>k</mtext><mtext>d</mtext>}}$ generated CTL responses in vivo that were completely restricted toward the H-2^k haplotype or the K end of the $\text{H-2}{}^{\mathrm{<mtext>k</mtext><mtext>d</mtext>}}$ haplotype, respectively. The CTL activity of C3H × DBA/2)F1 and A/J mice against haptenated H-2^k targets was found to be more than 25-fold higher than the CTL activity on H-2^d targets. The CTL responses in vitro under macroculture conditions showed, on the other hand, only a 3- to 6-fold higher cytotoxic activity against the haptenated H-2^k targets as compared with haptenated allogeneic or H-2^d targets; and limiting dilution experiments in microcultures revealed that the CTL precursor frequencies were only 2- to 3-fold smaller for TNP-haptenated H-2^d or haptenated allogeneic targets than for haptenated H-2^k target cells. This indicated that sufficient numbers of H-2^d-restricted and allorestricted CTL precursors were actually present in these strains, but did not develop detectable cytotoxic activity in vivo. The exceptional property of the H-2^k haplotype is, therefore, only partly determined by a difference in the CTL precursor frequencies, and to the larger extent determined at the level of the activation of the CTL response.     

Nature of T-cells resident in spleens of thymectomized,lethally irradiated,bone marrow-reconstituted mice

Adult thymectomized, lethally irradiated, bone marrow-reconstituted (ATxXB) mice that had been weakly primed with SRBC or HRBC between thymectomy and irradiation were shown to retain antigen-specific immunological memories for at least 1–5 months after bone marrow reconstitution. This could be shown by anamnestic antibody response in vivo as well as by proliferative response of the spleen cells to the test antigens in vitro. Spleen cells taken from ATxXB mice showed a reduced but significant proliferative response to nonspecific T-cell mitogens, in particular to Con A, in vitro. Treatment of the donor bone marrow cells used for reconstitution of ATxXB mice with anti-Thy 1.2 sera + C′ did not affect the generation of immunological memories nor the magnitude of the proliferative response of spleen cells to nonspecific T-cell mitogens in vitro, indicating that the cells responsible for such functions were host derived. Finally, the antibody-forming capacity of spleen cells derived from SRBC-primed ATxXB mice to the test antigen in vitro was completely abrogated by exposure to 450 R, whereas the helper function of the same cell suspension remained unaffected even after exposure to 1000 R. Implication of these findings on the nature of T cells resident in spleens of ATxXB mice was discussed.