Reversal of immunosuppression induced with plasma of malarious rats by supplemented complement

Suppression of antibody producing splenic lymphocytes by plasma from rats infected with Plasmodium chabaudi malaria was confirmed. Suppressive activity was found in plasma drawn on the sixth, seventh and eighth day of infection. It was temporally associated with anemia, elevated levels of soluble immune complex, reduced titers of lytic complement and elevated titers of immunoconglutinin (IK) in the plasma. Heat inactivation of the plasma to destroy complement and removal of IK by absorption did not reduce the suppressive activity. Incubating the plasma-treated lymphocytes with normal rat complement largely, but not completely, reversed the suppressive action. Soluble immune complexes prepared from bovine serum albumin (BSA) and antiBSA (BSA-antiBSA) alexinated complex (BSA-antiBSA-C') and immunoconglutinated complex (BSA-antiBSA-C'-IK) each suppressed the capacity of splenic lymphocytes from rats immunized with sheep blood cells to produce hemolytic Jerne plaques. Incubating the complex-treated cells with fresh complement largely reversed the suppressive activity. It is suggested that the suppressed responses of lymphocytes from malarious animals to antigens or mitogens, reported by others, may have been in part induced by complexes in blood of the animals, and that antibody producing cells might also have been suppressed. Since suppressive activity was not influenced by complement inactivation, but was reversed when plasma-treated cells were incubated with fresh complement, it is suggested that the hypocomplementemic state of suppressive plasma may have contributed to immunosuppression.     

Antigen-reactive cell opsonization: a mechanism of antibody-mediated immune suppression.

Antisera against sheep red blood cells (SRBC) specifically suppressed the direct anti-SRBC plaque-forming cell (PFC) response in mice when passively administered with the antigen. The suppressive activity of mouse and rabbit anti-SRBC sera was found to correlate with anti-SRBC opsonic activity but not with hemagglutination or hemolysin titers. Macrophage depletion of mice, using carrageenan treatment, inhibited antibody-mediated immune suppression. When mice immunized with SRBC were given ¹²⁵I-labeled Udr, radiolabeled spleen lymphocytes were obtained which specifically formed rosettes with SRBC. These radiolabeled antigen-reactive cells (1ARC) were specifically opsonized in mice treated with antigen-antibody complexes but not in mice treated with antigen or antibody alone. These results suggest that antibody-mediated immune suppression may be due to specific opsonization (and subsequent destruction) of ARC in the presence of antigen-antibody complexes.     

Suppressive effect of nonviable Mycobacterium paratuberculosis on the delayed-type hypersensitivity reaction to sheep erythrocytes in mice.

The effect of nonviable Mycobacterium paratuberculosis on the delayed-type hypersensitivity reaction to sheep erythrocytes (SRBC) in mice was evaluated by means of delayed-type footpad swelling. Intraperitoneal (i.p.) injection with nonviable M. paratuberculosis into mice from 28 days before to 1 day after immunization with SRBC resulted in a significant suppression of foot-pad swelling to SRBC. The suppressive effect could be transferred by i.p. injection of spleen cells or peritoneal exudate cells from mice which had been pre-treated with nonviable M. paratuberculosis into non-treated recipient mice. The suppressive effect of spleen cells was retained even after passing them through a nylon wool column. The suppressive effect of spleen cells was abolished by treatment with anti-Thy 1.2 monoclonal antibody plus complement or anti-Lyt 2.2 monoclonal antibody plus complement. However, treatment of spleen cells with anti-mouse gamma globulin antiserum plus complement or anti-Lyt 1.2 monoclonal antibody plus complement did not affect the suppressive effect of spleen cells. The suppression of footpad swelling to SRBC induced by pre-treatment with nonviable M. paratuberculosis could be reversed by i.p. administration of cyclophosphamide. Serum antibody response to SRBC in mice was not affected by pre-treatment with nonviable M. paratuberculosis. These findings indicate that T cells appear to be involved in the suppression of delayed-type hypersensitivity reaction to SRBC in mice by pre-treatment with nonviable M. paratuberculosis.     

In vitro induction of suppressor cells by plasma of rats with Trypanosoma brucei rhodesiense infection

Mitogenic responses of B and T lymphocytes from spleens of rats infected with Trypanosoma brucei rhodesiense were suppressed. Plasma from infected rats suppressed the mitogenic responses of B and T lymphocytes from spleens of normal uninfected rats. Removal of immune complexes from plasma of infected rats significantly reduced the suppressive effect of the plasma on splenic lymphocytes of normal uninfected rats. Normal thymus cells treated with plasma from infected rats and added to cultures of normal spleen lymphocytes inhibited the mitogenic responses of B and T lymphocytes. We suggest that the interaction of immune complexes and Fc or C3b receptors of T lymphocytes resulted in the in vitro induction or activation of T suppressor lymphocytes.     

Study of the phenomenon of specific suppression of the immune response in an adoptive transfer system]

It was revealed that the administration of the spleen cells (SC) of syngeneic animals immunized with a high dose of sheep red blood cells (SRBC) to intact mice led to a marked specific suppression of the recipients' immune response. The donors' SC obtained on the 14th day after the intraperitoneal injection of SRBC had the greatest suppressive activity. The SC of intact animals and mice given rat erythrocytes preliminarily failed to influence the immune response of the intact recipients in their SRBC immunization. Treatment of immune SC with the anti-T-serum (ATS) or the anti-B-globulin (ABG) and the complement considerably decreased or completely eliminated the suppressive activity. Administration of a mixture of two immune SC suspensions one of which was ATS- and another ABC-treated did not produce any suppression of the immune response in the intact recipients. It is supposed that the suppressor cells in the given model were T-lymphocytes expressing the antigens, common of cross-reacting with the B-cells.     

Feedback suppression of the immune response in vivo. III. Lyt-1+ B cells are suppressor-inducer cells

We previously demonstrated that injection of a high dose (4 X 10(9] of sheep erythrocytes (SRBC) into C57BL/6 mice results in the generation of splenic B cells (plastic nonadherent, Thy-1- and Ig+) which, when transferred to normal syngeneic recipients, subsequently induce antigen-specific suppressor T cells to suppress the recipient's plaque-forming cell (PFC) responses to SRBC. In the present study we characterized the suppressor-inducer B cells phenotypically. Cytotoxic treatment of the donor's immune spleen cells with anti-Lyt-1 antibody plus complement (C'), but not with anti-Lyt-2 antibody plus C', relieved the suppression of PFC responses in recipients. The FcRr+ population separated by EA-rosette formation showed enriched suppressor-inducing activity, whereas the FcRr- population showed no activity. Our findings, taken together with the previous ones, suggest that suppressor-inducer cells are Thy-1-, Lyt-1+, Lyt-2-, FcRr+, and Ig+.     

Immune complexes and immunoconglutinin interactions associated with altered lymphocyte activity in Plasmodium chabaudi infections

Fresh plasma from rats infected with Plasmodium chabaudi, incubated with splenic lymphocytes from rats immunized 5 days previously with sheep blood cells, suppressed the capacity of the spleen cells to produce antibody against the sheep cells as was indicated by reductions in the numbers of hemolytic Jerne plaques formed by the treated cells. The effect was maximal in plasma of rats drawn on the 7th day of infection at a time the rats experienced a hemolytic crisis. Serologic studies indicated that the active plasma contained elevated titers of antibody against fibrinogen products, antibody against the soluble serum antigens elaborated during blood infections and antibody against the third component of fixed complement (C3) or immunoconglutinin. Titers of lytic complement were reduced and amounts of soluble immune complex precipitated with polyethylene glycol 6000 were elevated. The active plasma may have affected the antibody producing cells by one or both of two mechanisms. Soluble antigen-antibody complexes could have interacted with Fc receptors of activated lymphocytes to alter their function. Alternatively, the complexes may have fixed complement and interacted with receptors for fixed C3 on the lymphocyte membrane. Such cells, being coated with the antigen for immunoconglutinin, could be altered by immunoconglutination. Inasmuch as the immune complexes in the active plasma were generated in vivo, it would seem unlikely that the plasma would contain significant amounts of complex that had not fixed complement. With immunoconglutinin present in the plasma, alteration of the cells by immunoconglutination seems a more likely possibility.     

Adherent cells (macrophages?) in tumor-bearing mice suppress MLC responses

The spleens of mice bearing transplanted methylcholanthrene (MCA)-induced fibrosarcomas (MCA-1425 and MCA-1460) were shown to contain cells capable of suppressing the generation of cytolytic T lymphocytes (CTL) in mixed leukocyte cultures (MLC). The suppressive activity was first detected 21 days after tumor transplantation. No suppression was seen with lymph node cells taken at the same time as the spleen cells. The cells responsible for the suppressive activity were adherent to nylon wool and plastic dishes and they were not lysed by anti-T-cell serum plus complement. The suppressor cells were phagocytic and were resistant to irradiation (3000 rads) in vitro. Spleen cells from tumor-bearing nude mice were as suppressive as were spleen cells from tumor-bearing conventional mice. We conclude from these findings that T cells were not involved either as inducers or as effectors of the suppression observed, although the responsible adherent cells may have exerted their effect by interacting with a T-suppressor cell population in the MLC mixtures. While spleen cells of tumor-bearing mice were suppressive when added at any time during the first 4 days of a 5-day MLC, they showed no effect on the cytotoxicity of fully differentiated CTL. Indomethacin reversed suppression, suggesting that prostaglandins may have been involved.     

Macrophage-mediated suppression of immune responses in Toxoplasma-infected mice. I. Inhibition of proliferation of lymphocytes in primary antibody responses

The suppressor cells induced by Toxoplasma infection were shown to be macrophages, since they adhered to plastic, and their suppressive activity in anti-sheep erythrocytes (SRBC) antibody responses was abrogated by treatment with silica or carrageenan, which are selectively cytotoxic for macrophages. The suppressor macrophages strongly inhibited the uptake of tritiated thymidine ( [3H]TdR) by normal mouse spleen cells in the responses to SRBC and Toxoplasma antigens. Supernatant fluids from the suppressor macrophages could not passively transfer the suppressive effect on anti-SRBC antibody responses. Furthermore, when the suppressor macrophages were isolated by a cell-impermeable membrane from normal mouse spleen cells, the antibody responses of normal spleen cells were not suppressed. These results indicate that suppression of antibody responses in Toxoplasma-infected mice is caused by an inhibitory effect of the suppressor macrophages upon proliferation of lymphocytes via direct contact with responder target cells. The suppressive effect of the macrophages was not counteracted by indomethacin, a potent inhibitor of prostaglandin synthesis, or catalase, a catabolic enzyme for hydrogen peroxide (H2O2).     

Regulation of the cytotoxic effect of human ‘normal killer cells’ on tumor cell lines by neuraminidase-treated T-lymphocytes

Summary Subpopulations of peripheral blood lymhocytes (PBL) from healthy individuals were separated according to their capacity to form various rosettes and tested for their cytotoxic activity on cell lines of urinary bladder and breast carcinomas. The subpopulation exerting the highest natural cytotoxic activity was characterized by the presence of cell surface Fc-receptors and by the lack of receptors for sheep red blood cells and for C'3 on their surface. Treatment with vibrio cholera neuraminidase (VCN) increased the cytotoxicity of unseparated PBL to a level twice as high as that of untreated PBL. The attachment of T-lymphocytes to tumor monolayers was increased several fold after VCN-treatment, while the attachment of other lymphocyte subpopulations was not. Evidence is presented that the augmentation of the cytotoxicity of PBL following VCN-treatment results from the interaction of VCN-treated T-lymphocytes, attached to target cells, with normal killer cells. It is suggested that augmentation of the activity of killer cells by T-lymphocytes may play a role in antitumor defense mechanisms.Abbreviations CMC Cell-mediated cytolysis - E-rosettes Rosettes formed with sheep red blood cells - EA-rosettes Rosettes formed with red blood cells coated with antibody - EAC'-rosettes Rosettes formed with red blood cells coated with antibody and complement - FCS Heat inactivated fetal calf serum - PBL Peripheral blood lymphocytes - RBC Red blood cells - RF-TAL E-rosette forming, target-attached lymphocytes - SRBC Sheep red blood cells - VCN Vibrio cholera neuraminidase     

Proliferation of natural suppressor cells in long-term cultures of spleen cells from normal adult mice.

Natural suppressor cells were induced by culturing spleen cells from normal adult mice for 2 to 3 wk. The suppressor cells were large in size, nonadherent and nonspecifically suppressed the plaque-forming cells response of fresh spleen cells to SRBC in vitro. The suppressive activity of the cells was not affected by treatment with indomethacin or anti-Thy-1, anti-Ig, anti-Ia, or anti-asialoGM1 plus complement. Phenotype analysis by FACS showed that Thy-1, L3T4, Ly-2, CD3-epsilon, TCR-alpha beta, Ig, B220, Ia, and asialoGM1 Ag were all absent in the suppressor cells, although they were wheat germ agglutinin receptor positive. The suppressor cells did not demonstrate cytotoxicity against either YAC-1 or P-815 cells. Enriched large cell populations from fresh normal spleens expressed the same phenotypes and also exhibited the suppressive activity. These findings suggest that a minor population of natural suppressor cells exist in the normal adult mouse spleen and they proliferate during the in vitro culture of spleen cells.     

NK and T cell subsets regulate antibody production by human in vivo antigen-induced lymphoblastoid B cells

This study demonstrates the existence of two different suppressive systems for the regulation of antitetanus toxoid antibody production by human lymphoblastoid (LB) B cells. These B cells appear in the circulation 5 to 7 days after in vivo immunization and spontaneously secrete antibody during a 3-day in vitro culture. One suppressive system was mediated by large granular lymphocytes that exhibited high natural killer activity. This suppressive cell subset spontaneously inhibited the antibody production by autologous LB cells, and this effect could be enhanced by the addition of interferon. This inhibition of antibody synthesis could be readily reversed by the addition of as few as 10(2) K-562 cells to the culture. Additionally, the activity of this suppressive cell population could be reduced by complement (C)-mediated lysis with Leu-7 antibody. These results strongly suggest that this autologous suppression was mediated by NK cells. The other suppressor system was contained in the fraction of high density T cells depleted of Fc receptor-bearing cells, which was low in NK activity. This subset inhibited LB function in the presence of pokeweed mitogen but not interferon, and even the addition of up to 10(6) K-562 NK target cells only minimally reversed this inhibition. These results indicate that two distinct subsets of cells share regulatory functions on the in vivo induced B lymphoblastoid cells. The observation that NK cells can inhibit these highly differentiated B cells expands our view of the spectrum of natural targets recognized by NK cells.     

In vitro activation of suppressor cells from spleens of mice treated with radioactive strontium

Mice were treated with two 100-muCi injections of 89Sr to deplete marrow-dependent (M) cells. Mice so treated responded normally to immunization with sheep red blood cells (SRBC) in vivo; moreover, spleen cells from 89Sr-treated mice were able to respond to SRBC after infusion into irradiated recipient mice. However, spleen cells from mice treated with 89Sr did not respond to SRBC in vitro and mixtures of normal spleen cells with the latter were also not able to respond in vitro. The discrepancy between in vivo and in vitro responses was abolished by culturing spleen cells for 24 hr before testing their ability to respond to SRBC in the adoptive transfer in vivo. Pretreatment of spleen cells from 89Sr-treated mice with 1000 R of gamma-radiation lessened their suppressive activity. The suppressor cells were detected in spleens of athymic nude mice treated with 89Sr. The suppressive activity, after the 24-hr culture period, was not abolished by irradiation and was active in vivo as well as in vitro. Thus, depletion of M cells by 89Sr results in the appearance within the spleen of thymus-independent suppressor cells, which require a short period of in vitro cultivation before becoming functionally active.     

Nonspecific suppressor elements in murine allogeneic radiation chimeras.

Spleen cells from long-term mouse allogeneic radiation chimeras were tested for their ability to modulate the graft-versus-host (GVH) or plaque-forming cell (PFC) response of normal lymphocytes transplanted in lethally X-irradiated recipients. In vivo GVH proliferation of normal lymphocytes (syngeneic to donor cells of the chimera) against antigens of host-type in which the chimeric state had been established was reduced by chimera cells. Inhibition varied, some chimeras suppressing GVH more than others and a few not suppressing at all. The suppressive effect was abrogated if the chimera cells were treated with anti-θ; treatment with anti-IgM did not eliminate this activity. When mixtures of normal donor lymphocytes and chimera cells were given to irradiated recipients genetically different from host or donor, reduction of donor cell GVH also occurred. Further, chimera cells reduced the GVH activity of normal host cells in irradiated recipients differing from the host at one H-2 locus and from the donor at minor histocompatibility loci. The modulating effect of spleen cells from chimeras on the PFC response by normal lymphocytes also varied. Six chimeras induced a 25 to 90% suppression, two enhanced the response, and one showed no effect. Where suppression occurred, treatment of chimera cells with anti-θ most often, but not always, restored PFC production. Our results show that the suppressive action of splenic lymphoid cells by chimeras is highly nonspecific and variable in expression. We suggest that tolerance in chimeras may be mediated by nonspecific suppressor elements leading to unresponsiveness to a variety of antigens including SRBC.     

Immunologic suppression after oral administration of antigen. I. Specific suppressor cells formed in rat Peyer's patches after oral administration of sheep erythrocytes and their systemic migration.

Rats given 10(10) sheep erythrocytes (SRBC) orally were found to contain specific suppressor cells to SRBC in their Peyer's patches (PP) and mesenteric lymph nodes (MLN) after 2 days of feeding. After 4 days of feeding, similar suppressor cells were found in the thymus and spleen, but they were missing in the PP or MLN. These suppressor cells effectively blocked IgM and IgG plaque-forming cell responses to SRBC in Mishell-Dutton cultures and delayed-type-hypersensitivity responses to SRBC when transferred to syngeneic recipients, but they did not affect responses to horse erythrocytes. The orally induced specific suppressor cells appeared to be T2 cells since their activity was eliminated by in vivo treatment of SRBC-fed rats with anti-rat lymphocyte serum but not by adult thymectomy. Because carrageenan partially relieved the suppression observed in culture, the actual suppressive mechanism may also involve a macrophage.     

Protection of peritoneal macrophages by granulocyte/macrophage colony-stimulating factor (GM-CSF) against dexamethasone suppression of killing of Aspergillus, and the effect of human GM-CSF

Murine peritoneal macrophages in vitro could kill Aspergillus fumigatus conidia, and this activity could be suppressed with dexamethasone. Treatment with granulocyte/macrophage colony-stimulating factor (GM-CSF) alone did not boost killing, but GM-CSF treatment concurrently with dexamethasone reversed the dexamethasone suppression. Both recombinant human and recombinant murine GM-CSF were equivalent in this activity, even though the human reagent reportedly does not stimulate differentiation of murine stem cells. Recombinant human GM-CSF could also reverse dexamethasone suppression of bronchoalveolar macrophage conidiacidal activity. Sequential studies with peritoneal macrophages indicated that recombinant human GM-CSF pretreatment also blocked dexamethasone suppression, but the GM-CSF treatment given after dexamethasone did not block the suppressive effect. Recombinant human GM-CSF did not boost spleen cell proliferation to a mitogenic stimulus, and did not reverse dexamethasone suppression of proliferation. These studies suggest GM-CSF treatment prior to and concurrent with steroid immunosuppression may ameliorate the steroid effect on tissue macrophage antifungal activity, but does not affect steroid suppression of T-cell immunity.     

The influence of phase shift in the light-dark cycle on humoral immune responses of mice to sheep red blood cells and polyvinylpyrrolidone

The influence of a phase shift in the light-dark cycle on humoral immune responses against sheep red blood cells (SRBC), a thymus-dependent antigen, and against polyvinylpyrrolidone (PVP), a thymus-independent antigen, was studied by using 180 BALB/c mice and 150 C3H/HeN mice. Significant suppression of the immune response to SRBC and the number of splenic plaque-forming cells (PFC) and hemagglutination (HA) titers was observed on days 5 and 6 after inversion of the light-dark cycle. On the other hand, the number of splenic PFC and HA titers in the blood against PVP were minimally suppressed by the phase shift in C3H/HeN mice, except for distortion of the rhythmicity. Corticosterone levels in the blood on days 5 and 6 after inversion were higher than those under a normal lighting regimen. The appearance of the high corticosterone level in the blood after the inversion almost concurred with the suppression of the immune response to SRBC. A decrease of the proportion of splenic T cells was also observed on day 6 after the inversion. These results show that a phase shift in the light-dark cycle provokes suppression of the immune response to SRBC, possibly through an increase of secretion of corticosterone after light-dark inversion, which induces a decrease of the proportion of T lymphocytes in the spleen.     

Cellular interaction against autologous tumor cells between IL-2-cultured lymphocytes and fresh peripheral blood lymphocytes in patients with breast cancer given immuno-chemotherapy

In patients with Stage II or III breast cancer and in patients with liver metastases from breast cancer, we examined cellular interaction in the cytotoxicity against autologous tumor cells by interleukin-2(IL-2)-cultured lymphocytes (CL) and fresh peripheral blood lymphocytes (FPBL) treated with immunochemotherapy including OK-432 and cyclophosphamide. In flow cytometric analysis, CD8 + CD11b+ and CD16+ cells significantly decreased after immuno-chemotherapy in both groups of patients. A protocol study in Stage II or III breast cancer patients showed suppressive activity of FPBL on the cytotoxic activity of CL in 3/9 of the non-treatment group but no suppressive activity and enhancing activity in 3/7 in the immuno-chemotherapy group. Moreover, in 19 patients with liver metastases from breast cancer treated with immuno-chemotherapy including adoptive immunotherapy, FPBL in 6/19 showed enhancing activity, and in 8/19 suppressive activity in the lysis of autologous tumor cells. In assaysin vitro using autologous and allogeneic tumor cells, FPBL showed a partial specificity in cellular interaction against autologous tumor cells. CD4-depleted FPBL inhibited cytotoxicity of CL, while CD8-depleted FPBL enhanced cytotoxicity of CL in patients with liver metastases. These results suggest that immuno-chemotherapy eliminates the suppressive population in FPBL and may induce tumor regression if combined with adoptive immunotherapy using CL.Abbreviations IL-2 interleukin-2 - CL IL-2-cultured lymphocytes - FPBL fresh peripheral blood lymphocytes - AIT adoptive immunotherapy     

Immune parameters of untrained or exercise-trained rats after exhaustive exercise

The effect of a single exhaustive swimming exercise bout on immune competence of untrained or exercise-trained female Wistar rats was compared with the competence of control sedentary rats. After the exhaustive exercise bout, the blastogenic response to concanavalin A by spleen cells of untrained rats was extensively suppressed, whereas the response of the trained rats was only marginally suppressed. The suppressed immune competence of the untrained rats after the exhaustive exercise was associated with an increase in immune-suppressive activity of splenic lymphocytes. The macrophages of the untrained rats and of the control sedentary rats were slightly immune suppressive to normal spleen cells through a prostaglandin-dependent mechanism. The addition of prostaglandin E2 (PGE2) to the blastogenesis cultures revealed that the spleen cells of untrained rats were unusually sensitive to the suppressive effects of PGE2. In contrast to the untrained rats, the marginal level of immune suppression in trained rats after the exhaustive exercise was associated with a lesser degree of lymphocyte-suppressive activity, an immune stimulatory activity by the splenic macrophages, and an insensitivity of the splenic lymphocytes to the suppressive effects of PGE2.     

Inhibition of T-lymphocyte rosetting by HL-A alloantisera and complement.

The relationship between HL-A antigens and rosetting of sheep red blood cells (SRBC) with peripheral human lymphocytes has been investigated by incubating them with HL-A antibodies. Although sensitizing the lymphocytes with HL-A alloantisera had no effect on their ability to form rosettes with SRBC, further sensitization with C6 deficient rabbit serum as a source of early complement components inhibited the formation of rosettes with SRBC. The involvement of HL-A alloantibodies in the inhibition of rosette formation was shown first by correlating the HL-A phenotype of the lymphocytes and the HL-A specificity of the alloantisera and, second, by specifically absorbing the HL-A alloantibodies from the alloantisera. Complement was needed to inhibit rosette formation since this effect was lost when rabbit serum was treated to inactivate complement. The participation of complement's classical pathway in rosette inhibition was shown by chelating the Ca2+ ions by EGTA treatment of the C6 deficient rabbit serum. Perhaps, binding of HL-A antibodies and early complement components to the lymphocyte surface disturbs the distribution of the receptors or affects the charge of the cell membrane, thus inhibiting the rosette formation with SRBC.