Cellular mechanisms of suppression of T-lymphocyte proliferation by lung cells in experimental tuberculosis]

The ability of interstitial lung cells from mice, infected with Mycobacterium tuberculosis H37Rv, to suppress proliferative responses of immune lymphocytes to mycobacterial (PPD) and unrelated (Staphylococcus aureus cytoplasm) antigens was studied. Two types of suppression were observed: the specific one, which was characteristic of the PPD-response only; and non-specific. The latter was mediated mainly by prostaglandins, since it could be abolished by indomethacin. Both types of suppression depended on the presence of plastic and nylon wool adherent phagocytes from infected lung. Though the depletion of T or B lymphocytes from the lung cell population have not abrogated the suppressive effect, some intercellular interactions were required for antigen-specific suppression, since the presence of nylon wool adherent cells in the population of responder lymph node cells was necessary for its development.     

Suppression of parasite antigen-specific lymphoid blastogenesis in African trypanosomiasis

Inbred C57BL/6J mice were infected with either Trypanosoma rhodesiense organisms of Walter Reed Army Trypanozoon antigenic type 3 or 5 (WRATat 3 or WRATat 5) or were immunized with soluble trypanosomal antigens. Spleen cells obtained from immunized hosts undergo blastogenesis, measured by thymidine incorporation, when exposed to trypanosomal antigens in vitro. Spleens obtained from mice infected with T. rhodesiense organisms do not respond or respond only minimally to trypanosomal antigens in vitro. Spleen cells of infected mice suppress the trypanosomal antigen-induced proliferative response of spleen cells from immunized mice in co-culture experiments. The suppressive activity was found in both the plastic adherent and plastic nonadherent spleen cell populations. The in vitro responses of normal spleen cells to LPS and Con A were also suppressed by spleen cells obtained from infected mice.     

Trypanosoma cruzi-induced suppression of IL-2 production. II. Evidence for a role for suppressor cells

Suppression of IL-2 production during experimental Chagas' disease accounts at least in part for the overall depressed state of the immune system in infected mice. The failure to produce IL-2 in response to mitogen stimulation is not the result of the lack of cells capable of producing IL-2, but appears to be due to regulation of IL-2 production by suppressor cells. This conclusion is supported by cell-mixing experiments where the ability of cells from infected mice to suppress normal spleen cell IL-2 production is evident. Although depletion of plastic and Sephadex G-10 adherent cells results in modest increases in IL-2 production by spleen cells from infected mice, even in the presence of normal adherent cells as a source of IL-1 producers, IL-2 production does not approach normal levels. Also, isolated macrophages are not by themselves suppressive for normal spleen cell IL-2 production, whereas plastic and G-10 nonadherent cells from infected mice are. Depletion of Thy-1+ and Ly-2+ cells not only completely abrogates the ability of spleen cells from infected mice to suppress normal IL-2 production, but results in a cell preparation which actually enhances IL-2 production. Anti-Ly-2 and C treatment of infected spleen cells also markedly enhances their ability to produce IL-2. These results indicate a major role for Ts cells in the regulation of IL-2 production, and a relatively minor role of macrophages as direct effector cells of suppression in this response. The ability to enhance IL-2 production in this system with PG synthesis inhibitors suggests a role for PG-producing cells such as macrophages in the suppressor mechanism, perhaps as inducers of the suppressor effector cells.     

The role of adherent cells in the secondary cell-mediated response in vitro to a natural poxvirus pathogen.

The role of adherent cells in an in vitro secondary response to ectromelia virus infection was investigated. Spleen cells from ectromelia-primed mice ("responder" cells) depleted of adherent cells by either carbonyl iron treatment, adherence to plastic or passage through cotton wool columns had a markedly decreased capacity to produce a secondary response, as indicated by decreased T cell-mediated cytotoxicity against virus-infected target cells, when cultured with virus-infected "stimulator" cells. The secondary response was restored by the addition of peritoneal cells from either normal or ectromelia-immune mice. Small numbers of peritoneal cells completely reconstituted the response within a certain dose range but larger numbers produced a marked inhibition of the response. Spleen cells were less effective in restoring the response. The peritoneal cells were not merely acting as additional, infected "stimulator" or antigen-presenting cells, since they could be added as late as 3 days after culture. Reconstituting activity was not affected by pretreatment with anti-theta serum and complement and cell separation studies showed that the activity was associated mainly with Ig-negative cells and that the active cell probably bears Ia antigens on its surface. These results indicate that the adherent cells involved are probably macrophages and that they act non-specifically to produce optimum conditions for the specific response of T cells.     

Suppressor cells in mice infected with Trypanosoma brucei.

Within 2 to 3 days of infection with Trypanosoma brucei strain S42, the ability of spleen cells from infected CBA mice to mount a primary in vitro antibody response to sheep red blood cells (SRBC) is profoundly reduced, and suppressor cells are generated as detected by cell mixture experiments. Suppressor cell activity lies in the T and adherent cell compartments of spleens from infected mice, but not in the B cell compartment, although antibody responses to a thymus-independent antigen, DNP-Ficoll, are significantly reduced. Suppression of antibody responses of normal spleen cells depends on viable cells from infected mice. The trypanosome, itself, plays no direct role in suppression, and we have ruled out the possibility of antigenic competition as a mechanism of suppression. Our data is consistent with the model of suppressor T cells induced by concanavalin A mitogenesis. We hypothesize that trypanosome antigens may directly stimulate T cells with the concomitant release of factors with affinity for macrophage surfaces thus becoming suppressive for T and B cell responses.     

The mouse mutant "motheaten." II. Functional studies of the immune system.

Motheaten mice have normal levels of T lymphocytes but reduced levels of B lymphocytes. Those B cells that are present show an impaired proliferative response to B cell mitogens and no plaque-forming cell response to thymus-independent antigens. T lymphocyte function is also defective in motheaten mice, as assayed by the proliferative responses to T cell mitogens, and by the capacity to develop cytotoxic killer cells against allogeneic cells. Motheaten mice possess spleen cells capable of suppressing normal B cell responses to thymus-independent antigens. This suppressor cell is not sensitive to anti-Thy-1 antibody plus complement treatment but is partially removed by adherence on plastic. Overall, the motheaten mouse suffers a functional severe combined immunodeficiency of both B and T cells, even though these cells are present. We postulate that the inescapable lethality of the motheaten defect is due to the lack of immunocompetence during the critical developmental period before adulthood and perhaps to an autoaggressive component as well.     

Primary type II alveolar epithelial cells present microbial antigens to antigen-specific CD4+ T cells

Type II alveolar epithelial cells (AEC) can produce various antimicrobial and proinflammatory effector molecules. This, together with their abundance and strategic location, suggests a role in host defense against pulmonary pathogens. We report that murine type II AEC, like their human counterparts, express class II major histocompatibility complex (MHC). Using a murine model of pulmonary tuberculosis, we find that type II AEC become activated and have increased cell surface expression of class II MHC, CD54, and CD95 following infection. Type II AEC use the class II MHC pathway to process and present mycobacterial antigens to immune CD4+ T cells isolated from mice infected with Mycobacterium tuberculosis. Therefore, not only can type II AEC contribute to the pulmonary immunity by secreting chemokines that recruit inflammatory cells to the lung, but they can also serve as antigen-presenting cells. Although type II AEC are unlikely to prime na?ve T cells, their ability to present antigens to T cells demonstrates that they can participate in the effector phase of the immune response. This represents a novel role for type II AEC in the immunological response to pulmonary pathogens.     

Interleukins 1 and 2 production and responsiveness in the early stages of retroviral infections of mice

Infection of BALB/c mice with the Friend leukemia complex (FLC) or its helper F-MuLV produced no major changes of IL 1 production and responsiveness but caused profound derangements of IL 2 homeostasis. IL 2 production by spleen cells was severely decreased from the early stages postinfection (pi). By Day 8 the effects of the two viral preparations were similar. Reminiscent of the kinetics of immunosuppression produced by the two viruses, subsequently the effects diverged: in the case of FLC, IL 2 accumulation became progressively lower, while F-MuLV-infected spleen cells produced approximately half the normal levels of IL 2 irrespective of time pi. At Day 8 pi unstimulated spleen cells absorbed enhanced amounts of IL 2, but failed to proliferate in response to it. Unfractionated and adherent spleen cells from infected mice (but not cell-free virus or culture fluids) inhibited the proliferative response of CTLL-2 cells to IL 2, suggesting a "suppressor" function for infected macrophages. Exogenous IL 2 failed to bring in vitro antigen or mitogen responsiveness of infected spleen cells to the levels seen with control cells and did not affect FLC-induced leukemogenesis in vivo.     

Suppressor cells in tumor-bearing mice capable of nonspecific blocking of in vitro immunization against transplant antigens.

Spleen cells from mice with progressively-growing methyl-cholanthrene-induced tumors, when immunized in vitro against transplant alloantigens, developed less cytotoxic activity against these antigens as measured by a short-term chromium-release assay than did spleen cells from normal mice. The hyporesponsiveness of spleen cells from the tumor-bearing mice seemed to be due to the presence of suppressor cells which could be removed by nylon-column passage but not by anti-theta treatment and which, in mixture experiments, could inhibit the response of normal spleen cells. The suppression appeared to occur at the sensitization stage and not at the effector stage of the in vitro tests. No evidence was found for mediation of the suppression by soluble factors. These observations emphasize the growing importance of suppressive mechanisms in tumor immune systems.     

In vitro sensitization of human lymphocytes against histiocytic lymphoma cell lines. III. The activity of culture-induced suppressor cells.

Normal PBL were sensitized in vitro against an allogeneic diffuse histiocytic lymphoma cell line and their activity was measured by radiolabel release from target cells. We have reported earlier that a non-T cell population, found among the PBL, was responsible for inhibiting in vitro sensitization. In the present work we found that culturing PBL in vitro caused the induction of radioresistant suppressor cells which affected the sensitization phase of the in vitro response. The culture-induced suppressor cells had macrophage-like characteristics. The activity of the suppressor cells depended on an additional helper population that was adherent to nylon wool, but did not adhere to plastic and was non-phagocytic. The cooperation of these two different cell populations was required for the expression of suppressive activity.     

Trypanosoma cruzi: Responses by cells from infected mice to alloantigens

In unidirectional mixed lymphocyte cultures containing (as responders, stimulators, or regulators) spleen cells from mice infected with Trypanosoma cruzi, alloantigen responses were less than in cultures containing normal spleen cells only. Depletion of plastic adherent cells from infected spleen cells (stimulators or regulators) reversed their inhibitory effect on normal spleen cells (responders); removal of adherent responder cells and/or B lymphocytes did not alter the low alloantigen responses of normal spleen cells (stimulated by infected spleen cells) or infected spleen cells (stimulated by normal spleen cells). Infected spleen cells were effective in regulating mixed lymphocyte cultures only when added at the initiation of the culture. Serum from infected mice suppressed mixed lymphocyte cultures containing responder spleen cells syngeneic to the serum donor if added up to 24 hr after initiation of cultures, whereas the “suppressor serum” had to be present at the initiation of cultures when responder cells were allogeneic to the serum donor. Cultures of infected spleen cells (whole or macrophage enriched) produced a factor which was suppressive when added to mixed lymphocyte cultures containing syngeneic responder cells at initiation. It is proposed that the serum suppressor substance regulates cell-mediated immune responses directly by suppressing the response-potential of cells and indirectly by triggering the release of a factor from adherent splenic cells which induces a hyporesponsive state in T lymphocytes.     

Non-specific immunosuppression by Cryptococcus neoformans infection

Cryptococcus neoformans-infected animals were found to be immunosuppressed when tested by a variety of assays for immune competence. Primary humoral immune responses and delayed-type hypersensitivity reactions to sheep erythrocytes were suppressed in animals which had been infected for two weeks. Lymphocyte proliferation (LP) assays to sRBC stroma were also significantly diminished at two weeks of infection. Spleen cells of infected mice suppressed the LP response of sRBC immunized, normal mice in vitro. At least a part of the suppression could be attributed to a nylon wool non-adherent cell. Suppressor cells continued to be present in spleen cell suspensions following treatment with anti-T cell serum or anti-immunoglobulin and complement. When infected spleen cells were separated by adherence to plastic, both the adherent and non-adherent fractions exhibited suppressive activity. Incubation of infected spleen cells in tissue culture for 48 hr resulted in the elaboration of soluble immunosuppreessive factors into the tissue culture medium. These data indicated that immune suppression in cryptococcosis can occur as a result of infection with Cryptococcus neoformans, and that at least one mechanism involved is the induction of adherent and non-adherent suppressor cells in the spleens of infected mice.     

Possible mechanism of the preventive effect of BCG against diabetes mellitus in NOD mouse. I. Generation of suppressor macrophages in spleen cells of BCG-vaccinated mice.

With the aim of clarifying the mechanism of the suppressive action of BCG against insulitis and overt diabetes in NOD mice, we studied the effects of BCG on spleen cell populations and on the in vitro immune responses of spleen cells. The spleen cells of BCG-vaccinated mice showed much lower responsiveness to various mitogens such as Con A, PHA, PWM, and LPS than those of saline-treated mice. Low responsiveness to alloantigens was also observed. Flow cytometric analysis of the spleen cells revealed that Mac-1+ and Mac-2+ cells had increased while T and B cells had decreased in the BCG-vaccinated mice compared with the saline-treated mice at the time when the maximum level of inhibition of mitogen responses of BCG-vaccinated mice was observed. This suggests that the decreased in vitro immune response was due to the increase in macrophages which suppress lymphocyte functions. Support for this interpretation comes from the following two findings: (1) the restoration of mitogen responses of spleen cells when macrophages were eliminated by plastic adhesion or FACS sorting and (2) resuppression of PHA and Con A responses of plastic-nonadherent spleen cells by addition of adherent cells or flow cytometrically sorted Mac-1+ cells obtained from BCG-vaccinated mice. These results indicate the generation of suppressor macrophages after BCG vaccination and suggest that these macrophages prevent the autoimmune pathogenesis leading to diabetes in NOD mice.     

Selective impairment of B cell function by Neisseria meningitidis

Spleen cells from CBA/J mice infected with Neisseria meningitidis displayed depressed in vitro plaque-forming cell (PFC) responses to T-dependent (sheep red blood cell; SRBC) and T-independent (TNP-LPS, TNP-Ficoll) antigens. The inhibition was observed over a wide range of antigen concentrations. The decreased responsiveness of splenocytes from infected mice was due to a selective impairment of B-cell function since helper-T-cell activity was intact in infected mice as shown by the ability of T-enriched lymphocytes to cooperate with normal B-enriched lymphocytes in the generation of an anti-SRBC response, accessory macrophage function was preserved since adherent spleen cells from bacteria-injected mice were shown to produce normal or increased levels of IL-1 and were able to cooperate with normal non-adherent spleen cells in the generation of PFC against SRBC. Addition of peritoneal cells from normal animals or extraneous IL-1 both failed to restore normal PFC responses in cultures of splenocytes from infected mice. Finally, B-enriched lymphocytes from infected mice produced poor anti-SRBC responses when cultured with either Con A supernatant or T-enriched lymphocytes from normal or infected mice. Cell-mixing experiments failed to detect the presence of suppressor cells in cultures of unfractionated spleen cells or B-enriched lymphocytes from infected mice. Therefore, the immunological unresponsiveness associated with a Neisseria meningitidis infection was attributed to a meningococcus-induced defect(s) in B-cell function. In vivo polyclonal B-cell activation leading to clonal exhaustion did not play a major role in the depression of humoral responses since meningococcal infection induced little or no polyclonal Ig secretion.     

Suppression of responses to cryptococcal antigen in murine cryptococcosis

Subpopulations of spleen cells responsible for responsiveness and unresponsiveness to cryptococcal antigen in vitro were identified. Lymphocytes which responded in lymphocyte transformation (LT) assays were nylon wool nonadherent and theta antigen positive. These lymphocytes required the presence of an accessory cell which could be supplied by normal peritoneal exudate cells. Spleen cells taken from mice which had been infected for 3 to 15 days were tested to determine their ability to respond to cryptococcal antigen in LT assays. A minimal response was detected at the ninth day of infection. The response of infected spleen cells was attributed to a nonadherent lymphocyte. Nonadherent spleen cells of infected animals had enhanced responses after removal of adherent cells and addition of normal peritoneal exudate cells. Suppressor cells were detected in the spleens of infected mice by the 12th day of infection and thereafter. A nonadherent suppressor cell was identified, but indirect evidence suggested that an adherent cell could also be present in infected spleens.     

Characterization of accessory cell function during acute infection of BALB/cByJ mice with mouse hepatitis virus (MHV), strain JHM.

Earlier studies revealed defective concanavalin A-stimulated proliferation and cytokine production by spleen cells derived from BALB/cByJ mice acutely infected with mouse hepatitis virus (MHV), strain JHM. Based on those observations, assays of in vitro antigen-presenting cell (APC) function were undertaken. APC function of unfractionated spleen cells from individual MHV-infected mice was highly variable. Experiments using pooled spleen cells derived from MHV-infected mice revealed that adherent spleen cell APC function was impaired to a much greater degree than B cell APC function. Adherent cells derived from peritoneal exudates of infected mice exhibited an APC defect that was similar in magnitude to that observed for splenic adherent cells. Splenic B cells derived from acutely infected BALB/cByJ mice harbored infectious MHV. In contrast, lysates of adherent spleen cells from acutely infected mice did not kill intracerebrally inoculated neonatal mice, but did induce seroconversion among all survivors. Despite impairment of APC function of cells derived from MHV-infected donors, neither indomethacin nor accessory cells from uninfected control mice restored concanavalin A-induced proliferative responses of spleen cells collected from acutely infected mice. These results and those of earlier studies suggest that, although APC function is impaired, in vitro T cell dysfunction exhibited by spleen cells from MHV-JHM-infected donors is probably related to an inherent proliferative defect subsequent to T cell activation. Defective concanavalin A-stimulated proliferation does not appear to be secondary to accessory cell function suppression or to inhibitory factors secreted by accessory cells.     

Regulation of the immune response to tumor antigens. IX. In vitro Lyt-1+2- cell proliferative responses to cellbound or subcellular tumor antigen

We investigated the cellular basis of immune reactivity to the S1509a fibrosarcoma in tumor-immune A/J mice. In a Winn assay, immune Lyt-1+2- T cells are capable of retarding S1509a tumor growth in naive A/J mice. In vitro proliferation to S1509a is also mediated by tumor-immune Lyt-1+2- T cells. This response is specific to the immunizing tumor and appears 5 to 7 days after reexposure to the tumor in vivo. Proliferation also requires the presence of a population of adherent cells. In fact, adherent peritoneal exudate cells pulsed with tumor membrane fragments derived from S1509a cells can stimulate proliferation. Proliferation is blocked by the addition of anti-I-Ak monoclonal antibody to the culture medium without complement or by treatment of the responder population with anti-I-Ak and complement. In vitro responsiveness is also inhibited by the presence of tumor-specific suppressor T cells in vivo. These observations suggest in vitro proliferation may provide a potential means of defining tumor antigens and cell-surface structures involved in tumor immunity.     

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.     

A virus-sensitive suppressor cell is involved in the regulation of human allospecific T cell-mediated cytotoxicity

The in vitro generation of allospecific CTL by human PBMC was enhanced 4- to 16-fold by sequential plastic and nylon wool adherence, which depleted the PBMC of macrophages and B cells. The enhanced CTL response was suppressed by adding back irradiated, unfractionated PBMC or adherent cells to the depleted cells. This finding suggests that the enhanced CTL response was not simply a consequence of enrichment of T cells, but was instead due to active suppression by radioresistant cells contained in the adherent fraction. Of note is the finding that, unlike the CTL response, the proliferative response to allostimulation was not affected by the removal of adherent cells. The suppressor function could be abrogated by preincubation of irradiated PBMC with influenza A virus before the coculture with depleted cells. Furthermore, costimulation of unfractionated PBMC with influenza A virus and allogeneic stimulators augmented allospecific CTL activity. Thus, in the adherent fraction of human PBMC, there appears to be a native suppressor population that can be functionally inactivated by virus. This result may account for the clinical observation of increased allograft rejection after certain viral infections.     

The regulatory effect of histamine on the immune response: characterization of the cells involved

Any immunological response is the end result of the equilibrium between many positive and negative regulatory factors. It has been recently demonstrated that histamine receptor-bearing T lymphocytes could play a role in this regulation. This work aims to study the effects of different cell populations after incubation with histamine on the proliferative response of normal lymphocytes. The histamine-incubated peripheral blood lymphocytes (PBL) lower the proliferative response of normal cells toward mitogens (phytohemagglutinin, concanavalin A) and antigens (mixed lymphocyte culture). In order to precise the cell subpopulations involved in this suppression, PBL have been depleted of adherent cells and B and T lymphocytes have been purified by a standard rosette technique. The enriched B cells do not suppress the normal response but the suppressor activity of T cells, as well as adherent cell-depleted PBL, are significantly reduced compared to the one of PBL. The initial suppressor activity is restored by addition of 1% adherent cells (and not 5 or 10%) to adherent cell-depleted lymphocytes and 10% adherent cells (not 1 or 5%) to T-enriched population. These observations suggest a role for adherent cells in this regulation.