Role of interleukin 1 in experimental pulmonary granuloma in mice

Pulmonary granulomas were induced in immunized BALB/c mice by the intratracheal injection of antigen-coated and plain agarose beads. Prominent lesions developed within 24 hr, reached peak intensity within 3 days, and gradually declined in size thereafter. The hypersensitivity granulomas induced in sensitized mice by antigen-coated beads were much larger than the lesions induced by plain beads. Minimal inflammation was produced in unsensitized mice injected with antigen-coated or plain beads. Aqueous extracts prepared from pulmonary granuloma lesions induced in sensitized mice by antigen-coated beads contained high levels of interleukin 1 (IL 1) and migration inhibition factor (MIF) activities. The kinetics of appearance of these mediators were similar. Lower but detectable activity of both mediators was detected in extracts prepared from sensitized mice injected with plain beads. Neither interleukin 2 (IL 2) nor IL 2 neutralizing activities were detected in the extracts. The presence of IL 1 and MIF in extracts prepared from early and peak pulmonary granulomatous lesions suggests that these soluble factors are produced by cells within the lesions, and that they are involved in mediating the expression and/or maintenance of the granulomas.     

Antigen-nonspecific and specific suppression of lymphokine production in desensitized guinea pigs

Doubly immunized guinea pigs may be desensitized with respect to delayed hypersensitivity reactions against both antigens (anergy) by injection of large doses of either one. This anergic response therefore has both a specific and nonspecific component. The specific component of desensitization persists longer than the nonspecific one. In the present study, we have explored the mechanism of both antigen-specific and antigen-nonspecific suppression during the later stages of desensitization. Guinea pigs immunized with two antigens, DNP-KLH and DNP-EA, were desensitized with DNP-EA. The lymph node cells obtained from the animals 1 day after desensitization were unable to produce MIF in the presence of either antigen. The cells obtained 3, 5, and 7 days after desensitization were able to generate MIF when stimulated with the non-specific antigen (DNP-KLH), but not with specific antigen (DNP-EA). It was shown that both T- and non-T-cell fractions obtained 1 day after desensitization had the capacity to antigen-nonspecifically suppress MIF production. In contrast, if the cells were obtained 3 or 5 days after desensitization, T cells could inhibit only the antigen-specific production of MIF, while non-T cells were still capable of suppressing antigen-specific and nonspecific MIF production. Interestingly, when these two populations were mixed back again, it was now only suppressive to the specific antigen-induced MIF production. This latter observation indicates that nonspecific suppressor non-T cells may themselves be regulated by suppressor T cells. Furthermore, antigen-specific suppressor T cells were shown to produce soluble factor(s) which inhibited the production of MIF.     

Subpopulations of splenic T and B lymphocytes producing and regulating leukocyte adherence inhibition factor

Picryl chloride induces contact hypersensitivity in mice, accompanied by spleen cell sensitization that is demonstrable in vitro by specific antigen-induced formation of leukocyte adherence inhibition factor (LAIF). This cellular activity was detected only up to 7 days after sensitization; thereafter the spleen cells appeared to be unreactive with the antigen. The cells were still normally reactive with the mitogen concanavalin A. Antigen reactivity of such “late” cells was restored by passage through a glass-bead column (provided resulting nonadherent cells were reconstituted with normal macrophages), and the restored reactivity was again suppressed by the eluted glass-bead-adherent cells. Suppression was antigen specific. Separation of T and B lymphocytes by affinity chromatography, after glass-bead treatment of sensitized spleen cells, showed that two subpopulations of B cells—those responsible for producing LAIF as well as those suppressing LAIF production by T cells—were glassbead adherent. This was extended by showing directly with anti-Thy-1.2 serum that B cells producing LAIF and suppressor T cells were glass adherent. Thus two suppressive cell populations, and the B cell producing LAIF, were glass adherent while the T-cell LAIF producer was not. Tests for adoptive transfer of cutaneous hypersensitivity in vivo demonstrated the relevance of many of the above observations to conditions in the whole animal. “Late” spleen cells from sensitized mice could not transfer hypersensitivity but this property was restored by glass-bead passage. The eluted adherent cells suppressed transfer. Both adoptive transfer and its suppression were antigen specific.     

Desensitization of contact allergy to DNFB in mice. I. Description of a model system

We investigated the down-regulation of contact sensitivity (desensitization) in mice sensitized to DNFB. Mice were sensitized with DNFB, desensitized with antigen 2 wk later, and resensitized 2 wk after desensitization. Large doses of antigen (DNFB or DNBSO3) produced about 50% inhibition of the anamnestic response as measured by ear swelling after challenge with DNFB. Desensitization was antigen specific and long lasting. Lymph node cells from desensitized mice showed diminished antigen-induced proliferation in vitro. Although the anamnestic response can be inhibited by afferent- or efferent-acting suppressor cells, such suppressor cells were not demonstrated in desensitized animals. The most likely explanation is that antigen desensitizes by inactivating effector cells for contact sensitivity, although suppressor mechanisms have not been completely excluded.     

Desensitization V: Suppression of MIF production by lymphokine-activated macrophages

The systemic injection of high doses of antigen into a previously immunized animal results in a state of transient anergy with respect to cell-mediated immune reactions. This phenomenon is known as desensitization. We have previously shown that desensitization is a multistage process. The initial 24-hr period is characterized by excessive lymphokine production with a failure to express delayed hypersensitivity reactions due to abolition of local chemotactic gradients. Subsequent stages of desensitization involve failure of lymphokine production in vivo. The results presented here demonstrate that lymphocytes obtained from immunized and desensitized animals later than 24 hr after desensitization are markedly suppressed in their ability to produce MIF. In addition, it was found that lymphokine-activated macrophages can suppress in vitro MIF production by lymphocytes from immune, nondesensitized animals. In vitro and in vivo activation of macrophages were equally effective. Thus, it is likely that at least one mechanism for the inhibition of lymphokine production in the post-24-hr period of desensitization, involves activation of a population of suppressor macrophages by lymphokines produced during the initial 24-hr period.     

Antigen-specific immune-suppressor factor in herpes simplex virus type 2 infections of UV B-irradiated mice.

UV B-irradiation (280 to 320 nm) of mice at the site of cutaneous infection with herpes simplex virus type 2 (HSV-2) induced suppressor T-cell circuits that decreased HSV-2-induced proliferative responses of HSV-2-immune lymph node cells. Adoptive transfer experiments indicated that splenocytes from UV B-irradiated HSV-2-infected animals contain L3T4+ cells that suppress proliferative responses in vivo, consistent with suppressor inducer cells. However, following in vitro culture of the splenocytes with HSV-2 antigen, the proliferation of immune lymph node cells was inhibited by Lyt2+ suppressor T cells, consistent with antigen-induced suppressor effector cells. Antigen-specific and nonspecific suppressor factors were fractionated from supernatants of HSV-2-stimulated spleen cells by molecular-sieve chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the Sephadex fraction that contained the antigen-specific suppressor factor, in the presence or absence of 2-mercaptoethanol, defined a 115-kilodalton protein consisting of two disulfide-bound components with molecular sizes of 70 and 52 kilodaltons. The implications of these results with respect to the regulation of HSV-induced cell-mediated immunity following UV B-irradiation are discussed.     

Desensitization of delayed-type hypersensitivity in mice: suppressive environment

The systemic injection of high doses of antigen into a preimmunized animal results in transient unresponsiveness of cell-mediated immune responses. This phenomenon is known as desensitization. Serum interleukin 2 (IL-2) activity was found transiently in desensitized mice at 3 h after the antigen challenge. These mice could not reveal antigen nonspecific delayed-type hypersensitivity (DTH) 1 d after the challenge. Specific suppression of DTH was observed at later stages. Sera from 3 h desensitized mice showed suppressive effects on DTH in preo immunized mice. Administration of recombinant IL-2 into preimmunized mice led to the failure of development of DTH to antigens. These observations suggest that IL-2 plays an important role in the suppressive environment.     

Induction of protective immunity against Schistosoma mansoni by a nonliving vaccine. III. Correlation of resistance with induction of activated larvacidal macrophages

Mice protected against Schistosoma mansoni infection by intradermal (i.d.) immunization with nonliving larval or adult worm antigens plus bacterial adjuvant developed 24-hr skin test responsiveness to schistosome antigens with the histologic features of delayed hypersensitivity. Intraperitoneal antigen injection elicited a mononuclear cell-enriched exudative population containing macrophages activated for direct cytotoxicity against schistosomula and tumor cell targets. This was likely to be due to in vivo exposure to macrophage-activating lymphokines, since these cells were unresponsive to further lymphokine stimulation in vitro and splenocytes from immunized mice reacted to specific in vitro antigen challenge by production of lymphokines capable of conferring larvacidal activity upon control macrophages. In contrast, mice treated with schistosome antigens by i.v. injection, which were not protected against challenge infection, failed to develop delayed hypersensitivity or activated macrophages in response to specific antigen challenge in vivo, and the titers of macrophage-activating lymphokine produced by in vitro antigen-stimulated splenocytes from these mice were threefold to fourfold lower than those produced by cells from animals immunized by the i.d. route. Thus, sensitization for cell-mediated immune responses including lymphokine production and macrophage activation correlated with induction of resistance to S. mansoni in this model of vaccination.     

Immunosuppression in experimental cryptococcosis in rats

Using a rat model, we have previously demonstrated that infection with Cryptococcus neoformans can trigger the production of a series of suppressor cells that specifically inhibit the cell-mediated immune response to a non-related antigen, human serum albumin (HSA), that has been injected 7 days after the infection. We previously determined that the cryptococcal infection induces afferent suppressor or suppressor induction cells (Ts₁) to HSA. The primary objective of the present study was to investigate the suppressor cells involved in the efferent phase of delayed-type hypersensitivity (DTH) response to HSA in rats infected with C. neoformans and immunized with the non-related antigen and determine the role that the Ts₁ cell plays in the induction of that cell. For this purpose, the spleen mononuclear (SpM) cells containing the Ts₁ or SpM cells from immunized non-infected rats (used as donor controls) were transferred to two groups of syngeneic naive recipients (first recipients). Later, the SpM cells from both groups of animals were transferred to rats immunized with HSA (second recipients). The efferent limb of the DTH response to HSA was suppressed in the recipients that received SpM cells from donors injected with Ts₁ cells. Additional HSA antigen was not required for induction of these efferent suppressor cells. Furthermore, we here show that these cells are resistant to treatment with cyclophosphamide (Cy), and that they can activate another suppressor population. The latter are Cy sensitive and are present in the immune recipient.     

Activation of suppressor cells of the delayed hypersensitivity response in BALB/c mice infected or immunized with Leishmania mexicana pifanoi

A T suppressor cell population that specifically shut down delayed hypersensitivity responses (DHR) to the parasite was found in both BALB/c mice chronically infected with Leishmania mexicana pifanoi and in naive mice which had received a single IV supraoptimal dose of killed parasites. At the early phase of infection mice exhibited a transitory state of cell-mediated immunity against the parasite that was abrogated when lesions reached their accelerated phase of growth. Results suggest that in both infected and high-dose immunized mice, the activation of T suppressor cells of DHR is related to antigen overload.     

Suppression of natural killer cytolytic activity in mice undergoing pulmonary granulomatous inflammation

CBA/J mice undergoing pulmonary granulomatous inflammation exhibited depressed NK cytolytic activity. Granulomas induced by i.v. embolization of Schistosoma mansoni eggs (hypersensitivity type) or Sephadex beads (foreign body type) both caused reduced NK activity, although hypersensitivity granulomas induced a significantly higher level of NK suppression. Kinetic analysis of hypersensitivity lesions at 4, 8, 16, and 32 days post-embolization indicated that NK activity was significantly suppressed by day 8, maximally suppressed by day 16 (at the peak of the inflammatory response) then returned to near control values by day 32 (as the granulomas resolved). Suppression of NK activity ranged from three- to 15-fold in different experiments. NK cells obtained from both spleen and peripheral blood demonstrated reduced NK activity with kinetic patterns similar to the granuloma NK cells. Suppression was not due to reduced splenic NK cells as the frequency of YAC-1 binding cells, as well as asialo GM1+ or laminin+ cells remained constant over the entire study period. Suppression of NK activity did not appear to be due to serum components or suppressor cells present in the spleen preparations. However, the suppression of NK activity could be reversed by overnight incubation of spleen cells at 25 or 37 degrees C or daily treatment of the mice with indomethacin. Suppression also appeared relatively specific for NK cells as the generation and expression of cytotoxic T lymphocyte activity was not affected.     

Systemic immunological reactivity in the absence of delayed type hypersensitivity during murine leprosy

The generation of cell-mediated immunological reactivity has been examined following systemic infection of mice with M. lepraemurium (MLM). It has been found that although delayed-type hypersensitivity to MLM is ablated within 2 weeks of infection, resistance, as determined by a containment of the multiplication of the organism at various sites, persists for at least 7 weeks. During this time it was found that a population of lymphocytes sensitized to MLM antigens appeared within these animals and that DTH could he generated if these cells were focused at a footpad site.The possibility that these changes in immunological status are determined by increasing levels of antigen, resulting from a systemic killing of MLM is discussed. It is postulated that persistent desensitization eventually results in anergy to MLM.     

Histamine-induced suppressor factor (HSF): effect on migration inhibitory factor (MIF) production and proliferation.

Histamine added in vitro to cultures of sensitized lymphocytes suppresses antigen-induced production of migration inhibitory factor (MIF) and proliferation by these cells. Recent studies have suggested that lymphocytes bearing histamine type-2 receptors play a regulatory role in these in vitro responses. The present studies were undertaken to determine if suppressor function by cells having histamine receptors was mediated through a soluble product. It was found that lymph node cells from nonimmune or immune strain 2 guinea pigs elaborate a nondialyzable factor into the culture supernatant when incubated with 10(-3) to 10(-5) M histamine (histamine-induced suppressor factor of HSF). HSF, when cocultured with sensitized lymphocytes, suppressed their MIF and proliferative responses to antigen. HSF was made by lymphocytes but not macrophages. Its production could be blocked by an H2 receptor antagonist (burimamide) but not an H1 receptor antagonist (chlorpheniramine). Furthermore, the inhibitory effect of HSF was reversible as lymphocytes washed free of the factor after 24 hr and recultured with fresh medium and antigen were able to produce MIF. Gel filtration by Sephadex G-100 chromatography indicated that HSF had an approximate m.w. of 23,000 to 40,000. These results suggest that the release of histamine at the sites of immediate hypersensitivity reactions, possibly by generating HSF activity, may play a regulatory role in the subsequent development of cellular-immune reactions at the same site.     

Unresponsiveness to experimental allergic encephalomyelitis in mice: replacement of suppressor cells by a soluble factor

A soluble suppressor factor has been prepared from cells of mice rendered nonsusceptible to experimental allergic encephalomyelitis (EAE) by treatment with mouse spinal cord homogenate in incomplete Freund's adjuvant. The specific activity of this factor can be augmented by using a cell population enriched on plates coated with anti-mouse Fab and the specific antigen, mouse basic encephalitogen (MBE). The resultant suppressor factor had the same biologic activities as the cells from which it originated. Thus, it suppressed specifically the delayed-type hypersensitivity (DTH) response to MBE in vivo, and blocked in vitro the effector lymphocytes that adoptively transfer the DTH response. The suppressor factor reactivity was manifested also by the capacity to suppress the activity of macrophage migration inhibition factor produced by sensitized lymphocytes in the presence of the specific antigen MBE. The suppressor factor is antigen-specific and can bind the MBE in vitro and thus compete with its antibody binding. The most significant activity of the soluble suppressor factor is its ability to interfere with the induction of clinical EAE.     

Delayed hypersensitivity and nonspecific cellular immunity. The role of mono- and polynuclear phagocytes

Differences in the influence produced by sensitization with BCG vaccine and Staphylococcus aureus and by the reaction of delayed hypersensitivity (DH) induced, respectively, by the injection of old tuberculin and staphylococcal phagolysate on the phagocytic activity of peritoneal macrophages and blood leukocytes in different animals were experimentally demonstrated. A considerable activation of the bactericidal and ingesting functions of macrophages was observed in animals showing a pronounced DH reaction (rabbits, guinea pigs and mice), while in Wistar rats no such activation was noted. The latter showed no DH reaction after sensitization with BCG vaccine and the injection of the specific antigen. Among different strains of mice, the activation of macrophages occurred in the animals with the most pronounced DH reaction. Sensitization with BCG vaccine led to an insignificant sensitization of macrophages, and sensitization with S. aureus even suppressed the phagocytic activity of macrophages. The treatment of mice with antimacrophagal preparations (carrageenan, silica and trypan blue, but T-lymphocyte antiserum) before and after the injection of the specific antigen into the sensitized animals abolished the stimulation of anti-infection immunity.     

A novel suppressive activity: complementation between a T cell induced with first-order T-suppressor factor and an I-J-restricted antigen-nonspecific T cell

Previous studies demonstrated that the first-order T-suppressor factor (TsF1) requires the presence of antigen to induce idiotype-specific Ts cells which readily suppress phenyltrimethylamino (TMA) hapten-specific delayed-type hypersensitivity (DTH) responses when transferred into already immune recipients. In this study we show that TsF1 in the absence of antigen induces a splenic population which limits DTH in recipient mice only when an additional accessory lymphoid population was also cotransferred. Neither of these populations alone was sufficient to mediate suppression and depletion of T cells in either population's abrogated suppression, indicating the T-cell dependency of the complementing cell types. Moreover, suppression was seen only when TMA-TsF1-induced and not normal spleen cell lysate-induced cells were cotransferred with the antigen-induced population, suggesting the requirement for a specific signal to induce the factor-induced population. Further experiments showed that the antigen-induced lymphoid population could be replaced by either heterologous antigen-induced or adjuvant alone-induced splenic populations, indicating the lack of specificity of this secondary population. Further analysis showed that the cell complementation between TMA-TsF1-induced and the nonspecific accessory lymphoid population resulted in antigen-specific and genetically restricted immune suppression. The TsF1-induced lymphoid population was not responsible for the genetic restriction, and furthermore, there was no restriction observed between the two complementing populations. However, matching of the nonspecific accessory cell with the recipient host at the I-J subregion of the H-2 complex was essential for immune suppression. Finally, the activity of complementing cells was found to be independent of cyclophosphamide-sensitive Ts populations of the recipient mice. The ramifications of these findings with reference to the existing suppressor pathways are discussed.     

Studies on the role of the thymus and T cells in the in vivo suppression of delayed hypersensitivity (desensitization): radiosensitivity of the mechanism inducing nonspecific anergy.

Guinea pigs immunized with two or more antigens can have their ability to manifest delayed hypersensitivity (DH) reactions to all these antigens temporarily blocked by the administration of large (mg) amounts of one or more of these antigens 9 days after immunization. This nonspecific anergy is called desensitization. This study presents evidence for the induction of the desensitized state by an active, radiosensitive, immunoregulatory mechanism involving the peripheralization of thymocytes. Desensitization was associated with 1) a marked reduction in thymic weight; 2) an increase in mature T cells in the peripheral blood; 3) decreased responsiveness of the lymphocytes in the spleen to concanavalin-A; and 4) markedly reduced numbers of mono-nuclear cells, basophils, and polymorphs at the skin sites of specific and nonspecific desensitization. Small doses of whole-body irradiation which left DH capacity intact prevented nonspecific desensitization, but did not prevent specific desensitization, suggesting that a radiosensitive cell was involved in the production of anergy.     

Further evidence for non-T-cell regulation of delayed hypersensitivity in the guinea pig.

The nature of the suppressor activity in the spleens of guinea pigs immunized with dinitrophenyl-bovine γ-globulin in Freund's incomplete adjuvant was investigated. An anti-T-cell serum was prepared in rabbits and, after extensive absorption, showed specific killing for T-lymphocytes. After treatment with this antiserum and complement, spleen cells from animals immunized with the antigen in Freund's complete adjuvant showed marked reduction in ability to transfer sensitivity to normal recipients. However, when immune spleen cells, treated in the same way, were transferred into antigen immunized animals which had been pretreated with cyclophosphamide, the suppressor activity was unaltered. These results confirm earlier impressions that the regulation of delayed hypersensitivity reactions in the guinea pig is normally mediated by non-T-cells.     

Effects of suramin on the immune responses to sheep red blood cells in mice. I. In vivo studies

The effect of Suramin on the cell-mediated delayed-type hypersensitivity (DTH) and the humoral immune responses elicited in mice by sheep erythrocytes was studied. The results show that administration of Suramin, at various times before or after antigenic sensitization, results in a profound inhibition of cell-mediated responses but has no adverse effect on antibody production. Suramin was particularly effective when given during the effector phase of DTH: mice which were treated with this drug, 4 days after immunization, at the time of skin testing, exhibit negative or low DTH responses compared to control mice. Evidence is presented that this short-term Suramin-induced suppressive effect on the expression of DTH is related to a defective recruitment, by sensitized T lymphocytes, of phagocytic cells at the site of the inflammatory reaction. In addition, when treatment with Suramin precedes by 8 days (Day -8) or by 1 hr sensitization with sheep erythrocytes for DTH, decreased DTH reactions over controls were observed. The inhibitory effect exerted by Suramin administered on Day -8 can be reversed by increasing the dose, from 10(6) to 10(8) sheep erythrocytes, of the sensitizing antigen. The possibility is discussed that, in this case, Suramin may interfere with the generation of DTH-mediating cells through a rapid degradation of antigen related to the Suramin-induced hyperplasia of the mononuclear phagocyte system. In contrast, DTH anergy in mice treated with Suramin 1 hr before sensitization is maintained regardless of the sensitizing antigen dose. Analysis of the sensitized lymphocyte population in these mice indicates that Suramin does not prevent the induction of DTH-mediating cells and suggests that the expression of these latter is inhibited by suppressive cells which are generated as a result of drug treatment.     

Prostaglandin-mediated suppression of delayed-type hypersensitivity to infected erythrocytes during Babesia microti infection in mice

The mechanism of suppression of delayed-type hypersensitivity (DTH) to intraerythrocytic Babesia microti which occurs during infection in mice was examined. The suppression was not specific for anti-parasite DTH; infected mice immunized and challenged with sheep red blood cells had a similar depression of anti-sheep red blood cell DTH. Sublethal or lethal irradiation did not significantly alter the suppression of the DTH response, and cyclophosphamide pretreatment of infected mice also had no effect on suppression. Multiple passive transfer experiments using serum or regional lymph node cells from immunized or infected and immunized (suppressed) donor animals failed to demonstrate any ability to transfer suppression of DTH. Adherent cells from the spleens or peritoneal exudates of suppressed mice, however, did significantly depress the ability of immunized mice to express a DTH response. The cells responsible for this suppression were Thy 1- and nonspecific esterase+. Treatment of suppressive cell populations with 10 micrograms/ml indomethacin for 24 hr in vitro abrogated their suppressive ability, and in vivo administration of indomethacin to suppressed mice also restored DTH to normal levels. By examining levels of prostaglandin E2 (PGE2) in supernates of cultured peritoneal exudate cells from immune or suppressed mice, it was shown that infected mice had peritoneal exudate cells which produced significantly more PGE2 than similar cells from immune mice. These data suggest that B. microti infection elicits synthesis of PGE2 by macrophage-like cells which results in suppression of DTH to parasite as well as heterologous antigens.