The role of immunoglobulin receptors on lymphocytes in production of MIF in guinea pigs

The effect of anti-guinea pig IgG sera and anti-rabbit light kappa chain serum on the capacity of sensitized lymphocytes of guinea pigs to production of migration inhibitor factor (MIF) was investigated. The lymph node cells, thymocytes and circulating lymphocytes taken from dinitrophenyl- (DNP) sensitized guinea pigs were preincubated with antisera against gamma₁ + gamma₂ globulins, gamma₁ globulins, gamma₂ globulin, light kappa chains or normal rabbit serum as control and stimulated with antigen in vitro to production of MIF. The inhibitory effect of lymphocyte culture supernates on the migration of guinea pig normal macrophages was determined by capillary tube test. It was found that all the anti-immunoglobulin sera used suppressed, in varied degree, the release of MIF by sensitized lymphocytes. It is suggested that the suppressive influence of anti-IgG sera reflects their blocking effect on surface receptors specific for antigen.     

Identification and purification of immunosuppressive activity in the urine of rats and a human patient treated with niridazole.

Administration of the antischistosomal compound niridazole to mice, guinea pigs, and humans results in the suppression of several manifestations of cell-mediated immunity. Sera from animals treated with niridazole blocked the in vitro production of migration inhibitory factor (MIF) while niridazole itself was inactive, suggesting that these effects are caused by water soluble mediators. We now report that crude extracts prepared from the urine of rats and a patient receiving nirdazole, but not from pretreatment control urine, similarly suppress antigen-induced inhibition of migration of peritoneal exudate cells from sensitized guinea pigs. With immunosuppressive activity monitored by the direct MIF assay, combined solvent extraction and chromatographic techniques were used to fractionate immunosuppressive activity from the urine of niridazole-treated rats and the patient; the most active fractions, purified about 100-to 1000-fold as compared to methanol-water extracts of dried voided urine, inhibited MIF production at 0.1 to 0.01 ng/ml of assay mixture. These purified fractions also showed immunosuppressive activity by an in vivo assay wherein doses as low as 1 mug/kg injected intravenously (i.v.) into mice suppressed cell-mediated granuloma formation around Schistosoma manisoni eggs. Identically purified fractions prepared from urine of rats and the patient before they received niridazole showed no immunosuppressive activity either in the MIF or in the granuloma assay systems.     

Production and in vivo effect of antibodies against guinea pig lymphokines

Supernatants from guinea pig lymph node lymphocytes stimulated with insoluble Concanavalin A in serum-free medium were fractionated by Sephadex chromatography and preparative electrophoresis. The isolated fraction possessed migration inhibition, mitogenic, and skin reactive activities. Associated with these were apparently two newly synthesized haemoproteins of unknown function. Antibodies were prepared against this partially purified lymphokine fraction. MIF produced by sensitized lymphocytes activated with an antigen (PPD tuberculin) could be completely absorbed from whole supernatants by immunoadsorbent columns prepared with that antibody whereas mitogenic factor and skin reactive factor were not retained. The anti-lymphokine antiserum totally inhibited the delayed skin response of sensitized guinea pigs challenged with PPD.     

Suppression of the intradermal hypersensitivity reaction of the delayed type by a serum fraction from patients containing leukocyte migration inhibition factor]

The blood serum of patients with active tuberculosis of the lungs and chronic pneumonia inhibited migration of donor's leukocytes and macrophages of the peritonal exudate of guinea pigs when compared with migration of similar cells in the medium with the serum of cattle or donors. After chromatography these sera were fractionated on the columns with Sephadex G-100. Fractions containing the leukocyte migration inhibition factor (LMIF) suppressed, up to complete abolition, the intradermal reaction to tuberculin in man and guinea pigs sensitized with BCG. The LMIF is supposed to act in the regulation of delayed hypersensitivity reaction.     

Guinea pig macrophage agglutination factor is antigenically distinct from migration inhibition factor and immunoglobulin.

Lymph node cells from guinea pigs with specific delayed hypersensitivity release macrophage agglutination (MAggF) and migration inhibition factors (MIF) upon exposure to antigen or concanavalin A in serum-free medium. MAggF in culture supernatants was absorbed neither by immunoabsorbents made with a rabbit anti-guinea pig lymphokine serum that removed MIF, nor by immunoabsorbents made with rabbit anti-guinea pig Ig. These results suggest that MAggF is antigenically distinct from MIF and Ig.     

Staphylococcal enterotoxin B induced release of macrophage migration inhibition factor from normal lymphocytes

Staphylococcal enterotoxin B (SEB), a potent lymphocyte mitogen, inhibits migration of peritoneal exudate cells from most guinea pigs but does not inhibit migration of purified macrophages. Experiments were designed to test the ability of highly purified SEB to induce normal lymphocytes to release migration inhibition factor (MIF). Supernatants of lymph node lymphocytes cultured with SEB inhibited the migration of purified macrophages, indicating the release of a migration inhibition factor. Mitomycin-C blocked the SEB-induced release of MIF. SEB-induced MIF localized in the albumin fraction on Sephadex G-200 chromatography. Antibody to SEB specifically blocked the inhibitory effect of SEB on migration of normal guinea pig peritoneal exudate cells.     

Antibodies to guinea pig lymphokines. II. Suppression of delayed hypersensitivity reactions by a "second generation" goat antibody against guinea pig lymphokines.

A "second generation" antibody to a highly purified lymphocyte product was raised in a goat against material eluted from a rabbit anti-guinea pig lymphokine immunoadsorbent column. This anti-lymphokine serum, in constrast to anti-lymphocyte serum (ALS) did not appear to contain cytotoxic antibodies directed against membrane antigens on guinea pig lymph node lymphocytes. Furthermore, the anti-lymphokine serum did not inhibit the formation of spontaneous T rosettes nor significantly depress lymphocyte response to mitogens. The anti-lymphokine serum totally suppressed the delayed skin reactivity to PPD and contact sensitivity to DNCB when injected intradermally around the site of antigen challenge. By contrast, intradermally injected ALS did not appear to suppress the PPD response in sensitized guinea pigs. Intravenously and i.p. administered anti-lymphokine serum was somewhat less effective in suppressing the delayed skin response to PPD. The intradermal injection of the antiserum had no effect on nonspecific inflammation evoked by turpentine-olive oil or on the extravasation of circulating Evans blue evoked by intradermally injected histamine. Histologic examination of 24-hr DNCB-induced skin lesions from sensitized guinea pigs treated with intradermally injected anti-lymphokine serum showed marked reduction of mononuclear infiltration of the dermis and of epidermal lesions, as compared with skin sites taken from sensitized animals pretreated with normal goat serum. The anti-lymphokine serum injected i.v. also markedly reduced the perivascular infiltration of the dermis and subcutis in skin reaction sites from sensitized animals challenged with PPD. Intravenous treatment with ALS for 3 consecutive days caused extensive depletion of the paracortical areas of peripheral lymph nodes whereas treatment with normal serum and anti-lymphokine serum caused no such depletion. It is proposed that the anti-lymphokine serum is directed against activated lymphocyte products, one of them being MIF. These products are involved in the mediation of delayed hypersensitivity reactions. This is in marked contrast to ALS, the suppressive action of which appears to be central rather than peripheral.     

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.     

In vitro studies on transplantation immunity. I. MIF production by sensitive lymphocytes in mice

Sensitized lymphocytes from mice immunized with skin homografts produce migration inhibitory factor upon incubation with lymphocytes (antigen) from the sensitizing strain. The MIF is produced within 14 hr following incubation of sensitized lymphocytes and antigen. In this reaction, antigenic specificity is a prerequisite for MIF production; however, the action of MIF transcends the strain barrier. Also, MIF produced in homograft reactions in mice inhibited the migration of peritoneal cells from normal guinea pigs. Finally, lymphocytes from mice bearing skin homografts do not develop the capacity to produce MIF prior to the rejection of the sensitizing skin grafts.     

Mechanisms involved in the expression of Jones-Mote hypersensitivity: II. Lymph node morphology and in vitro correlates

Lymph node morphology, in vitro lymphocyte transformation, and inhibition of macrophage migration were studied at varying intervals after sensitization for Jones-Mote hypersensitivity (JMH) with ovalbumin (OA) in Freund's incomplete adjuvant (FIA). The effect of cyclophosphamide (CY, 300 mg/kg), given 3 days before sensitization with OA in FIA, was also studied in an attempt to clarify further its role in increasing the intensity of skin reactions and its effect on the passive transfer of skin reactivity described in the preceding paper. There were increased numbers of large pyroninophilic cells in paracortical areas of draining lymph nodes and increased in vitro DNA synthesis, by lymph node cells, in animals treated with CY 3 days before sensitization with OA in FIA. There was no inhibition of macrophage migration of PEC from animals sensitized with OA in FIA, whether or not these guinea pigs had been treated with CY before sensitization.     

Effect of C-reactive protein on peritoneal macrophages. I. Human C-reactive protein inhibits migration of guinea pig peritoneal macrophages

The effect of human C-reactive protein (CRP) isolated and purified from pooled patients' sera on macrophage function, especially on macrophage migration, was studied. Peritoneal exudate cells (PEC) from guinea pigs were used for macrophage migration inhibition (MMI) test of capillary method. Migration of either PEC or adherent purified macrophages exposed to CRP were inhibited dose-dependently. These findings indicate that CRP inhibits macrophage migration directly, not via activation of lymphocytes contained in PEC. As control, we examined the effect of normal human serum, anti C-polysaccharide antibodies isolated from patients' sera, and free endotoxin at the dose contaminated in CRP preparation on macrophage migration and found that none of them were effective. The effect of CRP on MMI of sensitized PEC exposed to antigen was also studied. Large amounts of CRP inhibited MMI induced by antigen, indicating the possibility that CRP may act on macrophages competitively with migration inhibitory factor (MIF) and may modulate MMI. CRP possesses MIF-like activity and may play a functional role at the site of tissue injury by causing the accumulation of macrophages.     

Properties of TAS-1D3, a Tuberculin-Active Substance from BCG,in Regard to Delayed Hypersensitivity

The properties of TAS-1D3, a tuberculin-active substance purified from the cell extract of Mycobacterium bovis BCG, were studied in vivo and in vitro. In the delayed hypersensitivity skin reaction, TAS-1D3 showed far more potent activity than tuberculin purified protein derivative (PPD) in guinea pigs sensitized with BCG vaccine. This was consistently observed from 6 to 24 weeks after sensitization. The histological findings of the skin reaction to TAS-1D3 were similar to those of the reaction to PPD. Moreover, TAS-1D3 induced well both thymidine incorporation and the production of migration inhibitory factor (MIF) by the spleen cells from guinea pigs sensitized with BCG vaccine. In contrast, TAS-1D3 showed weaker activity than PPD in guinea pigs sensitized with either heat-killed M. tuberculosis Aoyama B or heat-killed M. tuberculosis H37Ra, and it weakly stimulated the spleen cells from animals sensitized with M. tuberculosis Aoyama B to incorporate thymidine and to produce MIF.     

Blocking of delayed hypersensitivity by humoral antibody in an in vivo mouse transfer assay using sensitized guinea pig cells

Humoral antibody was shown to interfere specifically with the expression of cell-mediated immunity (delayed hypersensitivity) in an in vivo system. Mice that received peritoneal exudate cells obtained from guinea pigs sensitized to 1-chloro-2,4dinitrobenzene (DNCB) exhibited delayed hypersensitivity reactions after challenge with the sensitizing agent. While control groups that received either normal sera, saline, or anti-BSA (bovine serum albumin) in addition to peritoneal exudate cells from sensitized guinea pigs exhibited positive delayed reactons to challenge with DNCB, mice that received anti-DNP (dinitrophenyl group) in addition to the senstized cells were prevented from exhibiting a delayed reaction to DNCB.     

Fractionation of murine macrophage inhibitory factor into two distinct species

Murine migration inhibitory factor (MIF) produced by concanavalin A-stimulated lymph node cells from C57BL/6 mice was fractionated by Sephadex G-100 gel filtration, density gradient electrophoresis, and isoelectrofocusing in a sucrose density gradient and assayed on in vitro-cultivated bone marrow macrophages from C57BL/6 mice. Two major MIF species, pH3-MIF with an isoelectric point of 3.0–4.3 and pH5-MIF with an isoelectric point of 4.6 to 5.2, were obtained. The similarity of murine MIF to guinea pig and human MIF is discussed.     

Modulation of adoptive cell transfers in experimental allergic encephalomyelitis by antigen treatment of donors

Experimental allergic encephalomyelitis has been adoptively transferred using lymph node cells from Strain 13 guinea pig donors sensitized with purified encephalitogenic myelin basic protein. Adoptive cell transfer was used to examine the immunocompetence of lymph node cells obtained from guinea pigs protected from disease development by treatment with MBP. Lymph node cells from guinea pigs unresponsive to EAE challenge do not adoptively transfer disease. Cells obtained from guinea pigs treated with MBP following encephalitogenic challenge are competent in adoptive transfer with respect to pathologic lesions, but not clinical disease. The clinical and pathologic responses of recipients of the histocompatible lymphocyte populations are similar to those seen in the treatment-matched donor controls, suggesting that under these circumstances lymphoid cells, rather than circulating soluble factors, are responsible for disease induction and suppression.     

Release of macrophage migration inhibitory factor(s) from lymphocytes stimulated by streptococcal preparations

Lymphocytes from apparently healthy subjects, incubated for 5 hours with cellular components or extracellular products of group A streptococci and then washed and reincubated, were found to release factor(s) capable of inhibiting guinea pig lung macrophage migration (“indirect method”). Inhibitition of macrophage migration was also obtained when the same preparations were tested directly on guinea pig lung cells, a macrophage-lymphocyte population (“direct method”). The guinea pigs had not been experimentally sensitized. The inhibition of migration appeared to depend on the presence of lymphocytes among the macrophages, since macrophages purified by repeatedly discarding nonadherent cells proved resistant to the migration inhibiting activity of the most active Streptococcal preparation, a 20 × concentrated filtrate. Reconstitution of the original lymphocyte-macrophage mixture reestablished the reactivity. The macrophage migration inhibition did not correlate with the age of the guinea pigs. It could not be obtained with preparations of group D streptococci or of Salmonella paratyphi. Group C streptococci did not inhibit the macrophage migration with the indirect method, but it did with the direct one.The factor(s) released into the medium on stimulation of apparently normal lymphocytes by Streptococcal preparations was relatively heat resistant, nondialyzable, and DNase and RNase resistant; its release was inhibited by puromycin. Pretreatment of the cells with trypsin prevented the absorption of the factor(s) and left migration unaffected. These characteristics are similar to those previously described for the migration inhibitory factor (MIF) produced by the interaction of sensitized lymphocytes and specific antigens. Whether or not these similarities indicate an identity remains to be determined.     

Role of mediators of cellular hypersensitivity in the stimulation of the antibody formation to unrelated antigen

The effect of a concurrent delayed hypersensitivity reaction on the antibody response to sheep red cells was assessed by a plaque assay. Guinea pigs with delayed hypersensitivity to tuberculin purified protein derivative (PPD) or egg albumin showed an increased antibody response to sheep red cells when the cells were injected intravenously at the same time as PPD or egg albumin. This effect was transferred to normal guinea pigs by serum from guinea pigs with delayed hypersensitivity to PPD or egg albumin taken 24 hr after injecting the corresponding antigen. Supernatants containing migratory inhibitory factor were prepared by incubating lymphocytes from sensitized rabbits with antigen. These supernatants were injected with sheep red cells and gave rise to an enhanced plaque response. Similar results were obtained with supernatants from normal rabbit thymus cells. The role of mediators of delayed hypersensitivity in enhancing antibody formation and in T cell/B cell cooperation is discussed.     

The role of B lymphocytes in cell-mediated immunity II. Delayed hypersensitivity induced by dinitrophenyl-ficoll in dinitrophenyl-keyhole limpet hemocyanin-immunized guinea pigs.

Dinitrophenyl (DNP)-Ficoll will elicit typical delayed hypersensitivity skin reactions in guinea pigs immunized with DNP-keyhole limpet hemocyanin (KLH). We observed that lymph node cells (LNC) from these animals produced the lymphokine, monocyte chemotactic factor (MNL CTX) when stimulated by DNP-Ficoll in vitro. This response was antigen and hapten specific since LNC from nonimmune guinea pigs or those immunized with nonDNP containing antigens were not stimulated by DNP-Ficoll. Lymph node cells were fractionated into T- and B-cell-enriched populations to determine the nature of the DNP-Ficoll-responsive cell. Only the B-lymphocyte-enriched population produced MNL CTX in response to DNP-Ficoll. The purity of the B-cell population was demonstrated by its failure to respond to PHA and by the fact that B cells derived from DNP-although they could no longer respond without T-cell help to the T-dependent antigen, DNP-OVA. These findings suggest that the hapten-specific response of guinea pigs to DNP-Ficoll may be a form of B-cell-mediated delayed hypersensitivity.     

Functional activation of immune lymphocytes by antigenic stimulation in cell mediated immunity: I. Requirement for macrophages in antigen-induced MIF production by guinea pig immune lymphocytes in vitro

The role of macrophages in the process of antigen-induced production of mediators in cellular immune response was studied, using the antigen-induced production of migration inhibitory factor (MIF) as a measure of the activation of immune lymphocytes.The production of MIF by guinea pig immune lymph node cells in response to the stimulation with PPD was abolished when the lymph node cells were depleted of adherent cell population by passing the cells through a Tetron fiber column and incubating the effluent cells in plastic dishes. These purified immune lymphocytes did not respond to particle-bound PPD, either. However, the response was obviously restored by the addition of a small number of the purified peritoneal adherent cells (macrophages) which had been pulse-treated with PPD. The PPD-pulsed macrophages produced no MIF by themselves. Thus, the results clearly indicated the requirement for macrophages in the process of antigen-induced MIF production by immune lymphocytes. Destruction of PPD-pulsed macrophages by freezing and thawing or by homogenization abrogated their ability to stimulate immune lymphocytes. Attempts to restore the response of the purified immune lymphocytes to PPD by adding 2-mercaptoethanol or the culture supernatant of macrophages to the medium have so far been unsuccessful.     

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.