Macrophage-lymphocyte interaction in the formation of delayed-type hypersensitivity

Macrophage-lymphocyte interaction was studied on 121 CBA mice during a 2-hour contact of lymph-node cells of non-immune mice with a monolayer of peritoneal macrophages of BCG-immunized mice and subsequent intravenous administration of 4.10(7) pre-incubated lymphocytes to syngenic recipients. Sensitivity to tuberculin was demonstrated in the recipients by means of blast-transformation reaction of spleen cells (stimulation index was evaluated according to incorporation of 3H-thymidine--SI = 1.32 +/- 0.40) using administration of tuberculin into the paws (Mantoux reaction--MR = 0.11 +/- 0.02 mm) and the cytotoxic effect (CTE) of the lymphocytes on tuberculin-loaded sheep-cell erythrocytes whose disintegration was assessed according to discharge of iron from the target cells (CTE = 13.98 +/- 2.73%). At transfer of intact lymphocytes after contact with non-immune macrophages, SI = 1.046 +/- 0.019; MR = 0.014 +/- 0.002 mm; CTE = 0.214 +/- 0.048%. The treatment of lymphocytes with indomethacin during the contact with macrophages induced idvere changes in the indices of delayed-type hypersensitivity (DTHS). The conclusion has been drawn that the antigen-presenting ability of macrophages can materialize in vitro.     

Regulatory mechanism of delayed-type hypersensitivity in mice. II. Effect of suppressor cells on the development of memory cells for delayed-type hypersensitivity

Murine lymph node cells (LNC), which we showed previously to noncompetitively inhibit antibody-dependent cellular cytotoxicity (ADCC) to an erythrocyte target, were tested for their ability to inhibit ADCC to a tumor target, EL-4. Both a 4-hr ⁵¹Cr-release cytotoxicity assay and an overnight ¹²⁵IUdR (iododeoxyuridine) postlabeling cytostasis assay were used. Normal autologous lymph node cells inhibited spleen cell-mediated ADCC in both assays. Inhibition by LNC was dose dependent, but comparable numbers of sheep erythrocytes did not inhibit, indicating that LNC-mediated inhibition was not simply a matter of crowding. Inhibitory activity was enriched in LNC after removal of Fc receptor-bearing cells on EA monolayers.     

Regulatory mechanism of delayed-type hypersensitivity in mice. I. Properties of memory cpells and suppressor cells for delayed-type hypersensitivity against ovalbumin.

Delayed-type hypersensitivity (DTH) response in mice induced by sc injection of alum-absorbed ovalbumin (OA) was accelerated and enhanced by priming sc with a low dose of urea-denatured ovalbumin (UD-OA), 2 or more days earlier, whereas it was suppressed by priming sc with a high dose of UD-OA, 0 or more days earlier. The ability in primed mice to accelerate or suppress the DTH response could be transferred antigen specifically into cyclophosphamide (CY)-pretreated recipients or normal recipients by spleen cells from primed mice, but not by the T-cell-depleted spleen cells. Furthermore, the ability of spleen cells to transfer the acceleration or the suppression appeared transiently around 7 or 4 days after priming, although the acceleration or the suppression in donor mice persisted for a much longer time. Pretreatment with CY abolished the suppression of DTH response in high dose-primed mice and resulted in the acceleration of DTH response. These results suggest that the activity of DTH-related memory T cells which accelerate and enhance the response can be inhibited by suppressor T cells for the DTH response.     

Antigen recognition in delayed-type hypersensitivity.

It is still uncertain if cell-mediated immune reactions are more or less specific than antibody-mediated reactions. Accordingly, hapten and carrier specificity were examined in delayed hypersensitivity in guinea pigs. Hapten specificity was demonstrated with 2,4-dinitrophenyl (DNP)-guinea pig albumin (GPA), 2,6-DNP-GPA, 2,4,6-trinitrophenyl (TNP)-GPA, and dansyl (DNS)-GPA. Guinea pigs immunized with each of these conjugates were tested 7 days later with the immunogen and the other conjugates. Strong delayed skin responses were highly specific for the immunogen; there were some weak cross-reactions among the nitrophenyl conjugates, no crossre-actions between the DNS and nitrophenyl conjugates, and no responses to unconjugated GPA. Conjugates carrying different numbers (1–45) of 2,4-DNP groups per molecule were all able to elicit specific responses to 2,4-DNP.Carrier specificity in delayed hypersensitivity was confirmed by immunizing with 2,4-DNP-GPA, and challenging with the immunogen, with 2,4-DNP coupled to bovine albumin (BSA), rabbit IgG, ovalbumin, and hemocyanin. Strong responses were seen to the immunogen, a weak response to 2,4-DNP-BSA, and no response to the other conjugates. Specific immune recognition of both hapten and carrier determinants is therefore required for expression of delayed hypersensitivity. These cell-mediated reactions thus appear to be more specific than those of antibody-mediated reactions in solution.     

Regulation of delayed-type hypersensitivity reactions by cyclophosphamide-sensitive T cells.

The onset, intensity, and duration of DTH reactions elicited in mice immunized with either SRBC or products of the major histocompatibility complex can be altered significantly by pretreatment with CY 1 to 2 days before immunization. Such drug pretreatment tends to augment low DTH responses caused by the use of too much antigen and to diminish many responses that are optimal. Thus, pretreatment with CY does not specifically eliminate suppressor cells. Our results are most consistent with the notion that the cellular targets of low doses of CY are positive and negative feedback regulatory cells, which may consist of one population with two effects or, more likely, two distinct cell populations.     

The macrophagal-lymphocytic interaction of heterochronic cells in the induction of delayed hypersensitivity]

The influence of senescence on the functional activity of lymphocytes and macrophages in the induction of sensitivity to tuberculosis has been studied in experiments on 226 CBA mice. The study has revealed that after the injection of BCG old animals exhibit decreased capacity for the formation of delayed hypersensitivity, and their lymphocytes, transplanted to recipients, induce a lower level of hypersensitivity. Joint incubation of lymphocytes and macrophages from animals of different ages has shown that immunological defect appearing with age is localized in lymphocytes, while the antigen-presenting function of macrophages remains basically unchanged.     

Regulatory mechanisms of cutaneous delayed-type hypersensitivity. II. Suppression of cutaneous delayed-type hypersensitivity by macrophage disappearance reaction

Studies were performed on the behavior of cutaneous delayed-type hypersensitivity (DTH) in guinea pigs in which macrophage disappearance reaction (MDR) was induced. Guinea pigs were immunized with dinitrophenylated egg albumin (DNP-EA), followed by intraperitoneal (ip) injection of liquid paraffin in order to elicit peritoneal macrophages. Subsequently 20 micrograms of EA was injected into these animals and the animals were divided into two groups. One group of animals was sacrificed for estimation of MDR 6 hr after the subsequent ip injection. The other group received a skin test by EA at the time of the subsequent ip injection. The first group of animals sacrificed for estimation of MDR exhibited a marked reduction in the number of peritoneal macrophages. The second group of animals that received skin tests revealed suppressed skin reactions 24 hr after the subsequent ip injection. A similar experiment was performed using the guinea pigs doubly immunized with DNP-EA and dinitrophenylated bovine gamma-globulin (DNP-BGG). Induction of MDR was performed by ip injection of BGG and skin tests were done by both EA and BGG. As a result, suppression of not only BGG-induced skin reactions but also EA-induced skin reactions was observed in animals in which MDR had been induced by BGG. In addition, the guinea pigs in which MDR was induced showed hyporeactivity to phytohemagglutinin (PHA). Reactivity to skin reactive factor (SRF) was also suppressed in these animals. The culture supernatants of macrophages incubated with the MIF fraction in vitro showed the ability to suppress skin reactions of cutaneous DTH, PHA and SRF.     

A requirement for helper T cells in the induction of delayed-type hypersensitivity

This paper describes a model system for studying the role of helper T cells in the induction of delayed-type hypersensitivity (DTH). Cyclophosphamide- (CP) treated mice sensitized with antigen 3 days later develop high levels of delayed-type immunity; however, DTH cannot be demonstrated in mice that are sensitized with antigen 1 day after drug treatment. The inability to respond to antigen 1 day after CP treatment can be restored if either normal or low-dose primed spleen cells are transferred at the time of sensitization. Although irradiated (1500 rad) normal spleen cells are unable to restore DTH, such treatment has no effect on the primed spleen cell population. The lymphocytes responsible for restoring the DTH response were identified as T cells, in that treatment with anti-Thy-1.2 serum and C abrogated their effect. Furthermore, restoration of the DTH response was dependent on the presence of antigen at the time of lymphocyte transfer; irradiated primed cells could not transfer DTH alone. The DTH effector cells in reconstituted mice were identified as originating from the host and not from the transferred cell population. This was accomplished by using anti-H-2 serum to identify the source of the DTH effector cells after transferring parental (H-2b) irradiated primed spleen cells into CP-treated F1 mice (H-2b,k). Thus, the irradiated transferred cells are behaving as helper T cells and promoting the development of DTH effector cells in the host.     

Regulatory mechanism of delayed-type hypersensitivity in mice. V. Augmentor cells for DTH responses

Mice primed with 1 microgram of reduced and alkylated ovalbumin (RA-OA) developed not only long-lived memory cells for delayed-type hypersensitivity (DTH), capable of differentiating into DTH-effector T cells (DTH-Te) against ovalbumin (OA) when restimulated in vitro with OA, but also spleen cells capable of augmenting recipients' DTH responses to OA when transferred into cyclophosphamide (CY)-pretreated mice. The augmenting activity in spleen cells, upon transfer, was found 7 days, but not 21 or 91 days, after priming with RA-OA, although memory DTH-Te were present throughout the period of observation. The loss of augmenting activity after day 7 of priming was not due to the presence of suppressor cells; spleen cells taken 21 days after priming failed to suppress, upon transfer, the augmenting activity in 7-day-primed spleen cells as well as induction and expression of DTH responses to OA. When 7-day-primed spleen cells were fractionated on a discontinuous bovine serum albumin density gradient, the augmenting activity was found only in the medium-density-cell layer, although memory DTH-Te were separated in the high-density layer. Augmentation of DTH-Te generation could also be demonstrated in vitro when 7-day-primed spleen cells, but not 21-day-primed spleen cells, were added to cultures of spleen cells from CY-pretreated mice. These results indicate that, in the 7-day-primed spleen, there is an augmentor cell population which is different from memory DTH-Te and interacts with CY-resistant unprimed cells to facilitate DTH-Te generation.     

Regulatory mechanisms of cutaneous delayed-type hypersensitivity: I. Suppression of cutaneous delayed-type hypersensitivity by migration inhibitory factor

The macrophage migration inhibitory factor (MIF) fraction was prepared from the immunoadsorbent column by using anti-guinea pig MIF antiserum. Suppression of cutaneous delayedtype hypersensitivity was achieved by intraperitoneal injection of the MIF fraction into the animals bearing macrophage-rich peritoneal exudates. Skin reactions induced by phytohemagglutinin (PHA) were also suppressed in these animals. Reactivity to skin reactive factor (SRF) was suppressed in these animals as well. The sera obtained from these animals exhibited the inhibitory activity against production of lymphokines from sensitized lymphocytes.     

B-cell-mediated regulation of delayed-type hypersensitivity

We obtained immune sera from mice which received suppressor B cells induced in vitro, injected them into immunized mice, and measured suppression of the delayed-type hypersensitivity (DTH) of these recipient mice. In the recipients, effector-phase suppressor T (Ts) cells were induced, and the action of these Ts cells was antigen-nonspecific. The suppressive material of the sera was adsorbed on a Sepharose column coated with anti-mouse immunoglobulin antibody and acid elution of the column yielded the elute fraction that showed significant suppressive activity. The suppressive activity of the sera was also adsorbed by an antigen-coated Sepharose column, and the eluate from the column had suppressive activity. Moreover, we established antigen-specific monoclonal antibodies, some of which suppressed the DTH in an H-2-nonrestricted way. The isotype or specificity of the antibodies was not related to the suppression, because suppressive and nonsuppressive antibodies belonged to the same immunoglobulin isotype and because the antibodies that recognized the same epitope had different suppressive activities. The Fc portion was not the functional site, because the F(ab')2 fragment had the activity. The suppressive antibody induced effector-phase Ts cells, which had the anti-idiotypic receptor. These findings suggested that antigen-specific antibodies in the immune sera mediated the suppression of DTH by the induction of effector-phase Ts cells in vivo and the idiotype of the antibody stimulated the anti-idiotypic receptor of these Ts cells.     

Induction of T-suppressors of delayed-type hypersensitivity with a background of T-effector formation

Administration to mice of 10(5) syngeneic splenocytes modified with trinitrobenzene sulfonic acid leads to the formation of a population of T suppressors which are capable to sorb on a specific antigen. In recipients, these cells suppress only one phase of the induction of delayed type hypersensitivity (DTH). Their precursors are sensitive to the action of low doses of cyclophosphamide. The formation of the suppressors in question occurs during the generation of T effectors of DTH. It is suggested that the suppressors described may be attributed to Tc3 which are activated in the lymph nodes as a result of subcutaneous sensitization with antigen, and which are similar to Tc1 but have the Ly 2+ phenotype.     

Regulatory action of immune B cells on delayed-type hypersensitivity in mice

Suppressor cells in delayed-type hypersensitivity (DTH) to soluble protein antigens were induced in vitro from BALB/c spleen cells. Transfer of these cells into syngeneic recipients resulted in suppression of the hosts' DTH responses in an antigen-specific manner. These suppressor cells were characterized as B cells by their adherence to nylon-wool columns, resistance to treatment of anti-Thy 1, -Ly 1, and -Ly 2 antibodies plus complement, adherence to anti-mouse immunoglobulin-coated dishes, and nonadherence to uncoated plastic dishes. In addition to being radiation sensitive, these suppressor B cells showed the capability of binding to the primed antigen. Thus, it was demonstrated that our in vitro-induced suppressor cells were antigen-specific B cells. When these suppressor B cells were transferred into the recipients, serum titers of specific antibodies were elevated and effector phase suppressor T cells were induced in the recipients. These results suggest that suppressor B cells exert their suppressor activity through the idiotype-anti-idiotype network.     

The in vitro induction of T cells which mediate delayed-type hypersensitivity toward horse red blood cells.

Humoral and cell-mediated immunity to the antigen horse red blood cells (HRBC) were induced in vitro. The type of immune response induced, however, was dependent on the concentration of antigen present in the culture. Whereas intermediate concentrations of HRBC induced antibody-forming cells, high and low concentrations of HRBC induced T cells which, on transfer, mediated delayed-type hypersensitivity reactions. The inverse relationship between humoral and cell-mediated immunity often observed in vivo is, therefore, also evident when lymphocytes are stimulated with antigen in vitro.     

Lymphocyte recruitment in delayed-type hypersensitivity. The role of IFN-gamma

Lymphocytes are recruited out of the blood into delayed-type hypersensitivity (DTH) reactions, but the factors controlling their migration are poorly understood. Our previous studies have shown that IFN-alpha/beta, its inducers, and T cell lymphokines can induce lymphocyte migration into the skin after intradermal injection. The present studies were designed to determine the effect of rIFN-gamma, IL-1, and anti-IFN-gamma on lymphocyte recruitment into DTH. Small peritoneal exudate lymphocytes, which preferentially migrate to inflammatory sites, were labelled with 111In and injected i.v. into rats. The intradermal injection of IFN-gamma stimulated the migration of these lymphocytes into the skin. IL-1 induced very little migration by itself, but enhanced the effect of IFN-gamma. Kinetic analysis demonstrated that the migration of lymphocytes to IFN-gamma was rapid, with a peak at 6 h, whereas migration into a DTH reaction was minimal for the first 8 h and reached a peak 24 h after intradermal injection. Polyclonal rabbit anti-IFN-gamma anti-serum, and a Mab to IFN-gamma, DB-2, could almost completely block lymphocyte migration induced by IFN-gamma. Furthermore, DB-2 inhibited lymphocyte recruitment into DTH reactions by 50 to 90%. This Mab did not affect migration in response to IFN-alpha/beta, although it partially inhibited the response to polyI:C. The effect of IFN-gamma on lymphocyte recruitment was not specific for small peritoneal exudate lymphocytes, because both spleen T cells and lymph node cells migrated in response to IFN-gamma and DB-2 inhibited the recruitment of splenic T cells to DTH. Thus, IFN-gamma is a potent stimulator of lymphocyte migration into the skin and a major mediator of lymphocyte recruitment into DTH.     

Evanescent delayed-type hypersensitivity: mediation by effector cells with a short life span.

Four days after i.v. immunization of mice with optimal low doses of heterologous erythrocytes (2 x 10(5) RBC), strong delayed-type hypersensitivity (DTH) responses can be elicited in the footpad. At later intervals after immunization, DTH responsiveness is progressively diminished and replaced by 4-hr antibody-dependent reactions. These evanescent T cell-mediated DTH responses, which are progressively replaced by antibody-dependent reactions, resemble Jones-Mote type delayed hypersensitivity responses of humans and guinea pigs. Since higher doses of immunizing antigen activate suppressor mechanisms that inhibit DTH responses, we examined the possibility that the evanescence of DTH in mice immunized with an optimal low dose of antigen might also be due to suppression. Using techniques that could clearly demonstrate the suppression produced by high antigen doses, we failed to find evidence for either humoral or cellular suppression in optimally immunized mice with declining of DTH responses. Thus, it appears that the evanescence of produced by optimal low dose immunization with RBC may be due to an intrinsic short life span of the effector cells rather than to the activation of an identifiable shut-off mechanism.     

Activation of T cells by glutaraldehyde-fixed erythrocyte antigens: radiosensitivity of cells mediating delayed-type hypersensitivity reactions in the mouse.

Mice immunized with glutaraldehyde-fixed sheep red blood cells (G-SRBC) show delayed-type hypersensitivity (DTH) reactions to G-SRBC or SRBC. The specificity of the DTH reaction of mice sensitized with glutaraldehyde-fixed antigens is similar to that found after sensitization with unfixed antigens. The dose-response curve for sensitization by glutaraldehyde-fixed SRBC was very different from the curve for normal SRBC. At low doses, both antigens were effective in sensitizing to show DTH but neither induced an antibody response. However, at high antigen doses, only the glutaraldehyde-fixed antigen was efficient in sensitizing to show DTH and it failed to raise an antibody titer. Spleen cells of mice sensitized with fixed RBC can transfer DTH locally but if the donor cells are irradiated (500 R), the transfer is abrogated. In contrast, the transfer of DTH by spleen cells of mice immunized with unfixed antigen is not affected by 500 R. The transfer of DTH by spleen cells of mice immunized with fixed antigen can be blocked by “in vitro desensitization” while the transfer of DTH by spleen cells from mice primed with normal antigen is resistant to “in vitro desensitization.” These results suggest that immunization of mice with different physical states of the same antigen can result in the activation of antigen-specific T cells which exhibit markedly different properties.