Specific, transient suppression of the immune response by HGG tolerant spleen cells. II. Effector cells and target cells.

In a previous report, it was shown that spleen cells from mice made tolerant to human gamma-globulin (HGG)5 could specifically inhibit the immune response of normal spleen cells after adoptive transfer to lethally irradiated recipients. However, that report also showed that the suppressive activity was only transiently associated with tolerant spleen cell populations. It was concluded from those experiments that while suppressive activity could be demonstrated in tolerant spleen cells under certain conditions, such activity was not obligatory for the maintainance of the tolerant state. The experiments presented here were performed to determine the nature of the effector cell(s) and the target cell(s) involved in this system of suppression of the immune response. Treatment of cells from tolerant animals with anti-thymocyte serum and complement to remove thymus-derived (T) cells completely abrogated suppresive activity. Removal of adherent cells from tolerant spleen cells by passage over glass wool columns resulted in partial loss of the suppression. The inhibitory activity of the suppressor cells was resistant to 900 R irradiation regardless of whether the tolerant spleen cells were irradiated before or after adoptive transfer. The cellular target(s) for the supprssor cells was examined by using lipopolysaccharide (LPS) as an alternative source of helper activity for the response to HGG. LPS, injected at the time of the initial antigenic challenge of mice that had been reconstituted with tolerant and normal spleen cells, prevented the expression of suppression against bone marrow-derived (B) cells. However, when LPS was presented only at the time of secondary antigenic challenge, it was unable to overcome suppression of the immune response of reconstituted recipients. Thus, LPS could produce a state where the B cells were resistant to suppression, but LPS could not rescue the responsiveness of B cells once the cells in the reconstituted recipient had been suppressed. In addition, the immune response to both the hapten dinitrophenol (DNP) and the carrier (HGG) were suppressed when recipients of tolerant and normal spleen cells were challenged with DNP6HGG. This indicates that T helper cells are also a target for suppression. The results presented in this paper are discussed in relation to a possible mechanism of suppression which proposes that suppressive activity represents the induction of tolerance in immunologically competent cells by HCG which is closely associated with the tolerant spleen cells.     

Immunologic tolerance to HGG in mice. I. Suppression of the HGG response in normal mice with spleen cells or a spleen cell lysate from tolerant mice.

Adoptive transfer of spleen cells or spleen cell lysates from mice tolerant to human-gamma-globulin (HGG) specifically suppressed the response of normal syngeneic recipients to HGG. The suppressive activity could be transferred for over 100 days after tolerance induction. The suppression induced by both spleen cells and spleen cell lysate was found to be specific as evidenced by a normal response to a challenge with turkey-gamma-globulin or goat erythrocytes. The activity of the suppressive lysate could be removed by passing the material through an HGG immunoadsorbent column but not by passing it through an anti-HGG column or a BSA column. These results indicated that the factor had antigen specificity and was probably not antigen-antibody complexes. That this suppression was not due to a shifting of the kinetics of the antibody response has also been demonstrated. The antigen-specific suppressor factor in the tolerant spleen cell lysates was a protein with a m.w. of approximately 45,000 daltons. The kinetics of the appearance of both suppressor cells and suppressor factor were consistent with a mechanism of active suppression functioning in the maintenance of tolerance to HGG.     

Suppressor cells in tolerance to HGG: kinetics and cross-suppression in high dose tolerance--absence in low dose tolerance.

Spleen cells from mice made tolerant with high doses of human gamma-globulin (HGG) specifically suppress the immune response of normal, syngeneic, spleen cells. These suppressor cells were found to be cross-reactive in that they would suppress the immune response of normal spleen cells to bovine gamma-globulin (BGG) as well as to HGG. In contrast, suppressor cells could not be demonstrated in spleens of mice made tolerant with low doses of HGG (i.e., T-cell tolerance), nor could they be found in high dose tolerant mice following a second injection of DHGG at a time when the initial suppressor activity had waned. The role of suppressor cells in the induction, maintenance, and loss of tolerance is discussed.     

Suppressors of the graft vs graft reaction in tolerance to alloantigens

Immune response and suppressor cell activity of CBA (H-2k) mice made tolerant to allogeneic C57B1/6 (H-2b) heart graft were studied in graft-versus-graft reaction (GvGR). Intact CBA spleen cells inhibited response of (CBA X C57B1/6)F1 cells to antigenic stimulus (sheep red blood cells--SRBC), when injected together into lethally irradiated (CBA X C57B1/6)F1 mice. Spleen cells of tolerant mice were unable to decrease immune response of (CBA X C57B1/6F1 lymphocytes to SRBC and suppressed specifically the inhibition induced by intact CBA spleen cells. Spleen cells from tolerant mice were also capable of suppressing GvGR induced by CBA lymphocytes immune to C57B1/6 cells. Pretreatment of tolerant spleen cells with rabbit antithymocyte globulin and complement before adoptive transfer diminished markedly the suppression. The results obtained in the study suggest that suppression of transplantation immunity in this model is mostly due to T suppressor cells.     

Direct demonstration of specific suppressor T cells in the mice tolerant to type III pneumococcal polysaccharide: two-step requirement for development of detectable suppressor cells

Spleen cells from CAF1 mice made tolerant to type III pneumococcal polysaccharide (S3) with S3 coupled to syngeneic spleen cells (S3-SC) develop S3-specific suppressor T cells (Ts). These Ts could be demonstrated consistently only when spleen cells from tolerant mice were cultured in vitro with the specific antigen and the specific tolerogen. Spleen cells from normal mice cultured under the same conditions did not suppress the antibody response to S3. When different numbers of Ts were transferred to normal CAF1 mice, an unusual dose-effect pattern was observed. Maximal suppression of the S3 response occurred when relatively low numbers of Ts, 3 to 30 x 10(5) per recipient, were transferred, whereas larger numbers of cells, 150 x 10(5) per recipient, were not suppressive. These results indicate that a presumably T-independent antigen, S3, can activate antigen-specific Ts. These Ts exhibit unusual dose effects upon transfer and require both an in vivo induction period and in vitro activation for development of maximal activity. These latter observations suggest that S3 may activate a different population of T cells with suppressor function than do conventional T-dependent antigens. The loss of suppression observed when greater than optimal numbers of cells were transferred suggests that a second type of T cell, which has the ability to 'neutralize' the activity of S3-specific Ts, is also induced in the same spleen cell population.     

Induction of immunologic tolerance in nursing neonates by absorption of tolerogen from colostrum.

Deaggregatedhuman gamma-globulin (DHGG) injected into female mice within 24 hr after delivery of a litter enters the colostrum and is absorbed intact through the intestine by nursing neonates. This absorbed HGG was present in the neonatal circulation at concentrations of 0.3 to 0.6 mg/ml of serum under the experimental conditions used. This absorption of HGG by the nursing neonate resulted in a complete, specific, tolerant state to HGG. This tolerant state was stable upon adoptive cell transfer and could not be abrogated by transfer of normal syngeneic spleen cells.     

Establishment of unresponsiveness in primed B lymphocytes in vivo

As an approach to examine the influence of the state of cellular activation on the ability to tolerize B cells, the induction of unresponsiveness in human gamma-globulin-(HGG) primed B lymphocytes was studied in an adoptive transfer system. In contrast to transferred normal spleen cells, spleen cells from HGG-primed mice are not readily rendered unresponsive when exposed to the tolerogen, deaggregated HGG (DHGG), in irradiated recipients. A kinetic study showed that unfractionated primed spleen cells do not respond to an antigenic challenge given between 6 and 10 days after cell transfer and injection of DHGG, indicating that they are transiently depressed. In contrast, isolated primed B cells are tolerized when transferred to recipients and treated with DHGG in the absence of T cells. Furthermore, primed B cells exposed to tolerogen in the recipients do not recover the ability to respond to HGG either after a secondary challenge with AHGG given up to 14 days after transfer, or after 2 consecutive challenges given on days 14 and 24 after transfer. The presence of primed T cells at the time of tolerization interferes with the induction of unresponsiveness in these primed B cells. These studies suggest that the presence of primed T cells is responsible for the inability to tolerize unfractionated primed spleen cells populations and that primed B cells themselves are not intrinsically resistant to the induction of unresponsiveness.     

A study of the mechanism of Con A-induced immunosuppression in vivo

The plaque-forming cell (PFC) response to sheep erythrocytes (SRBC) is suppressed in a dose-related manner when concanavalin A (Con A) is administered intravenously to mice prior to or after immunization with antigen. The magnitude of suppression as well as the duration of the Con A effect greatly depends on the concentration of antigen used for immunization. Although profound suppression of the anti-SRBC PFC response is observed in intact mice pretreated with Con A for 4-24 hr, spleen cells from these mice do not exhibit suppressive activity when transferred into normal recipients or when cotransferred with normal spleen cells into irradiated recipients. Moreover, the cells from Con A-treated mice respond as normal spleen cells to SRBC when transferred alone into irradiated hosts. Suppression of the anti-SRBC PFC is only observed when adoptive hosts of cells from Con A-treated mice are also injected with Con A within 48 hr (but not 72 hr) of cell transfer and immunization. This time course of responsiveness to the suppressive effects of Con A is similar to that observed in normal mice and in irradiated recipients of normal spleen cells. The immune response to SRBC is also suppressed in adoptive hosts of normal spleen cells that are pretreated with Con A 4-24 hr prior to irradiation and cell transfer. Although functionally inactive when transferred into adoptive hosts, spleen cells from mice pretreated with Con A for 4-24 hr can suppress a primary antibody response to SRBC in vitro. The suppressive activity, which cannot be detected in the spleens of mice when the interval between pretreatment and assay is longer than 24 hr, is present in a subpopulation that bears the Thy 1.2 and Lyt 2 phenotype. Taken together the results obtained in in vivo and in vitro functional assays suggest that a suppressor cell population is activated following in vivo treatment with Con A, but that the cells rapidly lose their state of activation when removed from a Con A environment. This phenomenon is in all probability responsible for the failure to demonstrate suppressive activity in the spleens of Con A-treated mice using in vivo functional assays.     

Absence of suppression in natural and induced tolerance to F antigen

The role of suppression in natural and induced tolerance to F antigen was investigated in two sets of experiments. In the first, CBA mice were submitted to pretreatments which decrease suppression and the antibody response to self- or allo-F type was investigated. The second set of experiments involved the transfer of spleen cells from tolerized or from naturally tolerant mice into normal mice which were then primed with allo-F, as well as the co-transfer of tolerant and primed lymphocytes into normal mice, to test whether tolerant lymphocytes present suppressor cells. The results indicate that the immune response against allo-F antigen is normally kept in a low level by a suppressive mechanism, and that F-specific suppressor T cells are absent from tolerant mice.Abbreviations used in this paper ATx adult thymectomy - BSS buffered salt solution - CFA Freund's complete adjuvant - CY cyclophosphamide - F.1 type-1 F antigen - F.2 type-2 F antigen - PBS phosphate-buffered saline - RIA radioimmunoassay - Th T helper cell - Ts T suppressor cell     

Immune suppression in vivo with antigen-modified syngeneic cells. II. T cell-mediated nonresponsiveness to fowl gamma-globulin.

Intravenous administration of syngeneic spleen cells coupled with the palmitoyl derivative of fowl gammma-globulin (p-F gamma G) results in a profound state of F gamma G-specific tolerance in C57BL/6 mice. Administration of p-F gamma G coupled syngeneic cells specifically reduces both the primary and secondary hapten and carrier-specific PFC responses to TNP-F gamma G. Since the haptenic response is affected, the tolerance functions at the level of the F gamma G-specific helper T cell. As few as 10(3) p-F gamma G spleen cells carrying only 1 ng of p-F gamma G can induce tolerance. At least a 2-day-induction period is required. This nonresponsiveness is long lived, lasting over 120 days. Spleen cells from tolerized mice can transfer suppression to normal syngeneic recipients. Treatment of tolerant spleens with anti-Thy 1.2 antiserum + C eliminates the suppressor cell activity. In addition, thymocytes and purified splenic T cells from tolerized mice can transfer suppression to normal recipients. Thus, at least a component of this nonresponsiveness is mediated by suppressor T cells. The requirement of antigen association with cell membrane components and the general applicability of this method of inducing T cell nonresponsiveness are discussed.     

Specific suppression of the immune response by a factor obtained from spleen cells of mice tolerant to human gamma-globulin.

An antigen-specific suppressive factor was extracted from spleen cells of mice made tolerant by injection of deaggregated human gamma-globulin (HGG). The active material could be prepared from T cells, obtained by passaging spleen cells through an anti-immunoglobulin column, although not from cells adherent to the column nor from spleen cells pretreated with anti-Thy-1 serum and C. This factor was antigen-specific since it was retained on immunoadsorbents containing HGG, but not on columns coated with antibody to HGG or with irrelevant antigens. Despite its specificity for antigen it did not bear any classical immunoglobulin determinants. Its m.w. ranged between 30,000 and 55,000 daltons. It was a product of the I region of the major histocompatibility complex since it carried Ia determinants. The properties of this factor are very similar to those reported elsewhere for suppressive factors obtained from primed T cells, cells from nonresponder mice, and allotype-specific cells. This suggest the existence of a major class of immunoregulatory molecules, nonimmunoglobulin in nature, and responsible for the mediation of antigen-specific T cell-dependent suppression.     

Tolerance induced by TNP-derivatized syngeneic erythrocytes: evidence for cooperation between hapten-specific T and hapten-specific B lymphocytes in the immune response.

Tolerance to the DNP haptenic determinant was induced with a single i.v. injection of trinitrophenylated syngeneic red blood cells. The tolerant state lasted 1 month and was stable on transfer to irradiated thymectomized syngeneic recipients. Suppressor activity was found soon after injection of tolerogen but was lost before the termination of tolerance. The unresponsive state could be reversed by adding normal thymus cells to tolerant spleen cells but not by normal bone marrow cells. LPS when given with immunogen restored the normal immune response in tolerant mice. Thus the injection of TNP-MRBC induced partial immune unresponsiveness which was characterized by the induction of T cell suppressor activity and by a hapten-specific helper T cells tolerance. Finally, these studies suggest a cooperative interaction between DNP-specific T lymphocytes and DNP-specific B lymphocytes in the immune response to DNP-BGG.     

BCG-induced suppressor cells. I. Demonstration of a macrophage-like suppressor cell that inhibits cytotoxic T cell generation in vitro.

Spleen cells obtained from mice 5 to 40 days after infection with viable BCG organisms (BCG-spleens) were found to be unresponsive in vitro to both mitogenic and alloantigenic stimuli. Moreover, suppressor cells could be demonstrated in the spleens from these infected animals. When spleen cells from BCG-infected mice were added to either syngeneic or allogeneic normal spleen cells, the mixtures neither proliferated nor developed cytotoxic activity when cultured with alloantigen or with concanavalin A (Con A). The development of unresponsiveness post-infection paralleled the onset of suppressive activity. Spleen cells obtained from mice given heat-killed BCG were neither suppressive nor unresponsive. The suppressive activity of BCG-spleen cells was associated with an adherent, phagocytic cell that lacked membrane-associated Thy-1 antigen. Removal of this cell by passage through nylon wool columns resulted in a cell population that was no longer capable of suppression and that responded normally to alloantigen and to Con A. It would thus appear that BCG infection results in the development of a "suppressor" macrophage-like cell population within the spleen. The role of this cell type in regulation of the immune response in BCG-infected animals is as yet undefined.     

Regualtion of the immune response to tumor antigens. I. Immunosuppressor cells in tumor-bearing hosts.

A/Jax mice were rendered immune to the syngeneic and transplantable methylcholanthrene-induced Sarcoma 1509a by the surgical removal of the tumor 7 days after implantation; subsequent injection i.v. transfer of 10(7) to 10(8) washed thymus or spleen cells of tumor-bearing animals (TBA) to immune animals significantly inhibited the rejection of the tumor; this suppressive effect was entirely abolished by the treatment of these lymphocytes with anti-theta serum or anti-thymocyte serum (ATS) and complement before adoptive transfer. On the other hand, an equal number of thymus or spleen cells of normal animals or of animals bearing an unrelated tumor had no suppressive effect. Treatment of normal syngeneic animals with ATS after tumor cell inoculation or splenectomy of TBA resulted in the suppression of the tumor growth. The serum of TBA had no effect on tumor growth in immune syngeneic mice. Together these results suggest that TBA possess immunosuppressor T cells regulating negatively their immune response to the tumor.     

Studies on the resistance to tolerance induction against human IgG in DDD mice. I. Organ differences of tolerogen susceptibility and cellular sites responsible for the resistance.

Cellular sites of the tolerogen resistance in DDD mice against human IgG (HGG) were examined by reconstitution experiments in which cells of various lymphoid organs from tolerized mice were transferred into lethally irradiated syngeneic recipients with or without the supplement of an excess number of untreated T or B cells. It was shown that T cells but not B cells in the spleen and bone marrow-locating B cells were tolerogen resistant. Kinetic profiles of tolerance induction were compared among thymus, lymph node, and spleen T cells. Thymus cells fall into unresponsive state as early as 2 days after the tolerogen (tHGG) injection when only partial tolerance was observed in lymph node T cells. By 1 week of tolerogen treatment, the tolerant state was completed in both thymus cells and lymph node T cells, while spleen T cells showed marked resistance. Tolerance induced in thymus cells and spleen T cells was of relatively short duration and responsiveness was completely recovered by 5 weeks after the injection of tHGG. At this time lymph node T cells still showed hyporesponsiveness. The differences in tolerance inducibility were also shown among different lymphoid organs in tolerogen dose response. Lymph node T cells were very sensitive to tolerance induction, giving no response even by the injection of 0.01 mg of tHGG. Thymus cells were much less sensitive with the gradual loss of responsiveness by increasing the amount of tHGG. In contrast, spleen T cells showed gradual resistance with increasing amount of tHGG, indicating that some positive response was evoked in spleen T cells by a relatively high dose of tHGG. These results seem to suggest that the tolerogen resistance of spleen T cells may be due to their capability of showing positive response against the tolerogenic material. This was also suggested by the fact that the treatment with cyclophosphamide following the tolerogen injection diminished completely the responsiveness against the subsequent challenge immunization.     

B Cell Tolerance

The mechanisms of B cell tolerance were studied in an attempt to learn whether B cells rendered tolerant are present in the immune system in a potentially responsive form. The author tested the in vitro anti-trinitrophenyl (TNP) antibody-forming cell (anti-TNP AFC) response to TNP-immunogens and polyclonal B cell activators (PBA) of spleen cells taken from mice injected with a tolerogen, TNP-carboxymethylcellulose (TNP-CMC). Spleen cells from mice injected 5 days previously with 10 μg of TNP-CMC did not respond to TNP-sheep red blood cells (TNP-SRBC), T-dependent (TD) antigen or TNP-Ficoll, T-independent (TI) antigen. However, the same spleen cells responded to PBA, lipopolysaccharide (LPS) of Salmonella enteritidis and purified protein derivative (PPD) of BCG. The results indicate that B cells specific for TNP are present in a potentially responsive form. Spleen cells from mice injected with 500 μg of TNP-CMC did not respond to either TNP-immunogens or PBA. The state of unresponsiveness to PBA lasted for 12 days after the tolerogen injection. Responsiveness to PBA reappeared within the short period of 2 days, whereas unresponsiveness to TNP-immunogens lasted much longer. Unresponsiveness to PBA was relieved considerably by treating tolerant spleen cells with the proteolytic enzyme trypsin before in vitro stimulation. These results indicate that B cells rendered refractory are present in the immune system in a potentially responsive form.     

Analysis of certain mechanisms of antigen-specific suppression of the immune response

CBA mice were immunized with sheep red blood cells (SRBC) to obtain immune spleen cells (ISc) which were used to suppressor cells. Administration of ISC to intact syngeneic recipients on the immunization day led to a more powerful suppression of the immune response as compared to that seen one day after antigen injection. Four days after immunization the animals' immune response was not liable to be suppressed. ISC extract possessed similar effects with respect to the immune response of normal spleen cells which were transplanted to the cyclophosphamide-treated recipients. The immune response of spleen cells from mice immunized with SRBC in a dose of 10(6) was less liable to be suppressed. Hyperimmune spleen cells from donors immunized with SRC in a dose of 10(9) were insensitive to ISC or to the extract. Experiments with the use of adoptive transfer of a mixture of immune and intact T- and B-cells have disclosed that B-cells from hyperimmune donors were resistant to suppression. Therefore, B-lymphocytes are the most probable target cells exposed to T-suppressors in the given system. The mechanism is discussed of the selective effect of T-suppressors on B-cells in the course of the immune response development during immunization with high doses of antigen.     

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.     

Mechanisms of tumor-induced immunosuppression: evidence for contact-dependent T cell suppression by monocytes.

BACKGROUND: The progressive growth of tumors in mice is accompanied by down-regulation of specific T cell responses. The factors involved in this suppression are not completely understood. Here, we have developed a model to examine the role of host immune effector cells in the inhibition of T cell function. In this model, progressive growth of a colon carcinoma line, CT26, is accompanied by loss of T cell response to alloantigens in both cytolytic and proliferation assays. MATERIALS AND METHODS: The CT26 tumor was inoculated into BALB/c syngeneic mice. Tumor growth, cytolytic T cell responses, lymphocyte proliferation, and flow cytometric analysis was performed in tumor-bearing animals 7 or 28 days after tumor inoculation. RESULTS: Spleen cells from tumor-bearing mice were found to suppress the proliferative response of spleen cells from normal mice to alloantigens. Examination of the spleen cell population by FACS analysis revealed an increase in the percentage of monocytes as defined by expression of CD11b, the Mac-1 antigen. Removal of the Mac-1-positive cells from the tumor-bearing hosts spleen relieved suppression of the tumor-bearing mouse spleen cell proliferative response to alloantigens, and addition of the Mac-1-positive enriched cells suppressed proliferation of normal T cells in response to alloantigens. Cell contact was required for this inhibition. CONCLUSIONS: Tumor induction of suppressive monocytes plays an important role in the general immunosuppression noted in animals bearing CT26 tumors. Identification of the mechanisms responsible for this effect and reversal of tumor-induced macrophage suppression may facilitate efforts to develop effective immunotherapy for malignancy.     

Maturation of the lymphoid system. I. Induction of tolerance in neonates with a T-dependent antigen that is an obligate immunogen in adults.

A/J mice displayed a striking ontogenetic difference in the capacity to respond to DNP-Ficoll, a T-independent antigen, and to aggregated human gamma-globulin (AHGG), a T-dependent antigen. Thus, whereas responses to DNP-Ficoll of 4-day-old mice were similar in magnitude to those of adult animals, responses to AHGG did not become pronounced until mice were some 30 to 40 days of age. The inability of young animals to respond to AHGG was reflective of a negative consequence of lymphocyte/antigen interaction, since such mice became specifically unresponsive to subsequent challenges with AHGG. Unresponsiveness induced by neonatal injection of AHGG lasted 50 to 60 days, in contrast to that induced by deaggregated HGG, which persisted some 100 days longer. The unresponsive state induced by injection of neonates with AHGG maintained itself upon adoptive transfer and did not appear to be linked to suppressive factors associated with either serum or lymphoid cells for its maintenance. Finally, AHGG was also shown to be capable of inducing unresponsiveness in neonatal, athymic mice. These results demonstrate that AHGG, the normally immunogenic form of HGG in adult mice, can serve as an effective tolerogen when administered into a neonatal environment.