Unique homing properties of nonadherent peritoneal cells

The nonadherent lymphocytic cells from the peritoneum after ⁵¹Cr labeling and intravenous injection into normal syngeneic recipient mice were observed to distribute in a different manner from spleen and lymph node lymphocytes. These differences in dynamic behavior occurred despite the morphologic similarities of the cells. Such patterns of distribution were directly related to cell viability since heat-killed cells migrate in a distinctly different manner. Treatment of lymph node, spleen, and non-adherent peritoneal cells with anti-θ serum to eliminate T cells modified the dynamic behavior of all the cell populations somewhat, but did not eliminate major differences in the distribution patterns of nonadherent peritoneal “lymphocytes” compared to lymph node and splenic lymphocytes. The suggestion is made that the peritoneal lymphocyte differs from other lymphocytes.     

Characterization of bovine mononuclear cell populations with natural cytolytic activity against bovine herpesvirus 1-infected cells

Freshly isolated or overnight cultured peripheral blood mononuclear cells from immune or nonimmune animals had natural cytolytic activity against bovine herpesvirus 1 (BHV-1)-infected tumor target cells. No lysis was demonstrated against tumor target cells alone. This natural cytolytic activity was present in mononuclear cells from the spleen, lymph node, and peripheral blood but little or no cytolytic activity was detected in bone marrow or thymus cells. When monoclonal antibodies and complement to deplete bovine mononuclear cell subpopulations from the nonadherent cells were used, results indicated the effector cell was not a T cell, B cell, or activated monocyte. From nonadherent populations separated on density gradients, it was determined that the effector cells were large, low density mononuclear cells. These results indicate the nonadherent effector cells mediating lysis of BHV-1-infected xenogeneic adherent target cells were large null lymphocytes and/or immature monocytes.     

Adherent cells in tumor immunity

The present studies explored the role of adherent cells in tumor immunity. Lymph node cells from mice bearing large tumors appeared to be maximally stimulated in vivo and incapable of further stimulation by cells of the same tumor in vitro. Removal of the adherent cell population resulted in a marked decrease in the spontaneous background activity of the remaining nonadherent cells and allowed these cells to undergo stimulation when cultured in the presence of mitomycin-blocked tumor cells. The role of the adherent cell in the maintenance of a state of continuous stimulation was further elucidated by experiments in which lymph node cell populations were reconstituted from the adherent and nonadherent subpopulations. It was also shown that adherent lymphoid cells from tumor-bearing mice, but not from normal mice, were capable of stimulating tumor-immune lymphocytes in a manner similar to intact mitomycin-blocked tumor cells.     

Immunization of susceptible BALB/c mice against Leishmania braziliensis. I. Resistance induced using as immunogen adherent or nonadherent cells from infected mice

Strategies to produce resistance to infection with Leishmania braziliensis in BALB/c mice are described. Mice infected with virulent parasites were used as spleen cell donors (adherent/nonadherent cells) with which to immunize naive recipients which were themselves later challenged with the organism. Immunization with both adherent and nonadherent spleen cells (but not serum) in the presence of adjuvant led to protection. In the former case it seems that an immunogenic form of parasite antigen presented in the context of MAC-1+ adherent cells was responsible. In contrast immunization with nonadherent spleen cells depended upon the presence of Thy-1.2+ Lyt-1+ cells in the spleen cell preparation from infected animals. Immunization with adherent cells, but not with nonadherent cells, led to the development of a population of Thy-1.2+ spleen cells capable of adoptively transferring resistance to naive mice.     

Peripheral tolerance induced in lymph nodes by syngeneic spleen cells inhibits generation of CTLs to hapten-altered self antigens but not to alloantigens.

The immunological tolerance that is induced in lymph nodes that have been exposed to syngeneic spleen cells has been examined. Development of cytotoxic T lymphocytes was used to assess the immunological status of the lymph node cells. The tolerance was studied from the viewpoint of its induction, its activation, and its specificity. We had already reported that injecting either T or B cells of splenic origin into a regional lymph node environment a week prior to immunization for CTL to hapten-altered self antigens prevents development of the CTL. Here, we confirm that syngeneic splenic cells but not lymph node cells will induce the suppression provided that spleen cells are not coupled with hapten. We now report that splenic cells that cannot replicate or synthesize and secrete protein are capable of inducing the suppression. The data suggest a preformed surface marker peculiar to spleen cells and perhaps on cells that traverse the thymus induces local tolerance that is mediated by suppressor cells. Triggering the induced suppressor T cells (previously identified as CD8-) was achieved by syngeneic spleen cells as well as by H-2-compatible, Mls-disparate spleen cells but not by syngeneic lymph node cells or apparently by allogeneic spleen cells. Furthermore, triggering suppression was achieved by hapten-coupled syngeneic spleen cells whereas such cells would not induce the suppression. Thus, activating the suppressor cells requires reexposure to splenic cells of the proper MHC haplotype, unaltered or coupled with either TNP or FITC. Once triggered, the suppression was manifested toward CTL generation against hapten-coupled syngeneic antigens on either spleen or lymph node cells but not against allogeneic antigens. Thus, the specificity of the tolerance was directed to altered self antigens despite its induction by unaltered spleen antigen. Furthermore, for suppression to be seen the spleen antigen was not required to be on the hapten-coupled syngeneic cells used for the CTL immunization. The relationship of the splenic cell "antigen" to hapten-altered self antigens and to other surface markers and its site of acquisition within the body and its significance for cell homing have become intriguing questions of importance. This information has been discussed from the viewpoint of its applicability to autoimmune diseases as well as to cessation of inflammatory reactions that may be mediated by lymph node cells.     

Spontaneous helper factor production by nonadherent rabbit lymphoid cells and its feedback regulation by adherent cells

Normal, unstimulated rabbit lymphoid cells, when depleted of adherent cells, produced soluble helper factor activity that augmented antibody formation by rabbit spleen cells primed against sheep red blood cells (SRBC). Adherent cells inhibited the production of the helper factor by nonadherent cells via a soluble product. Thus unseparated (adherent cell-containing) appendix, lymph node, and spleen cell cultures did not produce the helper factor. On the other hand, the activity of the helper factor required the presence of adherent cells in the assay cultures. Peritoneal exudate cells, predominantly esterase positive, also inhibited the production of the helper factor if they were first exposed to the helper factor-containing culture supernatant. These results imply that a helper factor may participate in the feedback regulation of its own production via an adherent cell population.     

Comparative activation requirements of human peripheral blood, spleen, and lymph node B cells

Human peripheral blood, spleen, and lymph node B cells were stimulated with Cowan I Staphylococcus aureus (SA) or F(ab')2 fragments of anti-mu antibody (anti-mu) and various lymphokines and were analyzed for proliferation and generation of Ig-secreting cells (ISC). SA alone but not anti-mu stimulated minimal proliferation of each population. Recombinant IL 2 (r-IL 2) effectively promoted proliferation of SA-stimulated blood and spleen B cells, but supported less vigorous responses of lymph node B cells. By contrast, r-IL 2 enhanced DNA synthesis of all anti-mu-stimulated B cells early in culture, but did not promote sustained proliferation of anti-mu-stimulated lymph node B cells and only promoted ongoing DNA synthesis of some anti-mu-activated blood (eight out of 17) and spleen (five out of 14) B cell preparations. Recombinant interferon-gamma (r-IFN-gamma) and a commercial preparation of B cell growth factor (BCGF) also augmented DNA synthesis of all three B cell populations stimulated with SA or anti-mu early in culture, but neither alone was able to sustain maximal proliferation. Markedly enhanced sustained proliferation of all three anti-mu- and SA-stimulated B cell populations was noted when cultures were supported by the combination of r-IL 2 and BCGF, or to a lesser extent by r-IL 2 and r-IFN-gamma. The generation of ISC from SA-stimulated blood or spleen but not lymph node B cells was effectively supported by r-IL 2 alone. Differentiation of lymph node B cells required the combination of r-IL 2 and BCGF. These studies emphasize the importance of both the activation stimulus and the origin of the B cells in determining the lymphokine requirements of human B cell responsiveness.     

Tolerance induction to a thymus-dependent antigen in vitro: treatment of nonadherent cells with tolerogen biologically filtered in vitro

Highly tolerogenic bovine gamma globulin (BGG), a thymus-dependent antigen, was prepared by biologic filtraration in vitro. It readily induced tolerance in vivo in BALB/c mice and also rendered their nonadherent lymph node cells tolerant after in vitro incubation. Biologic filtration in vitro was carried out by incubating 2.5 × 10⁷ lymph node cells with 10 mg of nontolerogenic BGG in 10 ml of Eagle's medium containing 2% normal mouse serum at 37 °C for 6 hr. The BGG-containing medium was clarified by centrifugation and was used without further dilution.For tolerance induction in vitro, lymph node cells were separated into adherent and nonadherent populations on Falcon plastic. These cells were incubated for 0–18 hr at 37 °C with biologically filtered BGG (bBGG). After incubation, the cells were washed three times and (2–2.5) × 10⁷ nonadherent or 4 × 10⁶ adherent cells were injected iv with their untreated counterpart into lethally irradiated mice which had received 10⁶ bone marrow cells. The recipients were then challenged with 300 μg of aggregated BGG, and tolerance was assayed by the elimination of labeled BGG, rosette formation, and passive hemagglutination. Spleen cells were similarly treated for comparison. Our findings show that tolerance was not induced in vitro in adherent lymph node cells. However, in the nonadherent populations, those from the lymph node but not the spleen were rendered tolerant. The acquisition of tolerance in vitro was gradual. It was dependent upon the length of exposure to bBGG and required at least 6 hr.     

Immunopotentiating effects of amphotericin B. II. Enhanced in vitro proliferative responses of murine lymphocytes.

Enhanced in vitro proliferative responses to DNBSO3 were seen in lymph node cells and spleen cells after in vivo sensitization of mice with DNFB plus AmB compared with mice primed with DNFB alone. The T cell proliferation in the nylon column nonadherent fraction for both groups was highly similar, and the enhanced lymph node cell proliferation with AmB was demonstrated to be in the nylon adherent population consisting of both T and B cells. These and earlier studies of immunopotentiation by AmB are consistent with a mechanism that depends on selective interaction of the polyene with a subset of T cells and a resultant impairment of the normally induced suppressor regulation that limits the magnitude and duration of immune responses.     

A suppressor cell which interferes with antiallotype stimulated DNA synthesis of rabbit B cells

Responsiveness of rabbit spleen cells to anti-allotype antibody was measured in terms of increased thymidine incorporation. Incorporation was enhanced after removal of cells which had ingested or had adhered to magnetic particles. B lymphocytes, prepared from spleen cells by the removal of adherent cells and of RTLA bearing T cells, were more responsive to anti-allotype antibody than were the original spleen suspensions. This increase could not be explained by enrichment in B cells. It was concluded that an adherent cell suppressed B cell transformation. The addition of 2-mercaptoethanol to the cell cultures stimulated with mitogen augmented the incorporation of thymidine. Adherent cells interfered with 2-mercaptoethanol potentiation in the response to anti-allotype antibody but not in the response to Con A. Fractionation of spleen cells, over glass bead columns, yielded nonadherent and adherent cell populations. The responsiveness of nonadherent cells to anti-allotype induced thymidine incorporation was two to six times that of unfractionated cells. The responsiveness of nonadherent cells to stimulation by anti-allotype antibody was reduced after addition of adherent cells. Findings were discussed in terms of the inhibitory role played by adherent cells on anti-allotype antibody induced responsiveness of rabbit B cells and of the possible participation of a third cell type which functions as a promotor of mitogenic T cell stimulation.     

Effects of isolated tumor lymphocytes alone and with adherent cells

Summary The effect on the growth of gradient-isolated mouse mammary tumor cells of different populations of lymphoid cells were evaluated in micrototoxicity assays. Variable effects were obtained with tumor-bearer lymph node and spleen cells: in some experiments growth stimulation occurred, whereas in others inhibition was observed. Mixed effector populations gave more regular results: adherent spleen cells added to lymph node or spleen lymphocytes inhibited tumor cell growth in six of nine experiments; inhibition occurred when either of the effector populations in the mixture was derived from the tumor-bearing mouse. Tumor-associated lymphoid cells (TAL) stimulated growth of the tumor cells in five of seven experiments. However, TAL inhibited tumor growth when combined with adherent spleen cells from tumor-bearing animals. In contrast with the peripheral lymphoid cells, admixture of control adherent cells from normal animals with TAL did not inhibit growth. No natural killer effect was seen in these growth inhibition assays. These data indicate that lymphoid populations capable of inhibiting tumor cell growth can be found in tumor-bearing animals, but such combination of active cells are not present at the tumor site.     

Macrophage activation of allogeneic lymphocyte proliferation in the guinea pig mixed leukocyte culture.

The role of the macrophage in the guinea pig mixed leukocyte culture was investigated. Macrophages obtained from oil-induced peritoneal exudates, peritoneal wash-out cells, spleen, and alveolar washings were found to be effective stimulators of allogeneic lymph node and splenic lymphocyte DNA synthesis. The stimulatory properties of macrophages proved radioresistant but viability dependent. Unfractionated lymph node cells or adherence column purified lymph node lymphocytes and thymocytes were only minimally active as stimulators, even in the presence of macrophages syngeneic to the responder lymphocytes. Allogeneic fibroblasts, polymorphonuclear leukocytes, L2C leukemia cells, and xenogeneic (murine) macrophages failed to simulate. These data provide evidence that the macrophage is the predominant stimulator of the mixed leukocyte culture in the guinea pig.     

The accessory cell function of murine Peyer's patches

The cellular composition and certain functional characteristics of murine Peyer's patches (PP) were examined and compared with other lymphoid tissues. The composition of PP resembled most closely that of the spleen with the exception of a significant decrease in the number of adherent and phagocytic cells. Very few cells with dendritic morphology could be identified in Peyer's patches. Whole PP (and the nonadherent population) were capable of presenting antigen ovalbumin, human gammaglobulin, and purified protein derivative in a T proliferative assay to sensitized lymph node cells and to an antigen-specific T-cell clone. The antigen-presenting cell in both the spleen and PP was concentrated in the low-density population which floated on 1.080 bovine plasma albumin. However, equal numbers of whole and PP floaters were deficient in their capacity to present antigen compared with similar populations from spleen. Moreover, in PP the antigen-presenting cell appeared in the nonadherent rather than the adherent population as found with other lymphoid tissues. Similar results were obtained with (B6A)F1, CBA, A.TFR-1 and B10.S (12R) mice, suggesting that the inability of adherent cells from PP to present antigen effectively was not genetically determined. Whole and nonadherent PP contained cells capable of stimulating an allogeneic MLR, although again they were generally inferior to those of the spleen when comparable numbers of cells were employed. The adherent population of PP did not elicit an MLR. However, whole PP contained accessory cells needed for mitogen-induced proliferation since passage over nylon-wool columns resulted in a nonadherent fraction which did not respond to concanavalin A or phytohemagglutinin and the addition of adherent peritoneal exudate cells restored the lectin response. The differences noted in the accessory cell function in PP and other lymphoid tissues suggest the possibility that quantitative or qualitative differences in the function of these cells may explain some of the previously observed characteristics of PP, such as the inability to detect a primary antibody response in this tissue. The possibility that the development of gut-associated suppressor cells and their migration to peripheral tissues may be involved in the systemic tolerance that follows oral immunization and that these may be related to numerical and/or functional differences in macrophages or accessory cells is discussed.     

Studies of the T-lymphocytes resident in the spleens of thymectomized, irradiated, bone marrow-reconstituted (TXB) mice.

The T-lymphocytes resident in the spleens of thymectomized, lethally irradiated mice that had been reconstituted with syngeneic bone marrow (TXB) were characterized. Both recently reconstituted N-TXB, (approximately 3 weeks after bone marrow injection) and aged (>6 months after reconstitution) A-TXB animals were studied. The T-lymphocytes from spleens of recently reconstituted N-TXB donors did not respond to PHA but did react significantly to Concanavalin A (Con A). The lack of PHA sensitivity was not due to dilution of reactive cells by other cell types. Removal of adherent cells, likewise, did not restore N-TXB spleen cell PHA responsiveness. N-TXB splenic T-cells were cortisone resistant. N-TXB spleen cells by themselves did not cause a graft vs host response. However, N-TXB spleen cells amplified the graft vs host response of normal lymph node cells but not N-TXB lymph node cells. Addition of cyclic GMP enhanced [³H]thymidine uptake of N-TXB spleen cells caused by Con A. N-TXB spleen cells were exclusively spleen seeking. The Con A reactive cell within N-TXB spleens was demonstrated to be of donor origin. Fetal liver as well as syngeneic bone marrow contained cells capable of reconstituting the Con A response. Spleen cells from aged. (>6 months) A-TXB were found to be PHA sensitive. Competitive inhibition assays measuring θ expression in A-TXB spleen cells indicate a significant increase in the θ positive lymphocyte population occurred with time. The data indicate that considerable reconstitution of θ positive cells had occurred in A-TXB donors. The results also suggest that the T-lymphocyte population of the TXB spleen may be a unique subpopulation of T-lymphocytes that resides exclusively in spleen and bone marrow.     

Suppressor cell activity in tumor-bearing mice. I. Dualistic inhibition by suppressor T lymphocytes and macrophages.

Spleen cells from mice bearing methylcholanthrene-induced fibrosarcomas impaired mitogen responses of normal syngeneic lymphocytes. Nylon wool column and other depletion techniques were utilized to characterize the cellular source of suppressive activity in tumor-bearing host (TBH) spleens. Evidence is presented for two distinct suppressor cell systems operating in the spleens, but not lymph nodes, of BALB/c mice bearing transplanted tumors. Spleens from TBH were shown to have greatly increased numbers of macrophages over their normal counterparts. TBH macrophages were observed to have suppressive activity at low in vitro concentrations. Anti-Thy 1 serum treatment of TBH macrophages abrogated low dose inhibition but not suppression due to high numbers of macrophages. No functional difference was detected between anti-Thy 1 serum-treated TBH and normal splenic macrophages. In a macrophage-depleted culture system, mildly nylon wool adherent, anti-Thy 1 serum, and hydrocortisone succinate-sensitive suppressor cells could be detected. Soluble supernatant products of TBH spleen and thymus cells were also found to inhibit in vitro mitogen responses, whereas TBH macrophages and lymph node cells demonstrated no soluble suppressive activity. The major source of soluble inhibitor of DNA synthesis (IDS) seems to be an anti-Thy 1 serum, hydrocortisone-sensitive population.     

The polyvalent protease inhibitor, trasylol, inhibits DNA synthesis of mouse lymphocytes by an indirect mechanism.

By the use of incorporation of radiolabeled thymidine, uridine, and leucine into mouse lymphocytes, the inhibitory effect of the protease inhibitor, trasylol, on antigenor mitogen-induced lymphocyte triggering was studied in vitro. DNA synthesis, as well as RNA and protein syntheses, were effectively inhibited by 0.3–2.5 × 10^?7 mol of trasylol when responses were induced by homologous antigen, allogeneic cells, phytohemagglutinin, or endotoxic lipopolysaccharide of Escherichia coli. The inhibitory effect of trasylol was reversible. On the contrary, DNA synthesis by nonadherent spleen cells was hardly inhibited by the inhibitor when the cells were stimulated with a relatively large amount of concanavalin A. Antigen-induced DNA synthesis by non-adherent lymph node cells was enhanced by the culture supernatant of macrophages. This helping effect of macrophage supernatant was effectively inhibited either by soluble or insoluble trasylol. These results suggest that the inhibitory action of trasylol on lymphocyte triggering may operate indirectly to interfere with the helping action of macrophages on lymphocytes.     

Enhancement of the mixed lymphocyte response in the mouse by addition of thymocytes

Synthesis of DNA by mixtures of mouse lymph node and thymic cells was studied in vitro using mitomycin-treated allogeneic spleen cells as stimulator cells. The tests were performed to see whether there occurs a similar cell synergy during this reaction as has been reported during the in vivo graft-vs-host response.It was observed that mixtures of thymocytes and lymph node cells give higher incorporations of isotope-labelled thymidine than can be explained by a pure additive effect of the two cell populations tested separately. This enhancement of the reactivity was more pronounced using combinations of lymph node cells and medullary thymocytes obtained from cortisone-treated donors. Enhancement was also noted between lymph node cells and spleen cells. Blocking of the capacity of lymph node cells to synthesize DNA by treatment with mitomycin abolished this enhanced activity when mixed with thymic cells. On the contrary, mitomycin treatment of thymocytes did not abolish their capacity to increase the reactivity when mixed with normal lymph node cells. Thymocytes, which were unresponsive to the mitomycin-treated cells for genetic reasons, were also found to increase DNA synthesis when combined with lymph node cells. The mechanism by which thymocytes increase DNA synthesis of lymph node cells is not clear, but the results show that they have to be present during the reaction, since culture medium “conditioned” by thymocytes did not exhibit any enhanced capacity to promote a mixed lymphocyte reaction of lymph node cells.The results are thus in agreement with the findings obtained by others showing that mixtures of lymph node cells and thymic cells yield higher immunological reactivities in vivo against foreign transplantation, antigens than can be explained by a pure additive effect of the reactivities by the two cell populations tested separately. However, in contrast to these findings, the thymic cells do not have to be able to synthesize DNA or to react against the foreign cells in vitro to yield an enhanced response when mixed with lymph node cells.     

Immunologic deficiency during experimental Chagas' disease (Trypanosoma cruzi infection): role of adherent, nonspecific esterase-positive splenic cells

The involvement of adherent splenic cells in the production of deficient lymphocyte responses during the acute phase of experimental Chagas' disease was investigated. When cultured together, purified adherent splenocytes from mice acutely infected with Trypanosoma cruzi caused a significant reduction in the responses of normal mouse spleen cells to T and B cell-specific mitogens. Similar observations were made when infected mouse adherent splenocytes were co-cultured with normal mouse nonadherent cells. Exchange of adherent cells in infected mouse spleen cells suspensions for adherent cells from uninfected mice resulted in increased responses to stimulation with the T and B cell mitogens tested. Treatment of infected mouse cell suspensions with indomethacin improved the responsiveness of these cells to the mitogens. These results support the concept that the immunosuppression that is characteristic of experimental acute Chagas' disease is at least in part mediated by an adherent cell population and is dependent on a prostaglandin-mediated mechanism.     

Effects of B-lymphocytes from different organs on hemopoietic colony formation in the spleen by bone marrow cells]

The influence of B-lymphocytes from various sources on splenic colony formation was studied in the syngeneic system. B-lymphocytes were obtained by panning with IgG-fraction of rabbit anti-mouse Ig, absorbed on Petri dishes. In addition, adherent cells, Thy-1+ and SC-1+ were eliminated from the fraction of Ig(+)-cells. SC-1- and SC-1+ fractions, containing, respectively, stem cells and T-lymphocyte precursors, were obtained by panning with IgG-fraction of rabbit anti-SC-1 serum. SC-1- cells transferred to irradiated syngeneic mice did not induce colony formation in the spleen. Introduction of SC-1- and SC-1+ cells induced formation of colonies. A similar helper effect occurred when SC-1(-)-cells were introduced with bone marrow or lymph node B-cells, but not with splenic B-cells. Splenic, but not bone marrow and lymph node B-cells inhibited colony formation by combination of SC-1- and SC-1+ cells. All effects of Ig+ cells were abolished by treatment of cells with rabbit anti-MBLA serum. Thus, B-cells of various origin can either enhance or inhibit colony formation. The enhancing of inhibitory effect after B (MBLA+)-cells elimination from suspension of bone marrow and lymph node (but not spleen) Ig(+)-cells resulted from the activity of B-contrasuppressors.     

Graft versus host-induced immunosuppression: mechanism of depressed T-cell helper function in vitro.

The cellular basis of graft versus host (GVH)-induced immunosuppression was investigated. Results showed that thymus, lymph node, and splenic T cells from normal mice and thymus and lymph node T cells from GVH mice, when cultured on one side of a cell impermeable membrane, restored the plaque-forming cell (PFC) response to sheep erythrocytes of GVH-immunosuppressed spleen cells (GVH-SC) cultured on the other side of the membrane. The restoring ability of T cells present in GVH-SC was inhibited by splenic accessory (A) cells. A direct relationship was shown between the proportion of splenic A cells and the degree of suppression of the PFC response during the first 10 days of the GVH reaction. Normal or GVH A cells reconstituted the PFC response of normal cells and GVH-SC depleted of their A-cell fraction. An optimum ratio of A: nonadherent (NA) cells (1: 10) was required for maximum reconstitution. Larger proportions of A cells inhibited the PFC response. The results suggest that GVH-induced immunosuppression is due, at least in its initial phase, to a depressed T-cell helper function caused by a marked increase of A cells in the spleen.