The detection of Fc-IgA receptors on T and non-T,non-B acute leukemic lymphoblasts

Fc-IgA receptors have been described on purified human T-lymphocyte populations from normal individuals. More recently, non-T-cell subpopulations bearing Fc-IgA receptors have also been described. In this study, receptors for the Fc portion of IgA were detected on both T and non-T, non-B leukemic lymphoblasts from 15 patients with acute lymphoblastic leukemia (ALL). From 1.6 to 6.8% of the T lymphoblasts of 7 patients expressed Fc-IgA receptors and 0.5 to 3.9% of the non-T, non-B lymphoblasts of the remaining 8 patients expressed Fc-IgA receptors. The expression of IgA receptors on these cells may reflect the maturational state of these leukemic lymphoblasts. The detection of Fc-IgA receptors on leukemic lymphoblasts suggests that expression of these receptors on lymphoid cells represents an early maturational event.     

Regulation of the immune response to tumor antigen. IV. Tumor antigen-specific suppressor factor(s) bear I-J determinants and induce suppressor T cells in vivo.

The nature and function of suppressor factor(s) elaborated by suppressor T cells in response to certain chemically induced tumors have been further defined. Thus, suppressor factor(s) specific for the S1509a methylchol-anthrene-induced fibrosarcoma have been shown to bear determinants encoded by the I-J subregion of the murine MHC since suppressive activity is removed by passage of the factor through an immunoadsorbent composed of anti-I-Jk coupled to Sepharose. No loss of activity was observed after passage of factor through control columns composed of normal mouse globulin. Furthermore, activity could be recovered from the relevant immunoadsorbent by elution with high salt. The administration of crude suppressor factor(s) to normal animals for 4 days resulted in the development of a population of suppressor cells that act in a manner analogous to the suppressor cell population used for production of factor. These factor-induced suppressor cells are T cells and exhibit an antigen specificity similar to that displayed by the tumor-induced suppressor cells. Thus, tumor-specific suppressor factor(s) bear I-J determinants and are capable of inducing the appearance of suppressor T cells in the nontumor-bearing host, which may then act in a specific manner to limit host responsiveness to tumor antigen.     

Ly-1 inducer and Ly-1,2 acceptor T cells in the feedback suppression circuit bear an I-J-subregion controlled determinant

An I-J-subregion controlled determinant is expressed on Ly-1 inducer and Ly-1,2 acceptor T cells in the feedback suppression circuit. Ly-1 T cells absorb the I-J antibody reactive with the Ly-1,2 acceptor T cell, suggesting that both inducer and acceptor T cells have the same I-J determinant. Since less than 10 percent of Ly-1 or Ly-1,2 T cells are killed by anti-I-J plus complement treatment, the I-J determinant demarcates functionally distinct subsets of both the Ly-1 and Ly-1,2 T-cell sets. This I-J determinant is not expressed on a detectable number of Ly-1 helper T cells which induce B lymphocytes to produce anti-sheep red cell antibody in tissue culture.     

Age-related changes within a suppressor T cell circuit

The effects of aging on cellular and molecular components of the 4-hydroxy-3-nitrophenyl acetyl-specific suppressor T (Ts) cell circuit were analyzed in vitro using inducer (Ts1), transducer (Ts2), and effector (Ts3) cells and activating factors (TsF1 and TsF2) derived from young or old mice. The activation of Ts2 cells by TsF1 and of Ts3 cells by TsF2 was found age-restricted, suggesting a loss of Ts2 and Ts3 cell subsets in old mice. However, the activation of Ts3 cells by small amounts of TsF2 is more efficient when both are derived from old rather than from young mice while the same level of maximum suppression is attained. Higher affinity of the interactions involved in Ts cell activation may compensate for loss of Ts cell subsets in old mice. No age restriction was found for antigen presentation to Ts1 cells and for the interaction between Ts3 cells and target B cells. Thus, the effects of aging on immunosuppression result from changes within the Ts cell circuit.     

DNA-synthesizing T and non-T cells in chronic lymphocytic leukemia.

In 21 patients with chronic lymphocytic leukemia (CLL) and in 8 hematologically normal persons the number of DNA-synthesizing peripheral blood lymphocytes was investigated by autoradiographic techniques. The lymphocytes were differentiated by EN-rosette tests into T and non-T lymphoid cells. The results show a normal number of proliferating T lymphoid cells and an increased number of proliferating non-T lymphoid cells in clinical stages O-I. Stages III-IV demonstrate a significant increase of the proliferation rate of both T and non-T lymphoid cells. The possible pathogenetic factors and the prognostic value of these results are discussed.     

Murine neonatal spleen contains natural T and non-T suppressor cells capable of inhibiting adult alloreactive and newborn autoreactive T-cell proliferation

The spleen of neonatal mice is known to be a rich source of cells capable of suppressing a variety of immune functions of adult lymphocytes in vitro. From such observations has emerged the concept that the gradual development in ability to express immune functions after birth is due in part to the parallel normal physiological decay of naturally occurring regulatory suppressor cells. There is, however, some confusion in the literature as to the exact nature of the newborn of the newborn inhibitory cell type(s). In contrast to most previous reports which detect only a single type of neonatal suppressor cell, usually a T cell, we show here that newborn spleen harbors both T and non-T inhibitory cells. Both types of suppressor cells could be shown to suppress the proliferative response of adult spleen to alloantigens as well as newborn T cells reacting against self-Ia antigen in the autologous mixed lymphocyte reaction (AMLR). Newborn suppressor T cells were characterized as being non-adherent to Ig-anti-Ig affinity columns, soybean agglutinin receptor negative (SBA-), and susceptible to lysis by anti-T-cell specific antiserum plus complement. Non-T suppressor cells were identified as non-phagocytic, SBA receptor positive (SBA+), and resistant to cytotoxic treatment with anti-T-cell antibodies and complement. The apparent controversy surrounding previous reports as to the T versus non-T nature of newborn suppressor cells can be reconciled by the present observation that both types of inhibitory cells coexist in the spleen. Furthermore, the demonstration that newborn suppressor cells can effectively regulate T-cell proliferative activity mediated by other newborn cells provides more direct support for the contention that such inhibitory cells play a physiological role in controlling immune responsiveness during early ontogeny.     

Generation in vivo of non-T suppressor cells with the use of anti-allotype antibody

Anti-Igh-1b antiserum induced allotype-specific suppression of adult mouse spleen cells in an adoptive transfer system. Suppression of Igh-1b anti-sheep red blood cell plaque-forming cells was measured as late as 4 wk after the injection of allotype heterozygous (Igha/b) spleen cells, antiserum, and sheep red blood cells. Suppression was maintained on retransfer of the allotype-suppressed spleen cells to further irradiated recipients in the absence of additional exogenous anti-allotype antibody. Mixing experiments were performed to test the putative inhibitory effects of allotype-suppressed spleen cells from the first adoptive transfer (stage I) on the antibody response of normal spleen cells in a second adoptive transfer (stage II). No suppression was observed by using unfractionated stage I spleen cells. In contrast, when these allotype-suppressed spleen cells were depleted of T cells, they strongly inhibited the antibody production of admixed normal spleen cells in stage II. This inhibitory activity of antibody-induced stage I spleen cells was directed primarily toward the target allotype, but some suppression of the Igh-1a plaque-forming cell response and total IgG production also occurred. Although removal of adherent cells did not affect the inhibitory activity of allotype-suppressed spleen cells from stage I, removal of Ig+ cells completely abrogated the inhibitory activity. These results suggest that antibody-induced regulatory B cells may play a role in maintaining long term allotype suppression.     

Involvement of antigen and I-J determinants in the induction of effector T suppressor cells by immune B cells

Immune B cells induce effector T suppressor cells in vitro. The B cells act as antigen-presenting cells, and express both I-A and I-J determinants. Antigen and I-J determinants are required for the induction of suppressor T cells by immune B cells, but I-A determinants are not. These findings indicate that precursors of suppressor T cells appear to recognize antigen in the context of I-J determinants on the surface of immune B cells.     

Nature of hapten-modified determinants involved in induction of T cell tolerance and suppressor T cells to NDFB contact sensitivity

Unresponsiveness to DNFB contact sensitivity induced by DNP-modified lymphoid cells (DNP-LC) is mediated by two separable pathways: a rapidly induced, long lasting inhibition of reactive T cell clones (donor tolerance), and a transient period of suppressor T cell (Ts) activity. The present report has examined the nature of the hapten-modified determinants responsible for the induction of these pathways by utilizing soluble DNP-LC cell lysate preparations as tolerogens. The results indicate that both DNP-modified MHC and non-MHC encoded determinants can mediate donor tolerance 7 days after tolerization. On the other hand, the induction of Ts requires DNP-modified MHC determinants, since DNP-LC lysates passed over lentil lectin or specific anti-H-2 immunoabsorbent columns lost their ability to induce Ts. Additional experiments showed that the injection of DNP-LC lysate compatible with the recipient strain at the H-2K and H-2D region of the MHC was sufficient for the induction of Ts. We propose that Ts induction involves the direct presentation of DNP-H-2 determinants to Ts precursors, whereas the induction of donor tolerance may involve host processing and presentation of DNP-modified membrane determinants in conjunction with host MHC structures.     

Cellular immunity in Q fever: modulation of responsiveness by a suppressor T cell-monocyte circuit

Human infection with the rickettsia Coxiella burnetii presents as an acute flulike primary Q fever, as a subacute granulomatous hepatitis, or, rarely, as chronic endocarditis. We have previously described lymphocyte unresponsiveness to Coxiella antigen in patients with Q fever endocarditis. This unresponsiveness was antigen specific and was mediated in part by adherent suppressor cells. In this report we show that the adherent suppressor cells work via prostaglandin E2 (PGE2)4 production. Addition of the cyclooxygenase inhibitor indomethacin to cultures of PBMC from patients with endocarditis or chronic laboratory exposure resulted in consistent increases in Coxiella-specific lymphocyte proliferation. The degree of increase in proliferation induced by indomethacin correlated strongly with the amount of PGE2 produced in a 4-hr culture stimulated by Coxiella antigen, but it also correlated with the sensitivity to inhibition of mitogenesis by PGE2. The suppressor mechanism was antigen nonspecific, because induction of suppression in vitro by Coxiella antigen also suppressed Candida-induced proliferation when both antigens were present in the same culture. Addition of indomethacin to these antigen cocultures totally reversed the Coxiella-induced suppression, confirming the evidence above that the nonspecific effector mechanism of suppression was prostaglandin (PG)-mediated. Elicitation of suppression, however, was antigen specific and involved a T cell-monocyte suppressor circuit. Supernatants from Coxiella-stimulated immune T cells and from the suppressor subset (OKT8+-enriched) of those T cells, but not unstimulated immune cells, induced augmented PGE2 production by unrelated nonimmune PBMC. We conclude that the lymphocyte unresponsiveness characterizing patients with Q fever endocarditis is modulated in part by an antigen-specific T suppressor cell which secretes a lymphokine to stimulate PGE2 production by adherent cells.     

Human suppressor T cells induced by concanavalin A: suppressor T cells belong to distinctive T cell subclasses.

Human peripheral blood lymphocytes were stimulated by concanavalin A (Con A) and then evaluated by their suppressive activity for thymus-derived (T) cell- and bone marrow-derived (B) cell-proliferative responses to mitogen and allogeneic cells. Con A-activated T cells markedly suppressed these responses, but Con A-activated B cells failed to demonstrate suppressor activity. Discontinuous bovine serum albumin (BSA) density gradient separation of T cells which had been activated by Con A demonstrated that a fraction containing blast cells as well as fractions containing unproliferated cells manifest the same degree of suppressor capabilities. However, when density gradient separation of T cells followed by subsequent incubation with Con A was performed, fractions of proliferating cells of low density exhibited no suppression; a fraction containing high density T cells produced marked suppression, but this fraction incorporated only little thymidine in response to Con A. Thus, these studies indicate that Con A-induced suppressor T cells belong to a distinctive subpopulation which has already been programmed to express this function before exposure to Con A and that cell proliferation may not be a prerequisite for the development of such suppressor T cells.     

Interaction between T cells and non-T cells in suppression of cytotoxic lymphocyte responses.

Generation of cytotoxic T lymphocytes (CTL) in mixed leukocyte cultures was suppressed by a factor elaborated by alloantigen-activated T cells. This suppressor factor, CTL-TsF, in contrast to a factor that suppresses proliferative responses in mixed leukocyte reactions (MLR-TsF), was effective only when added during the first 24 hr of a 6-day-culture period. Moreover, removal of CTL-TsF 24 hr after culture initiation failed to restore CTL responses. CTL activity could be rescued from suppressed cultures, however, by addition of 2-mercaptoethanol on days 3 or 4. Similarly, transfer of nonadherent cells at 3 or 4 days from cultures treated with CTL-TsF to cultures of adherent cells initiated in control factor restored CTL responses. Mixing experiments with cells pulsed with CTL-TsF for 4 hr at culture initiation identified a target of CTL-TsF as a Thy-1 negative cell that was adherent to plastic and to Sephadex G-10. Suppression was not due to interference with physiologic accessory cell function, but more likely was accomplished via a negative signal from CTL-TsF-pulsed cells. The results thus suggest that CTL-TsF acts early, but reversibly, in the CTL differentiative process via a second suppressor effector cell, possibly a macrophage.     

Regulatory responses in contact sensitivity: afferent suppressor T cells inhibit the activation of efferent suppressor T cells.

Two types of suppressor cells regulate the contact sensitivity (CS) response to picryl chloride (PCL). Afferent suppressor T cells (Ts-aff) inhibit the generation of CS responses to PCL, while efferent suppressor T cells (Ts-eff) inhibit the activity of Th 1 cells that mediate CS reaction. Intravenous injection of mice with TNP-substituted peritoneal exudate cells (TNP-PEC) induces Ts-eff cells that block the adoptive transfer of contact sensitivity. The induction of Ts-eff cells is prevented by the presence of Ts-aff cells, which in turn are induced by the injection of TNP-PEC coupled with antibodies of the IgG2a and IgG2b isotype (TNP-PEC-Ab). If an animal is injected with TNP-PEC prior to or simultaneously with TNP-PEC-Ab, it generates only Ts-aff cells, while if it is injected with TNP-PEC alone or TNP-PEC prior to TNP-PEC-Ab, it generates Ts-eff cells. Ts-aff cells effect only the generation of Ts-eff cells, as the addition of Ts-eff cells to assays for Ts-eff cells has no inhibitory effect on the suppressive effects of Ts-eff cells in adoptive transfer. Our experiments show that Ts-aff cells induced by TNP-PEC-Ab are phenotypically either Lyt 1+2- or Lyt 1-2+, but only the latter inhibit the generation of Ts-eff cells in vivo. The Ts-aff cells that inhibit Ts-eff activity adhere to the lectin Vicia villosa (VV), while Ts-eff cells are VV nonadherent. In addition, Ts-aff cells can prevent the generation of Ts-eff to linked haptens presented on the same PEC. It appears that a cascade of Ts cell interactions are involved in the regulation of CS responses.     

The contribution of NKT cells,NK cells,and other gamma-chain-dependent non-T non-B cells to IL-12-mediated rejection of tumors

IL-12 is a potent cytokine that impairs the growth of several tumors in vivo in natural as well as in therapeutic conditions. Although IL-12 can enhance a number of immunological antitumor mechanisms, including those mediated by NK cells and CTL, recent reports have suggested that the mouse CD1d-restricted V alpha 14-J alpha 18 NKT cell was the essential cell type recruited in most, if not all tumor rejection models, including the B16 melanoma. In this study, we have examined and compared the role of NKT cells, T cells, NK cells, and other non-T non-B cells in the rejection of B16 melanoma cells after exogenous administration of IL-12. Surprisingly, our results failed to confirm a necessary role for NKT cells in this model. Instead, we found that NK cells mediated the rejection of liver metastases, whereas other gamma c-dependent non-T non-B cells, possibly lymphoid dendritic cells, were required for rejection of skin tumors. These findings challenge the view that NKT cells are systematically required for IL-12-mediated rejection of tumors, and instead reveal that a variety of effector pathways can be recruited depending on the tumor microenvironment.     

Suppressor T cell growth and differentiation: evidence for induced receptors on suppressor T cells that bind a suppressor T cell differentiation factor

T suppressor cell differentiation factor (TsDF) induces the differentiation of alloantigen-primed suppressor T cells (MLR-Ts) to expression of their effector function, i.e., to active TsF production. The initial activation stimulus to Ts is provided by alloantigen binding; after this binding, Ts are functionally responsive only for a period of hours to the additional stimulus provided by TsDF. The present studies addressed the possibility that MLR-Ts responsiveness to TsDF reflects the induced and transient display of TsDF-binding receptors. TsDF receptor expression was investigated by determining the capacity of TsDF-responsive MLR-Ts to adsorb TsDF activity and to respond to that TsDF pulse by TsF production. Primed Ts populations that were alloantigen restimulated for 8 hr adsorbed TsDF in a cell dose-dependent fashion and produced TsF in response to that adsorption, whereas alloantigen-stimulated naive cells or primed but nonrestimulated cells neither responded to nor bound TsDF. Primed and restimulated L3T4-Ly-2+ but not L3T4+-Ly-2--enriched T cells bound TsDF. TsDF adsorption was saturable and time and temperature dependent. Glutaraldehyde fixation did not prevent TsDF adsorption by restimulated MLR-Ts, whereas pronase treatment abolished their TsDF-binding capacity. Kinetic analyses demonstrated that the capacity to bind TsDF developed rapidly after alloantigen reexposure, with maximal binding within 8 hr, followed by rapid decay with loss of TsDF binding by 36 hr. The kinetics of TsDF-induced TsF production correlated precisely with those of TsDF binding. These observations provide strong evidence that TsDF affects primed alloantigen-reactive Ts by interaction with antigen-induced and transiently expressed cell surface receptors. TsDF-receptor binding is then the stimulus for expression of Ts effector function.     

Immunoregulation after thermal injury: sequential appearance of I-J+, Ly-1 T suppressor inducer cells and Ly-2 T suppressor effector cells following thermal trauma in mice

Immunoregulation as a consequence of thermal injury was investigated by using a murine model involving a 30% surface area full thickness burn. Both allogeneic mixed lymphocyte reaction (MLR) and in vitro anti-SRBC responses were depressed from days 3 to 25 post-burn. Suppressor T cells could be identified in both systems between days 5 and 15. On day 5 post-burn, an Ly-1+,2-, I-J+ T cell is responsible for the majority of the suppression observed. This cell behaves like a T suppressor inducer T cell in that it must interact with an Ly-2+ cyclophosphamide-sensitive cell to manifest suppression. On day 7 post-burn, only Ly-1-,2+ suppressor T cells are found which can directly suppress the activity of Ly-1+,2- helper T cells. Thus, these cells behave as T suppressor effector cells. We suggest that feedback suppression is in operation after thermal injury, with functional suppressor inducer cells appearing on day 5 post-burn, leading to the appearance of T suppressor effector cells by 7 days post-burn. Recovery from post-burn immunosuppression occurs by day 25 post-burn and is associated with the appearance of V. villosa-adherent T cells, whose activity antagonizes that of the day 7 post-burn suppressor effector. These cells may represent contrasuppressor T cells, which could play a role in the restoration of immunocompetence after burn injury.