Simultaneous induction of antigen-specific IgA helper T cells and IgG suppressor T cells in the murine Peyer's patch after protein feeding

The effects of feeding the dietary protein antigen, ovalbumin (OVA), on OVA-specific IgG and IgA immune responses involving Peyer's patches (PP) and mesenteric lymph nodes (MLN) were examined. Mice were administered soluble OVA by gastric intubation. One to 3 days later, PP, MLN, or spleen cells from these donor mice were adoptively transferred into normal syngeneic recipients. After two subsequent immunizations, spleens from the recipient mice were assayed for IgA and IgG anti-OVA plaque-forming cell (PFC) responses. None of the tissues from normal (unfed) mice had the inherent ability to alter recipients' IgG or IgA PFC responses. Within 1 day of OVA feeding, however, cells were generated in the PP that could augment recipients' IgA anti-OVA PFC responses and suppress IgG PFC responses. Three days after OVA feeding, these cells were present in MLN as well, and whereas the IgG suppressor cell also appeared to migrate to spleen, the IgA helper cell did not. The cells mediating antigen-specific IgG suppression and IgA help were both T cells but could be distinguished by surface phenotype. We therefore conclude that protein feeding induces differential, isotype-specific immunoregulation in gut-associated lymphoid tissues, part of which is mediated by an antigen-specific IgA helper T cell.     

Murine IgA binding factors produced by Fc alpha R(+) T cells: role of Fc gamma R(+) cells for the induction of Fc alpha R and formation of IgA-binding factor in Con A-activated cells

The relationship between the production of a T cell factor having affinity for IgA (IgA-binding factor(s); IgA BF) and the expression of Fc receptors specific for IgA (Fc alpha R) was studied by using murine spleen cells activated with concanavalin A (Con A blasts). Fc alpha R was detected by the cytophilic binding of anti-TNP murine IgA myeloma protein (MOPC 315 IgA) to Con A blasts as determined by an indirect rosette method with trinitrophenylated sheep red blood cells (TNP-SRBC). After 18 hr preculture with IgA, Fc alpha R was expressed on 15 to 20% of Con A blasts, which released IgA BF suppressing the in vitro IgA synthesis of the spleen cells stimulated with pokeweed mitogen (PWM). Without preculture with IgA, there was neither induction of Fc alpha R nor the production of IgA BF from Con A blasts. Fc alpha R was not induced on Con A blasts by IgA if Fc gamma R(+) cells were depleted from the blasts by rosetting with SRBC sensitized with rabbit IgG antibody (EA gamma). Even after preculture with IgA, the suppressive IgA BF was undetectable in the culture supernatant of Con A blasts depleted of the Fc gamma R(+) cell population. By using a double rosette method with EA gamma and trinitrophenylated quail red blood cells, Fc alpha R proved to be co-expressed on Fc gamma R(+) precursor T cells in the Con A blasts. The results suggested that both Fc gamma R and Fc alpha R could be co-expressed on Con A blasts, as is the case with T2D4 Fc gamma R(+), Fc alpha R(+) T hybridoma cells, which are known to produce IgG-binding factor(s) (IgG BF) and IgA BF. The relationship between Fc gamma R and Fc alpha R on a single cell was studied by using monoclonal anti-Fc gamma R antibody (2. 4G2 ). The reactivity of 2. 4G2 antibody with T cell Fc gamma R was proved by the inhibition of EA gamma rosette formation by Con A blasts or T2D4 cells. The addition of 2. 4G2 monoclonal antibody, however, did not affect the induction of Fc alpha R on Con A blasts by IgA. Furthermore, the binding of IgA to Fc alpha R already expressed on L5178Y T lymphoma cell line cells was not inhibited by the monoclonal antibody. The results confirmed that Fc alpha R are distinct from Fc gamma R co-expressed on the same Con A blasts, and that the expression of Fc alpha R on Fc gamma R(+) T cells and their production of suppressive IgA BF may be induced by the binding of IgA to Fc alpha R.     

Isotype-like suppression of T cell-mediated immunity in vivo. II. Suppression of the early component of contact sensitivity by a Ly-2+ T cell-derived suppressor factor that binds to contact sensitivity-initiating, antigen-specific, Ly-1+ T cell-derived factors that are of different antigen specificities

Recognition that delayed-type hypersensitivity (DTH) reactions, such as contact sensitivity (CS) in mice, are initiated by Ly-1+ T cell-derived, antigen-specific factors has led to identification of a new kind of suppressor T cell that regulates this initiation phase of CS. Regulation by these suppressor T cells is T cell isotype-like in that initiation of DTH of various antigenic specificities is suppressed, whereas, Ly-1+ T cells mediating the antigen/major histocompatibility complex-restricted, classic delayed phase of CS responses are not affected, nor are other T cell activities. This study shows that these isotype-specific suppressor T cells probably act by release of soluble, isotype-specific, suppressor factors. These isotype-specific T cell factors bind to and can be eluted from columns linked with antigen-specific Ly-1+ T cell factors that initiate CS, and are of different antigen specificities. These T cell regulating, anti-isotypic suppressor factors are derived from Lyt-2+ I-J- T cells and suppress CS-initiating T cells, but do not affect the delayed-acting T cells of CS. This is in contrast with antigen-specific T cell suppressor factors that affect the late-acting and not the early-acting T cells of CS. It is suggested that the antigen-binding, CS-initiating, T cell factors, and their regulatory, anti-isotypic T cell factors are, respectively, T cell analogues of immunoglobulin(Ig)E antibody, and IgE-binding factors, that regulate IgE antibody production by IgE+ B cells.     

Inhibitory activity of interleukin B on the suppressor T cell hybrid T2D4

Interleukin B (IL-B), a product of unstimulated B cells, is defined by its ability to selectively prevent the differentiation of suppressor T lymphocytes from precursors into effectors. The present study was undertaken to determine whether IL-B could also be active in modulating the activity of the T cell hybrid T2D4, which produces immunoglobulin-binding suppressor factors. T2D4 cells can be selectively induced by incubation with various isotypes of antibody to express isotype-specific Fc receptors and to release soluble factors that suppress production of the corresponding isotype. The data presented here demonstrate that IL-B is greatly effective in inhibiting T2D4 activities. Either pretreatment with IL-B or continuous exposure to IL-B prevents isotype activation of T2D4. As a result, T2D4 cells do not express isotype receptors and do not produce detectable amounts of isotype-specific suppressor factors. This IL-B regulatory activity on T2D4 is temperature dependent and is inhibited by cytochalasin B. These findings provide new insights on the mechanism by which IL-B enhances antibody responses, and they offer a conceptual framework for analyzing IL-B activity on suppressor T cells.     

A role for isotype-specific binding factors in the regulation of IgA- and IgG-specific responses by the anti/contrasuppressor T cell circuit

Previous studies have shown that the isotype of an antibody response is selected, in part, by the inhibition of isotype-specific suppression. The antisuppressor model predicts that isotype selection is initiated through an interaction between Ag, Ig, and a T cell-derived factor within 6 h of immunization. This report characterizes some of these molecules and their contribution to isotype regulation. Cultures of murine spleen cells stimulated with the T cell-dependent Ag SRBC led to Ag-specific IgG and IgA responses that could be suppressed and then antisuppressed by a molecular complex produced by mixing purified serum Ig with the supernatant of Ag-pulsed macrophages co-cultured with T cells. The supernatants from separate cultures of Ag-pulsed macrophages and rIL-1 alpha stimulated CD4+ T cells, could be pooled and mixed with Ig to produce functional antisuppressive complexes thereby allowing the factors from the different cell types to be studied separately. Adsorption of the co-culture or the rIL-1 alpha stimulated T cell supernatants against monoclonal IgG or IgA, removed IgG and IgA binding factors, respectively, and abrogated the ability to enhance the corresponding isotype. The adherent material could be recovered and used to reconstitute enhancement by the supernatants depleted of the binding factors. When affinity purified IgG or IgA was used as the source of Ig within the antisuppressive complexes, the enhancement of the antibody response was limited to the isotype of the regulatory Ig used to form the complex. Thus, manipulation of the antisuppressive molecules has a predictable effect on isotype selection. Release of isotype-specific binding factors by CD4+ cells by rIL-1 alpha supports the hypothesis that T cell circuits play a role in initiating isotype regulation.     

The expression of receptors for IgA on human monocytes and calcitriol-treated HL-60 cells

In this study, we investigated the expression of IgA Fc receptors (FcR alpha) by human myeloid cells. By using a sensitive cytofluorometric IgA binding assay, we found that approximately 85% of peripheral blood monocytes bound IgA in an isotype-specific fashion. The HL-60 human promyelocytic leukemia cell line failed to express FcR alpha; however, treatment of HL-60 cells with the differentiating agent calcitriol induced the expression of FcR alpha on greater than 90% of these cells. Monocytes and calcitriol-treated HL-60 cells were capable of ingesting IgA-coated erythrocyte targets, suggesting that phagocytosis could be mediated through FcR alpha. The induced HL-60 cell system represents a useful model for further studies on FcR alpha expression and function.     

The role of suppressor cells in the pathogenesis of common variable hypogammaglobulinemia and the immunodeficiency associated with myeloma.

The role of suppressor cells in the pathogenesis of immunodeficiency was analyzed using a technique that permits study of the differentiation of B lymphocytes into immunoglobulin-synthesizing plasma cells. Lymphocytes from normals synthesized 4,910 ng of IgM, 1,270 ng of IgA, and 1,625 ng of IgG per 2 X 10(6) cells when cultured for 7 days in the presence of pokeweed mitogen. In contrast the lymphocytes from patients with common variable hypogammaglobulinemia did not synthesize significant quantities of immunoglobulin. When lymphocytes from 9 of 13 patients with common variable hypogammaglobulinemia studied were cocultured with normal lymphocytes, the synthesis of immunoglobulin by the normal lymphocytes was depressed by 75-100%. A comparable suppression of immunoglobulin synthesis by normal lymphocytes was observed when they were cocultured with T cells from hypogammaglobulinemic patients. These studies suggest that in some patients the disease common variable hypogammaglobulinemia may not be due to an intrinsic defect of B cells alone but may be cuased or perpetuated by an abnormality of regulatory T cells that act to suppress B-cell maturation and antibody production. Peripheral blood lymphocytes from myeloma patients also had a drastically reduced capacity to produce polyclonal immunoglobulins. Three of 6 myeloma patients tested had circulating mononuclear cells that suppressed immunoglobulin production by cocultured normal lymphocytes. Purified T cells from myeloma patients did not mediate this suppressor effect. These observations suggest that one mechanism for the humoral immune deficiency observed in myeloma patients is a block of polyclonal B-cell maturation by suppressor cells.     

Human Vdelta1 gamma-delta T cells exert potent specific cytotoxicity against primary multiple myeloma cells

Abstract Background aims. Human gamma-delta (γδ) T cells are potent effector lymphocytes of innate immunity involved in anti-tumor immune surveillance. However, the Vδ1 γδ T-cell subset targeting multiple myeloma (MM) has not previously been investigated. Methods. Vδ1 T cells were purified from peripheral blood mononuclear cells of healthy donors and patients with MM by immunomagnetic sorting and expanded with phytohemagglutinin (PHA) together with interleukin (IL)-2 in the presence of allogeneic feeders. Vδ1 T cells were phenotyped by flow cytometry and used in a 4-h flow cytometric cytotoxicity assay. Cytokine release and blocking studies were performed. Primary myeloma cells were purified from MM patients' bone marrow aspirates. Results. Vδ1 T cells expanded from healthy donors displayed prominent cytotoxicity by specific lysis against patients' CD38 (+) CD138 (+) bone marrow-derived plasma cells. Vδ1 T cells isolated from MM patients showed equally significant killing of myeloma cells as Vδ1 T cells from normal donors. Vδ1 T cells showed similarly potent cytotoxicity against myeloma cell lines U266 and RPMI8226 and plasma cell leukemia ARH77 in a dose-dependent manner. The interferon (IFN)-γ secretion and Vδ1 T-cell cytotoxicity against myeloma cells was mediated in part through the T-cell receptor (TCR) in addition to involvement of Natural killer-G2D molecule (NKG2D), DNAX accessory molecule-1 (DNAM-1), intracellular cell adhesion molecule (ICAM)-1, CD3 and CD2 receptors. In addition, Vδ1 T cells were shown to exert anti-myeloma activity equal to that of Vδ2 T cells. Conclusions. We have shown for the first time that Vδ1 T cells are highly myeloma-reactive and have therefore established Vδ1 γδ T cells as a potential candidate for a novel tumor immunotherapy.     

Differential activation of cytotoxic and suppressor T cells against syngeneic tumors in the mouse.

The cytotoxic T cell against a methylcholanthrene-induced sarcoma, S1509a, was induced in syngeneic mice by deliberate immunization with mitomycin C (MMC)-treated live tumor cells. The soluble tumor antigen (STA) extracted from the same tumor by 3 M KCl was, however, unable to induce the cytotoxic T cell upon immunization, although it was able to activate predominantly the suppressor T cell that then specifically suppressed the effect of the cytotoxic T cell against the homologous tumor. The suppressor T cell generated by STA had the same characteristics as those found in tumor-bearing animals: 1) The suppressor T cell has a very strict specificity against individual tumors; 2) The cell expresses cell surface determinants controlled by genes in the I-J subregion of the mouse H-2 complex. The activity of the cytotoxic T cell was completely inhibited by live tumor cells but not by STA, whereas that of the suppressor T cell was neutralized by STA. The results that cytotoxic and suppressor T cells are activated under different conditions, and that the antigenic determinants recognizable by these two cell types are not the same. The soluble extract contains only the determinants recognizable by the suppressor T cell, and the cytotoxic T cell can be activated only by the determinants associated with self antigen present on the surface of live tumor cells.     

Defective isotype-specific regulation of IgA anti-erythrocyte autoantibody-forming cells in NZB mice

B cell hyperactivity characterizes many autoimmune diseases. In NZB mice this is manifested by a variety of immunologic aberrations, including increased B cell proliferation and hyper IgM and IgA secretion in vitro. Recent studies have shown that IgA secretion can be suppressed or enhanced in an isotype-specific manner by a soluble factor(s), called IgA-binding factor (IgABF), produced by IgA FcR-bearing T cells. We now show that T cells from young NZB mice, cultured with high concentrations of IgA, produce an IgABF that has aberrant biologic activity when compared to IgABF produced from IgA FcR+ T cells of BALB/c mice. Although BALB/c IgABF normally suppresses proliferation and secretion by IgA-producing B cells, neither proliferation nor IgA secretion from normal murine IgA-B cells is suppressed by NZB IgABF. In fact, IgA secretion is significantly enhanced by NZB IgABF. We also present the first evidence of IgA anti-mouse erythrocyte (anti-MRBC) autoantibody-forming cells present in the spleens of NZB mice. Whereas BALB/c IgABF suppresses the in vitro generation of IgA anti-MRBC autoantibody-forming cells by NZB spleen cells, NZB IgABF enhances this response. Of particular interest is the development of IgA anti-MRBC autoantibody-forming cells in cultures of spleen cells from nonautoimmune BALB/c mice in the presence of NZB IgABF. These studies suggest that isotype-specific T cells factors might play an important role in the development of autoantibody-forming cells.     

IgA responses in xid mice: oral antigen primes Peyer's patch cells for in vitro immune responses and secretory antibody production

Because the gut-associated lymphoreticular tissue (GALT), e.g., Peyer's patches (PP), of X-linked immunodeficient (xid) mice possesses a subpopulation of mature B cells, we have characterized the ability of xid mice to respond to the thymic-dependent antigen sheep erythrocytes (SRBC) given by the oral route. Gastric intubation of SRBC to xid (CBA/N X DBA/2) F1 male or CBA/N mice, followed by the in vitro culture of dissociated PP cells with SRBC, resulted in IgM, IgG1, IgG2, and high IgA anti-SRBC plaque-forming cell (PFC) responses. The addition of unprimed PP but not splenic T cells to splenic xid B cell cultures resulted in IgM anti-SRBC PFC responses, suggesting the importance of GALT T cells for support of the immune responses to SRBC by splenic B cells from xid mice. Furthermore, purified PP T cells from SRBC orally primed xid mice supported in vitro IgA anti-SRBC PFC responses in B cell cultures from either the PP or the spleens of nonprimed xid mice. Higher IgA responses, however, occurred in PP, when compared with splenic B cell cultures. Additional evidence that the GALT of xid mice contains functional IgA precursor cells was provided by the finding that cloned H-2k PP T helper cells (PP Th A) supported IgA responses in PP B cell cultures derived from (CBA/N X C3H/HeN) F1 male (xid) mice. On the other hand, splenic B cells from these xid mice, in the presence of PP Th A cells, did not support in vitro responses. These results suggest that unique subpopulations of T cells occur in the GALT of xid and normal mice; one T cell subpopulation may induce immature B cells to become precursor IgA cells in the PP. A separate GALT T cell subpopulation, e.g., isotype-specific helper T cells, effectively collaborates with mature IgA B cells for the induction of IgA responses to orally administered antigen. When xid mice were gastric intubated with SRBC, followed by i.p. injection of SRBC, good splenic IgA anti-SRBC PFC responses were seen. Salivary and serum IgA antibodies were also detected in these xid mice. Nevertheless, the magnitude of the anti-SRBC response in xid mice was lower than that seen in similarly treated normal mice. These studies indicate that the GALT of both xid and normal mice possess unique populations of T cells that support in vitro responses in xid B cell cultures from either the spleen or the PP, which direct the mature B cell populations present toward IgA isotype-specific responses.(ABSTRACT TRUNCATED AT 400 WORDS)     

T cells from naive mice suppress the in vitro cytotoxic response against endogenous Gross virus-induced tumor cells

Syngeneic normal lymphoid cells added in co-culture of immune lymphocytes and tumor cells reveal a suppressive activity inhibiting the generation of cytolytic T lymphocytes. The suppression was specific for the response directed against endogenous virus-induced or x-ray-induced tumor cells expressing endogenous C type virus antigens. Thymocytes, spleen cells, or lymph node cells from naive mice were able to express this suppressive activity. The same cells displayed no suppressive activity on killer cells directed against exogenous C type virus-induced tumor cells. The suppressor cells were Thy-1+, Lyt-1- 2+. Our results strongly suggested that the spontaneous suppressor cells exert their activity by interacting with an early step on the CTL response, probably at the level of the helper T cell function. The suppressive activity was mediated by soluble factor(s) that were antigen specific and possibly H-2 restricted. The possible implications of these spontaneous suppressor T lymphocytes in the development of endogenous virus-induced tumors and their possible implications in tolerance to self antigens are discussed.     

Characterization of the accessory cells involved in suppressor T cell induction

The ability of UV-treated splenic adherent cells (SAC) to induce T cell-mediated immunity and suppressor T cells was analyzed in the 4-hydroxy-3-nitrophenyl acetyl (NP) system. UV irradiation of 0.88 KJ/m2 decreased the capacity of NP-coupled SAC to induce delayed-type hypersensitivity (DTH) responses by about 50%. The ability of uncoupled UV-treated SAC to induce allogeneic DTH response was also imparied, indicating that UV-treated SAC are inefficient at inducing DTH in these systems. TS1 induction by UV-treated NP-SAC was evaluated TS1 induction by UV-treated NP-SAC was evaluated by using adherent cells that were subjected to the same dose of UV irradiation that impaired DTH induction. Intravenous administration of 10(3) or 10(4) UV-treated NP-coupled SAC induced TS1 cells with the same efficiency as non-UV-irradiated cells. The TS1 cells induced in this fashion were antigen specific. Furthermore, to establish that the antigen was not reprocessed by the host, I-J-mismatched, UV-treated NP-SAC were unable to induce TS1 cells. The population of antigen-presenting cells responsible for TS1 induction appear to express both I-A and I-J determinants. TS2 induction by UV-treated accessory cells was also analyzed. TSF1 inducer suppressor factor was pulsed onto graded numbers of either normal or UV-treated adherent cells. The same levels of antigen-specific suppression were induced with normal and UV-treated cells. Finally, TS3 induction by UV-treated NP-SAC was analyzed. UV-treated and normal NP-SAC (3 X 10(3] induced antigen-specific suppression of NP DTH responses. I-J-mismatched, UV-treated NP-SAC failed to induce suppression, suggesting that the hapten was not reprocessed by the host under these experimental conditions. The accessory cell population responsible for TS3 induction appears to express both I-A and I-J determinants. Thus, there are at least two functional distinctions between the antigen-presenting cells that induce immunity vs those that induce suppressor cells. First, UV treatment selectively impairs the antigen-presenting cells, which activate the positive limb of the immune response. Second, I-J determinants appear to be specifically associated with the SAC, which induce suppressor T cells. Although these criteria can be used to distinguish the accessory cells involved in suppressor cell pathways from those controlling helper T cell induction, there were no discernible phenotypic differences among the accessory cells that induce the TS1, TS2, and TS3 subsets.     

Increased T gamma and T mu cells in BALB/c mice with IgG and IgM plasmacytomas and hybridomas

The results of previous studies in our laboratory have shown that mice bearing plasmacytomas and hybridomas that secrete IgA or IgE are accompanied by increased frequencies of Lyt-1-2+ T lymphocytes bearing Fc receptors (FcR) for IgA (T alpha) or IgE (T epsilon), respectively. The present study was undertaken to examine whether IgG- or IgM-secreting tumors influenced the frequency of T lymphocytes that express FcR for IgG or IgM. We studied mice bearing IgG- and IgM-secreting plasmacytomas and hybridomas. BALB/c mice injected subcutaneously with the IgG-secreting hybridoma HDP1 (gamma 1 kappa, anti-TNP) were sequentially examined for the frequencies and Lyt phenotypes of splenic lymphocytes bearing FcR for IgG (T gamma), IgM (T mu), and IgA (T alpha). A threefold increase in the frequency of T gamma lymphocytes that were Lyt-1-2+, L3T4- was seen. The frequencies of T mu and T alpha lymphocytes in these mice were not significantly altered. Similarly, mice injected subcutaneously with the IgM-secreting plasmacytoma MOPC 104E (mu lambda, anti-dextran) or the IgM-secreting hybridoma C1D1 (mu kappa, anti-ox RBC) were examined sequentially for the frequencies of T gamma, T mu, and T alpha lymphocytes. Mice with established IgM subcutaneous tumors showed a twofold increase in splenic, nylon wool-nonadherent T mu lymphocytes. This was associated with a relative increase in Lyt-2+ splenic T lymphocytes and a relative decrease in Lyt-1+ splenic T lymphocytes. No changes were observed in the frequencies of either T gamma or T alpha lymphocytes. These studies extend to IgG and IgM the observation that plasmacytomas and hybridomas secreting immunoglobulins of a specific isotype cause an expansion of T lymphocytes bearing FcR specific for the corresponding isotype. The expansion of FcR+ Lyt-1-2+ T lymphocytes likely represents an exaggerated, but otherwise normal, immunoregulatory response of the host. These cells may be an important element in the regulation of isotype expression.     

Immunofluorescence analysis of IgA binding by human mononuclear cells in blood and lymphoid tissue

The nature of IgA-binding cells and their tissue distribution was examined by an indirect immunofluorescence assay with the use of IgA1 and IgA2 paraproteins and fluorochrome- or biotin-labeled F(ab')2 fragments of idiotype-specific antibodies. The frequency of IgA-binding mononuclear cells was approximately 13% in blood and spleen samples but less than 1% in tonsil samples. IgA binding could be visualized by flow immunocytometry on monocyte/macrophages, but not on T and B cells. IgA polymers were bound better than IgA dimers and monomers. Nonhomologous IgA myelomas of both IgA1 and IgA2 subclasses inhibited the IgA-binding to monocytes, whereas aggregated normal serum IgG, IgM paraproteins, and an IgG myeloma did not. IgA binding was relatively insensitive to changes in temperature or cation concentration. IgA-binding monocytes were found in IgA-deficient patients at the same frequency as in normal individuals. The results indicate that monocytes constitutively express class-specific binding sites for both IgA1 and IgA2 molecules.     

Normal human sera contain antibodies directed at Fab of IgA

Serum samples from 26 normal volunteers were evaluated by isotype-specific ELISA for the presence of IgG and IgM antibodies directed at IgA. Although there were wide variations in antibody levels, anti-IgA antibodies of both isotypes were found in all individuals tested. The anti-IgA activity was detected against a variety of polymeric and monomeric IgA1 and IgA2 myeloma proteins containing both kappa and lambda light chains. By using Fab and Fc fragments generated by incubation of an IgA1 myeloma protein with IgA1 protease, it was shown that the anti-IgA activity was specific for the Fab portion of the IgA molecule. It was also demonstrated that the serum of two individuals contained both IgG and IgM activity directed at autologous affinity-purified IgA. IgM antibody levels against both whole IgA and Fab of IgA were significantly higher than IgG antibody levels. Cells producing anti-IgA antibodies of both isotypes were detected in lipopolysaccharide-stimulated human spleen.     

Inhibition of ongoing myeloma IgE synthesis in vitro by activated human T cells

The ability of activated T cells to suppress ongoing IgE synthesis in vitro was assessed using U266--a human myeloma cell line spontaneously producing IgE. T cells were able to inhibit U266 IgE synthesis in the presence of 10 micrograms/ml of Con A by 41.8% (p less than 0.01). T cells preincubated with 10 or 50 micrograms/ml of Con A and washed extensively were still able to inhibit U266 IgE synthesis in the absence of Con A by 41 and 46% (p less than 0.05 and p less than 0.02, respectively). The decrease in IgE measured was due to inhibition of newly formed IgE by U266, as shown by control experiments with cycloheximide. The inhibition was not due to the simple depletion of nutrient growth factors by the activated T cells, as it did not occur with MOLT-4, T cells that are very active metabolically; nor could it be reversed with medium containing IL 2 and B cell growth factors. Culture supernatants of Con A-activated T cells were also able to suppress IgE synthesis by U266 (21%; p less than 0.01), which suggests that upon appropriate activation, T cells secrete material(s) with inhibitory properties for IgE synthesis. Activation of T cells by mixed lymphocyte culture using puromycin-treated lymphoblastoid cell lines as stimulators also generated T cells that had suppressive activity for IgE synthesis. T cells activated with Con A and subsequently incubated with IgE demonstrated a diminished ability to suppress IgE synthesis. This observation is in agreement with the finding that patients with high levels of IgE may lack isotype-specific suppressor T cells for spontaneous IgE secretion. However, T cells from such patients have so far shown variable loss of IgE suppressive function. These results suggest that human IgE synthesis is susceptible to inhibition at a very differentiated stage, and this may be important in expression of allergic diseases.     

T lymphocyte-mediated suppression of myeloma function in vitro. I. Suppression by allogeneically activated T lymphocytes.

Alloreactive cells generated by in vitro stimulation of C57BL/6 (H-2b) spleen lymphocytes with irradiated MOPC 315 or MOPC 104E(H-2d) cells were shown to lyse 51Cr-labeled myeloma targets at high effector:target ratios under conditions of inefficient cell contact, the alloreactive cells cause variable and frequently minimal lysis of myeloma targets but markedly suppress antibody secretion even by viable myeloma cells. The suppressor cells are radioresistant T cells lacking I-J subregion-encoded surface determinants; their precursors are insensitive to cyclophosphamide; suppression is H-2 specific and not mediated by secreted factors; and the suppression is blocked by Cytochalasin B, a known inhibitor of T cell-mediated cytolysis. These properties are typical of cytolytic T lymphocytes (CTL) and not of defined suppressor T cells, suggesting that inhibition of myeloma function probably represents a pre-lytic effect of the alloreactive CTL, although a CTL-like suppressor cell effect cannot be definitively excluded. These results are discussed with reference to the possible relationships between suppressor and cytolytic T lymphocytes.     

Heterogeneity of long-term cultured activated killer cells induced by anti-T3 antibody

The present study has characterized the short term and long term cultured murine-activated killer (AK) cells that are induced by antibody directed against the epsilon-chain of T3 complex. The conventional lymphokine AK (LAK) cells were generated by culturing normal B6 spleen cells with purified human rIL-2. The alpha T3-induced AK cells (T3AK) were induced by culturing normal B6 spleen cells with alpha T3 and were then maintained in culture medium supplemented with human rIL-2 and/or alpha T3. After initial activation with alpha T3, lymphocyte proliferation and generation of cytotoxic effectors (T3AK) were noted, and these events were related to the endogenous production of IL-2 and IL-4. Addition of alpha IL-2 and/or alpha IL-4 suppressed both the proliferative response and the cytotoxic response induced by alpha T3. In comparing the T3AK cells with the conventional LAK cells, there were many similarities as well as some distinct differences. Both cells displayed a similar cytotoxic spectrum against a variety of tumor targets. The T3AK cells usually gave much higher levels of cytotoxic activity against susceptible targets. However, the susceptibility of different tumor targets to conventional LAK cells and T3AK cells varied. The time course for the generation of lytic activity also differed between the conventional LAK and T3AK cells. One distinct difference was their ability to survive in vitro. The conventional LAK cells survived in culture for only 1 wk. The T3AK cells could survive for at least 4 to 5 wk with active growth. The serologic phenotype of the LAK precursors was asialo GM1 (AsGM1+) cells, but the T3AK precursors could be either AsGM1+ or AsGM1-, depending on the target cell. The LAK effectors were both Lyt-2+ and Lyt-2-, but the short-term T3AK effectors were exclusively Lyt-2+. The long term T3AK cells (cultured for more than 2 wk) were found to consist of Lyt-2+ and Lyt-2- cells, and these subsets of T3AK cells showed different target specificities. These findings demonstrate the heterogeneity of LAK and T3AK cells, and this heterogeneous property may contribute to their diversity in specificity against different tumor targets and thus may affect their effectiveness in the immunotherapy of cancer.     

The suppressor T cell induced by syngeneic splenic cell antigen down-regulates hapten-specific cytotoxic T cells by elaborating a factor inhibitory for IL2-dependent cell replication

An in vitro study has been made of the mechanism by which a suppressor T cell, that is induced in lymph nodes by a syngeneic splenic cell antigen, prevents generation of cytotoxic T cells specific for hapten-altered self antigens. When popliteal lymph node cells exposed in vivo to syngeneic splenic cells were immunized in vitro with heat-treated syngeneic TNP-coupled thymocytes and excess helper factors, the Ts remained inactive. In this condition the exposed popliteal lymph node cells routinely demonstrated approximately twice the CTL response developed by lymph node cells from normal mice. Nevertheless, when triggered in vitro by splenic antigen on either X-irradiated B or T cells, the exposed but not the normal lymph node cells exhibited reduced hapten-altered self-specific CTL responses. Furthermore, T cells within spleen cell-exposed popliteal lymph node cell populations when reexposed to splenic T cells made a factor that was found to be suppressive of CTL generation by normal lymph node cells in vitro. The nondialyzable T-cell suppressor factor (TsF) did not appear to act on lymph node precursor CTLs, nor on helper T cells but instead acted at the level of utilization of helper factors in the development of CTLs. In an examination of the effect of TsF on cellular replication, TsF was found to be nontoxic for CTLL-20, an IL-2-dependent T cell, and it did not hinder the uptake of IL-2 by receptor blockade of this cell. Nevertheless, the replication of CTLL-20 that is IL-2 driven was diminished in the presence of TsF. Similarly, TsF was found to be inhibitory for T-cell proliferation stimulated by mitogen but had no effect on a B myeloma cell proliferative response. Thus, TsF appears to act as an inhibitor of a T cell's capability to replicate despite the presence of the stimulus for replication, namely, IL-2.