T cells produce TRF in response to Con A and factors in T cell hybridoma supernatants

In recent experiments, a soluble factor (TRF) that mediates the differentiation of anti-immunoglobulin (Ig)-activated B cells to Ig-secreting cells has been identified. TRF works in concert with a growth factor, probably IL 2, in the induction of activated B cells. In previous studies, TRF was identified in culture supernatants of activated T cells and accessory cells, and thus the cellular source (T cell or accessory cell) of the factor was not determined. In the present studies, we succeeded in inducing the production of TRF by T cell populations from which accessory cells had been vigorously depleted. Lymph node cells were depleted of accessory cells by nylon wool adherence and anti-Ia and complement treatment; these cells were activated with Con A and a T cell hybridoma supernatant that contains IL 2. Supernatants from these activated T cell cultures supported the differentiation of anti-Ig-activated B cells to Ig secreting cells. These results show that T cells produce the differentiation factor, and further that they do so in response to ligand (Con A) plus a T cell-derived factor.     

Expression of macrophage migration inhibitory factor by neuroblastoma leads to the inhibition of antitumor T cell reactivity in vivo

Neuroblastomas and many other solid tumors produce high amounts of macrophage migration inhibitory factor (MIF), which appears to play a role in tumor progression. We found that MIF expression in neuroblastoma inhibits T cell proliferation in vitro, raising the possibility that MIF promotes tumorigenesis, in part, by suppressing antitumor immunity. To examine whether tumor-derived MIF leads to suppression of T cell immunity in vivo, we generated MIF-deficient neuroblastoma cell lines using short hairpin small interfering RNAs (siRNA). The MIF knockdown (MIFKD) AGN2a neuroblastoma cells were more effectively rejected in immune-competent mice than control siRNA-transduced or wild-type AGN2a. However, the increased rejection of MIFKD AGN2a was not observed in T cell-depleted mice. MIFKD tumors had increased infiltration of CD8(+) and CD4(+) T cells, as well as increased numbers of macrophages, dendritic cells, and B cells. Immunization with MIFKD AGN2a cells significantly increased protection against tumor challenge as compared with immunization with wild-type AGN2a, and the increased protection correlated with elevated frequencies of tumor-reactive CD8(+) T cells in the lymphoid tissue of treated animals. Increased numbers of infiltrating tumor-reactive CD8(+) T cells were also observed at the site of tumor vaccination. In vitro, treatment of AGN2a-derived culture supernatants with neutralizing MIF-specific Ab failed to reverse T cell suppressive activity, suggesting that MIF is not directly responsible for the immune suppression in vivo. This supports a model whereby MIF expression in neuroblastoma initiates a pathway that leads to the suppression of T cell immunity in vivo.     

Modulation of granulomatous inflammation in murine schistosomiasis mansoni by enteric exposure to schistosome ova: in vitro characterization of a regulatory mechanism within the granuloma

Enteric immunization with schistosome ova results in a diminished granulomatous response. This study explored a mechanism by which enteric immunization may decrease granuloma size. Granulomas from livers of acutely infected mice were dissociated and the dispersed cells were depleted of macrophages. As defined by a direct in vitro migration inhibition factor (MIF) assay, the macrophage-depleted cells, composed of lymphocytes and eosinophils, inhibited the migration of normal peritoneal exudate cells when exposed to soluble egg antigens. Anti-Thy 1.2 or -Lyt 1.1, but not -Lyt 2.1, treatment of these cells abrogated MIF activity. Next, mice were exposed enterically to eggs 4 weeks prior to sacrifice. Cells from granulomas isolated from these animals demonstrated no MIF activity unless treated with anti-Lyt 2.1. When granuloma cells from enterically immunized mice were mixed with those from unimmunized animals, MIF activity by the latter was abrogated. Treatment of cells from immunized mice with anti-Lyt 2.1 or -Thy 1.2, but not -Lyt 1.1 prior to mixing once again permitted MIF activity. These results suggest that the diminished granulomatous response induced by enteric immunization could be mediated by Lyt 2+ suppressor T cells. These suppressor cells may regulate the MIF activity of Lyt 1+ T lymphocytes residing within these lesions.     

Antigen-nonspecific and specific suppression of lymphokine production in desensitized guinea pigs

Doubly immunized guinea pigs may be desensitized with respect to delayed hypersensitivity reactions against both antigens (anergy) by injection of large doses of either one. This anergic response therefore has both a specific and nonspecific component. The specific component of desensitization persists longer than the nonspecific one. In the present study, we have explored the mechanism of both antigen-specific and antigen-nonspecific suppression during the later stages of desensitization. Guinea pigs immunized with two antigens, DNP-KLH and DNP-EA, were desensitized with DNP-EA. The lymph node cells obtained from the animals 1 day after desensitization were unable to produce MIF in the presence of either antigen. The cells obtained 3, 5, and 7 days after desensitization were able to generate MIF when stimulated with the non-specific antigen (DNP-KLH), but not with specific antigen (DNP-EA). It was shown that both T- and non-T-cell fractions obtained 1 day after desensitization had the capacity to antigen-nonspecifically suppress MIF production. In contrast, if the cells were obtained 3 or 5 days after desensitization, T cells could inhibit only the antigen-specific production of MIF, while non-T cells were still capable of suppressing antigen-specific and nonspecific MIF production. Interestingly, when these two populations were mixed back again, it was now only suppressive to the specific antigen-induced MIF production. This latter observation indicates that nonspecific suppressor non-T cells may themselves be regulated by suppressor T cells. Furthermore, antigen-specific suppressor T cells were shown to produce soluble factor(s) which inhibited the production of MIF.     

The cellular basis for differential lymphokine responses to mitogen stimulation

Human mononuclear cells from some individuals produce macrophage migration inhibition factor (MIF) when stimulated with Con A while those of others produce migration stimulation factor (MStF). T cells were responsible for these different responses but T4 cells produced MIF and T8 cells produced MStF regardless of the global response which was not explained by the individual T4:T8 ratios. Admixing the T-cell subpopulations in vitro revealed that MIF responses switched to MStF responses between T4:T8 ratios of 75:25 and 50:50 with MStF responders switching at higher ratios than MIF responders. Pulse exposure to supernatants from Con A-stimulated T4-enriched cells significantly reduced migration indices resulting from stimulation of fresh cells, promoting MIF responses regardless of the responder status of the supernatant donor. In contrast, supernatants from T8-enriched cells, when obtained from MStF responders, significantly increased migration indices while there was no effect when the supernatants were obtained from MIF responders. These results suggest that soluble factors from T8 cells are primarily responsible for determining whether an individual mounts a MIF or MStF response to Con A stimulation.     

Macrophages in resistance to rickettsial infection: susceptibility to lethal effects of Rickettsia akari infection in mouse strains with defective macrophage function

We have confirmed the requirement of macrophages in the antigen-induced T-lymphocyte proliferative response and in the generation of migration inhibition factor (MIF) by immune lymphocytes. Extending these observations, we have found that autologous and non-syngeneic, oil-induced peritoneal exudate macrophages were equally effective in restoring the proliferative response and MIF production by column-purified lymph node T cells. MIF activity was optimally restored when T cells were reconstituted with 1 to 40% exudate-derived macrophages whereas 10 to 30% macrophages were needed to optimally restore the T-cell proliferative response. Normal resident macrophages from the peritoneal cavity were also capable of restoring T-cell reactivity as were normal or BCG-activated pulmonary alveolar macrophages. It was also found that the addition of as few as 1.0% glycogen-elicited peritoneal exudate cells restored the production of MIF by T cells. Quantitative considerations demonstrated that the responsible cells in these preparations were polymorphonuclear cells rather than macrophages. In contrast, neither MIF production nor the proliferative response by T cells were restored by the addition of red blood cells. In these studies we were able to demonstrate that freeze-thawed macrophages could restore antigen-induced MIF production, but not antigen-induced cellular proliferation. The ability of freeze-thawed macrophages to stimulate T cells to produce MIF was apparently associated with the macrophage membranes and not with a soluble factor in the macrophage extracts. These results demonstrate that multiple sources of phagocytic cells may interact cooperatively with lymphocytes in reactions of cell-mediated immunity. Further, at least in the case of MIF production, this interaction involves a membrane-bound determinant that is effective even in the absence of viable macrophages.     

Characterization of a keratinocyte-derived T cell growth factor distinct from interleukin 2 and B cell stimulatory factor 1

Epidermal epithelial cells (keratinocytes) produce and secrete a variety of immunologically active cytokines. We have previously reported that both transformed (PAM 212) and normal murine keratinocytes produce a soluble factor which induces proliferation of the T cell line, HT-2. In the present study we sought to compare keratinocyte-derived T cell growth factor (KTGF) with other T cell growth factors, characterize its physicochemical properties, and substantially purify KTGF from PAM 212 conditioned medium. KTGF from PAM 212 conditioned medium was not inhibited by antibodies which block the effect of interleukin 2 (IL 2) (S4B6) or B cell stimulatory factor 1 (BSF 1) (11B11). KTGF is heat-stable, has an isoelectric point of 4.8, and a relative molecular mass of 16 to 23 kilodaltons under nonreducing conditions. KTGF activity was enhanced at least 41,413-fold by sequential hydroxylapatite bulk preparation, desalting by reversed-phase chromatography, gel filtration high pressure liquid chromatography (HPLC), and reversed-phase HPLC. Keratinocytes produce a T cell growth factor with physicochemical properties distinct from IL 2 and BSF 1. KTGF may play a role in regulating the growth and differentiation of T cells in the epidermis.     

Stimulation of mouse migration inhibitory factor (MIF) production form MSV-immune lymphocytes by soluble tumor-associated antigen: requirement for histocompatible macrophages.

Spleen cells from C57BL/6 mice immunized with murine sarcoma virus (MSV) are capable of producing migration inhibition factor (MIF) in response to stimulation with a specific tumor-associated antigen prepared by solubilization with 3 M KCL. We have previously demonstrated that this response is T cell-dependent. Further investigations into the effector cells involved in the production of MIF have revealed that spleen cells from mice immunized with MSV cannot produce MIF when stimulated with tumor extract if the population has been previously depleted of macrophages. However, the response can be restored by adding nonimmune syngeneic macrophages but not by allogeneic macrophages. The inability of allogeneic macrophages to provide this function was not due to their increased suppressor activity since in mixing experiments they did not interfere with the ability of immune spleen cells to produce MIF. Furthermore, they were not defective since they could supply this "cooperative function" to appropriate F1 mice. The results indicate that macrophages are required for stimulation of MIF by soluble tumor antigens and that for efficient interaction the macrophages and lymphocytes must share some genetic similarities.     

The necessity for T cell help for human tonsil B cell responses to pokeweed mitogens: induction of DNA synthesis, immunoglobulin, and specific antibody production with a T cell helper factor produced with pokeweed mitogen.

Human B lymphocytes obtained from tonsils do not proliferate when stimulated with pokeweed mitogen. A soluble factor produced from T cells cultured with pokeweed mitogen stimulates B cells to synthesize DNA and differentiate into immunoglobulin producing cells. This PWM produced supernatant induced a PFC response to SRBC. The T cell supernatant activity is produced within 12 hr of stimulation in the presence of serum and without a requirement for T cell division. Optimal stimulation of B cells occurred at 7 to 9 days of culture. This helper factor activity eluted postalbumin from a column of Sephadex G-200. Insolubilized pokeweed mitogen was not mitogenic for B cells. The continuous presence of the lectin in culture was not required for B cell proliferation or for immunoglobulin synthesis.     

A spleen-derived maturational factor allows immature thymocytes, prepared as cells bearing low amounts of surface sialic acid, to become cytotoxic T cells

A population of immature mouse thymocytes bears low levels of surface sialic acid and can be separated from the more mature high sialic acid-bearing thymocytes by selective agglutination with the sialic acid-specific lectin, lobster agglutinin 1. These immature thymocytes do not proliferate in response to concanavalin A (Con A). They do not produce interleukin 2 (IL-2), do not provide T cell help to B cells for an in vitro antibody response, and as shown here, do not become cytotoxic T lymphocytes when polyclonally stimulated with Con A + IL-2. We describe here a spleen-derived maturational factor which stimulates these immature thymocytes, in the presence of Con A and IL-2, to become cytotoxic T lymphocytes. The maturational factor is a protein secreted by Con A-stimulated mouse or rat spleen cells; it is apparently neither interleukin 1, IL-2, interleukin 3, gamma-interferon, nor combinations of these cytokines, because these materials do not replace the maturational factor. The active material in Con A-stimulated mouse spleen cell supernatant was recovered from a G-75 column in the 33,000-48,000 m.w. range. These experiments suggest that within the lobster agglutinin 1-negative thymocyte population there are cells which can mature under the influence of a spleen-derived factor. It is possible that these cells represent the small subpopulation of immature cells destined to become immunocompetent peripheral T cells. On the other hand, the factor may be rescuing cells destined to die in the thymus.     

Skin allografts generate an enhanced production of histamine and histamine-producing cell-stimulating factor (HCSF) by spleen cells in response to T cell mitogens

In response to T cell mitogens, spleen cells produce a large amount of histamine, whereas no or a slight increase is observed after B cell mitogen stimulation. This increased histamine production results from the effect of a factor having all the characteristics of HCSF (histamine-producing cell-stimulating factor) already described in secondary MLC supernatant. This factor is produced by Thy-1, 2, Lyt-1, 2-positive cells. Spleen cell cultures derived from skin-allografted mice during rejection produce more histamine in response to T cell mitogens than do spleen cells from normal or syngeneic grafted mice. Such a phenomenon is not observed in response to B cell mitogens. A striking association is found between enhanced histamine synthesis and skin allograft rejection. This phenomenon results from a) a five to 10-fold increase in HCSF production by allograft recipient spleen cells in response to T cell mitogens, and b) an increase in HCSF sensitivity of these spleen 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.     

Orally induced tolerance generates an efferently acting suppressor T cell and an acceptor T cell that together down-regulate contact sensitivity

Intragastric administration of the hapten trinitrochlorobenzene (TNCB) suppresses development of contact sensitivity (CS) to attempted epicutaneous sensitization with TNCB. Suppression induced by feeding TNCB is hapten specific and can be transferred to normal animals with lymphoid cells from fed mice. The lymphoid cells in hapten-fed mice that cause suppression of CS have been identified as Thy-1.2-positive cells in spleen and mesenteric nodes. The suppression with Peyer's patch cells from hapten-fed mice appears to be attributable to cells bearing Thy-1.2 antigen (T cell) and to cells with surface Ig (B cell). Feeding TNCB induces an efferent-acting suppressor T cell (Ts eff), as well as an intermediary acceptor T cell (T acc) with which it interacts to block adoptive transfer of CS with immune cells. Ts eff emanating from hapten-fed mice was identified by its specificity for the hapten, insensitivity to pretreatment with cyclophosphamide (CY), ability to produce soluble suppressor factor (SSF), and requirement for T acc to be functional. The presence of T acc in hapten-fed mice, on the other hand, was confirmed by its sensitivity to treatment with CY, interaction with Ts eff or SSF, and the ability to produce nonspecific inhibitor of TDTH cells. Thus, the suppressor T cells that are induced by administering the hapten intragastrically appear to function much like the cells of the suppressor T cell cascade that are induced by giving hapten via parenteral routes.     

The role of macrophages in anti-idiotypic antibody and T suppressor factor induction of timothy grass pollen antigen B-specific T suppressor cells

Cultures of normal spleen cells with anti-idiotypic antibody (anti-Id) or antigen B (AgB)-specific T suppressor factor (Tsf1) in mini-Marbrook chambers for 4 days at 37 degrees C lead to the in vitro induction of AgB-specific T suppressor (TS) cells. These TS cells significantly suppress a secondary AgB-specific IgE response, but they do not affect a secondary AgB-specific IgG response. Depletion of both B cells and macrophages from normal spleen cells by panning on anti-Ig-coated petri dishes provides an enriched T cell population. These enriched T cells when cultured with anti-Id or Tsf1 in mini-Marbrook chambers do not produce AgB-specific TS cells, and mice treated with cells harvested from the mini-Marbrook chambers have normal secondary AgB-specific IgG and IgE responses. The addition of as few as 1000 bone marrow-derived macrophages (BMDM) to cultures of the enriched T cells with anti-Id, or Tsf1 restores the ability of these cultures to produce significant levels of AgB-specific TS cells. Further studies reveal that the macrophage population must be histocompatible and express a cell surface I-J antigen. Attempts to pulse BMDM with anti-Id or Tsf1 at 4 degrees C and to culture in mini-Marbrook chambers 10(3) pulsed BMDM with enriched T cells were unsuccessful in producing AgB-specific TS cells. However, pulsing BMDM with anti-Id or Tsf1 at 37 degrees C, and adding 10(3) of these pulsed BMDM to enriched T cells in culture led to the formation of significant levels of AgB-specific TS cells.     

Tumor-derived macrophage migration inhibitory factor (MIF) inhibits T lymphocyte activation

Macrophage migration inhibitory factor (MIF) is a multi-functional cytokine that is considered a pro-inflammatory cytokine. However, our studies show that MIF, when produced in super-physiological levels by a murine neuroblastoma cell line (Neuro-2a) exceeding those normally seen during an immune response, inhibits cytokine-, CD3-, and allo-induced T-cell activation. MIF is also able to inhibit T cells that have already received an activation signal. The T-cell inhibitory effects of culture supernatants from neuroblastoma cells were reversed when the cells were transfected with dicer-generated si-RNA to MIF. When T cells were activated in vitro by co-culture with interleukin (IL)-2 and IL-15 and analyzed for cytokine production in the presence or absence of MIF-containing culture supernatant, inhibition of T-cell proliferation and induced cell death were observed even as the treated T cells produced high levels of interferon-gamma (IFN-gamma). The inhibitory effects of MIF were partially reversed when lymphocytes from IFN-gamma knockout mice were tested. We propose that the high levels of MIF produced by neuroblastoma cause activation induced T-cell death through an IFN-gamma pathway and may eliminate activated T cells from the tumor microenvironment and thus contribute to escape from immune surveillance.     

The role of T cells in immunoglobulin class switching of specific antibody production system in vitro in humans

Only antibodies of the IgM class were produced in vitro by peripheral blood mononuclear cells stimulated with streptococcal carbohydrate. B cells of the peripheral blood mononuclear cells, however, synthesized both IgM and IgG class antibodies when combined with tonsillar T cells, suggesting that T cells inducing immunoglobulin class switching are present in the tonsils. Peripheral blood T cells also became capable of inducing B cells to produce IgG class antibodies when the T cells were incubated with antigen-pulsed macrophages. Surface IgM-positive, IgG-negative high-density B cells produced IgG antibodies for streptococcal carbohydrate in the presence of these T cells or tonsillar T cells. The culture supernatant solutions from these T cells or tonsillar T cells, however, failed to cause the B cells to produce IgG, indicating that class switching is not mediated by factors released from T cells. Lymphokines such as interleukin-2, human B cell growth factor, helper T cell factor, or interferon-gamma were also incapable of inducing IgG production. These results suggest that the cognate interaction between T cells and B cells is necessary for the immunoglobulin class switching.     

In vitro and in vivo regulation by macrophage migration inhibitory factor (MIF) of expression of MHC-II,costimulatory, adhesion,receptor, and cytokine molecules

The secretion of macrophage migration inhibitory factor (MIF) is enhanced by inflammatory and other stimuli. MIF regulates innate and adaptive immune responses, but the mechanisms of this regulation are poorly understood. Our hypothesis was that MIF generated by these stimuli regulates these responses by modulating key molecular expression. This hypothesis was tested by adding greater than constitutive concentrations of recombinant MIF to cultures of various cell types and flow cytometric assay. MIF modulated surface expression of MHC-II, B7-2, CD40, CD40 ligand, ICAM-1 and Fcgamma, CR1/CR2, and IL-10 receptors and intracellular expression of IL-10, TNFalpha, and p40 (IL-12). MIF increased expression of B7-1 by B cells and CD40 L by T cells in spleens from Schistosoma mansoni-infected mice. Footpad injection of MIF reduced expression of MHC-II and CD40 by B cells in draining lymph nodes. Footpad injection of Mab to MIF reduced expression of B7-2 and CR1/CR2 by B cells and B7-2 by macrophages in these nodes. These data support our hypothesis.