Induction of antigen-specific antibody response in human peripheral blood lymphocytes in vitro by a dog kidney cell vaccine against rabies virus (DKCV)

In the present report an in vitro method for obtaining a secondary human antibody response to a dog kidney cell vaccine against rabies virus (DKCV) is described. Cultures of peripheral blood mononuclear cells from normal rabies-immune and nonimmune donors were stimulated in vitro by DKCV. The production of virus-specific antibody in supernatant fluids was monitored by ELISA. Antibody was produced by lymphocytes from rabies-immune individuals, whereas those of nonimmune subjects consistently failed to produce anti-rabies antibodies after in vitro stimulation with DKCV. The generation of the anti-rabies virus antibody response of lymphocytes stimulated with DKCV was shown to be an antigen-dependent, as well as an antigen-specific process. Optimal antigen-specific responses were observed at relatively low concentrations of antigen (10(-1) to 10(-2) micrograms/culture). At increasing concentrations of antigen in culture (greater than 1 microgram/culture), the anti-rabies virus response was suppressed. Antibody produced upon stimulation was capable of neutralizing rabies virus. The response to rabies virus requires T cell help because lymphocytes depleted of SE rosetting cells did not respond to an antigenic stimulus. Studies in which the same individuals were followed over time showed a sequential development of circulating B cell subsets. The system may provide a model for the study of human B cell differentiation in vivo and in vitro and may be valuable for testing the potency of rabies vaccines in vitro.     

T-T interactions in the induction of antigen-specific human suppressor T lymphocytes in vitro.

We intended to investigate whether the suppression of antigen-induced antibody responses in vitro in man by T suppressor cells required contact of T suppressor cells with target cells or whether this effect was mediated by factors released by T suppressor cells. To this end supernatants of antigen-induced T suppressor cells were tested (by a plaque forming cell assay) for their capacity to suppress antibody responses of autologous and allogeneic human peripheral blood lymphocytes. We have shown that supernatants of antigen-specific T suppressor cells, designated as TsF24: a) can suppress an antibody response of autologous but not allogeneic lymphocytes to the inducing antigen; b) are antigen-specific in their effect; and 3) are produced by radiosensitive T cells. Furthermore, the target of the factor is a radiosensitive T cell. These findings taken together indicate that, in the generation of T-effector suppressor cells in man, T-T interactions occur, and in addition, that cellfree factors may be involved in these interactions.     

The induction and suppression of in vitro IgG anti-tetanus toxoid antibody synthesis by human lymphocytes stimulated with tetanus toxoid in the absence of in vivo booster immunizations

This report presents a new approach that by-passes booster immunizations with tetanus toxoid (TT) before in vitro studies of antibody (Ab) production. The methodology for optimal TT-induced synthesis of specific IgG anti-tetanus toxoid Ab (IgG anti-TT) by peripheral blood mononuclear cells (PBMC) from randomly selected TT immune individuals without recent booster immunizations is described. PBMC from most normal immune subjects could be repeatedly induced to produce in vitro IgG anti-TT; PBMC from subjects with high TT titers are not required for this new approach. This approach uses high cell concentrations in multiple replicate microcultures and TT washout to obtain optimal IgG anti-TT synthesis. Washed cultures produced more Ab than nonwashed cultures (p less than or equal to 0.005). The readdition of TT (2.5 to 250 ng/ml) to the culture media after washout of TT on day 4 suppressed specific Ab formation, whereas diphtheria toxoid added at comparable doses did not inhibit specific Ab formation. Suppression of antibody synthesis mediated by T cells could be induced by TT per se, and was not due to binding of synthesized Ab to TT in the latter 8 days of culture. In addition, suppression could not be induced in the first 4 days of culture by IgG anti-TT, IgG, or IgM. This approach permits the analysis of antigen-specific regulatory circuits in the steady and activated immune states, and the evaluation of in vivo and in vitro effects of biologic response modifiers on specific Ab production.     

Antigen-specific human B-cell responses: modulation by immunoregulatory T-cell subsets

In vitro T-cell requirements for and modulation of human B-cell responses were studied in individuals immunized in vivo to the protein antigen keyhole limpet hemocyanin or tetanus toxoid. T cells were required for antibody synthesis in both antigen-driven and pokeweed mitogen (PWM)-driven cultures. T cells were separated into T4+ and T8+ subpopulations using monoclonal antibodies, and their modulation of antibody synthesis was studied. T4+ cells functioned as helper cells in both antigen-driven and PWM-driven cultures in a dose-dependent manner. Whereas T8+ cells suppress both total and specific immunoglobulin secretion in PWM-stimulated cultures, in antigen-stimulated cultures T8+ cells do not suppress unless activated by another cell population present in peripheral blood mononuclear cells (PBMNC). This cellular requirement was further investigated by prestimulation of cells prior to addition to optimally stimulated antigen-driven cultures of PBMNC or B cells, monocytes, and helper T cells. No suppression of these optimally stimulated cultures was seen when T8+ cells were precultured with antigen or PWM. However, after 3-5 days preculture of total T cells with PWM or antigen and then selection of T4+ cells, these cells were able to induce fresh autologous T8+ cells to suppress optimally stimulated antigen-driven cultures. Addition of a precultured mixture of T8+ cells with 20% T4+ cells also resulted in antigen-induced suppression. These data indicate that T8+ cells can suppress antigen-driven cultures but require the presence of preactivated T4+ cells for induction of this suppression of antigen-specific T-cell-dependent human B-cell responses.     

The development of standard samples with a defined number of antigen-specific T cells to harmonize T cell assays: a proof-of-principle study

The validation of assays that quantify antigen-specific T cell responses is critically dependent on cell samples that contain clearly defined measurable numbers of antigen-specific T cells. An important requirement is that such cell samples are handled and analyzed in a comparable fashion to peripheral blood mononuclear cells (PBMC). We performed a proof-of-principle study to show that retrovirally TCR-transduced T cells spiked at defined numbers in autologous PBMC can be used as standard samples for HLA/peptide multimer staining. NY-ESO-1_157–165-specific, TCR-transduced CD8+ T cell batches were successfully generated from PBMC of several HLA-A*0201 healthy donors, purified by magnetic cell sorting on the basis of HLA tetramer (TM) staining and expanded with specific antigen in vitro. When subsequently spiked into autologous PBMC, the detection of these CD3+CD8+TM+ T cells was highly accurate with a mean accuracy of 91.6 %. The standard cells can be preserved for a substantial period of time in liquid nitrogen. Furthermore, TM staining of fresh and cryopreserved standard samples diluted at decreasing concentrations into autologous cryopreserved unspiked PBMC revealed that the spiked CD3+CD8+TM+ T cells could be accurately detected at all dilutions in a linear fashion with a goodness-of-fit of over 0.99 at a frequency of at least 0.02 % among the CD3+CD8+ T cell population. Notably, the CD3+CD8+TM+ cells of the standard samples were located exactly within the gates used to analyze patient samples and displayed a similar scatter pattern. The performance of the cryopreserved standard samples in the hands of 5 external investigators was good with an inter-laboratory variation of 32.9 % and the doubtless identification of one outlier.     

Activation and immunoregulation of antigen-specific human b lymphocyte responses: multifaceted role of the monocyte

The multifaceted role of the monocyte in the induction and modulation of antigen-specific antibody responses by human B cells was delineated. Monocytes were absolutely required for the induction of specific antibody responses to both TT and KLH in an antigen-induced in vitro assay. Monocytes were also required for the PWM induction of specific antibody in immunized subjects. Pulsing monocytes with specific antigen or with PWM consistently stimulated proliferation of T cells in absence of added antigen and could also stimulate specific antibody synthesis although less consistently. Stimulation of specific antibody responses with antigen required fewer numbers of monocytes than did stimulation of specific antibody responses with PWM. Polyclonal antibody synthesis induced by PWM was also dependent on monocytes. However, polyclonal antibody synthesis induced by supraoptimal concentrations of antigen was usually optimal in the absence of monocytes and was actually suppressed when increased numbers of monocytes were added to monocyte-depleted cultures. Monocyte supernatants could not replace the absolute requirements for monocytes in the induction of specific antibody synthesis. However, monocyte supernatants could profoundly modulate the antigen-specific as well as the polyclonal Ig response of lymphocytes to either antigen or PWM stimulation in a manner closely resembling monocytes themselves. Thus, we demonstrated that monocytes and their products play a critical role in the activation and immunoregulation of antigen-specific antibody responses of human B cells.     

In vitro immunization can elicit the expansion of diverse repertoire of B cells from peripheral blood mononuclear cells

We previously developed an in vitro immunization (IVI) protocol of human peripheral blood mononuclear cells (PBMC) for generating antigen-specific human antibodies. In order to clarify whether IVI protocolinduces antigen-specific B cell responses in PBMC, we analyzed family gene usage and sequence of the variable region gene of immunoglobulin heavy chain (VH gene) of the antibody produced from the in vitro immunized PBMC. Sequence homology analyses of VH gene demonstrated that a larger repertoire of B cells can be sensitized with mite-extract than with cholera toxin B subunit and rice allergen. Further, antigen-specific B cells were efficiently expanded by using CpG oligodeoxynucleotide as adjuvant. These results suggest that appropriate combination of sensitizing antigen and adjuvant is primarily important for expansion of antigen-specific B cells in IVI protocol.     

Vascular endothelial cells enhance T cell responses by markedly augmenting IL-2 concentrations

Cultured human endothelial cells (EC), dermal fibroblasts (DF), and blood monocytes were compared for their effects on IL-2 concentration measured in the medium of both unfractionated peripheral blood mononuclear cells (PBMC) and highly enriched CD4+ T cell populations maximally stimulated by the polyclonal mitogen phytohemagglutinin (PHA). EC, but not DF or blood monocytes, could markedly augment IL-2 concentrations, up to 30-fold or more. This action of EC could not be replaced by fixed EC, EC-conditioned medium, or recombinant IL-1. Antibody to CD2 but not to CD18 blocked the EC effect. The augmented IL-2 concentrations generated in the presence of EC appeared biologically active in that the addition of living EC conferred a proliferative advantage to PBMC at suboptimal PHA concentrations, an effect which could be mimicked by exogenous IL-2. We propose that EC augmentation of IL-2 synthesis may contribute to the relatively unique ability of EC to stimulate a primary allogeneic response in vitro and may function in vivo to boost T cell responses to limiting quantities of antigen.     

Induction of suppressor cells to T- and B-cell proliferative responses and immunoglobulin production by monoclonal antibodies recognizing the CD3 T-cell differentiation antigen

Monoclonal antibodies (mAb's) recognizing the CD3 T-cell differentiation antigen induced the generation of suppressor cells. These cells inhibited (1) proliferative responses of human peripheral blood mononuclear cells (PBMC) to PHA and allogeneic cells in mixed leukocyte culture; (2) proliferative responses of purified E-rosette-negative cells to Staphylococcus aureus Cowans I; and (3) de novo immunoglobulin synthesis and secretion in the pokeweed mitogen (PWM)-induced differentiation system. Monoclonal antibodies recognizing other T-cell differentiation antigens (anti-Leu 2a, anti-Leu 3a, and anti-Leu 5) did not induce the generation of suppressor cells, even at very high antibody concentrations. Statistically significant differences were not observed in the ability of the OKT3 and anti-Leu 4 mAb's to induce suppressor cells. Monocytes were not required for the generation of anti-CD3-induced suppressor cells. F(ab')2 fragments of the OKT3 mAb's were equally effective when compared with intact antibody molecules in inducing suppressor cells, although they did not induce proliferative responses. Proliferation was not required for the induction of suppressor cells. Irradiation (2500 rad) of PBMC before incubation with the anti-CD3 mAb did not affect the generation of suppressor cells. Furthermore, anti-CD3-induced suppressor cells were radioresistant. Addition of recombinant IL-2 to the cultures of responding cells and suppressor cells did not reverse the suppression. In vitro treatment of anti-CD3-induced suppressor cells with either the OKT4 mAb plus complement or the OKT8 mAb plus complement partially decreased the suppression of proliferative responses of PBMC to PHA or allogeneic cells in mixed lymphocytes culture. However, treatment with both OKT4 and OKT8 mAb's plus complement or the OKT11 mAb plus complement completely abolished the suppression. These results suggest that the suppressor cells are of the T11+T4+T8- and T11+T4-T8+ phenotypes. In other experiments, T4+T8- and T8+T4- cells were isolated from PBMC treated for 48 hr with anti-CD3 mAbs. Both these two populations significantly inhibited proliferative responses of autologous PBMC to PHA and de novo immunoglobulin synthesis and secretion by mixtures of purified T4 and B cells from normal donors, in the PWM-induced differentiation system. These results demonstrate that anti-CD3-induced suppressor cells are of the T4 or T8 phenotype. Treatment of purified T4+T8- and T8+T4- cells with anti-CD3 mAb's resulted in the generation of suppressor cells, suggesting that the precursors of the anti-CD3-induced suppressor cells can belong to either of these two populations.(ABSTRACT TRUNCATED AT 400 WORDS)     

Antigen-specific and polyclonal immunoglobulin production induced by a cloned tetanus toxoid-specific T cell line

This report describes the isolation and the phenotypic and functional characterization of a cloned, IL 2 dependent, TT-specific human helper T cell line (TCL), designated 1A1. 1A1 was derived by limiting dilution culture of a bulk IL 2-dependent TCL that was found to contain both TT and trinitrophenyl (TNP) altered self-reactive T cells. Specifically, 1A1 represents the outgrowth of one well of a microwell cloning plate initially seeded at 1 TCL/well, from which less than 4% (3/96) wells grew. Phenotypic analysis, utilizing a battery of monoclonal antibodies, demonstrates that all 1A1 cells are T cells belonging to a stable and discrete T cell subset: T3+, T4+, T17+, T8-. In proliferative assay, 1A1 responds specifically to TT but not to other soluble antigens against which the donor is sensitized, a panel of allogeneic stimulators, nor to TNP-modified-self. Moreover, 1A1 is HLA-DRw-restricted, proliferating only to TT in association with DRw3+ antigen-presenting cells. Of greater interest is the observation that 1A1 is an antigen-specific helper T cell line. Thus, by utilizing ELISA systems to quantitate class-specific immunoglobulin and antigen-specific antibody, it was determined that co-culture of autologous B cells, 1A1 cells, and a low concentration (1 to 10 ng/ml) of TT results in an IgG response that is predominantly, if not exclusively, antigen-specific antibody. In contrast, the presence of high concentrations of TT (4 micrograms/ml) triggers a polyclonal immunoglobulin response comprised of IgM with a small IgG component that is essentially devoid of anti-TT antibody. These results demonstrate that depending on the mechanism of activation, a cloned antigen-specific helper T cell line can mediate antigen-specific or polyclonal help for autologous B cells.     

Characterization of human cytotoxic lymphocytes directed against cells infected with typhus group rickettsiae: evidence for lymphokine activation of effectors

An in vitro culture and assay system was used to determine whether cytotoxic lymphocytes are generated in humans after rickettsial infection. Peripheral blood mononuclear cells (PBMC) were obtained from six individuals with serologic evidence of prior infection with typhus group rickettsiae and from six nonimmune individuals. After PBMC from immune individuals were stimulated in vitro for 7 days with rickettsial antigen, they were capable of lysing typhus group rickettsia-infected, autologous phytohemagglutinin (PHA)-induced blasts, but not uninfected PHA-blasts. No cytotoxic effector cells were generated when either PBMC from immune individuals were placed in culture for 7 days without antigenic stimulation, or when PBMC from nonimmune individuals were stimulated in vitro with antigen for 7 days. Freshly isolated PBMC from immune donors were also unable to lyse typhus group rickettsia-infected autologous PHA-blasts or an autologous rickettsia-infected lymphoblastoid cell line (LCL). Neither supernatants from antigen-stimulated cultures of PBMC from immune donors nor recombinant human interferon-gamma were capable of significantly lysing typhus group rickettsia-infected PHA blasts by this assay. Populations of cytotoxic effector cells depleted of OKT3, OKT4, or OKT8-positive cells by treatment with the respective monoclonal antibodies and complement were assayed for their cytotoxic capacity. The results suggest that the cytotoxic effector cell population is predominantly OKT3 and OKT8-positive, but OKT4-negative. Positive selection with the use of a fluorescence-activated cell sorter also suggested that most of the cytotoxic effector cells are OKT8-positive. PBMC from immune donors after in vitro stimulation with rickettsial antigen were capable of significantly lysing infected autologous LCL or infected HLA-mismatched LCL as compared with the respective uninfected controls. In addition, PBMC from either immune donors or nonimmune donors after stimulation in vitro for 7 days with media containing purified lymphokines were capable of significantly lysing autologous infected LCL as compared with the uninfected autologous control. We conclude that lysis of cells infected with typhus group rickettsiae is mediated by a lymphokine-activated killer.     

Antigen presentation by EBV-B cells to resting and activated T cells: role of interleukin 1

We have previously demonstrated that Epstein Barr virus-transformed human B lymphocytes (EBV-B cells) present antigen to activated T cells (lines and clones) in a MHC-restricted manner. In the present study, using EBV-nonimmune donors, we demonstrate that EBV-B cells are unable to trigger tetanus toxoid (TT) antigen-specific proliferation in autologous highly purified resting T cells. EBV-B cells from these same individuals were able to present TT to autologous TT-specific activated T cell blasts (Tbl). The inability of EBV-B cells to present TT to resting T cells was not caused by defective antigen processing by EBV-B cells. Thus, paraformaldehyde treatment of antigen-pulsed EBV-B cells did not impair their ability to trigger proliferation of antigen-specific Tbl, and EBV-B cells pulsed with antigen in the presence of autologous TT-specific T cell blasts did not present antigen to resting T cells. Furthermore, antigen-specific proliferation of resting T cells triggered by monocytes was enhanced rather than suppressed by EBV-B cells. The addition of partially purified human IL 1 allowed EBV-B cells to present TT antigen to resting T cells, suggesting that failure to secrete IL 1 contributed to the failure of EBV-B cells to present antigen. IL 1 could not be detected in supernatants of EBV-B cells stimulated with Staphylococcus epidermidis, concanavalin A, and TT antigen in the presence or absence of up to 5% autologous T cells. The differential capacity of EBV-B cells to present antigen to resting T cells vs activated T cells correlated with the T cell requirement for IL 1, because a rabbit antibody to human IL 1 inhibited the monocyte-supported proliferation of resting T cells but not that of activated T cells. These results suggest that the inability of EBV-B cells to present antigen to resting T cells is related to their inability to secrete detectable IL 1.     

Differentiation of NK-like cells from OKT3-, OKT11+, and OKM1+ small resting lymphocytes by culture with autologous T cell blasts and lymphokine

NK-like cells have been generated in vitro from a resting lymphocyte population of PBMC by 8 days culture with mitomycin C-treated autologous T cell blasts and lymphokine. The responder lymphocyte population was purified to the extent that it lacked classical NK cells, and lacked the precursors of MLC-derived NK-like cells and of lymphokine-activated killer cells. The NK-like cells were not generated when the responder lymphocytes were cultured with either T cell blasts or lymphokine alone. Thus, at least two signals are required for their activation. Metabolically inactive T cell blasts plus lymphokine were effective in stimulating the generation of NK-like cells, suggesting that a membrane determinant on the T cell blasts was involved in activation. The phenotype of the NK-like cells and their precursors was analyzed by monoclonal antibody and complement treatment. The phenotype of both precursor and effector cells was OKT3-, OKT11+, and OKM1+, with a distinct pattern of reactivity with OKT8 and Leu-7 for each individual donor tested. The NK-like cells were morphologically large granular lymphocytes, and they killed a variety of target cells. These studies show that signals provided by autologous T cell blasts and lymphokine are essential in triggering the differentiation of NK-like cells from appropriately purified resting lymphocytes. This mechanism of activation could occur in vivo, leading to the generation of NK cells subsequent to an antigen-specific T cell response.     

Involvement of IL-10 in the suppression of antibody production by in vitro immunized peripheral blood mononuclear cells

Previously, we have established an in vitro immunization method to induce antigen-specific antibody-producing B cells. In the present study, we have attempted to clarify the mechanisms that regulate antibody production by in vitro immunized peripheral blood mononuclear cells (PBMC). Freshly isolated PBMC did not induce antibody production following in vitro immunization, but expressed the interleukin (IL)-10 gene. On the other hand, PBMC pretreated with l-leucyl-l-leucine methyl ester (LLME) induced antibody production, but did not express the IL-10 gene. IL-10 induced functional impairment of CD4⁺ Th cells and CD11c⁺ DC, resulting in the suppression of antibody production by in vitro immunized PBMC.     

Activation through CD3 molecule leads a number of human T cell clones to induce IgE synthesis in vitro by B cells from allergic and nonallergic individuals

Seventy-eight clones established from tonsillar T lymphocytes of two nonallergic children were tested under different experimental conditions for their ability to induce in vitro IgE synthesis by B cells from allergic or nonallergic donors. After 24 hr preactivation with phytohemagglutinin (PHA), 11 out of 32 CD4+ clones from the first and 17 out of 36 CD4+ clones from the second tonsil donor showed the ability to induce IgE synthesis in vitro by B cells from both allergic and nonallergic individuals, whereas none of 10 CD8+ clones nor T blasts of PHA-induced cell lines obtained from unfractionated T cell suspensions of the same tonsils had such an effect. Seven of the 11 T cell clones from the first tonsil donor active on IgE production after pre-activation with PHA also induced IgE synthesis in vitro by nonallergic and allergic B cells upon stimulation with anti-CD3 monoclonal antibody. Under the same experimental conditions, virtually all of the T cell clones able to induce IgE synthesis in vitro by target B cells showed the ability to stimulate IgG and IgM production as well. T cell clones were also established from the peripheral blood of a nonallergic donor and were tested for their ability to induce IgE synthesis in autologous B cells. After preactivation with PHA, seven out of 35 CD4+ clones induced the production of detectable amounts of both IgE and IgG in autologous B cells. The addition to the cultures of PHA-stimulated unfractionated T cells inhibited in a dose-dependent manner the IgE but not the IgG synthesis induced by an autologous helper T cell clone in autologous B cells. Taken together, these data indicate that a remarkable proportion of human T cell clones upon triggering of the CD3 molecular complex were able to provide help for the synthesis of IgE in B cells from both allergic and nonallergic individuals. The successful induction of IgE synthesis by single T cell clones was apparently related to the lack of concomitant suppressor activity to which IgE-producing cells appeared to be exquisitely sensitive.     

T cell activation of antigen-specific antibody responses by large B cells is MHC restricted

The activation of small, resting B cells for antibody synthesis by helper T cells has been proposed to require an MHC-restricted interaction between the T and B cells. Large, activated B lymphocytes were, in contrast, thought to be activated by an unrestricted pathway. We re-examined this issue and found that both large and small size fractionated murine B lymphocytes required an MHC-restricted interaction with helper T cells to be activated for specific antibody synthesis. Polyspecific antibody synthesis in the same cultures was not dependent upon an MHC-restricted T-B interaction for any size category of B cell. These results are interpreted as reflecting the ability of antigen-specific B cells to focus and present antigen to T cells, in contrast to B cells of random specificity, which have no effective focusing mechanism for a given experimental antigen. We found that the polyspecific response required much higher antigen concentrations than the antigen-specific response, a result consistent with the antigen-focusing hypothesis.     

Antigen handling by guinea pig macrophages: further evidence for the sequestration of antigen relevant for activation of primed T lymphocytes.

Guinea pig macrophages can take up sufficient 2,4 dinitrophenyl guinea pig albumin during a brief in vitro exposure at 37 degrees C to trigger proliferation and lymphokine production with primed T lymphocytes on subsequent co-culture. Treatment of such antigen-bearing macrophages with trypsin, a procedure which removes surface antigen, does not alter the ability of such macrophage to initiate the release of migration inhibition factor from sensitized T lymphocytes. In addition, formation of antigen-specific rosettes between primed T cells and antigen-bearing macrophages is not blocked by high concentrations of antibody directed against the antigen mediating this interaction. Similarly, primed T lymphocyte DNA synthesis induced by antigen-bearing macrophages is not inhibited by specific antibody to that antigen. These data support the conclusion that the fraction of macrophage-associated antigen which is relevant to T lymphocyte activation does not reside on the macrophage surface but rather remains in a restricted compartment from which it is accessible to the T cell but unavailable to either blockade by specific antibody or removal by proteolytic enzymes.     

Dendritic cell secretion of IL-15 is induced by recombinant huCD40LT and augments the stimulation of antigen-specific cytolytic T cells

Dendritic cells (DC) are professional antigen-presenting cells which stimulate strong proliferative and cytolytic T cell responses. Stimulation of CD40 on dendritic cells by its ligands and anti-CD40 antibodies induces maturation and enhances DC stimulatory ability. In order to understand the mechanism by which ligand:CD40 interactions augment DC function, we assessed the role of T cell stimulatory cytokines IL-12 and IL-15 in the function of DC stimulated with soluble trimeric CD40L, a recombinant fusion protein incorporating three covalently linked extracellular CD40L domains (huCD40LT). Peripheral blood derived DC treated with huCD40LT and/or IFN-gamma were used to stimulate T cell responses in vitro to specific antigens. DC treated with huCD40LT or IFN-gamma/huCD40LT stimulated enhanced T cell proliferation to CASTA, a soluble protein from C. albicans, induced T cells with augmented antigen-specific lysis, and increased the yield of antigen-specific IFN-gamma-producing T cells. IL-15 production by DC was enhanced in cultures treated with huCD40LT and correlated with expansion of antigen-specific cytolytic T cells. Addition of a neutralizing anti-IL-15 monoclonal antibody inhibited the expansion of viral and tumor antigen-specific T cells stimulated by IFN-gamma and huCD40LT-treated DC. In contrast, this enhanced stimulatory ability of DC did not appear to depend on synthesis of IL-12 since huCD40LT treatment stimulated the generation of antigen-specific cytokine producing and cytolytic T cells without increased IL-12 production. Addition of anti-IL-12 monoclonal antibody did not inhibit expansion of these cells. These data suggest that production of IL-15 but not IL-12 is an important factor in the enhanced immunostimulatory ability of huCD40LT-treated DC.     

In vivo immunomodulation by monoclonal anti-L3T4. 1. Effects on humoral and cell-mediated immune response

The in vivo administration of monoclonal anti-L3T4 antibody has been shown to be an effective preventative and, in some cases, therapeutic treatment for several murine models of autoimmune disease. This report deals with the effect of such treatments on humoral and cell-mediated responses to T-dependent antigens. Both the primary and secondary IgG responses to tetanus toxoid were inhibited when anti-L3T4 was administered prior to immunization, but it was ineffective in modulating an ongoing IgG response. Cell-mediated immunity, as detected by in vitro antigen-specific proliferative responses, was inhibited only if anti-L3T4 was given prior to immunization. It was not effective if treatment was delayed until 48 hr prior to lymph node harvest even though greater than 90% of L3T4+ lymph node cells were depleted by this treatment. The refractory behavior of the lymph node cells to anti-L3T4 treatment was not exhibited by antigen-primed cells obtained from peripheral blood or spleen. The importance of these findings with regard to antibody therapy for chronic autoimmune disease is discussed.