T cell-dependent hapten-specific and polyclonal B cell responses require release of interleukin 5

CD4+ T cells in the mouse have recently been subdivided into two major subpopulations which differ in their functional activities and in the lymphokines they produce. Although cloned T cells lines representative of both sets will activate B cells in polyclonal responses, only the subset producing interleukin 4 (IL-4) will activate antigen-specific B cells in linked recognition assays. This suggested that IL-4 was essential for such responses. In the present experiments, the requirements were compared for B cell activation in specific as opposed to polyclonal antibody responses by T cell clones of the helper (IL-4 producing) subset. It was found that specific responses involve primarily small B cells, whereas polyclonal responses activate exclusively the large B cells. Second, polyclonal B cell responses can proceed in the absence of T:B contact, whereas specific responses require physical interaction of the two cells. Third, it was found that interleukin 5 (IL-5, formerly known as T cell replacing factor/B cell growth factor II) is essential for these polyclonal responses by inhibition of such responses with monoclonal anti-IL-5 antibody. Anti-IL-5 also inhibits specific antibody responses involving direct T:B interaction. Thus, IL-5 is clearly a critical mediator of differentiation to immunoglobulin secretion of activated B cells, whether such B cells are obtained as large B cells from freshly isolated spleen cells or are initially activated in an IL-4-dependent fashion by cognate interaction by a helper T cell clone.     

Polyclonal activation of the murine immune system by an antibody to IgD. VII. Demonstration of the role of nonantigen-specific T help in in vivo B cell activation

Previous studies from this laboratory have shown that the injection of mice with an affinity-purified goat antibody to mouse IgD (GaM delta) induces T-independent polyclonal increases in: 1) B cell DNA synthesis, and 2) expression of surface Ia antigen and receptors for T helper factors, 1 to 2 days after injection. In addition, T-independent polyclonal increases in B cell number and IgG1 secretion are observed 6 to 7 days after injection. The administration of normal goat IgG (GIgG) along with GaM delta has been shown to augment GaM delta-induced polyclonal IgG1 secretion. To obtain information about the characteristics of the T help that is required for polyclonal antibody production in this model system, we investigated: 1) the length of the period during which GaM delta must be present to induce day 7 polyclonal antibody production, and 2) the kinetics of the induction of splenic T cell DNA synthesis. We found that GaM delta can be neutralized 3 days after injection by the administration of IgD without decreasing day 7 polyclonal IgG1 secretion, as long as mice are given GIgG at the time that GaM delta is neutralized. In contrast, polyclonal IgG1 secretion is greatly inhibited if GaM delta is neutralized 1 to 2 days after injection or if GaM delta is neutralized 3 days after injection, but GIgG is not administered at this time. Because GIgG can stimulate activated GIgG-specific T cells to secrete helper factors, but, unlike GaM delta cannot focus GIgG-specific T help polyclonally onto B cells, these findings suggest that nonspecific T help, rather than antigen-specific T help, is required in this system after day 3 for the induction of polyclonal IgG1 secretion. Determination of the kinetics of the induction of T cell DNA synthesis in this system by in vivo [3H] thymidine incorporation studies, as well as dual laser fluorescence-activated cell sorter analysis of T and B cell DNA content, indicate that T cells are induced to synthesize DNA 2 days after GaM delta injection and reach plateau rates of DNA synthesis 3 days after injection. Taken together, the GaM delta neutralization experiments and DNA synthesis studies suggest that one reason that GaM delta is required for 3 days in this system is to allow maximal activation of GIgG-specific T cells, which when stimulated later by GIgG secrete nonantigen-specific helper factors that induce GaM delta-activated B cells to secrete IgG1.     

In vivo CD40-CD154 (CD40 ligand) interaction induces integrated HIV expression by APC in an HIV-1-transgenic mouse model

Because of their relative resistance to viral cytopathic effects, APC can provide an alternative reservoir for latently integrated HIV. We used an HIV-transgenic mouse model in which APC serve as the major source of inducible HIV expression to study mechanisms by which integrated virus can be activated in these cells. When admixed with transgenic APC, activated T lymphocytes provided a major contact-dependent stimulus for viral protein expression in vitro. Using blocking anti-CD154 mAb as well as CD154-deficient T cells, the HIV response induced by activated T lymphocytes was demonstrated to require CD40-CD154 interaction. The role of this pathway in the induction of HIV expression from APC in vivo was further studied in an experimental model involving infection of the HIV-transgenic mice with PLASMODIUM: chabaudi parasites. Enhanced viral production by dendritic cells and macrophages in infected mice was associated with up-regulated CD40 expression. More importantly, in vivo treatment with blocking anti-CD154 mAb markedly reduced viral expression in P. chabaudi-infected animals. Together, these findings indicate that immune activation of integrated HIV can be driven by the costimulatory interaction of activated T cells with APC. Because chronic T cell activation driven by coinfections as well as HIV-1 itself is a characteristic of HIV disease, this pathway may be important in sustaining viral expression from APC reservoirs.     

T cell receptor specific apoptosis: an endogenous mechanism for T cell homeostasis and potential strategy for antigen modulation of disease

T lymphocytes can undergo an activation/proliferation response or an apoptotic response following T cell receptor engagement. The choice between these outcomes is dictated by the activation state of the T lymphocyte, the presence of interleukin-2 and the strength of the T cell receptor stimulus. Specifically, when quiescent cells encounter effectively presented antigen they are activated and begin to proliferate. In contrast, activated cells, moving through the cell cycle under the influence of IL-2, undergo apoptosis upon reencountering antigen. Both the tumour necrosis factor receptor and CD95 (FAS) are known to participate in mediating this cell death. Genetic defects in the molecules of the lymphocyte death pathway (CD95, FAS ligand, IL-2 receptor) lead to syndromes of autoimmunity and dysregulated lymphocyte homeostasis. An understanding of the principles of the autocrine feedback death model can provide the rationale basis for effective antigen specific modulation of T cell mediated disease processes.     

Activation of B cells by autoreactive T cells: cloned autoreactive T cells activate B cells by two distinct pathways

Although the existence of autoreactive T cells has been widely reported, the functional capacities of these populations have been less well defined. Studies were therefore carried out to characterize the relationship of autoreactive T cells to antigen-specific major histocompatibility complex (MHC)-restricted T cells in their ability to act as helper cells for the induction of immunoglobulin synthesis by B cells. A number of autoreactive T cell lines and clones were isolated from antigen-primed spleen and lymph node cell populations. Autoreactive T cells were found to proliferate in response to direct recognition of syngeneic I-A or I-E subregion-encoded antigens in the absence of any apparent foreign antigen. It was shown that cloned autoreactive T cells were capable of activating B cell responses through two distinct pathways. After appropriate stimulation by syngeneic cells, autoreactive T cells polyclonally activated primed or unprimed B cells to synthesize IgM antibodies. These activated T cells functioned in these responses through an MHC-unrestricted pathway in which polyclonal responses were induced in both syngeneic and allogeneic B cells. These cloned autoreactive T cells were also able to activate IgG responses by primed B cells through a different activation pathway. In contrast to the polyclonal activation of IgM responses, the induction of IgG antibodies by the same cloned T cells required primed B cells and stimulation with the priming antigen. The activation of B cells to produce IgG was strongly MHC restricted and required the direct recognition by the autoreactive T cells of self MHC determinants expressed on the B cell surface, with no bystander activation of allogeneic B cells. These results indicate that cloned autoreactive T cells resemble antigen-specific MHC-restricted T cells in their ability to function as T helper cells through distinct MHC-restricted and MHC-unrestricted pathways.     

The Th2 lymphoproliferation developing in LatY136F mutant mice triggers polyclonal B cell activation and systemic autoimmunity

Lat(Y136F) knock-in mice harbor a point mutation in Tyr(136) of the linker for activation of T cells and show accumulation of Th2 effector cells and IgG1 and IgE hypergammaglobulinemia. B cell activation is not a direct effect of the mutation on B cells since in the absence of T cells, mutant B cells do not show an activated phenotype. After adoptive transfer of linker for activation of T cell mutant T cells into wild-type, T cell-deficient recipients, recipient B cells become activated. We show in vivo and in vitro that the Lat(Y136F) mutation promotes T cell-dependent B cell activation leading to germinal center, memory, and plasma cell formation even in an MHC class II-independent manner. All the plasma and memory B cell populations found in physiological T cell-dependent B cell responses are found. Characterization of the abundant plasmablasts found in secondary lymphoid organs of Lat(Y136F) mice revealed the presence of a previously uncharacterized CD93-expressing subpopulation, whose presence was confirmed in wild-type mice after immunization. In Lat(Y136F) mice, B cell activation was polyclonal and not Ag-driven because the increase in serum IgG1 and IgE concentrations involved Abs and autoantibodies with different specificities equally. Although the noncomplement-fixing IgG1 and IgE are the only isotypes significantly increased in Lat(Y136F) serum, we observed early-onset systemic autoimmunity with nephritis showing IgE autoantibody deposits and severe proteinuria. These results show that Th2 cells developing in Lat(Y136F) mice can trigger polyclonal B cell activation and thereby lead to systemic autoimmune disease.     

Immunodeficiency of aging: restorative effects of phorbol ester combined with calcium ionophore

Current models for lectin-induced T cell proliferation suggest that activation of protein kinase C (PK-C) and elevation of cytoplasmic Ca2+ may both play important roles in the earliest phases of signal transduction. To learn more about the relative inability of T cells from old mice to proliferate in response to mitogenic stimuli, we attempted to stimulate T cells by the synergistic effects of a PK-C activator, phorbol myristate acetate (PMA), and the calcium ionophore ionomycin. T cells from young mice respond as well to optimal combinations of these agents as they do to the strong polyclonal activator Con A, but T cells from old mice respond much better to PMA plus ionomycin than they do to Con A. This result suggests that an inability to transduce the signal supplied by extracellular ligands into the intracellular signals represented by Ca2+ and PK-C activators may underlie the age-associated loss of T cell reactivity. We also found evidence for a second defect in old T cells related to their response to elevated intracellular Ca2+: old T cells, compared with young, required higher levels of ionomycin for maximal proliferation.     

Differential MHC class II presentation of a pathogenic autoantigen during health and disease

Glucose-6-phosphate isomerase (GPI) is the target autoantigen recognized by KRN T cells in the K/BxN model of rheumatoid arthritis. T cell reactivity to this ubiquitous Ag results in the recruitment of anti-GPI B cells and subsequent immune complex-mediated arthritis. Because all APCs have the capacity to process and present this autoantigen, it is unclear why systemic autoimmunity with polyclonal B cell activation does not ensue. To this end, we examined how GPI is presented by B cells relative to other immunologically relevant APCs such as dendritic cells (DCs) and macrophages in the steady state, during different phases of arthritis development, and after TLR stimulation. Although all APCs can process and present the GPI:I-A(g7) complex, they do so with different efficiencies. DCs are the most potent at baseline and become progressively more potent with disease development correlating with immune complex uptake. Interestingly, in vivo and in vitro maturation of DCs did not enhance GPI presentation, suggesting that DCs use mechanisms to regulate the presentation of self-peptides. Non-GPI-specific B cells are the weakest APCs (100-fold less potent than DCs) and fail to productively engage KRN T cells at steady state and during arthritis. However, the ability to stimulate KRN T cells is strongly enhanced in B cells after TLR ligation and provides a mechanism whereby polyclonal B cells may be activated in the wake of an acute infection.     

Role of the autologous rosette-forming T cells in the concanavalin A-induced suppressor cell function

It was recently reported that the human autologous rosette-forming T cells (Tar cells) are devoid of Fc receptors for IgM and IgG but that they give rise in vitro to Tμ and Tγ cells and that these cells participate actively in feedback inhibition. We now investigated whether Tar cells participate in the concanavalin A-induced suppressor cell function, using two indicator systems, namely, mitogen- or alloantigen-induced DNA synthesis and mitogen-driven polyclonal immunoglobulin synthesis. When Tar cells were removed from peripheral blood T cells (T-Tar) there was no generation of suppression determined on both DNA synthesis and immunoglobulin production. When Tar cells were readded to T-Tar cells suppressor activity was restored. When purified Tar cells were activated by concanavalin A they showed the highest degree of suppression as compared to that exerted by total T cells or T-Tar cells. Tar cells lose their capacity to generate suppression when treated with mitomycin C before their activation; however, they are no longer sensitive to mitomycin C treatment once they have completed the period of activation. These results together with our previous findings showing that Tar cells give rise in vitro to Tμ and Tγ cells after their activation by Con-A suggest that Tar cells participate in the Con-A-induced suppressor cell function as precursors of the suppressor effector T cells.     

Diminished calcium influx in lectin-stimulated T cells from old mice

T lymphocytes from aged donors function poorly, but the biochemical basis for the defect remains uncertain. We tested the hypothesis that T cells from old mice had a diminished ability to transmit extracellular signals into the cytoplasm, by measuring intracellular free calcium concentrations (Cai) in T cells stimulated by the polyclonal activator concanavalin A (Con A). Using the second-generation fluorochrome indo-1 as a reporter of Cai, we found that the Con A-induced elevation of Cai levels is reduced both in rate and extent in old T cells, as compared to T cells from young mice. Flow cytometric analysis showed that this age-sensitive change represents a decline, with age, in the number of T cells that can respond to Con A by increasing their Cai above resting baseline levels (100-120 nM). These results thus show that defects in activation are manifested by T cells from old donors within the first 5 minutes of the activation process, and suggest that aging may lead to alterations either in the surface molecules that receive extracellular signals, or in the sequence of coupled events by which these extracellular signals bring about alterations in the intracellular ionic milieu.     

Local cooperation dominates over competition between CD4+ T cells of different antigen/MHC specificity

Interactions between CD4(+) T cells in vivo are controlled by a balance between cooperation and competition. In this study the interaction between two populations of CD4(+) T cells of different MHC/peptide specificity was probed at different precursor frequencies, delivering one or both Ags to APC using particle-mediated DNA delivery. Expansion of clonal populations of Ag (OVA and pigeon cytochrome c-specific) CD4(+) T cells was limited at higher precursor frequencies, presumably reflecting intraclonal competition. In contrast, a strong enhancement of the number of cells expressing IFN-gamma, IL-4, and IL-2 was observed in populations of cells at low precursor frequency in the presence of a high frequency of activated cells of a different Ag specificity. The helper effect was most potent when both Ags were delivered to the same dendritic cell (i.e., linked). This reflects the requirement of epicrine or paracrine help for optimal activation of T cell clones at low frequency. A measure of help was also delivered in an endocrine manner (unlinked), especially for Th1 responses, suggesting that there is also limited diffusion of cytokines between dendritic cell clusters. The dominant effects of cooperation over competition between CD4(+) T cells responding to different Ags may have important implications in terms of the efficacy of multivalent vaccines.     

T cell effector function and anergy avoidance are quantitatively linked to cell division

We have shown previously that T cells activated by optimal TCR and CD28 ligation exhibit marked proliferative heterogeneity, and approximately 40% of these activated cells fail entirely to participate in clonal expansion. To address how prior cell division influences the subsequent function of primary T cells at the single cell level, primary CD4+ T cells were subjected to polyclonal stimulation, sorted based on the number of cell divisions they had undergone, and restimulated by ligation of TCR/CD28. We find that individual CD4+ T cells exhibit distinct secondary response patterns that depend upon their prior division history, such that cells that undergo more rounds of division show incrementally greater IL-2 production and proliferation in response to restimulation. CD4+ T cells that fail to divide after activation exist in a profoundly hyporesponsive state that is refractory to both TCR/CD28-mediated and IL-2R-mediated proliferative signals. We find that this anergic state is associated with defects in both TCR-coupled activation of the p42/44 mitogen-activated protein kinase (extracellular signal-related kinase 1/2) and IL-2-mediated down-regulation of the cell cycle inhibitor p27kip1. However, these defects are selective, as TCR-mediated intracellular calcium flux and IL-2R-coupled STAT5 activation remain intact in these cells. Therefore, the process of cell division or cell cycle progression plays an integral role in anergy avoidance in primary T cells, and may represent a driving force in the formation of the effector/memory T cell pool.     

Cell-cell interactions in synovitis. Interactions between T lymphocytes and synovial cells

Mechanisms whereby T lymphocytes contribute to synovial inflammation in rheumatoid arthritis are poorly understood. Here we review data that indicate an important role for cell contact between synovial T cells, adjacent macrophages and fibroblast-like synoviocytes (FLS). Thus, T cells activated by cytokines, endothelial transmigration, extracellular matrix or by auto-antigens can promote cytokine, particularly TNF alpha, metalloproteinase production by macrophages and FLS through cell-membrane interactions, mediated at least through beta-integrins and membrane cytokines. Since soluble factors thus induced may in turn contribute directly to T cell activation, positive feedback loops are likely to be created. These novel pathways represent exciting potential therapeutic targets.     

Cutting edge: T cells trigger CD40-dependent platelet activation and granular RANTES release: a novel pathway for immune response amplification

Platelets, in addition to exerting hemostatic activity, contribute to immunity and inflammation. The recent report that platelets express CD40 led us to hypothesize that CD40 ligand (CD40L)-positive T cells could bind to platelets, cause their activation, and trigger granular RANTES release, creating a T cell recruitment feedback loop. Platelets were cocultured with resting or activated autologous T cells and their activation was assessed by P-selectin expression. RANTES binding to endothelial cells was assessed by confocal microscopy, and its biological activity was demonstrated by a T cell adhesion assay. CD40L-positive T cells induced platelet activation through a contact-mediated, CD40-dependent pathway resulting in RANTES release, which bound to endothelial cells and mediated T cell recruitment. Soluble CD40L induced the same events via p38, but not extracellular signal-regulated kinase, phosphorylation. These results show the existence of a novel platelet-dependent pathway of immune response amplification which brings these nonimmune cells close to the level of pathogenic relevance traditionally attributed to classical immune cells.     

Cell-cell interactions in synovitis: Interactions between T lymphocytes and synovial cells

Mechanisms whereby T lymphocytes contribute to synovial inflammation in rheumatoid arthritis are poorly understood. Here we review data that indicate an important role for cell contact between synovial T cells, adjacent macrophages and fibroblast-like synoviocytes (FLS). Thus, T cells activated by cytokines, endothelial transmigration, extracellular matrix or by auto-antigens can promote cytokine, particularly TNFα, metalloproteinase production by macrophages and FLS through cell-membrane interactions, mediated at least through β-integrins and membrane cytokines. Since soluble factors thus induced may in turn contribute directly to T cell activation, positive feedback loops are likely to be created. These novel pathways represent exciting potential therapeutic targets.     

Dysregulation of T Lymphocyte Proliferative Responses in Autoimmunity

T cells are critically dependent on cellular proliferation in order to carry out their effector functions. Autoimmune strains are commonly thought to have uncontrolled T cell proliferation; however, in the murine model of autoimmune diabetes, hypo-proliferation of T cells leading to defective AICD was previously uncovered. We now determine whether lupus prone murine strains are similarly hyporesponsive. Upon extensive characterization of T lymphocyte activation, we have observed a common feature of CD4 T cell activation shared among three autoimmune strains–NOD, MRL, and NZBxNZW F1s. When stimulated with a polyclonal mitogen, CD4 T cells demonstrate arrested cell division and diminished dose responsiveness as compared to the non-autoimmune strain C57BL/6, a phenotype we further traced to a reliance on B cell mediated costimulation, which underscores the success of B cell directed immune therapies in preventing T cell mediated tissue injury. In turn, the diminished proliferative capacity of these CD4 T cells lead to a decreased, but activation appropriate, susceptibility to activation induced cell death. A similar decrement in stimulation response was observed in the CD8 compartment of NOD mice; NOD CD8 T cells were distinguished from lupus prone strains by a diminished dose-responsiveness to anti-CD3 mediated stimulation. This distinction may explain the differential pathogenetic pathways activated in diabetes and lupus prone murine strains.     

In vivo suppression of naive CD4 T cell responses by IL-2- and antigen-stimulated T lymphocytes in the absence of APC competition

After stimulation, T cells enter a transient refractory period, promoted by IL-2, during which they are resistant to re-stimulation. We previously demonstrated that these IL-2- and Ag-stimulated refractory T cells are able to suppress the Ag-induced proliferation of naive T cells in vitro. We show here that, after adoptive transfer, these T cells are also able to suppress naive T cell proliferation in vivo. More interestingly, potently suppressive T cells can be generated directly in vivo by stimulation with Ag and supplemental IL-2. The activity of the suppressive cells is dose dependent, and the suppressor and suppressed T cells need not be restricted to the same MHC or Ag. Similar to its role in promoting T cell-mediated suppression in vitro, IL-2 is critical for the induction of suppressive activity in activated T cells in vivo. Supplemental IL-2, however, cannot overcome the suppressive activity in target T cells, indicating that suppression is not mediated by competition for this cytokine. Although the activated T cells block naive T cell proliferation, the naive cells do engage Ag and up-regulate the CD25 and CD69 activation markers after stimulation. Therefore, activated T cells stimulated in the presence of IL-2 develop MHC- and Ag-unrestricted suppressive activity. These results provide a new mechanism for competition among CD4(+) T lymphocytes, in which initial waves of responding T cells may inhibit subsequently recruited naive T cells. They further suggest a novel negative feedback loop limiting the expansion of T cell responses that may be present during vigorous immune responses or after IL-2 immunotherapy.     

Dynamic simulation of the effect of calcium-release activated calcium channel on cytoplasmic Ca2+ oscillation

A mathematical model is proposed to illustrate the activation of STIM1 (stromal interaction molecule 1) protein, the assembly and activation of calcium-release activated calcium (CRAC) channels in T cells. In combination with De Young-Keizer-Li-Rinzel model, we successfully reproduce a sustained Ca(2+) oscillation in cytoplasm. Our results reveal that Ca(2+) oscillation dynamics in cytoplasm can be significantly affected by the way how the Orai1 CRAC channel are assembled and activated. A low sustained Ca(2+) influx is observed through the CRAC channels across the plasma membrane. In particular, our model shows that a tetrameric channel complex can effectively regulate the total quantity of the channels and the ratio of the active channels to the total channels, and a period of Ca(2+) oscillation about 29 s is in agreement with published experimental data. The bifurcation analyses illustrate the different dynamic properties between our mixed Ca(2+) feedback model and the single positive or negative feedback models.     

Fibrosis is regulated by Th2 and Th17 responses and by dynamic interactions between fibroblasts and macrophages

Dysregulated wound healing leads to fibrosis, whereby fibroblasts synthesize excess extracellular matrix and scarring impairs proper organ function. Although fibrotic diseases arise from diverse causes and display heterogeneous features, fibrosis commonly associates with chronic inflammation. Recent discoveries reinforce the idea that communication between fibroblasts, macrophages, and CD4 T cells integrates the processes of wound healing and host defense. Signals between macrophages and fibroblasts can exacerbate, suppress, or reverse fibrosis. Fibroblasts and macrophages are activated by T cells, but their activation also engages negative feedback loops that reduce fibrosis by restraining the immune response, particularly when the Th2 cytokine IL-13 contributes to pathology. Thus the interactions among fibroblasts, macrophages, and CD4 T cells likely play general and critical roles in initiating, perpetuating, and resolving fibrosis in both experimental and clinical conditions.