SUMMARY The intestinal mucosa promotes T cell responses that may be beneficial for effective mucosal vaccines. However, intestinal resident memory T (Trm) cell formation and function are poorly understood. We found that oral infection with Listeria monocytogenes induced a robust intestinal CD8 T cell response and blocking effector T cell migration showed that intestinal Trm cells were critical for secondary protection. Intestinal effector CD8 T cells were predominately composed of memory precursor effector cells (MPEC) that rapidly upregulated CD103, which was needed for T cell accumulation in the intestinal epithelium. CD103 expression, rapid MPEC formation, and maintenance in intestinal tissues were dependent on T cell intrinsic transforming growth factor-β signals. Moreover, intestinal Trm cells generated after intranasal or intravenous infection were less robust and phenotypically distinct from Trm cells generated after oral infection demonstrating the critical contribution of infection route for directing the generation of protective intestinal Trm cells.
The peroxisome proliferator-activated receptors (PPARs) are a family of transcription factors belonging to the nuclear receptor superfamily. Until recently, the genes regulated by PPARs were those believed to be predominantly associated with lipid metabolism. Recently, an immunomodulatory role for PPARγ has been described in cells critical to the innate immune system, the monocyte/macrophage. In addition, evidence for an antiinflammatory role of the PPARγ ligand, 15-deoxy-Δ12,14-PGJ2 (15d-PGJ2) has been found. In the present studies, we demonstrate, for the first time, that murine helper T cell clones and freshly isolated splenocytes express PPARγ 1. The PPARγ expressed is of functional significance in that two ligands for PPARγ, 15d-PGJ2 and a thiazolidinedione, ciglitazone, mediate significant inhibition of proliferative responses of both the T cell clones and the freshly isolated splenocytes. This inhibition is mediated directly at the level of the T cell and not at the level of the macrophage/APC. Finally, we demonstrate that the two ligands for PPARγ mediate inhibition of IL-2 secretion by the T cell clones while not inhibiting IL-2-induced proliferation of such clones. The demonstration of the expression and function of PPARγ in T cells reveals a new level of immunoregulatory control for PPARs and significantly increases the role and importance of PPARγ in immunoregulation.
The requirement of β7 integrins for lymphocyte migration was examined during an ongoing immune response in vivo. Transgenic mice (OT-I) expressing an ovalbumin-specific major histocompatibility complex class I–restricted T cell receptor for antigen were rendered deficient in expression of all β7 integrins or only the αEβ7 integrin. To quantitate the relative use of β7 integrins in migration in vivo, equal numbers of OT-I and OT-I-β7−/− or OT-I-αE−/− lymph node (LN) cells were adoptively transferred to normal mice. Although OT-I-β7−/− LN cells migrated to mesenteric LN and peripheral LN as well as wild-type cells, β7 integrins were required for naive CD8 T cell and B cell migration to Peyer's patch. After infection with a recombinant virus (vesicular stomatitis virus) encoding ovalbumin, β7 integrins became critical for migration of activated CD8 T cells to the mesenteric LN and Peyer's patch. Naive CD8 T cells did not enter the lamina propria or the intestinal epithelium, and the majority of migration of activated CD8 T cells to the small and large intestinal mucosa, including the epithelium, was β7 integrin–mediated. The αEβ7 integrin appeared to play no role in migration during a primary CD8 T cell immune response in vivo. Furthermore, despite dramatic upregulation of αEβ7 by CD8 T cells after entry into the epithelium, long-term retention of intestinal intraepithelial lymphocytes was also αEβ7 independent.
T lymphocytes have a central regulatory role in the pathogenesis of asthma. We delineated the participation of lymphocytes in the acute allergic and chronic tolerant stages of a murine model of asthma by characterizing the various subsets of lymphocytes in bronchoalveolar lavage and lung tissue associated with these responses. Acute (10-day) aerosol challenge of immunized C57BL/6J mice with ovalbumin resulted in airway eosinophilia , histological evidence of peribronchial and perivascular airway inflammation, clusters of B cells and TCR␥␦ cells in lung tissue, increased serum IgE levels , and airway hyperresponsiveness to methacholine. In mice subjected to chronic (6-week) aerosol challenge with ovalbumin, airway inflammation and serum IgE levels were significantly attenuated and airway hyperresponsiveness was absent. The marked increases in lung B and T cell populations seen in the acute stage were also significantly reduced in the chronic stage of this model. Thus , acute ovalbumin challenge resulted in airway sensitization characteristic of asthma, whereas chronic ovalbumin challenge elicited a suppressed or tolerant state. The transition from antigenic sensitization to tolerance was accompanied by shifts in lymphocyte profiles in the lung and bronchoalveolar lavage fluid. Asthma is the most common chronic illness in developed countries. Our current understanding of the pathophysiology of allergic asthma is that it occurs from a breakdown of the normal tolerance to inhaled antigens, as a result of complex interactions between host and environmental factors. Emerging evidence suggests that the development of clinical sensitivity versus normal tolerance to inhaled antigens involves the establishment of a dominant population of CD4 ϩ T lymphocytes that are either classified as Th2-like (sensitization) or Th1-like (tolerance).1 Th2 responses are characterized by secretion of the cytokines interleukin (IL)-4 and IL-13, which induce the production of IgE by B cells, 2-5 and IL-5, which regulates the growth, differentiation, and activation of eosinophils.6 Conversely, Th1 responses are characterized by secretion of IL-2, tumor necrosis factor (TNF)-, and interferon (IFN)-␥. IFN-␥ has been shown to stimulate low-level IgG production and to potently inhibit IL-4-mediated IgE responses both in vivo and in vitro.7 The mechanisms that control CD4 ϩ T lymphocyte polarization into either Th1 or Th2 phenotypes are incompletely understood but appear to involve genetic predispositions, local factors such as existing cytokine concentrations and inflammation, and antigenic factors such as the potency, dose, and duration of exposure of the eliciting antigen. In susceptible individuals, antigen sensitization results in specific local and systemic IgE production and airway eosinophilia, which in turn induce the airway inflammation, airway hyperresponsiveness, and reversible airway obstruction characteristic of asthma.The factors influencing antigen sensitization or tolerance can be better studied in mice, given their well defined...
The intestinal mucosa is suggested to support extrathymic T cell development, particularly for T cell receptor (TCR)-γδ intraepithelial lymphocytes (IELs). TCR-γδ cell development requires interleukin (IL)-7; IL-7−/− or IL-7 receptor−/− mice lack TCR-γδ cells. Using the intestinal fatty acid binding protein (iFABP) promoter, we reinstated expression of IL-7 to mature enterocytes of IL-7−/− mice (iFABP-IL7). In iFABP-IL7 mice, TCR-γδ IELs were restored, as were cryptopatches and Peyer's patches. TCR-γδ cells remained absent from all other tissues. Likewise, T cell development in thymus and B cell maturation in the bone marrow and spleen retained the IL-7−/− phenotype. Thus, IL-7 expression by enterocytes was sufficient for extrathymic development of TCR-γδ cells in situ within the intestinal epithelium and was crucial for organization of mucosal lymphoid tissue.
Sensitized mice acutely challenged with inhaled ovalbumin (OVA) develop allergic airway inflammation, characterized by OVA-specific IgE production, airway eosinophilia, increased pulmonary B and T lymphocytes, and airway hyperreactivity. In this study, a chronic exposure model was developed and two distinct patterns of response were observed. Discontinuous inhalational exposure to OVA (6 weeks) produced airway inflammation and hyperreactivity that were similar to acute (10 days) responses. Continuous inhalational exposure to OVA (6 or 11 weeks) resulted in attenuation of airway eosinophilia and hyperresponsiveness without reduction of OVA-specific IgE and IgG 1 levels. The inhibition of airway inflammation was dependent on continuous exposure to antigen, because continuously exposed mice with attenuated inflammatory responses redeveloped allergic airway disease if the OVA aerosols were interrupted and then restarted (11-week-discontinuous). Inhalational tolerance induced by continuous OVA exposure demonstrated bystander suppression of cockroach allergen-mediated airway eosinophilia. These findings may be attributed to changes in production of the anti-inflammatory cytokine interleukin-10 during continuous OVA aerosol exposure. The symptomatic and asymptomatic allergic responses in human asthmatics could be explained by similar variable or discontinuous exposures to aeroantigens. Throughout the past 40 years, the prevalence of allergic disease, including atopic dermatitis, hay fever, and asthma, has risen dramatically in the developed world. This disturbing trend is documented best for asthma. 1,2 A wealth of clinical and experimental data suggests that allergic asthma is due to an aberrant lung immune response mediated through T-helper type 2 cells (Th2 cells) and associated cytokine-signaling pathways. The normal lung is able to distinguish between airborne antigens associated with infectious agents, to which an immunological response is generated, and harmless inhaled antigens, which are usually ignored. In the asthmatic lung, some of these normally harmless antigens activate specific Th2 cells and elicit an inflammatory response characterized by Th2 cytokine production, eosinophilic airway inflammation, airway hyperresponsiveness, and bronchoconstriction. These pulmonary responses may be accompanied by systemic allergic sensitization, manifested by elevated titers of antigen-specific IgE. The mechanisms that control CD4 ϩ T lymphocyte polarization to allergenic Th2 phenotypes are incompletely understood but seem to involve genetic predispositions, local factors such as pre-existing cytokine concentrations and inflammation, and antigenic factors (ie, potency, dose, and duration of exposure).Several investigators have used mouse models to investigate the mechanisms of inhalational tolerance to antigens 3,4 or of allergic airway sensitization. [5][6][7][8][9][10] However, these responses have typically been assessed in isolation from each other. We have recently demonstrated that C57BL/6J mice undergo a biphasic...
TNF-α has a multifunctional role in autoimmune diseases as reflected in the variable responses of different human diseases to anti–TNF-α therapy. Recent studies have suggested that TNF-α modulates autoimmunity partially via effects on regulatory T cells (Tregs) and that these effects are mediated through the type II TNFR (TNFR2). We have investigated the requirement for TNFR2-expression on murine natural Tregs (nTregs) and induced Tregs (iTregs) in mediating suppression of colitis. Surprisingly, we find that TNFR2-expression is required for both spleen- and thymus-derived nTreg-mediated suppression, but is not required for iTreg-mediated suppression. Abnormal TNFR2−/− nTreg function was not associated with an in vivo decrease in accumulation, stability, or expression of markers known to be relevant in Treg function. Because iTregs are generated in the presence of TGF-β, we investigated whether activation in the presence of TGF-β could overcome the functional defect in TNFR2−/− nTregs. Although preactivation alone did not restore suppressive function of nTregs, preactivation in the presence of TGF-β did. These results identify potentially critical differences in activation requirements for nTregs versus iTregs. Furthermore, our findings are consistent with reports suggesting that nTregs are activated in sites of inflammation while iTregs are activated in lymph nodes. Finally, by demonstrating that nTregs require TNF-α for optimal function whereas iTregs do not, our results suggest that the enigma of variable responses of different human diseases to anti–TNF-α therapy may relate to whether nTregs or iTregs have the predominant regulatory role in a given disease.
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