The C-type lectin-like receptor CD161, which has recently been described to promote T cell expansion, is expressed on a discrete subset of human CD4 T cells. The function of such cells, however, has remained elusive. We now demonstrate that CD161+ CD4 T cells comprise a circulating and gut-resident T helper 17 (Th17) cell population. During Crohn's disease (CD), these CD161+ cells display an activated Th17 phenotype, as indicated by increased expression of interleukin (IL)-17, IL-22, and IL-23 receptor. CD161+ CD4 T cells from CD patients readily produce IL-17 and interferon γ upon stimulation with IL-23, whereas, in healthy subjects, priming by additional inflammatory stimuli such as IL-1β was required to enable IL-23–induced cytokine release. Circulating CD161+ Th17 cells are imprinted for gut homing, as indicated by high levels of CC chemokine receptor 6 and integrin β7 expression. Supporting their colitogenic phenotype, CD161+ Th17 cells were found in increased numbers in the inflammatory infiltrate of CD lesions and induced expression of inflammatory mediators by intestinal cells. Our data identify CD161+ CD4 T cells as a resting Th17 pool that can be activated by IL-23 and mediate destructive tissue inflammation.
Tumor immune surveillance and cancer immunotherapies are thought to depend on the intratumoral infiltration of activated CD8(+) T cells. Intratumoral CD8(+) T cells are rare and lack activity. IL-10 is thought to contribute to the underlying immune suppressive microenvironment. Defying those expectations we demonstrate that IL-10 induces several essential mechanisms for effective antitumor immune surveillance: infiltration and activation of intratumoral tumor-specific cytotoxic CD8(+) T cells, expression of the Th1 cytokine interferon-γ (IFNγ) and granzymes in CD8(+) T cells, and intratumoral antigen presentation molecules. Consequently, tumor immune surveillance is weakened in mice deficient for IL-10 whereas transgenic overexpression of IL-10 protects mice from carcinogenesis. Treatment with pegylated IL-10 restores tumor-specific intratumoral CD8(+) T cell function and controls tumor growth.
Th17 cells have been named after their signature cytokine IL-17 and accumulating evidence indicates their involvement in the induction and progression of inflammatory diseases. In addition to IL-17 single-producing T cells, IL-17/IFN-γ double-positive T cells are found in significantly elevated numbers in inflamed tissues or blood from patients with chronic inflammatory disorders. Because IFN-γ is the classical Th1-associated cytokine, the origin and roles of these subsets remain elusive. In this paper, we show that not only IL-17+/IFN-γ+ but also IFN-γ+ (IL-17−) cells arise under Th17-inducing condition and have distinct properties from the Th1 lineage. In fact, these populations displayed characteristics reminiscent to IL-17 single-producing cells, including production of IL-22, CCL20, and induction of antimicrobial gene expression from epithelial cells. Live sorted IL-17+ and Th17–IFN-γ+ cells retained expression of IL-17 or IFN-γ after culture, respectively, whereas the IL-17+/IFN-γ+ population was less stable and could also become IL-17 or IFN-γ single-producing cells. Interestingly, these Th17 subsets became “Th1-like” cells in the presence of IL-12. These results provide novel insights into the relationship and functionality of the Th17 and Th1 subsets and have direct implications for the analysis and relevance of IL-17 and/or IFN-γ–producing T cells present in patients’ peripheral blood and inflamed tissues.
The aim of the present study was to determine whether systemic sensitisation and chronic aeroallergen challenge in macaques replicate the classical and emerging immunology and molecular pathology of human asthma.Macaques were immunised and periodically challenged over 2 yrs with house dust mite allergen. At key time-points, serum, bronchoalveolar lavage (BAL) and bronchial biopsies were assayed for genes, proteins and lymphocyte subpopulations relevant to clinical asthma.Immunisation and periodic airway challenge induced changes in immunoglobulin E, airway physiology and eosinophilia consistent with chronic, dual-phase asthma. Sensitisation increased interleukin (IL)-1b and -6 concentrations in serum, and IL-13 expression in BAL cells. Airway challenge increased: early expression of IL-5, -6, -13 and -19, and eotaxin; and variable late-phase expression of IL-4, -5 and -13, and thymus-and activation-regulated chemokine in BAL cells. CD4+ lymphocytes comprised 30% of the CD3+ cells in BAL, increasing to 50% in the late phase. Natural killer T-cells represented ,3% of the CD3+ cells. Corticosteroid treatment reduced serum histamine levels, percentage of CD4+ cells and monocyte-derived chemokine expression, while increasing CD3+ and CD8+ cells in BAL.Sensitisation and periodic aeroallergen challenge of cynomolgus macaques results in physiological, cellular, molecular and protein phenotypes, and therapeutic responses observed in human asthma, providing a model system useful in target and biomarker discovery, and translational asthma research.KEYWORDS: Asthma, corticosteroid treatment, natural killer T-cell, primate model A sthma continues to present a significant unmet medical need [1] and the search for effective asthma drugs with novel mechanisms of action continues. Nonhuman primate models most closely replicate the genetics, physiology, immunology and pathology of the human disease [2][3][4]. The availability of these models uniquely allows examination of both induction of chronic allergy-driven airway inflammation and bronchoconstriction in a controlled setting, as well as identification of key mediators for the maintenance of chronic asthma. Additionally, these models provide a platform to assess pre-clinical safety, and proof of activity and efficacy for novel asthma therapeutics, under conditions that are observed in human patients.Models of asthma have been developed in a variety of common laboratory animals, including guinea pigs, rabbits, rats, mice, sheep, cats, dogs and macaques (see review by BICE et al.[5]).However, there are significant differences in airway architecture and immune responses to chronic allergen between species. Few species develop spontaneous allergic sensitivity to allergens, chronic or prolonged immune and inflammatory responses following pulmonary allergen exposure, progressive worsening of airway responses with repeated antigen challenge, and significant accumulation of lymphoid cells outside the bronchial-associated lymphoid tissue. Murine models have been instrumental ...
IL-12 is a heterodimeric cytokine that was identified on the basis of its ability to synergize with IL-2 in the induction of cytotoxic effector cells and was originally called cytotoxic lymphocyte maturation factor (CLMF). IL-12 was also found to stimulate the proliferation of PHA-activated lymphoblasts which were greater than 90% CD3+ T cells. In this report we further characterize the effects of IL-12 on lymphocyte proliferation. Studies with purified subpopulations of PHA-activated lymphoblasts and with cloned lines of human T cells indicated that IL-12 caused the proliferation of activated T cells of both the CD4+ and CD8+ subsets. This effect of IL-12 was independent of IL-2 because it was not blocked by antibodies to either IL-2 or IL-2R. The maximum proliferation induced by IL-12 was 31 to 72% of the maximum caused by IL-2; however, IL-12 was active at a lower effective concentration (EC50 = 8.5 +/- 1.3 pM) than IL-2 (EC50 = 52 +/- 8 pM). Combination of suboptimal amounts of IL-12 and IL-2 resulted in additive proliferation, up to the maximum induced by IL-2 alone. IL-12 also caused the proliferation of lymphocytes activated by culture with IL-2 for 6 to 12 days. CD56+ NK cells were among the IL-12-responsive cells in the IL-2-activated lymphocyte population. Unlike IL-2 or IL-7, IL-12 caused little or no proliferation of resting peripheral blood mononuclear cells (PBMC). In this regard, IL-12 was similar to IL-4. However, IL-12 could enhance the proliferation of resting PBMC caused by suboptimal amounts of IL-2, whereas IL-4 inhibited IL-2-induced PBMC proliferation. Thus, IL-12 is a growth factor for activated human T cells and NK cells; however, its spectrum of lymphocyte growth-promoting properties is distinct from that of IL-2, IL-4, or IL-7.
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