David P. Huston

IL-25 augments type 2 immune responses by enhancing the expansion and functions of TSLP-DC–activated Th2 memory cells

Interleukin (IL) 25 (IL-17E), a distinct member of the IL-17 cytokine family, plays important roles in evoking T helper type 2 (Th2) cell–mediated inflammation that features the infiltrations of eosinophils and Th2 memory cells. However, the cellular sources, target cells, and underlying mechanisms remain elusive in humans. We demonstrate that human Th2 memory cells expressing distinctive levels of IL-25 receptor (R) are one of the responding cell types. IL-25 promotes cell expansion and Th2 cytokine production when Th2 central memory cells are stimulated with thymic stromal lymphopoietin (TSLP)–activated dendritic cells (DCs), homeostatic cytokines, or T cell receptor for antigen triggering. The enhanced functions of Th2 memory cells induced by IL-25 are associated with sustained expression of GATA-3, c-MAF, and JunB in an IL-4–independent manner. Although keratinocytes, mast cells, eosinophils, and basophils express IL-25 transcripts, activated eosinophils and basophils from normal and atopic subjects were found to secrete bioactive IL-25 protein, which augments the functions of Th2 memory cells. Elevated expression of IL-25 and IL-25R transcripts was observed in asthmatic lung tissues and atopic dermatitis skin lesions, linking their possible roles with exacerbated allergic disorders. Our results provide a plausible explanation that IL-25 produced by innate effector eosinophils and basophils may augment the allergic inflammation by enhancing the maintenance and functions of adaptive Th2 memory cells.

IL-5 secretion by allergen-stimulated CD4+ T cells in primary culture: relationship to expression of allergic disease.

BACKGROUND IL-5-producing allergen-specific T cells are thought to play a prominent role in the pathogenesis of allergic inflammation. We hypothesized that T cell allergen-driven IL-5 synthesis is elevated in patients with atopic disease as compared with that in atopic patients free of disease and nonatopic control subjects. OBJECTIVES The purpose of this study was to compare IL-5 and interferon-gamma (IFN-gamma) secretion and proliferation by peripheral blood T cells from sensitized atopic patients with asthma, rhinitis, and no symptoms and from nonatopic control subjects in response to the allergen Dermatophagoides pteronyssinus (Der p) and the control recall antigen Mycobacterium tuberculosis purified protein derivative (PPD). METHODS To measure allergen-induced IL-5 production and proliferation, we developed a short-term culture technique that required a single antigenic stimulation of freshly isolated peripheral blood mononuclear cells (PBMC). With this technique, we measured Der p- and PPD-induced IL-5 production and proliferation in PBMC from atopic patients with asthma who were allergic to Der p, atopic patients with rhinitis, atopic patients with no symptoms, and a group of nonatopic normal control subjects. In four experiments, CD4+ or CD8+ T cells were depleted from PBMC to confirm that IL-5 synthesis was T cell dependent. RESULTS T cell IL-5 production, but not IFN-gamma production, in response to Der p was elevated in atopic patients with asthma and atopic patients with rhinitis compared with findings in atopic patients with no symptoms or nonatopic control subjects. IL-5 production was abrogated by depletion of CD4+, but not CD8+, T cells. In subjects with asthma, allergen-driven IL-5 production correlated with bronchial hyperreactivity. Allergen-induced proliferation was also higher in patients with asthma than in atopic subjects with no symptoms or nonatopic controls. T cell IL-5 and IFN-gamma production and proliferation in response to PPD were similar regardless of atopic status or disease. CONCLUSIONS Elevated IL-5 production is a characteristic of allergen-specific peripheral blood CD4+ T cells from sensitized patients with atopic disease but not atopy per se.

Prevention of Mast-Cell Degranulation by Ketotifen in Patients with Physical Urticarias

The capacity for ketotifen to prevent mast-cell degranulation in vivo was studied in patients with physical urticarias. Patients were exposed to the appropriate stimulus to elicit their physical urticaria before and during ketotifen therapy. Histamine concentrations in plasma samples, obtained before and serially after the physical provocation, were determined by radioenzymatic thin-layer chromatography. Ketotifen therapy was associated with marked reductions in plasma histamine levels after stimulation and in clinical evidence of urticaria in each patient. A direct correlation of ketotifen therapy and a reduction in histamine release was confirmed in a patient with a cold-induced urticaria who was studied again after discontinuation and again after reinstitution of therapy. Although the mechanism of action is unknown, this report shows that ketotifen is capable of inhibiting cutaneous mast-cell degranulation and its accompanying symptoms. These findings suggest important therapeutic alternatives for patients with mast-cell-mediated diseases.

Pulmonary alveolar proteinosis caused by deletion of the GM-CSFRα gene in the X chromosome pseudoautosomal region 1

Pulmonary alveolar proteinosis (PAP) is a rare lung disorder in which surfactant-derived lipoproteins accumulate excessively within pulmonary alveoli, causing severe respiratory distress. The importance of granulocyte/macrophage colony-stimulating factor (GM-CSF) in the pathogenesis of PAP has been confirmed in humans and mice, wherein GM-CSF signaling is required for pulmonary alveolar macrophage catabolism of surfactant. PAP is caused by disruption of GM-CSF signaling in these cells, and is usually caused by neutralizing autoantibodies to GM-CSF or is secondary to other underlying diseases. Rarely, genetic defects in surfactant proteins or the common β chain for the GM-CSF receptor (GM-CSFR) are causal. Using a combination of cellular, molecular, and genomic approaches, we provide the first evidence that PAP can result from a genetic deficiency of the GM-CSFR α chain, encoded in the X-chromosome pseudoautosomal region 1.

IL-13 production by allergen-stimulated T cells is increased in allergic disease and associated with IL-5 but not IFN-gamma expression.

Interleukin‐13 (IL‐13) shares many, but not all, of the properties of the prototypic T‐helper type 2 (Th2) cytokine IL‐4, but its role in allergen‐driven T‐cell responses remains poorly defined. We hypothesized that allergen stimulation of peripheral blood T cells from patients with atopic disease compared with non‐atopic controls results in elevated IL‐13 synthesis in the context of a ‘Th2‐type’ pattern. Freshly isolated peripheral blood mononuclear cells (PBMC) obtained from sensitized atopic patients with allergic disease, and non‐atopic control subjects, were cultured with the allergens Phleum pratense (Timothy grass pollen) or Dermatophagoides pteronyssinus (house dust mite) and the non‐allergenic recall antigen Mycobacterium tuberculosis purified protein derivative (PPD). Supernatant concentrations of IL‐13, along with IL‐5 and interferon‐γ (IFN‐γ) (Th2‐ and Th1‐type cytokines, respectively) were determined by enzyme‐linked immunosorbent assay (ELISA). Allergen‐induced IL‐13 and IL‐5 production by T cells from patients with allergic disease was markedly elevated (P=0·0075 and P=0·0004, respectively) compared with non‐atopic controls, whereas IFN‐γ production was not significantly different. In contrast to allergen, the prototypic Th1‐type antigen M. tuberculosis PPD induced an excess of IFN‐γ over IL‐13 and IL‐5 production, and absolute concentrations of cytokines were not affected by the presence or absence of atopic disease. Addition of exogenous recombinant IFN‐γ or IL‐12, cytokines known to inhibit Th2‐type responses, significantly inhibited allergen‐driven production of both IL‐13 and IL‐5, but not T‐cell proliferation, whereas exogenous IL‐4 did not significantly affect production of IL‐13 or IL‐5. We conclude that allergen‐specific T cells from atopic subjects secrete elevated quantities of IL‐13 compared with non‐atopic controls, in the context of a Th2‐type pattern of cytokine production.

Late response to allergen is associated with increased concentrations of tumor necrosis factor-α and IL-5 in induced sputum

Bronchial antigen challenge of sensitized atopic patients with asthma results in an early fall in FEV1, followed in a proportion of patients by a late (4 to 24 hours) fall. The late response is accompanied by an increase in bronchial reactivity, which is widely believed to reflect local influx and degranulation of inflammatory cells, particularly eosinophils, in association with elevated local secretion of cytokines. We hypothesized that the development of a late-phase bronchoconstrictor response and airway eosinophilia after allergen challenge of sensitized atopic patients with asthma is associated with elevated induced sputum concentrations of the eosinophil-active cytokines IL-5 and granulocyte-macrophage colony-stimulating factor and the proinflammatory cytokine tumor necrosis factor-alpha. We counted inflammatory leukocytes and measured cytokine concentrations in induced sputum at baseline and 24 hours after inhalational allergen challenge of 15 atopic patients with asthma who had previously demonstrated a late response. We observed significant increases in the numbers of eosinophils and the concentrations of their granule products, eosinophil cationic protein and eosinophil peroxidase. In contrast, the numbers of neutrophils and concentrations of two of their products, myeloperoxidase and human neutrophil lipocalin, did not significantly change. The numbers of sputum eosinophils correlated with the maximal late-phase fall in FEV1. Concentrations of IL-5 and tumor necrosis factor-alpha, but not granulocyte-macrophage colony-stimulating factor, were significantly elevated after allergen challenge. We conclude that the relatively noninvasive technique of induced sputum production can be used to monitor the effect of bronchial provocation on cytokine concentrations in asthma.

Understanding the pathogenesis of allergic asthma using mouse models

OBJECTIVE This paper reviews the current views of the pathogenesis of airway eosinophilic inflammation and airway hyperresponsiveness (AHR) in allergic asthma based on mouse models of the disease. The reader will also encounter new treatment strategies that have arisen as this knowledge is applied in practice. DATA SOURCES MEDLINE searches were conducted with key words asthma, mouse model, and murine. Additional articles were identified from references in articles and book chapters. STUDY SELECTION Original research papers and review articles from peer-reviewed journals were chosen. RESULTS Although the mouse model does not replicate human asthma exactly, the lessons learned about the pathogenesis of allergic airway inflammation and AHR are generally applicable in humans. Type 2 T helper lymphocytes (Th2) orchestrate the inflammation and are crucial for the development of AHR. Cells and molecules involved in T cell activation (dendritic cells, T cell receptor, major histocompatibility complex molecule, and costimulatory molecules) are also vital. Besides these, no other cell or molecule could be shown to be indispensable for the establishment of the model under all experimental conditions. There are at least three pathways that lead to AHR. One is dependent on immunoglobulin E and mast cells, one on eosinophils and interleukin-5 (IL-5), and one on IL-13. Eosinophils are probably the most important effector cells of AHR. Radical methods to treat asthma have been tested in the animal model, including modifying the polarity of lymphocyte response and antagonizing IL-5. CONCLUSIONS AHR, the hallmark of asthma, is attributable to airway inflammation ultimately mediated by helper T cells via three pathways, at least. The mouse model is also a valuable testing ground for new therapies of asthma.

Interleukins-4, -5, and -13: emerging therapeutic targets in allergic disease.

For the first time, allergic diseases have emerged as major public health concerns. Highly effective therapies for allergic disease now exist, but are plagued by serious side effects and the fact that a significant minority of patients remains unresponsive. Studies from many laboratories have established that T helper type 2 (T(H)2) cytokines contribute importantly to diseases such as asthma, and therapeutic strategies that target the key T(H)2 cytokines are of potential benefit in allergic disease. In this article, we will review the biology of the T(H)2 cytokines interleukin (IL)-4, IL-5, and IL-13 and their receptors, and will consider several novel strategies to neutralize these molecules in human and experimental asthma. While promising, newer therapies face a gauntlet of developmental challenges, but offer the hope of reducing allergic diseases once again to minor public health concerns.

Production of IL-5 and granulocyte-macrophage colony-stimulating factor by naive human mast cells activated by high-affinity IgE receptor ligation

BACKGROUND The late-phase allergic reaction is an eosinophilic inflammatory response that begins several hours after allergen exposure, may persist for 24 hours, and is an important pathogenic mechanism in allergic disease. OBJECTIVE Cultured naive human mast cells were used to investigate whether mast cells are a direct source of the eosinophil-promoting cytokines IL-5, IL-3, and granulocyte-macrophage colony-stimulating factor (GM-CSF). METHODS Naive human mast cells were derived from bone marrow mononuclear cells cultured in the presence of stem-cell factor. Cytokine message and protein production in response to high-affinity IgE receptor ligation of cultured mast cells were measured by semiquantitative polymerase chain reaction and ELISA, respectively. RESULTS IL-5, IL-3, and GM-CSF messenger RNA increased within 2 hours of mast cell activation, with IL-5 and GM-CSF message remaining elevated for 24 hours, whereas IL-3 mRNA rapidly declined. IL-5 and GM-CSF protein were measurable 4 to 6 hours after stimulation and peaked by 24 and 12 hours, respectively. IL-3 protein was not detectable. CONCLUSION These findings demonstrate that naive mast cells do not constitutively produce IL-5 or GM-CSF protein but are a major source of these eosinophilotropic cytokines on high-affinity IgE receptor ligation.

Urticaria and angioedema

Urticaria and angioedema are usually the clinical consequence of vasoactive mediators derived from mast cells in the skin or mucosal tissues. Efforts to classify mast cell-mediated causes of urticaria and angioedema have generally been frustrated by their diverse pathogenesis and clinical course. The term acute is typically used to describe fleeting lesions whose recurrence does not extend beyond 6 weeks. Chronic is the term used to describe lesions that persist for more than a few hours but usually less than a day, and recurrences extend for more than 6 weeks. These definitions do not take histology into account. Skin biopsies of fleeting lesions demonstrate a paucity of inflammatory cells, whereas more persistent lesions display a spectrum of perivascular cuffing by predominantly T cells and monocytes. The presence of leukocytoclastic vasculitis in persistent lesions indicates an underlying immune complex disease. Many of the physical urticarias have fleeting lesions that can be induced with the appropriate stimulus for years. This review article has emphasized the clinical course and histology of urticaria and angioedema lesions in an effort to provide a more complete understanding of the pathogenesis and appropriate treatment. Clearly, avoidance of an identifiable inciting stimulus is optimum management, although most patients have no etiology defined or the cause is not realistically avoidable. At present, treatment options for these patients rely on antihistamines to control the immediate consequence of mast cell degranulation. Corticosteroids are reserved for the treatment of patients whose urticaria or angioedema lesions persist, reflecting the increasing involvement of mononuclear cells in the disease process. For leukocytoclastic vasculitis, corticosteroids are indicated, and cytotoxic drugs may be required for adequate treatment. Future treatments of urticaria and angioedema will evolve based on elucidation of the relevant cells and soluble mediators and will include counterregulatory or antagonistic peptides and drugs. C1 esterase inhibitor deficiency is a relatively uncommon cause of angioedema but is important to understand because of its ability to clinically mimic mast cell-mediated angioedemas and its unique pathogenesis and treatment. HAE can be divided into two serologic subtypes that simply reflect the location of the defect in one of the codominantly expressed C1-INH genes on chromosome 11. AAE can be divided into two serologic subtypes. AAE type I is due to massive consumption of C1-INH, presumably by tumor-related immune complexes. AAE type II is due to an anti-C1-INH autoantibody.(ABSTRACT TRUNCATED AT 400 WORDS)