Ioannis Morianos

CXCL13 production in B cells via Toll-like receptor/lymphotoxin receptor signaling is involved in lymphoid neogenesis in chronic obstructive pulmonary disease.

RATIONALE Little is known about what drives the appearance of lymphoid follicles (LFs), which may function as lymphoid organs in chronic obstructive pulmonary disease (COPD). In animal infection models, pulmonary LF formation requires expression of homeostatic chemokines by stromal cells and dendritic cells, partly via lymphotoxin. OBJECTIVES To study the role of homeostatic chemokines in LF formation in COPD and to identify mechanism(s) responsible for their production. METHODS Peripheral lung homeostatic chemokine and lymphotoxin expression were visualized by immunostainings and quantified by ELISA/quantitative reverse transcriptase-polymerase chain reaction in patients with COPD with and without LFs. Expression of lymphotoxin and homeostatic chemokine receptors was investigated by flow cytometry. Primary lung cell cultures, followed by ELISA/quantitative reverse transcriptase-polymerase chain reaction/flow cytometry, were performed to identify mechanisms of chemokine expression. Polycarbonate membrane filters were used to assess primary lung cell migration toward lung homogenates. MEASUREMENTS AND MAIN RESULTS LFs expressed the homeostatic chemokine CXCL13. Total CXCL13 levels correlated with LF density. Lung B cells of patients with COPD were important sources of CXCL13 and lymphotoxin and also expressed their receptors. Cigarette smoke extract, H2O2, and LPS exposure up-regulated B cell-derived CXCL13. The LPS-induced increase in CXCL13 was partly mediated via lymphotoxin. Notably, CXCL13 was required for efficient lung B-cell migration toward COPD lung homogenates and induced lung B cells to up-regulate lymphotoxin, which further promoted CXCL13 production, establishing a positive feedback loop. CONCLUSIONS LF formation in COPD may be driven by lung B cells via a CXCL13-dependent mechanism that involves toll-like receptor and lymphotoxin receptor signaling.

Activin-A is overexpressed in severe asthma and is implicated in angiogenic processes

Activin-A is a pleiotropic cytokine that regulates allergic inflammation. Its role in the regulation of angiogenesis, a key feature of airways remodelling in asthma, remains unexplored. Our objective was to investigate the expression of activin-A in asthma and its effects on angiogenesis in vitro. Expression of soluble/immunoreactive activin-A and its receptors was measured in serum, bronchoalveolar lavage fluid (BALF) and endobronchial biopsies from 16 healthy controls, 19 patients with mild/moderate asthma and 22 severely asthmatic patients. In vitro effects of activin-A on baseline and vascular endothelial growth factor (VEGF)-induced human endothelial cell angiogenesis, signalling and cytokine release were compared with BALF concentrations of these cytokines in vivo. Activin-A expression was significantly elevated in serum, BALF and bronchial tissue of the asthmatics, while expression of its protein receptors was reduced. In vitro, activin-A suppressed VEGF-induced endothelial cell proliferation and angiogenesis, inducing autocrine production of anti-angiogenic soluble VEGF receptor (R)1 and interleukin (IL)-18, while reducing production of pro-angiogenic VEGFR2 and IL-17. In parallel, BALF concentrations of soluble VEGFR1 and IL-18 were significantly reduced in severe asthmatics in vivo and inversely correlated with angiogenesis. Activin-A is overexpressed and has anti-angiogenic effects in vitro that are not propagated in vivo, where reduced basal expression of its receptors is observed particularly in severe asthma. Anti-angiogenic role of activin-A, overexpressed in severe asthma, may be compromised by reduced receptor signalling http://ow.ly/W4kxF

Innate immunity as the orchestrator of allergic airway inflammation and resolution in asthma

The respiratory system is constantly in direct contact with the environment and, has therefore, developed strong innate and adaptive immune responses to combat pathogens. Unlike adaptive immunity which is mounted later in the course of the immune response and is naive at the outset, innate immunity provides the first line of defense against microbial agents, while also promoting resolution of inflammation. In the airways, innate immune effector cells mainly consist of eosinophils, neutrophils, mast cells, basophils, macrophages/monocytes, dendritic cells and innate lymphoid cells, which attack pathogens directly or indirectly through the release of inflammatory cytokines and antimicrobial peptides, and coordinate T and B cell-mediated adaptive immunity. Airway epithelial cells are also critically involved in shaping both the innate and adaptive arms of the immune response. Chronic allergic airway inflammation and linked asthmatic disease is often considered a result of aberrant activation of type 2 T helper cells (Th2) towards innocuous environmental allergens; however, innate immune cells are increasingly recognized as key players responsible for the initiation and the perpetuation of allergic responses. Moreover, innate cells participate in immune response regulation through the release of anti-inflammatory mediators, and guide tissue repair and the maintenance of airway homeostasis. The scope of this review is to outline existing knowledge on innate immune responses involved in allergic airway inflammation, highlight current gaps in our understanding of the underlying molecular and cellular mechanisms and discuss the potential use of innate effector cells in new therapeutic avenues.

Activin-A co-opts IRF4 and AhR signaling to induce human regulatory T cells that restrain asthmatic responses

Significance Here, we demonstrate that the cytokine activin-A instructs the differentiation of human IL-10–producing type 1 regulatory T (Tr1)-like cells that exhibit strongly suppressive functions against allergen-induced naive and effector CD4+ T-cell responses. In addition, we show that activin-A induces the activation of interferon regulatory factor (IRF4), which, along with aryl hydrocarbon receptor (AhR) and its binding partner, AhR nuclear translocator, forms a tripartite transcription factor complex that is essential for the differentiation and effector functions of human Tr1 cells. Importantly, administration of human activin-A–induced Tr1 cells in a humanized model of asthma confers protection against cardinal disease manifestations in preventive and therapeutic regimes. Collectively, our studies unravel a biological function for activin-A in the generation of suppressive human Tr1 cells that may be exploited for the control of allergic diseases. Type 1 regulatory T (Tr1) cells play a pivotal role in restraining human T-cell responses toward environmental allergens and protecting against allergic diseases. Still, the precise molecular cues that underlie their transcriptional and functional specification remain elusive. Here, we show that the cytokine activin-A instructs the generation of CD4+ T cells that express the Tr1-cell–associated molecules IL-10, inducible T-Cell costimulator (ICOS), lymphocyte activation gene 3 protein (LAG-3), and CD49b, and exert strongly suppressive functions toward allergic responses induced by naive and in vivo-primed human T helper 2 cells. Moreover, mechanistic studies reveal that activin-A signaling induces the activation of the transcription factor interferon regulatory factor (IRF4), which, along with the environmental sensor aryl hydrocarbon receptor, forms a multipartite transcriptional complex that binds in IL-10 and ICOS promoter elements and controls gene expression in human CD4+ T cells. In fact, IRF4 silencing abrogates activin-A–driven IL10 and ICOS up-regulation and impairs the suppressive functions of human activin-A–induced Tr1-like (act-A–iTr1) cells. Importantly, using a humanized mouse model of allergic asthma, we demonstrate that adoptive transfer of human act-A–iTr1 cells, both in preventive and therapeutic protocols, confers significant protection against cardinal asthma manifestations, including pulmonary inflammation. Overall, our findings uncover an activin-A–induced IRF4-aryl hydrocarbon receptor (AhR)–dependent transcriptional network, which generates suppressive human Tr1 cells that may be harnessed for the control of allergic diseases.

Dendritic cells conditioned by activin A–induced regulatory T cells exhibit enhanced tolerogenic properties and protect against experimental asthma

Background: Previously, we demonstrated that regulatory T (Treg) cells induced by the cytokine activin‐A suppress TH2‐mediated allergic responses and linked airway disease. Still, the effects of activin‐A–induced regulatory T (Act‐A‐iTreg) cells on the regulation of dendritic cell (DC)–driven allergic inflammation remain elusive. Objective: Here we investigated whether Act‐A‐iTreg cells can modulate DC responses and endow them with enhanced tolerogenic functions. Methods: Using adoptive cell transfer studies in mouse models of allergic airway disease, we examined the effects of Act‐A‐iTreg cells on DC phenotype, maturation status, and TH2 cell priming potential. Genome‐wide gene expression profiling characterized the transcriptional networks induced in tolerogenic DCs by Act‐A‐iTreg cells. The ability of DCs conditioned by Act‐A‐iTreg cells (Act‐A‐iTreg cell–modified DCs) to protect against experimental asthma, and the mechanisms involved were also explored. Results: Act‐A‐iTreg cell–modified DCs exhibited a significantly impaired capacity to uptake allergen and stimulate naive and TH2 effector responses on allergen stimulation in vivo accompanied by markedly attenuated inflammatory cytokine release in response to LPS. Gene‐profiling studies revealed that Act‐A‐iTreg cells dampened crucial TH2‐skewing transcriptional networks in DCs. Administration of Act‐A‐iTreg cell–modified DCs ameliorated cardinal asthma manifestations in preventive and therapeutic protocols through generation of strongly suppressive forkhead box P3+ Treg cells. Finally, programed death protein 1/programmed death ligand 1 signaling pathways were essential in potentiating the generation of DCs with tolerogenic properties by Act‐A‐iTreg cells. Conclusion: Our studies reveal that Act‐A‐iTreg cells instruct the generation of a highly effective immunoregulatory circuit encompassing tolerogenic DCs and forkhead box P3+ Treg cells that could be targeted for the design of novel immunotherapies for allergic disorders.