Pazit Salamon

Human mast cells release metalloproteinase-9 on contact with activated T cells: juxtacrine regulation by TNF-alpha.

Mast cells, essential effector cells in allergic inflammation, have been found to be activated in T cell-mediated inflammatory processes in accordance with their residence in close physical proximity to T cells. We have recently reported that mast cells release granule-associated mediators and TNF-α upon direct contact with activated T cells. This data suggested an unrecognized activation pathway, where mast cells may be activated during T cell-mediated inflammation. Herein, we show that this cell-cell contact results in the release of matrix metalloproteinase (MMP)-9 and the MMP inhibitor tissue inhibitor of metalloproteinase 1 from HMC-1 human mast cells or from mature peripheral blood-derived human mast cells. The expression and release of these mediators, as well as of β-hexosaminidase and several cytokines, were also induced when mast cells were incubated with cell membranes isolated from activated, but not resting, T cells. Subcellular fractionation revealed that the mature form of MMP-9 cofractionated with histamine and tryptase, indicating its localization within the secretory granules. MMP-9 release was first detected at 6 h and peaked at 22 h of incubation with activated T cell membranes, while TNF-α release peaked after only 6 h. Anti-TNF-α mAb inhibited the T cell membrane-induced MMP-9 release, indicating a possible autocrine regulation of MMP release by mast cell TNF-α. This cascade of events, whereby mast cells are activated by T cells to release cytokines and MMP-9, which are known to be essential for leukocyte extravasation and recruitment to affected sites, points to an important immunoregulatory function of mast cells within the context of T cell-mediated inflammatory processes.

T Cell-Induced Mast Cell Activation: A Role for Microparticles Released from Activated T Cells

Close physical proximity between mast cells and T cells has been demonstrated in several T cell-mediated inflammatory processes. However, the way by which mast cells are activated in these T cell-mediated immune responses has not been fully elucidated. We previously identified and characterized a novel mast cell activation pathway initiated by physical contact with activated T cells and showed that this pathway is associated with degranulation and cytokine release. In this study, we provide evidence that mast cells may also be activated by microparticles released from activated T cells that are considered miniature versions of a cell. Microparticles were isolated from supernatants of activated T cells by Centricon filtration or by high-speed centrifugation and identified by electron microscopy, flow cytometry (Annexin stain), and expression of the integrin LFA-1. Stimulated T cells were found to generate microparticles that induce degranulation and cytokine (IL-8 and oncostatin M) release from human mast cells. Mast cell activation by T cell microparticles involved the MAPK signaling pathway. The results were similar when mast cells were stimulated by activated fixed T cells or by whole membranes of the latter. This suggests that microparticles carry mast cell-activating factors similar to cells from which they originate. By releasing microparticles, T cells might convey surface molecules similar to those involved in the activation of mast cells by cellular contact. By extension, microparticles might affect the activity of mast cells, which are usually not in direct contact with T cells at the inflammatory site.

Induction of mast cell interactions with blood vessel wall components by direct contact with intact T cells or T cell membranes in vitro

Background Mast cells exert profound pleiotropic effects on immune cell reactions at inflammatory sites, where they are most likely influenced not only by the extracellular matrix (ECM) and inflammatory mediators but also by the proximity of activated T lymphocytes. We recently reported that activated T cells induce mast cell degranulation with the release of TNF‐α, and that this activation pathway is mediated by lymphocyte function‐associated antigen‐1 (LFA‐1)/intercellular adhesion molecule‐1 (ICAM‐1) binding.

Mast cells as sources and targets of membrane vesicles.

In addition to being major effector cells in the elicitation of allergic responses, mast cells have been found to play a significant role in the establishment of innate and adaptive immune responses. This occurs, in part, by regulating the phenotype and function of immune cells such as T cells, B cells and dendritic cells, and by acting as antigen presenting cells. Indeed, mast cells have been found to be activated in various T cell-mediated inflammatory processes and to reside in close physical proximity to T cells. Such observations have led investigators to propose a functional relationship between these two cell populations. Mast cells can interact with other cells including T cells in several ways such as cell-cell interaction via membrane associated receptors, release of cytokines and chemokines or by heterotypic adhesion to activated T cells. In this review, we focus on a novel communication pathway between mast cells and other inflammatory cells that occurs by the release of or response to membrane vesicles. Membrane vesicles are circular fragments, released from the endosomal compartment as exosomes or shed from the cell plasma membrane as microparticles. Because their membrane orientation is the same as that of the donor cell, they can be considered to be miniature versions of a cell. Growing evidence indicates that microparticles play a pivotal role in cell to cell communication. The functional consequences of such membrane transfers include the induction, amplification and/or modulation of immune responses, as well as the acquisition of new functional properties by recipient cells.

Characterization of ERK Activation in Human Mast Cells Stimulated by Contact with T Cells

Close physical proximity between mast cells and T cells has been demonstrated in several human conditions. We have identified and characterized a novel mast cell activation pathway initiated by contact with T cells, and showed that this pathway is associated with cytokine release. It has been shown recently that Ras is activated in this pathway. Thus, in the present study we further explore the downstream events associated with Ras activation and cytokine release in human mast cells stimulated by contact with T cells. ERK activation in human mast cells stimulated by either contact with T cells or by crosslinking the FC epsilon receptor was studied. Photobleaching experiments were used to study ERK localization. Enzyme linked immunosorbent assay was used to study the cytokine release by human mast cells. We show that stimulation of human mast cells by contact with activated T cells results is sustained ERK activation. Furthermore, sustained ERK activation in these cells is associated with increased dwell time at the nucleus and with IL-8 release. Interestingly, when mast cells were stimulated by crosslinking the FC epsilon receptor I, ERK activation was transient. ERK activation was associated with a shorter dwell time at the nucleus and with TNF-α release. Thus, retaining ERK in the nucleus might be a mechanism utilized by human mast cells to generate different cytokines from a single signaling cascade.

The Involvement of Protein Kinase D in T Cell-Induced Mast Cell Activation

Background: It has recently been reported that mast cells (MC) can be activated to degranulate and release certain cytokines in response to direct physical contact with activated but not resting T cells or their membranes. The MAPK family members ERK and p38 were found to participate. In this work, we further characterize the signaling events involved in this novel pathway of activation. Methods: Human MC were stimulated by activated T cell membranes (T*m). Phosphorylation of kinases was assessed by Western blotting. Protein kinase D (PKD) translocation was visualized by confocal microscopy. Degranulation was assessed by β-hexosaminidase release and cytokine production by ELISA. Results: Stimulation of human MC by activated T*m resulted in the activation of PKD. PKD inhibition by the specific pharmacological inhibitor Gö6976 resulted in a reduction in the phosphorylation of p38 but not ERK. Gö6976 also inhibited degranulation and cytokine release. Conclusions: MC stimulation by physical contact with T cells results in PKD activation, leading to the phosphorylation of p38, degranulation and release of cytokines. Understanding the molecular events associated with T cell-induced MC activation might lead to therapeutic approaches for controlling T cell-mediated inflammatory processes in which MC participate.