Mast cells mediate systemic immunosuppression induced by platelet-activating factor via histamine and cyclooxygenase-2 dependent mechanisms

Abstract

Platelet-activating Factor (PAF) stimulates various cell types by the activation of the G-protein coupled PAF-receptor (PAFR). Systemic PAFR activation induces an acute pro-inflammatory response, as well as delayed systemic immunosuppressive effects in vivo. De novo enzymatic PAF synthesis and degradation are closely regulated, but oxidative stressors, such as UVB, and cigarette smoke, can generate PAF-like species via the oxidation of membrane lipids in an unregulated process. Mast cells (MCs) and the PAFR have been shown to be necessary to mediate the resulting systemic immune suppression from oxidative stressors. The work herein implicates pro-oxidative chemotherapeutics, such as melphalan and etoposide, in mediating augmentation in tumor growth by inducing the generation of PAFR agonists via the oxidation of membrane lipids. This work also demonstrates the role of MCs and MC-released mediators in PAFR systemic immunosuppression. Through a contact hypersensitivity (CHS) model, the MC PAFR was found to be necessary and sufficient for PAF to mediate systemic immunosuppression. Additionally, activation of the MC PAFR seems to induce MC histamine and prostaglandin E2 release. Furthermore, by transplanting histamine- or COX-2-deficient MCs into MC-deficient mice, MC-derived histamine and prostaglandin release were found to be necessary for PAF to induce systemic immunosuppression. Lastly, we have evidence to suggest that prostaglandin release modulates MC migration to draining lymph nodes, a process necessary to promote immunosuppression. These studies fit with the hypothesis that MC PAFR activation mediates PAFR systemic immunosuppression in part by histamine and prostaglandin release.