The exposome plays a critical role in the development of autoimmune and inflammatory diseases. In this pro- posal, I will address the role of the dietary ?-3 fatty acid docosahexaenoic acid (DHA) in protecting against inflammation induced by the respirable toxicant crystalline silica (cSiO2). Previously, our laboratory found that supplementation with DHA dose-dependently decreased levels of several features of cSiO2-triggered autoim- munity in a lupus-prone mouse model. A key event in the development of systemic inflammation in this model is cSiO2-induced toxicity of the alveolar macrophage (AMph), which involves activation of the NLRP3 inflam- masome and release of potent IL-1 cytokines. The current literature and my preliminary experiments suggest that DHA and its metabolites, known as specialized proresolving mediators (SPMs), may attenuate this re- sponse. Activation of the NLRP3 inflammasome, which is implicated in many inflammatory and autoimmune conditions, requires an initial priming step, during which NF-kB family transcription factors upregulate inflam- masome components and pro-IL-1 cytokines. Anti-inflammatory G-protein coupled receptors (GPCRs) have been identified that bind DHA or SPMs and inhibit NF-kB activation. However, in vitro elucidation of the molecular events of DHA protection in AMph is limited by the low number of cells attainable from a single mouse (~105). To address this, I used Max Planck Institute (MPI) cells. MPI cells are a self-renewing macrophage cell line derived by culturing fetal mouse livers in GM-CSF-supplemented medium and are phenotypically similar to AMph. My preliminary data show that IL-1 cytokine release in response to LPS-priming and cSiO2 treatment is attenuated by DHA supplementation. I propose that DHA supplementation increases DHA in the cell membrane of MPI cells, which can be released and metabolized to SPMs. Free DHA and its SPMs can activate anti-inflam- matory GPCRs in an autocrine or paracrine manner to attenuate NF-kB signaling, which I hypothesize is a pri- mary mechanism by which they protect against cSiO2-induced inflammation.
In Aim 1, the phospholipid incorpo- ration of DHA will be measured, and then effects of DHA on IL-1 cytokine release and NF-kB activation will be assessed. I will also treat cells with chemical agonists, antagonists, and siRNA for specific GPCRs to verify their role in DHA signaling.
In Aim 2, the lipid metabolite profile of cells supplemented with DHA will be measured. I will then determine the extent to which SPMs suppress NF-kB activation and IL-1 cytokine release. Lastly, chem- ical antagonists and siRNA will be used to investigate the involvement of proposed SPM receptors. These ex- periments will be performed in a supportive environment with the necessary resources to accomplish these ob- jectives. My comprehensive training plan provides personal and professional development, which will assist me in becoming a successful independent researcher.
Chronic exposure to the earth?s most abundant environmental toxicant crystalline silica (quartz) induces inflam- mation in the lung that can eventually lead to chronic inflammatory and autoimmune diseases. Dietary omega-3 fatty acids found in fish oil prevent a variety of inflammatory conditions, however, their impact on toxicant-trig- gered lung disease is not well understood. The goal of this project is to learn how omega-3 fatty acids protect against silica-induced airway inflammation, thus improving the understanding of how dietary fats influence lung damage caused by silica and other airborne toxicants.