Phospholipase C‐epsilon links G‐protein coupled receptor activation to inflammatory responses in astrocytes (1066.5)

Neuroinflammation underlies many diseases of the central nervous system (CNS) and the role of astrocytes in this process is increasingly recognized. Thrombin and the lysophospholipids, LPA and S1P are generated during injury and can activate G‐protein coupled receptors (GPCRs) on astrocytes. We hypothesized that GPCRs that couple to RhoA induce inflammatory gene expression in astrocytes through phospholipase C‐epsilon (PLCε). Using wild‐type (WT) and PLCε (KO) astrocytes, we recently demonstrated that thrombin, LPA, and S1P signal through PLCε to mediate sustained PKD activation and subsequently activation of NFκB to induce expression of inflammatory genes including COX‐2, IL‐1β, and IL‐6 (Dusaban, SS et al. PNAS, 2013). We are currently investigating the molecular mechanism by which PLCε mediates sustained PKD activation and downstream inflammatory responses. Preliminary data using Golgi targeted PKD FRET reporters suggests that PLCε mediates sustained activation of PKD at the Golgi. We also find that disrupting the Golgi with brefeldin A inhibits both PKD activation and COX‐2 expression. We further determined that COX‐2 gene expression was induced through PLCε following in vitro wounding and in vivo cortical stab wound injury. In light of growing evidence for a role of glial cells and S1P receptors in neuroinflammation, we investigated the S1P receptor subtypes coupled to PLCε and its downstream targets. Taking advantage of receptor KO astrocytes and receptor knockdown, we determined that coupling occurs primarily through the S1P3 receptor. Future work is aimed at identifying other GPCRs that signal through PLCε to mediate neuroinflammatory responses. Grant Funding Source : GM 36927