Polar head groups are important for barrier-protective effects of oxidized phospholipids on pulmonary endothelium

We have previously described protective effects of oxidized 1- palmitoyl- 2- arachidonoylsn- glycero- 3- phosphocholine ( OxPAPC) on pulmonary endothelial cell ( EC) barrier function and demonstrated the critical role of cyclopentenone- containing modifications of arachidonoyl moiety in OxPAPC protective effects. In this study we used oxidized phosphocholine ( OxPAPC), phosphoserine ( OxPAPS), and glycerophosphate ( OxPAPA) to investigate the role of polar head groups in EC barrier-protective responses to oxidized phospholipids ( OxPLs). OxPAPC and OxPAPS induced sustained barrier enhancement in pulmonary EC, whereas OxPAPA caused a transient protective response as judged by measurements of transendothelial electrical resistance ( TER). Non- OxPLs showed no effects on TER levels. All three OxPLs caused enhancement of peripheral EC actin cytoskeleton. OxPAPC and OxPAPS completely abolished LPS-induced EC hyper-permeability in vitro, whereas OxPAPA showed only a partial protective effect. In vivo, intravenous injection of OxPAPS or OxPAPC ( 1.5 mg/ kg) markedly attenuated increases in the protein content, cell counts, and myeloperoxidase activities detected in bronchoalveolar lavage fluid upon intratracheal LPS instillation in mice, although OxPAPC showed less potency. All three OxPLs partially attenuated EC barrier dysfunction induced by IL-6 and thrombin. Their protective effects against thrombin- induced EC barrier dysfunction were linked to the attenuation of the thrombin- induced Rho pathway of EC hyperpermeability and stimulation of Rac- mediated mechanisms of EC barrier recovery. These results demonstrate for the first time the essential role of polar OxPL groups in blunting the LPS- induced EC dysfunction in vitro and in vivo and suggest the mechanism of agonist- induced hyperpermeability attenuation by OxPLs via reduction of Rho and stimulation of Rac signaling.