arachidonyltrifluoromethane and tetrandrine

Invasion of brain microvascular endothelial cells (BMECs) is a key step in the pathogenesis of meningitis due to Escherichia coli and Listeria monocytogenes. Although host cell actin cytoskeletal rearrangements are essential in BMEC invasion by E. coli K1 and L. monocytogenes, the underlying signaling mechanisms remain unclear. This study demonstrates that host cell cytosolic phospholipase A2 (cPLA2) contributes to E. coli K1 invasion of BMECs but not to L. monocytogenes invasion of BMECs. This difference was observed with 4-bromophenacyl bromide, a nonselective PLA2 inhibitor, and arachidonyl trifluoromethyl ketone, a selective cPLA2 inhibitor, and was confirmed with BMEC derived from cPLA2 knockout mice. Activation of cPLA2 leads to generation of intracellular arachidonic acid, which is metabolized via cyclooxygenase (COX) and lipo-oxygenase (LOX) pathways into eicosanoids. COX and LOX inhibitors also significantly inhibit E. coli K1 invasion of BMECs.

Topics: Alkaloids; Arachidonic Acids; Benzylisoquinolines; Cells, Cultured; Cerebral Cortex; Cerebrovascular Circulation; Child; Child, Preschool; Cytosol; Drugs, Chinese Herbal; Endothelium, Vascular; Enzyme Inhibitors; Escherichia coli; Humans; Indomethacin; Lipoxygenase Inhibitors; Listeria monocytogenes; Masoprocol; Microcirculation; Phospholipases A; Phospholipases A2; Signal Transduction

Mechanical loading of bone stimulates resident bone cells to produce prostacyclin (PGI(2)) and prostaglandin (PG)E(2) by a mechanism that can be differentially regulated by ion channel blockers. We have investigated differences in the loading-related PG production mechanisms in rat ulnae explants loaded ex vivo. Loading and aluminium fluoride (AlF(3), a nonselective activator of G-proteins) both increased PGI(2) and PGE(2) release into culture medium. Pertussis toxin (PTX) blocked loading-related release of PGE(2), but not PGI(2), while isotetrandrine, an inhibitor of G-protein-mediated activation of phospholipase (PL)A(2), abolished the loading-related release of both PGs. This suggests both PTX-sensitive and -insensitive G-protein-dependent, PLA(2)-mediated mechanisms for loading-related PG production. Blockade of secretory (s)PLA(2) activity prevented loading-related release of PGE(2) and PGI(2), whereas inhibition of cytosolic (c)PLA(2) activity blocked loading-related release of PGE(2) alone. cPLA(2) was localized immuno-cytochemically to osteoblasts, but not to osteocytes. sPLA(2) was localized to osteocytes and osteoblasts. Exogenous type-IA sPLA(2) and type-IB sPLA(2) stimulated significant increases in PGE(2) and PGI(2) release. PTX reduced the release of both PGs stimulated by type IA PLA(2), but not type IB. Furthermore, inhibition of protein kinase C (PKC) activity blocked loading-related release of PGE(2), but not that of PGI(2). These data suggest that loading-related release of PGI(2) and PGE(2) utilizes arachidonic acid derived from the activity of different PLA(2)s. In osteocytes and osteoblasts, arachidonic acid for PGI(2) synthesis is liberated by PTX-insensitive G-protein-dependent sPLA(2) alone. In osteoblasts, arachidonic acid for PGE(2) synthesis is released by PTX-sensitive, G-protein-dependent, cPLA(2)-mediated activity, which also requires upstream sPLA(2) and PKC activities.

Topics: Alkaloids; Aluminum Compounds; Animals; Antineoplastic Agents, Phytogenic; Arachidonic Acid; Arachidonic Acids; Benzylisoquinolines; Cells, Cultured; Dinoprostone; Enzyme Inhibitors; Epoprostenol; Fluorides; GTP-Binding Proteins; Indoles; Male; Maleimides; Osteocytes; Pertussis Toxin; Phospholipases A; Rats; Stress, Mechanical; Ulna; Virulence Factors, Bordetella; Weight-Bearing