Macrophage activation induces formation of the anti-inflammatory lipid cholesteryl-nitrolinoleate.

Nitroalkene derivatives of fatty acids act as adaptive, anti-inflammatory signalling mediators, based on their high-affinity PPARgamma (peroxisome-proliferator-activated receptor gamma) ligand activity and electrophilic reactivity with proteins, including transcription factors. Although free or esterified lipid nitroalkene derivatives have been detected in human plasma and urine, their generation by inflammatory stimuli has not been reported. In the present study, we show increased nitration of cholesteryl-linoleate by activated murine J774.1 macrophages, yielding the mononitrated nitroalkene CLNO2 (cholesteryl-nitrolinoleate). CLNO2 levels were found to increase approximately 20-fold 24 h after macrophage activation with Escherichia coli lipopolysaccharide plus interferon-gamma; this response was concurrent with an increase in the expression of NOS2 (inducible nitric oxide synthase) and was inhibited by the (*)NO (nitric oxide) inhibitor L-NAME (N(G)-nitro-L-arginine methyl ester). Macrophage (J774.1 and bone-marrow-derived cells) inflammatory responses were suppressed when activated in the presence of CLNO2 or LNO2 (nitrolinoleate). This included: (i) inhibition of NOS2 expression and cytokine secretion through PPARgamma and *NO-independent mechanisms; (ii) induction of haem oxygenase-1 expression; and (iii) inhibition of NF-kappaB (nuclear factor kappaB) activation. Overall, these results suggest that lipid nitration occurs as part of the response of macrophages to inflammatory stimuli involving NOS2 induction and that these by-products of nitro-oxidative reactions may act as novel adaptive down-regulators of inflammatory responses.

Synthesis, isomer characterization, and anti-inflammatory properties of nitroarachidonate.

Nitrated fatty acids (nitroalkenes) have been recently detected and quantified in cell membranes and human plasma. However, nitration of arachidonate (AA), that could redirect AA-dependent cell signaling pathways, has not been studied in detail. Herein, we synthesized and determined for the first time the isomer distribution of nitroarachidonate (AANO2) and demonstrate its ability to modulate inflammation. Synthesis of AANO2 was achieved by AA treatment with sodium nitrite in acidic conditions following HPLC separation. Mass spectrometry (MS) analysis showed the characteristic MS/MS transition of AANO2 (m/z 348/301). Moreover, the IR signal at 1378.3 cm(-1) and NMR studies confirmed the presence of mononitrated nitroalkenes. Positional isomer distribution was determined by NMR and MS fragmentation with lithium; four major isomers (9-, 12-, 14-, and 15-AANO2) were identified, which exhibited key anti-inflammatory properties. These include their ability to release biologically relevant amounts of nitric oxide, induce cGMP-dependent vasorelaxation, and down-regulate inducible nitric oxide synthase (NOS2) expression during macrophage activation, providing unique structural evidence and novel regulatory signaling properties of AANO2.