Carbon monoxide-releasing molecules (CO-RMs) are compounds capable of delivering controlled amounts of CO within a cellular environment. Ruthenium-based carbonyls (CORM-2 and CORM-3) and boronacorbonates (CORM-A1) have been shown to promote vasodilatory, cardioprotective and anti-inflammatory activities in a variety of experimental models. Here we extend our previous studies by showing that CORM-F3, an irontricarbonyl complex which contains a 2-pyrone motif, liberates CO in vitro and exerts pharmacological actions that are typical of CO gas. Specifically, CORM-F3 caused vasorelaxation in isolated aortic rings and inhibited the inflammatory response (eg nitrite production) of RAW264. 7 macrophages stimulated with endotoxin in a dose-dependent fashion. By analyzing the rate of CO release, we found that when the bromide at the 4-position of the 2-pyrone in CORM-F3 is substituted with a chloride group (CORM-F8), the rate of CO release is significantly decreased (4.5 fold) and a further decrease is observed when the 4-and 6-positions are substituted with a methyl group (CORM-F11) or a hydrogen (CORM-F7), respectively. Interestingly, the compounds containing halogens at the 4-position and the methyl at the 6-position of the 2-pyrone ring (CORM-F3 and CORM-F8) were found to be less cytotoxic compared to other CO-RMs when tested in RAW246. 7 macrophages. Thus, iron-based carbonyls mediate pharmacological responses that are achieved through liberation of CO and the nature of the substituents in the organic ligand have a profound effect on both the rate of CO release and cytotoxicity
