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  • In agreement with the role of

    2023-04-10

    In agreement with the role of ACLY in induced macrophage, we observe a drastically reduction of PGE2 levels when ACLY activity is inhibited. This is possible because PGE2 production requires arachidonic acid, which in turn is synthesized by elongation of dietary linoleic endothelin receptor antagonists with acetyl-CoA provided by ACLY activity (Fig. 4). Finally, gene silencing as well as activity inhibition of ACLY decrease NO and ROS production. A possible explanation for these results comes from the biochemical function of ACLY. This enzyme, besides acetyl-coA, produces oxaloacetate first reduced to malate, which in turn is converted to pyruvate via malic enzyme with production of cytosolic NADPH plus H+. Thus, ACLY can supply NADPH necessary for NO and ROS production during the inflammatory response of induced-macrophages (Fig. 4). In conclusion, this study demonstrates that inflammatory response triggered by exogenous and endogenous inducers causes an early ACLY upregulation. ACLY activity is essential for the production of PGE2, NO and ROS inflammatory mediators. Therefore, ACLY could be a new biomarker for predicting inflammation conditions and at the same time a potential target for inflammatory diseases.
    Acknowledgments This work was supported by grants from the Area Science Park [grant number J41H09000010007] to V. Infantino, the Ministero dell’Università e della Ricerca (MIUR) and the Universities of Basilicata and Bari “Aldo Moro”. We thank GlaxoSmith-Kline for providing us with SB-20499 ACLY inhibitor.
    Adenosine triphosphate (ATP) citrate lyase (ACL: EC 4.1.3.8) catalyzes the reaction of citrate and CoA to produce cytosolic acetyl-CoA, an essential building block for endogenous synthesis of fatty acids, cholesterol and isoprenoids, as well as for posttranslational modification of proteins via acetylation. In tumor, fatty acid synthesis occurs at heightened rates in order to sustain cancer cell proliferation., , ACL was identified as a highly expressed protein in many tumors and has recently emerged as an attractive target for developing novel anticancer drugs., , , , , Our own data have demonstrated that ACL knockdown (KD) by shRNA inhibited cancer cell proliferation and survival, inhibited tumor growth in a number of animal models, and reduced cancer stemness by selectively targeting cancer stem-like cells (CSCs) in multiple cancer types. The CSC is increasingly recognized as a major culprit for drug resistance and the metastasis of cancers. Therefore, inhibition of ACL activity may reduce the CSC population and re-sensitize cancer cells to standard therapies., The synthetic compound SB-201076 () and the natural product (−)-hydroxycitrate [(−)-HCA)] () are potent inhibitors of ACL enzyme (). However, the lack of cell permeability limits their usefulness as pharmacological tools. We have been interested in the discovery of structurally novel ACL inhibitors and evaluating their anticancer activities in cell based assays. Docking is a valuable computational approach to the identifications of bioactive molecules., , The recent report by Sun et al. of high resolution cocrystal structures of ACL in complex with its substrate citrate prompted us to conduct screens of chemical database. Herein we report our focused virtual high-throughput screening (vHTS) strategy and the discovery of a series of novel ACL inhibitors containing a furan carboxylate moiety. Of the 24 virtual hits selected for activity evaluations in an ACL enzymatic assay, 11 were confirmed as active inhibitors, which represented a remarkably high screening hit rate of 45.8%. ACL belongs to the superfamily of acyl-CoA synthetases (Nucleoside diphosphate-forming), of which the quintessential member is succinyl-CoA synthetase. Mammalian ACL oligomerizes to homotetramers, and the single chain monomeric human ACL (hACL) isoform is a 121kDa protein. ACL contains five domains that are typical to the acyl-CoA synthetases superfamily. The high resolution crystal structures of truncated ACL solved recently by Sun et al., reveals that domain 5 contains the citrate binding site while domains 2 and 3 constitute the ATP-grasp fold.