Abstract
The binding of all-trans retinoic acid (ATRA) to retinoid receptor-α (RAR-α) relieves transcriptional repression induced by the promyelocytic leukemia–retinoic acid receptor (PML–RAR) oncoprotein. The ATRA molecule contains a cyclohexenyl ring, a polyene chain containing conjugated double alkene bonds, and a terminal carboxyl group. To determine the contributions of these structural components of ATRA to its clinical efficacy, we synthesized three novel retinoids. These consisted of either a modified conjugated alkene backbone with an intact acid moiety (13a) or a modified conjugated alkene backbone and conversion of the acid group to either an ester (13b) or an aromatic amide (13c). Reporter assays demonstrated that compound 13a successfully relieved transcriptional repression by RAR-α, while 13b and 13c could not, demonstrating the critical role of the acid moiety in this binding. However, only ATRA was able to significantly inhibit the proliferation of APL cells while 13a, 13b, or 13c was not. Furthermore, only 13a led to partial non-significant differentiation of NB4 cells, demonstrating the importance of C9–C10 double bonds in differentiation induced CD11 expression. Our results demonstrate that both the acid moiety and conjugated double bonds present in the ATRA molecule are important for its biological activity in APL and have important implications for the design of future novel retinoids.
Declaration of interest: This study was supported by NIH 1R01HL082946-01, Gabrielle Angel Foundation, Hershaft Family Foundation, and American Cancer Society grants (A.V.); Immunooncology Training Program T32 CA009173 grant and MDS foundation award (L.Z.); and NIH grant CA121192 and a Merit Review grant from the Department of Veterans Affairs (L.C.P.).