Histone lysine demethylases (KDMs) have drawn much attention as targets of therapeutic agents. KDM5 proteins, which are Fe(II)/α-ketoglutarate-dependent demethylases, are associated with oncogenesis and drug resistance in cancer cells, and KDM5-selective inhibitors are expected to be anticancer drugs. However, few cell-active KDM5 inhibitors have been reported and there is an obvious need to discover more. In this study, we pursued the identification of highly potent and cell-active KDM5-selective inhibitors. Based on the reported KDM5 inhibitors, we designed several compounds by strategically merging two fragments for competitive inhibition with α-ketoglutarate and for KDM5-selective inhibition. Among them, compounds 10 and 13, which have a 3-cyano pyrazolo[1,5-a]pyrimidin-7-one scaffold, exhibited strong KDM5-inhibitory activity and significant KDM5 selectivity. In cellular assays using human lung cancer cell line A549, 10 and 13 increased the levels of trimethylated lysine 4 on histone H3, which is a specific substrate of KDM5s, and induced growth inhibition of A549 cells. These results should provide a basis for the development of cell-active KDM5 inhibitors to highlight the validity of our inhibitor-based fragment merging strategy.
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Article Synopsis
- Epigenetic factors like KDM5A and KDM5B are linked to cancer and immune regulation, and researchers studied their impact on gene expression and chromatin structure by removing these proteins in cells.
- Analysis showed a drop in specific gene expressions (KRAB-ZNF genes) when KDM5A or KDM5B were absent, while inhibition of their demethylase activity did not affect these genes as expected.
- The study found that loss of KDM5A rapidly increases the expression of endogenous retroviruses, suggesting a role for KDM5A alongside the NuRD complex in controlling these viral elements, highlighting potential therapeutic strategies in targeting these proteins to enhance cancer treatments.
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