MBD2 suppresses SFRP1 expression and promotes colorectal cancer development by blocking MED19 binding to its methylated promoter.
The Wnt signaling pathway antagonist SFRP1 is frequently silenced by promoter DNA hypermethylation in colorectal cancer (CRC). MBD2, a DNA methylation reader, is known to contribute to SFRP1 epigenetic silencing. Previous work showed that MBD2 critically suppresses SFRP1 expression without altering promoter methylation, though the underlying mechanism remained unclear. Elucidating how DNA methylation silences tumor suppressor genes, such as SFRP1, could reveal novel therapeutic targets with significant clinical potential.
MBD2 was inhibited in CRC models using either siRNA or a small molecule inhibitor (KCC07). The effects on SFRP1 and β-catenin expression, Wnt pathway activity, cell proliferation, and apoptosis were assessed. Tumor growth was also evaluated in vivo. Mechanistic studies investigated the role of MBD2 in mediating MED19 binding to the SFRP1 promoter and its impact on RNA polymerase II CTD-S7 phosphorylation.
The IC50 of KCC07 was 23.25 μM in SW480 cells, 26.83 μM in HCT116 cells, and 39.66 μM in NCM460 cells. Inhibition of MBD2, either genetically or pharmacologically with KCC07, upregulated SFRP1 expression, downregulated β-catenin, and suppressed the Wnt pathway. KCC07 treatment also inhibited CRC cell proliferation, promoted apoptosis, and suppressed tumor growth in vivo. Mechanistically, MBD2 was found to silence SFRP1 by blocking MED19 binding to its promoter, which subsequently reduced RNA polymerase II CTD-S7 phosphorylation and impaired transcription.
This study reveals a novel mechanism whereby DNA methylation suppresses gene expression via MBD2, independent of changes in methylation status, by disrupting MED19 binding and subsequent transcription. Targeting MBD2 represents a promising therapeutic strategy for colorectal cancer.
MBD2 was inhibited in CRC models using either siRNA or a small molecule inhibitor (KCC07). The effects on SFRP1 and β-catenin expression, Wnt pathway activity, cell proliferation, and apoptosis were assessed. Tumor growth was also evaluated in vivo. Mechanistic studies investigated the role of MBD2 in mediating MED19 binding to the SFRP1 promoter and its impact on RNA polymerase II CTD-S7 phosphorylation.
The IC50 of KCC07 was 23.25 μM in SW480 cells, 26.83 μM in HCT116 cells, and 39.66 μM in NCM460 cells. Inhibition of MBD2, either genetically or pharmacologically with KCC07, upregulated SFRP1 expression, downregulated β-catenin, and suppressed the Wnt pathway. KCC07 treatment also inhibited CRC cell proliferation, promoted apoptosis, and suppressed tumor growth in vivo. Mechanistically, MBD2 was found to silence SFRP1 by blocking MED19 binding to its promoter, which subsequently reduced RNA polymerase II CTD-S7 phosphorylation and impaired transcription.
This study reveals a novel mechanism whereby DNA methylation suppresses gene expression via MBD2, independent of changes in methylation status, by disrupting MED19 binding and subsequent transcription. Targeting MBD2 represents a promising therapeutic strategy for colorectal cancer.