A non-covalent inhibitor XMU-MP-3 overrides ibrutinib-resistant BtkC481S mutation in B-cell malignancies

Background and purpose: Bruton's tyrosine kinase (Btk) plays a key role in B-cell receptor signalling by regulating cell proliferation and survival in various B-cell malignancies. Covalent low-MW Btk kinase inhibitors have shown impressive clinical efficacy in B-cell malignancies. However, the mutant Btk^C481S poses a major challenge in the management of B-cell malignancies by disrupting the formation of the covalent bond between Btk and irreversible inhibitors, such as ibrutinib. The present studies were designed to develop novel Btk inhibitors targeting ibrutinib-resistant Btk^C481S mutation.

Experimental approach: BTK-Ba/F3, Btk(C481S)-Ba/F3 cells, and human malignant B-cells JeKo-1, Ramos, and NALM-6 were used to evaluate cellular potency of Btk inhibitors. The in vitro pharmacological efficacy and compound selectivity were assayed via cell viability, colony formation, and BTK-mediated signalling. A tumour xenograft model with BTK-Ba/F3, Ramos and Btk(C481S)-Ba/F3 cells in Nu/nu BALB/c mice was used to assess in vivo efficacy of XMU-MP-3.

Key results: XMU-MP-3 is one of a group of low MW compounds that are potent non-covalent Btk inhibitors. XMU-MP-3 inhibited both Btk and the acquired mutant BTKC481S, in vitro and in vivo. Further computational modelling, site-directed mutagenesis analysis, and structure-activity relationships studies indicated that XMU-MP-3 displayed a typical Type-II inhibitor binding mode.

Conclusion and implications: XMU-MP-3 directly targets the Btk signalling pathway in B-cell lymphoma. These findings establish XMU-MP-3 as a novel inhibitor of Btk, which could serve as both a tool compound and a lead for further drug development in Btk relevant B-cell malignancies, especially those with the acquired ibrutinib-resistant C481S mutation.