Bender Andrew T, Gardberg Anna, Pereira Albertina, Johnson Theresa, Wu Yin, Grenningloh Roland, Head Jared, Morandi Federica, Haselmayer Philipp, Liu-Bujalski Lesley
TIP Immunology (A.T.B., A.P., Y.W., R.G.) and Discovery Technologies (A.G., T.J., J.H., F.M., L.L.-B.), EMD Serono Research and Development Institute, Billerica, Massachusetts; and TIP Immunology, Merck, Darmstadt, Germany (P.H.)
TIP Immunology (A.T.B., A.P., Y.W., R.G.) and Discovery Technologies (A.G., T.J., J.H., F.M., L.L.-B.), EMD Serono Research and Development Institute, Billerica, Massachusetts; and TIP Immunology, Merck, Darmstadt, Germany (P.H.).
Mol Pharmacol. 2017 Mar;91(3):208-219. doi: 10.1124/mol.116.107037. Epub 2017 Jan 6.
Bruton's tyrosine kinase (Btk) is expressed in a variety of hematopoietic cells. Btk has been demonstrated to regulate signaling downstream of the B-cell receptor (BCR), Fc receptors (FcRs), and toll-like receptors. It has become an attractive drug target because its inhibition may provide significant efficacy by simultaneously blocking multiple disease mechanisms. Consequently, a large number of Btk inhibitors have been developed. These compounds have diverse binding modes, and both reversible and irreversible inhibitors have been developed. Reported herein, we have tested nine Btk inhibitors and characterized on a molecular level how their interactions with Btk define their ability to block different signaling pathways. By solving the crystal structures of Btk inhibitors bound to the enzyme, we discovered that the compounds can be classified by their ability to trigger sequestration of Btk residue Y551. In cells, we found that sequestration of Y551 renders it inaccessible for phosphorylation. The ability to sequester Y551 was an important determinant of potency against FcεR signaling as Y551 sequestering compounds were more potent for inhibiting basophils and mast cells. This result was true for the inhibition of FcγR signaling as well. In contrast, Y551 sequestration was less a factor in determining potency against BCR signaling. We also found that Btk activity is regulated differentially in basophils and B cells. These results elucidate important determinants for Btk inhibitor potency against different signaling pathways and provide insight for designing new compounds with a broader inhibitory profile that will likely result in greater efficacy.
布鲁顿酪氨酸激酶(Btk)在多种造血细胞中表达。已证明Btk可调节B细胞受体(BCR)、Fc受体(FcR)和Toll样受体下游的信号传导。它已成为一个有吸引力的药物靶点,因为抑制它可能通过同时阻断多种疾病机制而提供显著疗效。因此,已开发出大量Btk抑制剂。这些化合物具有不同的结合模式,并且可逆和不可逆抑制剂均已被开发出来。本文报道,我们测试了九种Btk抑制剂,并在分子水平上表征了它们与Btk的相互作用如何决定其阻断不同信号通路的能力。通过解析与该酶结合的Btk抑制剂的晶体结构,我们发现这些化合物可根据其触发Btk残基Y551隔离的能力进行分类。在细胞中,我们发现Y551的隔离使其无法被磷酸化。隔离Y551的能力是抗FcεR信号传导效力的一个重要决定因素,因为能够隔离Y551的化合物在抑制嗜碱性粒细胞和肥大细胞方面更有效。这一结果在抑制FcγR信号传导方面同样成立。相比之下,Y551隔离在决定抗BCR信号传导效力方面作用较小。我们还发现Btk活性在嗜碱性粒细胞和B细胞中受到不同调节。这些结果阐明了Btk抑制剂对不同信号通路效力的重要决定因素,并为设计具有更广泛抑制谱的新化合物提供了见解,这可能会带来更高的疗效。
