Structure-guided design of novel orthosteric inhibitors of integrin αIIbβ3 that prevent thrombosis but preserve hemostasis

A prevailing dogma is that effective inhibition of vascular thrombosis by therapeutic targeting of platelet integrin αIIbβ3 cannot be achieved without compromising hemostasis. The resulting serious bleeding and increased morbidity and mortality have limited use of current anti-αIIbβ3 drugs to high-risk cardiac patients. It is speculated that these adverse outcomes result from drug-induced conformational changes in αIIbβ3 but direct proof is lacking. We used structure-guided design to generate the ligand-mimetic peptide Hr10 and a modified form of the partial agonist drug Tirofiban that now act as “pure” orthosteric antagonists of αIIbβ3, i.e. they no longer induce the conformational changes in αIIbβ3 and also suppress these changes in presence of agonists. Both agents inhibited human platelet aggregation effectively but without interfering with clot retraction. When tested in a humanized mouse model of thrombosis predictive of clinical efficacy, Hr10 was as effective as the αIIbβ3 partial agonist peptide drug Eptifibatide in inhibiting arteriolar thrombosis, but in sharp contrast to Eptifibatide, Hr10 did not cause serious bleeding, establishing a causal link between partial agonism and impaired hemostasis. Pure orthosteric inhibitors of αIIbβ3 may thus offer safer alternatives for human therapy. Our structure-guided approach may also find utility in designing similar drug candidates targeting other integrins and in providing vital tools for further probing structure-activity relationships in integrins.