Khim Monique, Montgomery Jemma, Laureano De Souza Mariana, Delvillar Melvin, Weible Lyssa J, Prabakaran Mayuri, Hulverson Matthew A, Eck Tyler, Bheemanabonia Rammohan Y, Alday P Holland, Rotella David P, Doggett J Stone, Staker Bart L, Ojo Kayode K, Bhanot Purnima
Seattle Structural Genomics Center for Infectious Disease, Seattle, Washington 98109, United States.
Center for Global Infectious Disease ResearchSeattle Children's Research Institute, Seattle, Washington 98109, United States.
ACS Infect Dis. 2025 Jun 13;11(6):1497-1507. doi: 10.1021/acsinfecdis.5c00049. Epub 2025 May 8.
Malaria, toxoplasmosis, and cryptosporidiosis are caused by apicomplexan parasites spp., , and , respectively, and pose major health challenges. Their therapies are inadequate, ineffective or threatened by drug resistance. The development of novel drugs against them requires innovative and resource-efficient strategies. We exploited the kinome conservation of these parasites to determine the cellular targets and effects of two inhibitors in and . The imidazoles, ()-RY-1-165 and ()-RY-1-185, were developed to target the cGMP dependent protein kinase of (PfPKG), orthologs of which are present in and . Using structural and modeling approaches we determined that the molecules bind stereospecifically and interact with PfPKG in a manner unique among described inhibitors. We used enzymatic assays and mutant expressing PfPKG with a substituted "gatekeeper" residue to determine that cellular activity of the molecules is mediated through targets additional to PfPKG. These likely include calcium dependent protein kinase 1 and 4 (PfCDPK-1, -4), kinases that, like PfPKG, have small amino acids at the "gatekeeper" position. The molecules are active against and , with tachyzoites being particularly sensitive. Using mutant parasites, enzyme assays and modeling studies we demonstrate that targets in include TgPKG, TgCDPK1, TgCDPK4 and the mitogen activated kinase-like 1 (MAPKL-1). Our results suggest that this scaffold holds promise for the development of new toxoplasmosis drugs.
疟疾、弓形虫病和隐孢子虫病分别由顶复门寄生虫属、属和属引起,构成了重大的健康挑战。它们的治疗方法不足、无效或受到耐药性的威胁。开发针对它们的新型药物需要创新且资源高效的策略。我们利用这些寄生虫的激酶组保守性来确定两种抑制剂在疟原虫和弓形虫中的细胞靶点及作用。咪唑类化合物()-RY-1-165和()-RY-1-185被开发用于靶向疟原虫的环鸟苷酸依赖性蛋白激酶(PfPKG),其直系同源物存在于隐孢子虫和弓形虫中。通过结构和建模方法,我们确定这些分子立体特异性结合,并以一种在所描述的抑制剂中独特的方式与PfPKG相互作用。我们使用酶促测定和表达带有取代“守门人”残基的PfPKG的突变疟原虫来确定这些分子的细胞活性是通过PfPKG之外的靶点介导的。这些可能包括疟原虫钙依赖性蛋白激酶1和4(PfCDPK-1、-4),这些激酶与PfPKG一样,在“守门人”位置具有小氨基酸。这些分子对疟原虫和弓形虫有活性,弓形虫速殖子尤其敏感。使用突变寄生虫、酶促测定和建模研究,我们证明弓形虫中的靶点包括TgPKG、TgCDPK1、TgCDPK4和丝裂原活化激酶样1(MAPKL-1)。我们的结果表明,这种支架有望用于开发新的弓形虫病药物。
