Takeuchi Koh, Nagase Lisa, Kageyama Shun, Kanoh Hirotaka, Oshima Masashi, Ogawa-Iio Aki, Ikeda Yoshiki, Fujii Yuki, Kondo Sei, Osaka Natsuki, Masuda Takeshi, Ishihara Tsukasa, Nakamura Yoshikazu, Hirota Yoshihisa, Sasaki Takehiko, Senda Toshiya, Sasaki Atsuo T
Graduate School of Pharmaceutical Sciences, The University of Tokyo, Bunkyo-ku, Japan.
Cellular and Molecular Biology Research Institute, National Institute of Advanced Industrial Science and Technology, Tsukuba, Japan.
FEBS J. 2025 Jan 19. doi: 10.1111/febs.17393.
Phosphatidylinositol 5-phosphate 4-kinases (PI5P4K), also known as type II PIPKs or PIPKIIs, convert the lipid second messenger PI5P to PI(4,5)P. The PI5P4K family consists of three isozymes in mammals-PI5P4Kα, β, and γ-which notably utilize both GTP and ATP as phosphodonors. Unlike the other two isozymes, which can utilize both ATP and GTP, PI5P4Kβ exhibits a marked preference for GTP over ATP, acting as an intracellular GTP sensor that alters its kinase activity in response to physiological changes in GTP concentration. Knockout studies have demonstrated a critical role for PI5P4Kα and β in tumorigenesis, while PI5P4Kγ has been implicated in regulating immune and neural systems. Pharmacological targeting of PI5P4K holds promise for the development of new therapeutic approaches against cancer, immune dysfunction, and neurodegenerative diseases. Although several PI5P4K inhibitors have already been developed, challenges remain in PI5P4K inhibitor development, including a discrepancy between in vitro and cellular efficacy. This discrepancy is attributable to mainly three factors. (a) Most PI5P4K inhibitors were developed at low ATP levels, where these enzymes exhibit minimal activity. (b) Non-catalytic functions of PI5P4K require careful interpretation of PI5P4K depletion studies, as their scaffolding roles suppress class I PI3K signaling. (c) The lack of pharmacodynamic markers for in vivo assessment complicates efficacy assessment. To address these issues and promote the development of effective and targeted therapeutic strategies, this review provides an analytical overview of the distinct roles of individual isozymes and recent developments in PI5P4K inhibitors, emphasizing structural insights and the importance of pharmacodynamic marker identification.
磷脂酰肌醇5-磷酸4-激酶(PI5P4K),也被称为II型磷脂酰肌醇磷酸激酶或PIPKIIs,可将脂质第二信使PI5P转化为PI(4,5)P2。PI5P4K家族在哺乳动物中由三种同工酶组成——PI5P4Kα、β和γ——它们特别利用GTP和ATP作为磷酸供体。与其他两种既能利用ATP又能利用GTP的同工酶不同,PI5P4Kβ对GTP的偏好明显高于ATP,它作为一种细胞内GTP传感器,可根据GTP浓度的生理变化改变其激酶活性。基因敲除研究表明PI5P4Kα和β在肿瘤发生中起关键作用,而PI5P4Kγ与调节免疫系统和神经系统有关。对PI5P4K进行药物靶向治疗有望开发出针对癌症、免疫功能障碍和神经退行性疾病的新治疗方法。尽管已经开发出了几种PI5P4K抑制剂,但在PI5P4K抑制剂的开发中仍然存在挑战,包括体外和细胞内疗效之间的差异。这种差异主要归因于三个因素。(a)大多数PI5P4K抑制剂是在低ATP水平下开发的,在这种水平下这些酶的活性最低。(b)PI5P4K的非催化功能需要对PI5P4K缺失研究进行仔细解读,因为它们的支架作用会抑制I类PI3K信号传导。(c)缺乏用于体内评估的药效学标志物使疗效评估变得复杂。为了解决这些问题并促进有效和靶向治疗策略的发展,本综述对各同工酶的不同作用以及PI5P4K抑制剂的最新进展进行了分析概述,强调了结构见解和药效学标志物鉴定的重要性。
