Nuclear phosphoinositide signaling in cell biology and disease

生物 背景(考古学) 细胞生物学 信号转导 磷脂酰肌醇 细胞代谢 细胞 核定位序列 细胞信号 核受体 计算生物学 核运输 核蛋白 内膜 细胞代谢 化学生物学 生物信息学 细胞膜 细胞功能 疾病 代谢途径 膜蛋白 细胞核
作者
Yanan Sun,Fengting Liu,Chunbo Chen,Jichao Sun,Mo Chen
出处
期刊:Developmental Cell [Elsevier BV]
卷期号:61 (3): 473-504 被引量:2
标识
DOI:10.1016/j.devcel.2026.02.004
摘要

Phosphatidylinositol phosphates (PIPs), or phosphoinositides, are minor yet essential phospholipids that govern diverse cellular processes, from membrane trafficking to signal transduction. While traditionally studied within the cell membranes, emerging evidence reveals their dynamic metabolism and critical functions in the nucleus, particularly within the non-membrane nucleoplasm, continually reshaping our understanding of the nuclear PIP-lipidome and its therapeutic potential. However, an updated overview of the nuclear PIP landscape and its selective modulators remains lacking. This review addresses this gap by providing an integrated summary of nuclear PIP signaling components, encompassing their structures, species, distribution, transport, and metabolic regulation. A focus is placed on pharmacological modulation, including inhibitors and activators targeting nuclear phosphatidylinositol (PI/PtdIns) transfer proteins and PIP-metabolizing enzymes, with attention to structure-based inhibitor classes and representative clinical-stage compounds. We conclude by outlining therapeutic opportunities that arise from targeting the nuclear PIP pathway, particularly in the context of cancer, cardiovascular disease, and neurodegeneration. In this review, Chen et al. discuss how phosphoinositides function as spatially confined protein-centric signaling molecules within the nucleus, governed by principles distinct from membrane-delimited lipid signaling. They integrate emerging conceptual frameworks with a systematic analysis of inhibitors and activators targeting nuclear PIP metabolic enzymes and lipid transfer pathways.
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