Feed

Nuclear protein 1 (NUPR1) is an intrinsically disordered, stress-adaptive regulator that sits at the intersection of transcriptional plasticity and proteostatic control, broadly upregulated across malignancies and tightly associated with poor prognosis. Here, we synthesize evidence positioning NUPR1 as a central node of tumor adaptation that integrates metabolic rewiring, proteostatic balance, and cell-death checkpoints into a unified stress-response framework. NUPR1 orchestrates lipogenic and glycolytic programs, sustains lysosomal biogenesis and autophagic flux, and governs cell-fate decisions by restraining apoptosis and ferroptosis through iron and redox control. Beyond tumor-intrinsic roles, NUPR1 remodels the tumor microenvironment by driving immunosuppressive macrophage polarization and amplifying inflammatory signaling, collectively sustaining a pro-survival niche. These circuits underpin broad therapeutic resistance across modalities, spanning chemotherapy, targeted agents, endocrine therapy, and immune checkpoint blockade. We further discuss the development of small-molecule NUPR1 antagonists-including ZZW-115 and emerging chemotypes-that disrupt nuclear trafficking and stress tolerance, alongside formulation strategies to optimize pharmacodynamic potency and safety. Together, these insights establish NUPR1 as a druggable stress-response node and provide a mechanistic framework to overcome resistance and refine adaptive cancer therapy paradigms.