USP1-mediated lipophagy-lipogenesis axis drives cholangiocarcinoma progression and immune evasion
Journal for ImmunoTherapy of Cancer, 2026
Chen Y., Xu X., Shao S., Zhang J., Wang Z., Chen C., Jiang W., Chang J., Chen R., Zhou T., Wang J., Liu S., Yu Y., Zhang Y., Li C., Li X.
| Disease area | Application area | Sample type | Products |
|---|---|---|---|
Oncology | Pathophysiology | Cell Lysate |  Olink Target 96 |
Abstract
Background
Cholangiocarcinoma (CCA), a malignancy arising from biliary epithelial cells, features a tumor microenvironment (TME) characterized by metabolic dysregulation and immunosuppression. Although diverse metabolic aberrations have been observed, the dominant metabolic driver remains unclear. Therefore, the study aims to elucidate the molecular connections between metabolic reprogramming and immune evasion, and to provide the basis for developing TME-targeted therapies.
Methods
First, untargeted metabolomics was performed to identify key metabolite classes involved in CCA progression. We subsequently used next-generation sequencing combined with database analysis to identify the key genes involved in tumor fatty acid metabolism. Metabolomics, proteomics and metabolic phenotyping experiments were subsequently performed to investigate this metabolic process. Tumor malignancy was evaluated using a range of in vitro and in vivo models. Single-cell RNA sequencing, Olink proteomics, flow cytometry and multiplex immunohistochemistry were performed to analyze the changes in the TME. Finally, we used humanized NOG mice to evaluate the efficacy of the combination therapy.
Results
Integrated multi-omics analysis revealed that long-chain unsaturated fatty acids (LCUFAs) were enriched in CCA tissues and closely associated with tumor progression. Ubiquitin-specific peptidase 1 (USP1) was upregulated in CCA tissues, driving dynamic lipid metabolic reprogramming and was associated with poor prognosis. Mechanistically, USP1 orchestrated LCUFAs accumulation through coordinating the enhancement of lipophagy and lipogenesis, establishing a systems-level metabolic regulatory network. Tumor-secreted LCUFAs were preferentially internalized by tumor-associated macrophages (TAMs) through FABP5, thereby suppressing cytotoxic T cells activity. Additionally, TAMs upregulated USP1 in CCA cells, forming a positive feedback loop that perpetuates the metabolic-immune crosstalk.
Conclusion
In summary, based on multi-omics analysis, this study establishes a systemic mechanism that links tumor lipid metabolism, immune suppression, and therapeutic response in CCA. Targeting the USP1-mediated metabolic-immune axis not only significantly suppresses tumor progression but also enhances the efficacy of immunotherapy. These findings construct a conceptual framework that integrates metabolic reprogramming, immune evasion, and treatment sensitivity, thereby establishing USP1 as a precision therapeutic target with broad biological and clinical importance for patients with CCA.