佐谷 秀行

Pancreatic cancer is a highly intractable malignancy that necessitates personalized treatment strategies. Conventional patient-derived models, such as three-dimensional organoids, are often limited by intellectual property constraints and high costs. In this study, we developed an affordable adherent culture system for patient-derived pancreatic cancer cells using a proprietary medium and laminin-coated dishes. Primary cultures were successfully established from 28 patients with pancreatic ductal adenocarcinoma, exceeding a 90% success rate. Validation of eight samples confirmed maintenance of epithelial cell adhesion molecule expression and preservation of oncogenic KRAS mutations. Transcriptomic profiling revealed consistent upregulation of a six-gene signature (FAP, IGFBP5, PRRX1, SPARC, WNT5A, and ADAMTS12), which is associated with malignancy. In vitro drug sensitivity assays revealed interpatient heterogeneity with preliminary clinical associations. In conclusion, this simplified platform provides high-purity cancer cells and serves as a functional precision medicine tool. Beyond conventional chemotherapy, this platform has the potential to support applications ranging from biomarker validation and exploratory preclinical testing of novel therapeutics, including immune checkpoint inhibitors and antibody–drug conjugates. This optimization can lead to personalized therapeutic strategies for pancreatic cancer.

Redox regulation is a key mechanism supporting tumor survival and an attractive therapeutic target. In this study, we screened 1161 FDA-approved compounds to identify agents that induce reactive oxygen species (ROS) accumulation in head and neck squamous cell carcinoma (HNSCC) cells. Pimozide, a dopamine D2 receptor antagonist, emerged as the most potent ROS inducer. It selectively suppresses the growth of HNSCC cells with high oxidative stress resistance while exhibiting only modest effects on less resistant cells and normal keratinocytes. Notably, pimozide exhibited anti-tumor effects as a monotherapy and in combination with paclitaxel at clinically relevant doses. Mechanistic analysis revealed that pimozide rapidly induced ROS accumulation via a mechanism distinct from its known action on dopamine D2 receptors and STAT3/5. To identify markers of ROS-induced responses, we examined ROS-responsive genes and found that early growth response 1 (EGR1) was selectively induced in sensitive cells and correlated with pimozide responsiveness. Functional analysis revealed that EGR1 knockdown suppressed pimozide-induced cytotoxicity, suggesting its role as a functional pharmacodynamic marker of pimozide sensitivity. In a patient-derived xenograft model of HNSCC, pimozide significantly reduced the tumor burden alone and in combination with paclitaxel. While tumor volume reduction in the combination group was not statistically greater than that in the monotherapy group, fluorescence immunohistochemistry revealed a marked decrease in undifferentiated tumor cells, indicating enhanced therapeutic effects of combination treatment. Taken together, these findings indicate that pimozide is a promising candidate for repurposing as a novel therapeutic agent against HNSCC.

In the last decade, newly developed drugs have significantly improved the prognosis of patients with multiple myeloma (MM). However, most patients relapse sooner or later, and thus MM remains an incurable hematological malignancy. In addition, serious adverse events occasionally hamper the continuation of treatment. Exploitation of new drugs that potentiate antitumor activities and alleviate the adverse effects of existing drugs is needed. Here, we found through drug repositioning that ambroxol hydrochloride (ambroxol) induces apoptosis of MM cells. Interestingly, turnover and reporter assays revealed that ambroxol inhibits the late stage of autophagy. Transmission electron microscopy observation also revealed that MM cells treated with ambroxol accumulated autophagic vacuoles in the cytoplasm, further supporting the inhibition of late-stage autophagy. Existing anti-MM drugs demonstrate various effects on autophagy; panobinostat, a histone deacetylase inhibitor, induces autophagy, whereas bortezomib and lenalidomide do not. When administered together, ambroxol and panobinostat exhibited a synergistic antimyeloma effect, likely due to ambroxol inhibiting the activation of panobinostat-induced autophagy while downregulating MCL-1 expression. In the KMS11 xenograft model, ambroxol significantly delayed tumor growth when administered alone; when co-administered with panobinostat, ambroxol synergistically enhanced the panobinostat-induced inhibition of tumor growth. Interestingly, concomitant use of ambroxol and panobinostat alleviated panobinostat-induced diarrhea. Gene set enrichment and pathway analyses also revealed that ambroxol increased the expression of genes related to autophagy inhibition and unfolded protein response. These results suggested that autophagy is a promising therapeutic target for MM.

While the fallopian tube epithelium (FTE) is known to be composed of various differentiated cells such as secretory and ciliated cells, the upstream regulatory mechanisms of cell differentiation that are essential for tissue homeostasis remain under investigation. In this study, we established human FTE organoids and identified quiescent cells within the early organoid formation by observing cellular proliferation heterogeneity. We also analyzed two single-cell transcriptomic data to trace the differentiation trajectory in human FTE, and found that the gene LCN2 serves as a marker gene of early stage of the trajectory. Genetically manipulated FTE organoids indicated that LCN2 inhibits ferroptosis and promotes cell survival under oxidative stress. In addition, the FTE organoids introduced p53 dysfunction, the common genetic characteristics of high-grade serous carcinoma, showed upregulated LCN2 expression and enhanced ferroptosis resistance. This study provides insights into the LCN2-mediated protective mechanism of human FTE quiescent cells and its potential role in tumorigenesis.