Project description:To identify the therapeutic targets in a treatment-refractroy cancer patient, we performed single-cell RNA sequencing for 3,115 cells from primary bladder cancer (BC159-T#3) and patient-derived xenografts (BC159-T#3-PDX-vehicle and BC159-T#3-PDX-tipifarnib). Matched time-series bulk tumor tissues were also sequenced using whole exome target probe (WES) and whole transcriptome target probe (WTS).
Project description:To identify the therapeutic targets in a treatment-refractory cancer patient, we performed single-cell RNA sequencing for 3,115 cells from primary bladder cancer (BC159-T#3) and patient-derived xenografts (BC159-T#3-PDX-vehicle and BC159-T#3-PDX-tipifarnib). Matched time-series bulk tumor tissues were also sequenced using whole exome target probe (WES) and whole transcriptome target probe (WTS).
Project description:Purpose: While molecular targeted therapy has revolutionized the treatment of many cancers, little progress has been made in the development of novel therapies for muscle invasive bladder cancer (MIBC). Here we report on the establishment and characterization of patient-derived primary MIBC xenografts
Project description:Purpose: While molecular targeted therapy has revolutionized the treatment of many cancers, little progress has been made in the development of novel therapies for muscle invasive bladder cancer (MIBC). Here we report on the establishment and characterization of patient-derived primary MIBC xenografts Tumor fragments derived from 7 patients with MIBC were grafted under the renal capsule of NOD-SCID mice and subsequently transplanted to further mice over multiple generations. Patient tumor and xenograft tissue were processed for analysis of , gene expression by microarray, and expression of select potential target pathways by immunohistochemistry (IHC).
Project description:Bladder cancer is the fifth most prevalent cancer in the U.S., yet is understudied and relatively lacking in suitable models. Here we describe a biobank of patient-derived organoid lines that recapitulates the spectrum of human bladder cancer at the histopathological and molecular levels. Organoid lines can be established efficiently from patient biopsies, including from patients before and after disease recurrence, and are interconvertible with orthotopic xenografts. Notably, these organoid lines often retain tumor heterogeneity and exhibit changes in their mutational profiles that are consistent with tumor evolution in culture. Analyses of drug response using bladder tumor organoids show partial correlations with mutational profiles as well as changes associated with treatment resistance, and specific responses can be validated using xenografts in vivo. Overall, our studies indicate that patient-derived bladder tumor organoids represent a model system for studying tumor evolution and treatment response in the context of precision cancer medicine.
