FGFR3, HRAS, KRAS, NRAS and PIK3CA Mutations in Bladder Cancer and Their Potential as Biomarkers for Surveillance and Therapy

Background: Fifty percent of patients with muscle-invasive bladder cancer (MI-BC) die from their disease and current chemotherapy treatment only marginally increases survival. Novel therapies targeting receptor tyrosine kinases or activated oncogenes may improve outcome. Hence, it is necessary to stratify patients based on mutations in relevant oncogenes. Patients with non-muscle-invasive bladder cancer (NMI-BC) have excellent survival, however two-thirds develop recurrences. Tumor specific mutations can be used to detect recurrences in urine assays, presenting a more patient-friendly diagnostic procedure than cystoscopy. Methodology/Principal Findings: To address these issues, we developed a mutation assay for the simultaneous detection of 19 possible mutations in the HRAS, KRAS, and NRAS genes. With this assay and mutation assays for the FGFR3 and PIK3CA oncogenes, we screened primary bladder tumors of 257 patients and 184 recurrences from 54 patients. Additionally, in primary tumors p53 expression was obtained by immunohistochemistry. Of primary tumors 64% were mutant for FGFR3, 11% for RAS, 24% for PIK3CA, and 26% for p53. FGFR3 mutations were mutually exclusive with RAS mutations (p = 0.001) and co-occurred with PIK3CA mutations (p = 0.016). P53 overexpression was mutually exclusive with PIK3CA and FGFR3 mutations (p≤0.029). Mutations in the RAS and PIK3CA genes were not predictors for recurrence-free, progression-free and disease-specific survival. In patients presenting with NMI-BC grade 3 and MI-BC, 33 and 36% of the primary tumors were mutant. In patients with low-grade NMI-BC, 88% of the primary tumors carried a mutation and 88% of the recurrences were mutant. Conclusions/Significance: The mutation assays present a companion diagnostic to define patients for targeted therapies. In addition, the assays are a potential biomarker to detect recurrences during surveillance. We showed that 88% of patients presenting with low-grade NMI-BC are eligible for such a follow-up. This may contribute to a reduction in the number of cystoscopical examinations

Pharmacokinetics of intravesical gemcitabine: a preclinical study in pigs.

INTRODUCTION: Gemcitabine is a deoxycytidine analogue, used intravenously in the treatment of several tumours, including transitional cell carcinoma of the bladder. It has been shown to be effective and well tolerated when given systemically. We investigated the use of this agent administered intravesically in pigs for histological studies of the bladder and pharmacokinetic research. MATERIAL AND METHODS: Two groups of 5 female pigs each received once 175mg and 350mg gemcitabine intravesically for 2 hours. A third group of 5 pigs received 350mg gemcitabine weekly for 6 weeks. Animals were observed for clinical signs of toxicity. Blood was withdrawn for gemcitabine pharmacokinetics and in group 3 also for peripheral blood counts. The animals were euthanized 24 hours after (the last) instillation. Histological examination of the bladder wall was performed. RESULTS: Doses of 175 and 350mg gemcitabine were well tolerated. The animals showed no signs of deterioration of their well-being. Peripheral blood counts showed no signs of immunosuppression in the third group. In none of the pigs systemic absorption was seen, up to 4 hours after the beginning of instillation. Histology showed in all cases normal bladder wall histology, except for some cases with mild signs of infection (mainly group 3). CONCLUSION: The use of gemcitabine as an intravesical agent in pigs is well tolerated, has no bladder toxicity and is not absorbed systemically

Cellular origin of bladder neoplasia and tissue dynamics of its progression to invasive carcinoma

Understanding how malignancies arise within normal tissues requires identification of the cancer cell of origin and knowledge of the cellular and tissue dynamics of tumor progression. Here we examine bladder cancer in a chemical carcinogenesis model that mimics muscle-invasive human bladder cancer. With no prior bias regarding genetic pathways or cell types, we prospectively mark or ablate cells to show that muscle-invasive bladder carcinomas arise exclusively from Sonic hedgehog (Shh)-expressing stem cells in basal urothelium. These carcinomas arise clonally from a single cell whose progeny aggressively colonize a major portion of the urothelium to generate a lesion with histological features identical to human carcinoma-in-situ. Shh-expressing basal cells within this precursor lesion become tumor-initiating cells, although Shh expression is lost in subsequent carcinomas. We thus find that invasive carcinoma is initiated from basal urothelial stem cells but that tumor cell phenotype can diverge significantly from that of the cancer cell-of-origin

An evolutionary perspective on field cancerization

The authors acknowledge funding from Cancer Research UK (grants A19771 to T.A.G. and A21870 to N.A.W.), the Wellcome Trust (202778/Z/16/Z t