Cell-type Specific Protoporphyrin IX Metabolism in Human Bladder Cancer in vitro

5-Aminolevulinic acid (ALA)–supported fluorescence endoscopy of the urinary bladder results in a detection rate of bladder cancer superior to that of white light endoscopy. The different accumulation of the metabolite protoporphyrin IX (PPIX) in tumor cells after ALA instillation is poorly understood; however, it is crucial to optimize diagnosis and potential phototherapy. For systematic analysis of cell-type specific PPIX accumulation and metabolism two human bladder carcinoma cell lines (RT4 and J82), a normal urothelial cell line (UROtsa), and a fibroblast cell line (N1) were chosen, and grown in two different growth states to model important tissue components of the urinary bladder, i.e. tumor, normal epithelium and stroma. To quantitate PPIX content, fluorescence intensities measured by flow cytometry were matched with cellular PPIX extraction values, and related to relative ferrochelatase activity, cellular iron content, number of transferrin receptors per cell and porphobilinogen deaminase (PBGD) activity. For in vitro experiments, the initial correlation of relative flow cytometric and spectrometric measurements of PPIX provides a calibration curve for consequent flow cytometric PPIX quantification. Lower fluorescence of normal cells could be explained by significant differences of ferrochelatase activity and iron content in comparison to tumor cells. However, the content of iron was not related to transferrin receptor content. PBGD activity seemed to play a minor role for the differential accumulation of PPIX in urothelial cells. In conclusion, the in vitro culture of urothelial cells and fibroblasts indicates that the most important metabolic step for PPIX accumulation in the urinary bladder is the transition from PPIX to heme. Further investigation of PPIX metabolism does support the validation of photodynamic diagnosis, and might also lead the way to a highly specific tumor related molecule

No evidence for involvement of beta-catenin and APC in urothelial carcinomas

The wnt pathway plays an important role in embryonal patterning and cell fate determination, involving stabilization of nuclear and cytoplasmic beta-catenin (CTNNB1) mediated by APC, axin, and other proteins. Uncomplexed beta-catenin binds to TCF/LEF transcription factors and activates the expression of growth regulatory target genes such as c-myc or cyclin D1. In colorectal and other cancers, constitutive wnt signaling results frequently from mutations in one or more pathway components, e.g. APC and beta-catenin, resulting in nuclear and/or cytoplasmic accumulation of beta-catenin. In the present study, the most frequent alterations in the CTNNB1 and APC genes were investigated in primary urothelial bladder tumors and cell lines. Snap-frozen bladder tumors (n=99) of different stages and grades and 4 cell lines (RT4, RT112, J82, UROtsa) were investigated for APC allelic deletions by loss of heterozygosity (LOH) analysis. The most frequent mutated regions of CTNNB1 (degradation box in the third exon) and APC (mutation cluster region) were directly sequenced. Beta-catenin expression was analyzed by immunofluorescence in the cell lines. LOH at the APC gene locus on chromosome 5q21 was found in 7 of 72 (10%) of the informative cases. No mutations were found in either CTNNB1 or APC. A previously described polymorphism at codon 1493 of the APC gene was detected in 8 tumors and 3 cell lines. All cell lines showed normal membranous beta-catenin staining without evidence for nuclear or cytoplasmic accumulation. Alteration of APC and beta-catenin, which are the most frequent wnt pathway alterations in many tumor types, are rare events in urothelial carcinomas. Other wnt pathway members, such as axin, may play an important role in urothelial carcinogenesis