High-performance detection of somatic D-loop mutation in urothelial cell carcinoma patients by polymorphism ratio sequencing.

UNLABELLED: Utilizing a polymorphism ratio sequencing platform, we performed a complete somatic mutation analysis of the mitochondrial D-loop region in 14 urothelial cell carcinomas. A total of 28 somatic mutations, all heteroplasmic, were detected in 8 of 14 individuals (57.1 %). Insertion/deletion changes in unstable mono- and dinucleotide repeat segments comprise the most pervasive class of mutations (9 of 28), while two recurring single-base substitution loci were identified. Seven variants, mostly insertion/deletions, represent population shifts from a heteroplasmic germline toward dominance in the tumor. In four cases, DNA from matched urine samples was similarly analyzed, with all somatic variants present in associated tumors readily detectable in the bodily fluid. Consistent with previous findings, mutant populations in urine were similar to those detected in tumor and in three of four cases were more prominent in urine. KEY MESSAGES: PRS accurately detects high mtDNA mutations in UCCs and their body fluids. mtDNA mutations are universally heteroplasmic and often appear at low levels. The PRS technology could be a viable approach to develop mitochondrial biomarkers.

Detection of mitochondrial deoxyribonucleic acid alterations in urine from urothelial cell carcinoma patients.

Our study aims at understanding the timing and nature of mitochondrial deoxyribonucleic acid (mtDNA) alterations in urothelial cell carcinoma (UCC) and their detection in urine sediments. The entire 16.5 kb mitochondrial genome was sequenced in matched normal lymphocytes, tumor and urine sediments from 31 UCC patients and compared to different clinical stages and histological grades. The mtDNA content index was examined in all the specimens. Sixty-five percent (20/31) of the patients harbored at least 1 somatic mtDNA mutation. A total of 25 somatic mtDNA mutations were detected, which were more frequent in the respiratory complex coding regions (Complex I, III, IV and V) of the mtDNA and significantly affected respiratory Complex III compared to the other complexes (p = 0.021-0.039). Compared to Stage Ta, mtDNA mutation was higher in Stage T1 and significantly higher in Stage T2 (p = 0.01) patients. MtDNA mutation was also significantly higher (p = 0.04) in Stage T2 compared to Stage T1 patients. Ninety percent (18/20) of the patients harboring mtDNA mutation in the tumor also had mutation in their urine sediments. Eighty percent (20/25) of the tumor-associated mtDNA mutations was detectable in the urine sediments. Compared to the normal lymphocytes, the mtDNA content increased significantly in the tumor (p = 0.0013) and corresponding urine sediments (p = 0.0025) in 19/25 (76%) patients analyzed. Our results indicate that mtDNA alterations occur frequently in progressive stages of UCC patients and are readily detectable in the urine sediments. MtDNA mutations appear to provide a promising tool for developing early detection and monitoring strategies for UCC patients.