Field Cancerization Is Associated with Tumor Development, T-cell Exhaustion, and Clinical Outcomes in Bladder Cancer

Bladder field cancerization may affect tumor biology and disease recurrence rates. Urinary measurements have potential for real-time assessment of treatment response and bladder disease status. Field cancerization is characterized by areas of normal tissue affected by mutated clones. Bladder field c...

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Published in:European urology 2024-01, Vol.85 (1), p.82-92
Main Authors: Strandgaard, Trine, Nordentoft, Iver, Birkenkamp-Demtröder, Karin, Salminen, Liina, Prip, Frederik, Rasmussen, Julie, Andreasen, Tine Ginnerup, Lindskrog, Sia Viborg, Christensen, Emil, Lamy, Philippe, Knudsen, Michael, Steiniche, Torben, Jensen, Jørgen Bjerggaard, Dyrskjøt, Lars
Format: Article
Language:English
Subjects:
Adjuvants, Immunologic - therapeutic use
Administration, Intravesical
Bacillus Calmette-Guérin
BCG Vaccine - therapeutic use
Biomarkers
Bladder cancer
Disease Progression
Disease-Free Survival
Field cancerization
Field effect
Humans
Neoplasm Invasiveness
Neoplasm Recurrence, Local - pathology
Non-Muscle Invasive Bladder Neoplasms
Proteomics
T-Cell Exhaustion
Urinary Bladder Neoplasms - drug therapy
Urinary Bladder Neoplasms - therapy
Urinary tumor DNA
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Summary:Bladder field cancerization may affect tumor biology and disease recurrence rates. Urinary measurements have potential for real-time assessment of treatment response and bladder disease status. Field cancerization is characterized by areas of normal tissue affected by mutated clones. Bladder field cancerization may explain the development and recurrence of bladder cancer and may be associated with treatment outcomes. To investigate the predictive and prognostic roles of field cancerization in patients with high-risk non–muscle-invasive bladder cancer (NMIBC) treated with bacillus Calmette-Guérin (BCG). We conducted comprehensive genomic and proteomic analyses for 751 bladder biopsies and 234 urine samples from 136 patients with NMIBC. The samples were collected at multiple time points during the disease course. Field cancerization in normal-appearing bladder biopsies was measured using deep-targeted sequencing and error correction models. Endpoints included the rates of recurrence and progression. Cox regression and Wilcoxon rank-sum and Fisher’s exact tests were used. A high level of field cancerization was associated with high tumor mutational burden (p = 0.007), high tumor neoantigen load (p = 0.029), and high tumor-associated CD8 T-cell exhaustion (p = 0.017). In addition, high field cancerization was associated with worse short-term outcomes (p = 0.029). Nonsynonymous mutations in bladder cancer–associated genes such as KDM6A, ARID1A, and TP53 were identified as early disease drivers already found in normal-appearing bladder biopsies. Urinary tumor DNA (utDNA) levels reflected the bladder tumor burden and originated from tumors and field cancerization. High levels of utDNA after BCG were associated with worse clinical outcomes (p = 0.027) and with disease progression (p = 0.003). High field cancerization resulted in high urinary levels of proteins associated with angiogenesis and proliferation. Limitations include variation in the number of biopsies and time points analyzed. Field cancerization levels are associated with tumor development, immune responses, and clinical outcomes. utDNA measurements can be used to monitor disease status and treatment response. Molecular changes in the tissue lining the bladder result in tumor recurrence. Urinary measurements may be used to monitor bladder cancer status and treatment responses.
ISSN:0302-2838
1873-7560
1873-7560
DOI:10.1016/j.eururo.2023.07.014