Tumor markers can reveal lethality of bladder cancers, guide treatment

Tumor cells collected during the removal of a cancerous bladder and in some cases transplanted into mice with weakened immune systems, could help physicians rapidly identify high-risk cancers, determine prognosis and refine the use of biomarkers to personalize care for patients with this common cancer, according to a study published online on Oct. 24, 2016, in Scientific Reports (one of the Nature journals) by researchers from the Ludwig Center at the University of Chicago.

The researchers found that detection of poorly differentiated basal tumor cells in early stage cancers; overexpression in those cells of a gene known as cell division cycle 25C, which plays a key role in the regulation of cell division; or the ability of tumor fragments to grow when transplanted into a mouse, all predicted an increased risk of death.

"If confirmed in larger studies, our findings could help physicians get a better handle on how a patient's bladder cancer is likely to progress and allow them to personalize treatment based on that knowledge," said study author Ralph Weichselbaum, MD, the Daniel K. Ludwig Distinguished Service Professor of Radiation and Cellular Oncology and Chair of the Department of Radiation and Cellular Oncology at the University.

Bladder cancer is the fourth most common cause of cancer-related death among men in the United States. More than 75,000 new cases will be diagnosed this year and more than 16,000 people will die from this disease. Weichselbaum and colleagues obtained tumor samples from 71 bladder cancer patients treated at the University and used flow cytometry to isolate and count specific subtypes of tumor cells in each sample. They showed that an excess of one relatively rare subtype in early-stage cancers, the basal tumor cell (BTC), was associated with a 3-fold increase in risk of death.

Analyzing the global expression of genes in BTCs, the researchers also identified a potentially prognostic biomarker for bladder cancer: cell division cycle 25C (CDC25C), a protein that drives cell division. An expanded analysis, including 400 bladder cancer patients, found that the expression of this protein is associated with an increased risk of death even after the removal of the cancerous bladder.

This association disappeared in patients who had previously received chemotherapy. A test for CDC25C could, the authors suggest, help determine whether a bladder cancer patient is likely to benefit from drug treatment.

In more invasive tumors, the presence and number of BTCs had less prognostic value. When the researchers injected bladder-cancer tissue fragments from 69 patients with more advanced cancers into the flanks of immune-deficient mice, however, about 60 percent of these tumor fragments were able to take hold and grow in this setting. This was associated with a 6-fold increase in risk of death, compared to tumor fragments that did not survive and grow after transplantation.

"Prognostic knowledge can change a lot about how you choose to treat a cancer," said Weichselbaum. "We may be able to avoid aggressive measures if we find a tumor has relatively few basal cells," he said. "We could treat an early-stage bladder cancer with less aggressive therapy, avoiding debilitating interventions like radical cystectomy. But if a bladder tumor has a lot of basal cells, we may need to take the entire bladder out and follow that with chemotherapy.

Before this can happen, he added, the accuracy of his team's new prognostic model and biomarker "will need to be confirmed in larger studies."


The study was supported by Ludwig Cancer Research, Rosalind and Burton Spellman Family Cancer Fund, The Foglia Foundation and Mr. and Ms. Vincent Foglia. Additional authors were K. B. Skowron, S. P. Pitroda, J. P. Namm, O. Balogun, M. A. Beckett, M. L. Zenner, O. Fayanju, X. Huang, C. Fernandez, W. Zheng, G. Qiao, R. Chin, S. J. Kron, N. N. Khodarev, M. C. Posner and G. D. Steinberg.

John Easton
John Easton

John Easton is a senior science writer at UChicago Medicine.