Scientists have shown for the first time that immune cells in the urine of bladder cancer patients accurately reflect those in the tumour environment, according to research* published today (Wednesday) in the Journal of Experimental Medicine.
Unexpectedly, the Cancer Research UK-funded study showed that immune cells found in the urine were more representative of the tumour than immune cells from the blood, suggesting that urine, rather than blood liquid biopsies, could help to more accurately monitor response to immunotherapy in patients.
Immunotherapy has shown success in patients with advanced bladder cancer and is approved** in the UK for certain patients. Despite this, only around a quarter of patients respond to immune checkpoint-targeting drugs, demonstrating a pressing need to better understand the immune landscape of bladder cancer and develop new therapeutics.
The study, which was also supported by the National Institute for Health Research, looked at 32 patients with bladder cancer that had invaded the muscle wall. Urine and blood samples were taken on the day of surgery to remove their tumour, and these were compared with both their tumour and healthy bladder tissue.
The researchers at University College London (UCL) Cancer Institute and UCL Hospitals were able to identify T cells in the urine, which are usually absent in healthy individuals. Crucially, the T cells matched those found within the tumour environment of the bladder cancer, regardless of cancer stage and treatment history.***
Dr Sophia Wong, co-lead author from UCL, said: "Our results show for the first time that urine liquid biopsies can be used as a non-invasive window into the bladder tumour environment. This valuable information could be used to discover immunotherapy targets and aid the design of combination treatments that exploit different components of the immune system.
"This research looked at a single time point, so clinical trials that include urine analysis over time are now needed to find out whether urine-derived T cells could tell us if a patient is responding to treatment, or be an early warning that a switch in therapy is required."
The study also identified a relationship between urine-derived T cells and patients' chance of survival, as the disease was more likely to return in people with higher numbers of these cells. This indicates that urine-derived T cells may therefore also serve as a prognostic marker.
There are around 10,300 people in the UK diagnosed with bladder cancer every year. And it can be difficult to treat; just more than half (53%) of patients survive their disease for 5 years or more.
Professor Peter Johnson, an immunotherapy expert at the Cancer Research UK Southampton Centre, said: "Immunotherapy holds great promise for cancers that are difficult to treat, but a greater knowledge of the complex immune system is required to unlock their potential. By using a non-invasive urine test to profile the bladder cancer immune landscape, this small study could help us understand why only a fraction of patients respond to immunotherapy.
"If the findings are supported by larger studies, this early research suggests that urine liquid biopsies could one day help stratify patients for immunotherapy, identifying those most likely to benefit, while sparing unnecessary treatment in those who likely won't."
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For media enquiries contact Dr Justine Alford in the Cancer Research UK press office on 020 3469 8456 or, out of hours, on 07050 264 059.
Notes to editor:
* Wong et al. Urine-derived lymphocytes as a non-invasive measure of the bladder tumor immune microenvironment. Journal of Experimental Medicine.
** Pembrolizumab (Keytruda) and atezolizumab (Tecentriq) are available through the Cancer Drugs Fund for some patients with locally advanced or metastatic bladder cancer.
*** This included the checkpoint molecules PD-1 and CTLA-4, which are targeted by approved immunotherapy drugs, and others such as TIM-3 which are being evaluated in early clinical trials.
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Journal
Journal of Experimental Medicine