Like a criminal entering a witness protection program, cancer cells can shed their past and take on a new identity. Detecting such an identity switch is particularly challenging when metastatic castration-resistant prostate cancer (CRPC) advances from adenocarcinoma to neuroendocrine prostate cancer (NEPC), a very difficult cancer to treat.
Now, however, researchers at Dana-Farber Cancer Institute and the University of Trento, Italy, have developed a blood test, described in Cancer Discovery, that can reliably detect NEPC and differentiate it from CRPC-adenocarcinoma (CRPC-adeno).
NEPC is currently diagnosed using a biopsy of tumour tissue from a metastatic tumour site. Yet, it isn’t always clear to clinicians when to do a biopsy. Further, biopsies may be unreliable since metastatic tumours are often heterogeneous.
“As prostate cancer treatments get more effective, we expect the emergence of different types of treatment resistance like neuroendocrine prostate cancer that help them evade treatment,” says co-lead author Himisha Beltran, MD, associate professor of medicine, Lank Center for Genitourinary Oncology and the Division of Molecular and Cellular Oncology, Dana-Farber Cancer Institute. “We hope this blood test can be used by clinicians to determine if a patient is developing neuroendocrine prostate cancer.”
Approximately 10-15% of patients with metastatic prostate cancer develop NEPC. The transition involves a shift from cancer cells that are dependent on hormones called androgens to cancer cells that no longer even recognize androgens.
“They can stop expressing the androgen receptor,” says Beltran. “They shut down their hormone-driven identity and they turn on a new identity as a way to develop resistance to treatment.”
In previous research, the international team studied tissue samples from biopsies to identify the genetic and epigenetic changes related to this transition. They found that, across the whole genome, specific epigenetic changes, in the form of DNA methylation changes that switch genes on or off, distinguish CRPC-adeno from NEPC.
These epigenetic changes can be detected in blood because the body is constantly shedding fragments of dead cells into the bloodstream. Those cells come from all over the body, including from tumours. The fragments include bits of DNA, called cell-free DNA (cfDNA), along with whatever epigenetic tags and structures were attached to them when the cell died.
Beltran collaborated with a computational team at the University of Trento, led by Francesca Demichelis, PhD, co-lead author on the study, to create a blood panel test, called NEMO (NEuroendocrine MOnitoring panel). “The test selectively probes cfDNA in blood plasma for relevant DNA fragments and measures their methylation,” says Demichelis. “Because the number of methylated regions needed to distinguish between normal, CRPC-adeno, and NEPC cells is small, the panel of genes sequenced by the test is minimal and efficient.”
NEMO reports two measures: the tumour fraction, a measure of disease burden based on the ratio of tumour DNA to normal DNA in the blood; and the tumour type, either CRPC-adeno or NEPC. The tumour type is reported as a score on a continuum because a patient’s cancer might be a mix of the two.
“It not only picks up the neuroendocrine phenotype but also can pick up subtypes in the middle, as tumours transition from one subtype to the other,” says Beltran.
Beltran’s team tested NEMO in several preclinical models of prostate cancer and in blood samples from multiple patient cohorts with known prostate cancer subtypes. The NEMO tumor type score identified subtypes with a high level of accuracy.
The team also evaluated NEMO in two clinical trials of patients with aggressive CRPC. The panel’s estimation of tumour fraction was consistent with other accepted measures of disease burden, suggesting that the test could be used to monitor response to treatment by revealing if a tumour is shrinking or not. This is especially valuable because, measures of disease burden, such as prostate-specific antigen levels, become unreliable when a tumour switches its identity to NEPC.
NEMO successfully identified patients with NEPC in the two clinical trials based on pathology reports. It also identified patients who had not been diagnosed with NEPC yet had signs of a transition to NEPC in their pathology reports.
“Now that we have robustly shown the accuracy of this panel test, we’re excited to apply it to clinical questions,” says Beltran. “We’d like to determine if this test can help us predict which patients respond to certain prostate cancer treatments, including precise treatments that target neuroendocrine prostate cancer.”
The information in a NEMO panel may also help clinicians select targeted treatments for patients or help investigators learn more about the disease. Further, adds Beltran, the test’s approach could potentially be applied to other forms of cancer to distinguish subtypes.
Longer term, Beltran and colleagues will take steps toward transitioning NEMO into a clinical test that physicians can order and use in practice.
Funding: The Prostate Cancer Foundation, National Cancer Institute, Fondazione AIRC per la Ricerca sul Cancro ETS, Cancer Research UK, United States Department of Defense, the Doris Duke Foundation, the Safeway Foundation, the V Foundation, and the Institute for Prostate Cancer Research.
Source: Dana-Farber Cancer Institute
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