Glioblastoma brain tumors are especially perplexing. Inevitably lethal, the tumors occasionally respond to new immunotherapies after they’ve grown back, enabling up to 20% of patients to live well beyond predicted survival times.
What causes this effect has long been the pursuit of researchers hoping to harness immunotherapies to extend more lives.
New insights from a team led by Duke’s Preston Robert Tisch Brain Tumor Center, including Katherine Peters, MD, PhD, Dina Randazzo, DO, and Annick Desjardins, MD provide potential answers. The team found that recurring glioblastoma tumors with very few mutations are far more vulnerable to immunotherapies than similar tumors with an abundance of mutations.
The finding, appearing online Jan. 13 in the journal Nature Communications, could serve as a predictive biomarker to help clinicians target immunotherapies to those tumors most likely to respond. It could also potentially lead to new approaches that create the conditions necessary for immunotherapies to be more effective.
“It’s been frustrating that glioblastoma is incurable and we’ve had limited progress improving survival despite many promising approaches,” said senior author David Ashley, MD, PhD, professor in the departments of Neurosurgery, Medicine, Pediatrics and Pathology at Duke University School of Medicine.
“We’ve had some success with several different immunotherapies, including the poliovirus therapy developed at Duke,” Ashley said. “And while it’s encouraging that a subset of patients who do well when the therapies are used to treat recurrent tumors, about 80% of patients still die.”
Ashley and colleagues performed genomic analyses of recurrent glioblastoma tumors from patients treated at Duke with the poliovirus therapy as well as others who received so-called checkpoint inhibitors, a form of therapy that releases the immune system to attack tumors.
In both treatment groups, patients with recurrent glioblastomas whose tumors had few mutations survived longer than the patients with highly mutated tumors. This was only true, however, for patients with recurrent tumors, not for patients with newly diagnosed disease who had not yet received treatment.
“This suggests that chemotherapy, which is the standard of care for newly diagnosed glioblastoma, might be altering the inflammatory response in these tumors,” Ashley said, adding that chemotherapy could be serving an important role as a primer to trigger an evolution of the inflammation process in recurrent tumors.
Ashley said the finding in glioblastoma could also be relevant to other types of tumors, including kidney and pancreatic cancers, which have similarly shown a correlation between low tumor mutations and improved response to immunotherapies.
In addition to Ashley, study authors include Matthias Gromeier, Michael C. Brown, Gao Zhang, Xiang Lin, Yeqing Chen, Zhi Wei, Nike Beaubier, Hai Yan, Yiping He, Annick Desjardins, James E. Herndon II, Frederick S. Varn, Roel G. Verhaak, Junfei Zhao, Dani P. Bolognesi, Allan H. Friedman, Henry S. Friedman, Frances McSherry, Andrea M. Muscat, Eric S. Lipp, Smita K. Nair, Mustafa Khasraw, Katherine B. Peters, Dina Randazzo, John H. Sampson, Roger E. McLendon and Darell D. Bigner.
The study received support from The Brain Tumor Research Charity, Jewish Communal Fund, Circle of Service Foundation, Uncle Kory Foundation, Department of Defense (W81XWH-16-1-0354) and the National Institutes of Health (R35CA197264, P01CA154291, P50CA190991, R01NS108773, R01NS099463, R21NS112899, P01CA225622, F32CA224593). Support was also received through the Angels Among Us fundraising event and a gift from the Asness Family.
Authors Gromeier, Brown, Desjardins, Bolognesi, Henry Friedman, Nair, Sampson, Bigner and Ashley own intellectual property related to the poliovirus therapy, which has been licensed to Istari Oncology, Inc. Gromeier, Desjardins, Bolognesi, Allan Friedman, Henry Friedman and Bigner hold equity in Istari Oncology, Inc. Additional disclosures are provided in the published study.
This story originally appeared on the Duke Health website. View it in its original location here.