Glioblastoma multiforme (GBM) remains the most difficult of all brain cancers to study and treat, largely because of tumor heterogeneity. Treatment approaches, like surgery, radiation and chemotherapy, along with newer personalized cellular therapies, have proven to slow tumor growth and keep patients disease-free for some periods of time; however, a cure remains elusive.
“While we’ve made important strides in glioblastoma research, preclinical and clinical challenges persist, keeping us from getting closer to more effective treatments,” said senior author Hongjun Song, PhD, Perelman Professor of Neuroscience in the Perelman School of Medicine at the University of Pennsylvania. “One hurdle is the ability to recapitulate the tumor to not only better understand its complex characteristics, but also to determine what therapies post-surgery can fight it in a timelier manner.”
Co-senior authors include Guo-li Ming, MD, PhD, Perelman Professor of Neuroscience, and Donald O’Rourke, MD, the John Templeton, Jr., MD Professor in Neurosurgery, and director of the GBM Translational Center of Excellence at Penn’s Abramson Cancer Center.
Lab-grown brain organoids — derived from human pluripotent stem cells or patient tissues and grown to a size no bigger than a pea — can recapitulate important genetic composition, brain cell type heterogeneity, and architecture, for example. These models are allowing researchers to recreate key features of patients’ diseased brains to help paint a clearer picture of their cancer, and allowing them to explore ways to best attack it.
What makes organoids so attractive in GBM is timing and the ability to maintain cell type and genetic heterogeneity. While existing in vitro models have added to researchers’ understanding of the biological mechanisms underlying the cancer, they have limitations. Unlike other models, which need more time to exhibit gene expression and other histological features that more closely represent the tumor, brain tumor organoids developed by the research group grow into use much more rapidly. That’s important because current treatment regimens are typically initiated one month following surgery, so having a road map sooner is more advantageous.
In the new study, the researchers removed fresh tumor specimens from 52 patients to “grow” corresponding tumor organoids in the lab. The overall success rate for generating glioblastoma organoids (GBOs) was 91.4 percent, with 66.7 percent of tumors expressing the IDH1 mutation, and 75 percent for recurrent tumors, within two weeks. These tumor glioblastoma organoids can also be biobanked and recovered later for analyses.
Genetic, histological, molecular analyses were also performed in 12 patients to establish that these new GBOs had largely retained features from the primary tumor in the patient.
Eight GBO samples were then successfully transplanted into adult mouse brains, which displayed rapid and aggressive infiltration of cancer cells and maintained key mutation expression up to three months later. Importantly, a major hallmark of GBM — the infiltration of tumor cells into the surrounding brain tissue — was observed in the mouse models.
To mimic post-surgery treatments, the researchers subjected GBOs to standard-of-care and targeted therapies, including drugs from clinical trials and chimeric antigen receptor T (CAR-T) cell immunotherapy. For each treatment, researchers showed that the organoid responses are different and effectiveness is correlated to their genetic mutations in patient tumors. This model opens the possibility for future clinical trials for personized treatment based on individual patient tumor responses to various different drugs.
Notably, the researchers observed a benefit in the organoids treated with CAR T therapies, which have been used in ongoing clinical trials to target the EGFRvIII mutation, a driver of the disease. In six GBOs, the researchers showed specific effect to patient GBOs with the EGFRvIII mutation with an expansion of CAR T cells and reduction in EGFRvIII expressing cells.
“These results highlight the potential for testing and treating glioblastomas with a personalized approach. The ultimate goal is to work towards a future where we can study a patient’s organoid and test which CAR T cell is going to be the best against their tumor, in real time.” O’Rourke said. “A shorter-term goal, given the heterogeneity of glioblastomas, is that in vitro testing of various therapeutic options may also help refine patient enrollment in clinical trials, by more accurately defining mutations and selecting the appropriate, available targeted therapies for each.”
Co-authors include Fadi Jacob, Ryan D. Salinas, Daniel Y. Zhang, Phuong T.T. Nguyen, Jordan G. Schnoll, Samuel Zheng Hao Wong, Radhika Thokala, Saad Sheikh, Deeksha Saxena, Stefan Prokop, Di-ao Liu, Xuyu Qian, Dmitriy Petrov, Timothy Lucas, H. Isaac Chen, Jay F. Dorsey, Kimberly M. Christian, Zev A. Binder, MacLean Nasrallah, and Steven Brem.
This work was partially supported by Glioblastoma Translational Center of Excellence at the Abramson Cancer Center, grants from National Institutes of Health (R37NS047344, R35NS097370, U19AI131130), the Sheldon G. Adelson Medical Research Foundation, a Blavatnik Family Fellowship in Biomedical Research, and a Hearst Foundation Fellowship.
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