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To treat glioblastoma, researchers focus on tumour vulnerabilities

"Our study increases our understanding of this type of cancer and proposes a different approach to treating it that will hopefully improve the prognosis of patients"
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From left to right: researchers Graham MacLeod, Fatemeh Molaei and Stéphane Angers, director of U of T’s Donnelly Centre for Cellular and Biomolecular Research (supplied images)

A team led by researchers at the ߲ݴý has uncovered new targets that could be the key to effectively treating glioblastoma, a lethal type of brain cancer.

The targets were identified through a screen for genetic vulnerabilities in patient-derived cancer stem cells that represent the variability found in tumours.

The study was .

“Glioblastoma tumors have evaded treatment thus far because their composition is highly variable both within and between tumours,” said Graham MacLeod, co-first author on the study and senior research associate at U of T’s Donnelly Centre for Cellular and Biomolecular Research.

“The tumours vary quite a bit from person to person, and even within a single tumour there are multiple cell types that harbour differences at the genetic level.”

Glioblastoma is the most common type of brain cancer in adults. It is also the most challenging to treat due to the resistance of glioblastoma cancer stem cells, from which tumours grow, to therapy. Cancer stem cells that survive after a tumour is treated go on to form new tumours that do not respond to further treatment.

A key finding of the research is that the variability among glioblastoma cancer stem cells can be observed across a gradient between two cell subtypes. On one end is the developmental subtype, which resembles cells in which normal neurodevelopment has gone awry. On the other is the injury-response subtype, which is an inflammatory state. The aim of the study was to identify potential treatment methods to target each subtype, thereby tackling tumours in a more holistic manner.

This study follows  that identified vulnerabilities in glioblastoma cancer stem cells that impact their sensitivity to chemotherapy. The next step was to study how vulnerabilities in glioblastoma cancer stem cells vary in a large and diverse set of patient-derived cell lines to identify the most common of these vulnerabilities in each of the subtypes.

The team performed screens in glioblastoma stem cell lines from 30 patients, making this the largest screening study of its kind. The patient-derived cell lines were generated by the lab of Peter Dirks, chief of the division of neurosurgery at SickKids and a U of T professor of surgery and molecular genetics in the Temerty Faculty of Medicine. Within the cancer stem cell samples, the team found genes responsible for the proliferation of the two cell subtypes that could be targeted to prevent tumour growth. Combining drugs to target both cell subtypes simultaneously could potentially make for a more effective glioblastoma treatment.

“A lot of the research on glioblastoma is conducted with a limited number of immortalized cell lines grown in serum,” said Fatemeh Molaei, co-first author on the study and graduate student at the Donnelly Centre and the Leslie Dan Faculty of Pharmacy. “These cells aren’t the best model as they don’t resemble true glioblastoma cells as much as we would like. The findings from our study represent what we see in a patient’s tumour more accurately because our cell lines are derived directly from a large group of patients. 

“It’s through our screens of this group of cell lines that we were able to identify the OLIG2 and MEK genes as drug targets for the developmental cell subtype and the FAK and B1-Integrin genes as targets for the injury-response subtype.”

Stéphane Angers, principal investigator on the study and director of the Donnelly Centre, said it had already been established that there are different subtypes of glioblastoma stem cells, but that their differences are not currently being addressed in the clinic.

“In the future, our results will help in designing new treatments that are tailored to patients by targeting the predominant cell subtype, or both subtypes simultaneously,” said Angers, who is also a professor in the Leslie Dan Faculty of Pharmacy and Temerty Faculty of Medicine. “The ability of glioblastoma to adapt to therapeutic treatment is its greatest strength and our biggest challenge. Our study increases our understanding of this type of cancer and proposes a different approach to treating it that will hopefully improve the prognosis of patients.”

This research was supported by the Canadian Institutes of Health Research.

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