This article has been reviewed according to Science X's editorial process and policies. Editors have highlighted the following attributes while ensuring the content's credibility:


peer-reviewed publication

trusted source


Scientists use new approach to disable brain cancer cells' ability to survive

Ben-Gurion University scientist hunts for drug candidate to treat brain tumors
The mTORC1 substrates 4EBP1/2 prevent cell death in response to glucose starvation in human, mouse and yeast cells. Credit: Nature Communications (2024). DOI: 10.1038/s41467-024-48386-y

When you disable the brakes on a race car, it quickly crashes. Dr. Barak Rotblat wants to do something similar to brain cancer cells. He wants to disable their ability to survive glucose starvation. In fact, he wants to speed the tumor cells up, so they just as quickly die out. It is a novel approach to brain cancer based on a decade of research in his lab.

He, his students and co-lead researcher Gabriel Leprivier of the Institute of Neuropathology at University Hospital Düsseldorf published their findings in Nature Communications last week.

Until now, it was believed that cancer cells prioritized growth and rapid proliferation. However, it has been shown that there is less in tumors vs. normal tissue.

If cancer cells are solely focused on reproducing at the fastest possible rate, then they should be more dependent on glucose than regular cells. However, what if their absolute top priority is survival rather than ? Then, triggering a burst of growth under glucose could lead to the cell running out of energy to survive and dying out.

"It is an intriguing insight that comes after a decade of research," explains Dr. Rotblat. "We may be able to target just the cancer cells and not regular cells at all, which would be a very promising step forward on the path to personalized medicine and therapeutics that do not affect healthy cells the way chemotherapy and radiation do."

"Our discovery about glucose starvation and the role of antioxidants opens a therapeutic window to pursue a molecule which could treat glioma (brain cancer)," he adds. Such a therapeutic might also be able to treat other types of cancers.

Rotblat and his students, Dr. Tal Levy and Dr. Khawla Alasad began by considering that cells regulate their growth according to their available energy. When energy is plentiful, cells make fat and lots of proteins to store energy and grow. When energy is scarce, they must pump the brakes and stop making fat and proteins or burn themselves out.

Tumors are mostly in a de facto state of glucose starvation. So, they began thinking about locating the molecular brakes that enable the cancer cell's survival in glucose starvation. If they could turn that off, then the tumor would die, but the regular cells, which are not glucose-starved, would remain unaffected.

So, Rotblat and his students followed the trail of a mTOR (Mamelian Target of Rapamycin) pathway. A pathway equipped with proteins that measure the energetic state of the cell and, accordingly, regulate . They found that a protein in the mTOR pathway, known to pump the brakes on when energy drops, 4EBP1, is essential for human, mouse, and even , to survive glucose starvation.

They demonstrated that 4EBP1 does so by negatively regulating the levels of a critical enzyme in the fatty acid synthesis pathway, ACC1. This mechanism is exploited by cancer cells, particularly cells, to survive in tumor tissue and generate aggressive tumors.

Dr. Rotblat is now working with BGN Technologies and the National Institute for Biotechnology in the Negev to develop a molecule that will block 4EBP1 forcing glucose-starved tumor cells to keep making fat and burn themselves out when they are glucose-starved.

More information: Tal Levy et al, mTORC1 regulates cell survival under glucose starvation through 4EBP1/2-mediated translational reprogramming of fatty acid metabolism, Nature Communications (2024). DOI: 10.1038/s41467-024-48386-y

Journal information: Nature Communications
Citation: Scientists use new approach to disable brain cancer cells' ability to survive (2024, May 20) retrieved 15 July 2024 from
This document is subject to copyright. Apart from any fair dealing for the purpose of private study or research, no part may be reproduced without the written permission. The content is provided for information purposes only.

Explore further

Novel role for metabolites in cellular metabolism discovered


Feedback to editors