Après 7 ans de recherche, des scientifiques ont découvert un nouveau traitement pour les tumeurs cérébrales dévastatrices.

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Brain Cancer Tumor Illustration

Illustration d'une tumeur du cancer du cerveau

Les résultats d’un projet de recherche de sept ans suggèrent qu’il pourrait y avoir une nouvelle approche pour traiter l’une des formes les plus courantes et les plus dévastatrices de cancer du cerveau chez les adultes – le glioblastome multiforme (GBM).

Dans une étude évaluée par des pairs et publiée dans BMC Cancer, des scientifiques de l’Université de Surrey démontrent qu’une courte chaîne de

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;” data-gt-translate-attributes=”[{” attribute=””>amino acids (the HTL-001 peptide) is effective in targeting and inhibiting the function of a family of genes responsible for Glioblastoma Multiforme (GBM) growth – Hox genes. The research was carried out in cell and animal models.

The HTL-001 peptide tested in the study has completed safety testing and is ready for patient trials. These trials are now being considered in GBM and other cancers.

According to Hardev Pandha, project lead and Professor of Medical Oncology at the University of Surrey, “People who suffer from Glioblastoma Multiforme have a five percent survival rate over a five-year period – a figure that has not improved in decades. While we are still early in the process, our seven-year project offers a glimmer of hope for finding a solution to Hox gene dysregulation, which is associated with the growth of GBM and other cancers, and which has proven to be elusive as a target for so many years.”

Ironically, Hox genes are responsible for the healthy growth of brain tissue but are ordinarily silenced at birth after vigorous activity in the growing embryo. However, if they are inappropriately ‘switched on’ again, their activity can lead to the progression of cancer. Hox gene dysregulation has long been recognized in GBM.

The project was carried out in collaboration with the universities of Surrey, Leeds and Texas, and HOX Therapeutics, a University of Surrey start-up company based on the University’s Surrey Research Park.

Professor Susan Short, co-author of the study from the University of Leeds, said “We desperately need new treatment avenues for these aggressive brain tumors. Targeting developmental genes like the HOX genes that are abnormally switched on in the tumor cells could be a novel and effective way to stop glioblastomas growing and becoming life-threatening.”

James Culverwell, CEO of HOX Therapeutics, stated “HOX Therapeutics is excited to be associated with this project and we hope that with our continuing support, this research will eventually lead to novel and effective treatments for both brain and other cancers where HOX gene over-expression is a clear therapeutic target.”

Reference: “HOX and PBX gene dysregulation as a therapeutic target in glioblastoma multiforme” by Einthavy Arunachalam, William Rogers, Guy R. Simpson, Carla Möller-Levet, Gemma Bolton, Mohammed Ismael, Christopher Smith, Karl Keegen, Izhar Bagwan, Tim Brend, Susan C. Short, Bangxing Hong, Yoshihiro Otani, Balveen Kaur, Nicola Annels, Richard Morgan and Hardev Pandha, 13 April 2022, BMC Cancer. 
DOI: 10.1186/s12885-022-09466-8

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