Research explains dynamic cells associated to development and recurrence of brain tumour
Ann Arbor [Michigan], June 29 (ANI): Numerous cell types, including both malignant and benign cells, make up tumours. One distinctive feature of the condition that makes therapy exceedingly challenging is the particular intricacy of the cells found inside brain tumours. Despite the fact that there are many different types of cells in a brain tumour, scientists have long assumed that these cells are static, immobile, and largely fixed, according to a new study.
Ann Arbor [Michigan], June 29 (ANI): Numerous cell types, including both malignant and benign cells, make up tumours. One distinctive feature of the condition that makes therapy exceedingly challenging is the particular intricacy of the cells found inside brain tumours. Despite the fact that there are many different types of cells in a brain tumour, scientists have long assumed that these cells are static, immobile, and largely fixed, according to a new study.
The findings of the journal were published in the journal ‘Nature Communications’.
But researchers at the University of Michigan Department of Neurosurgery and Rogel Cancer Center have discovered that these aggressive tumours contain highly active cells that move throughout the tissue in complicated patterns.
What’s more, the accumulations of these elongated, spindle-like cells found throughout the tumour, coined ‘oncostreams,’ serve as the basis for cancerous cells’ behaviour, determining how tumours grow and invade normal tissue.
Pedro Lowenstein, M.D., PhD, Richard C. Schneider Collegiate Professor of Neurosurgery and lead author of this study in Nature Communications, said this organized growth is what makes brain tumours so relentless.
“Brain tumours are highly lethal, with less than 5 per cent of patients living beyond five years,” he said. “Unfortunately, reoccurrence is what eventually kills patients. They receive surgery for their initial tumour, but the tumour always comes back within 12 to 18 months,” he said.
Lowenstein and his team, including Maria Castro, PhD, also found that overexpression of Collagen 1, a protein produced by tumor cells, is essential to the growth and function of these structures.
“When we eliminated Collagen 1 production from tumour cells, the animal models with brain tumours lived much longer. This step removes oncostreams from tumours and reduces tumor aggressive behaviour because the tumours need Collagen 1 to move in the specific way we discovered,” said Lowenstein.
Lowenstein says this structure is likely to present in other types of cancer, too. “Once people recognize that there are dynamic areas of the tumour and that they’re related to tumour growth, eventual invasion and death, people will likely locate oncostreams in other tumour models,” he said.
To detect this previously unknown presence of oncostreams, the team collaborated with Todd Hollon, M.D., assistant professor in the Michigan Medicine Department of Neurological Surgery, and Sebastien Motsch, PhD, associate professor of mathematics at Arizona State University, to implement artificial intelligence methods to identify the structures in tissue.
“Essentially, we showed images to a computer and the computer eventually learns to recognize oncostreams,” Lowenstein explained.
Dismantling oncostreams through the removal of Collagen 1 could represent a novel therapeutic target to treat lethal brain tumours. “This research proves the crucial importance of continuing to investigate the complicated extracellular matrix,” notes Andrea Comba, PhD, research investigator and first author of the study.
“Based on this discovery, we propose targeting tumour collagen to disrupt oncostreams, and as a novel therapy for the treatment of brain glioma,” she said. (ANI)