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University of Cambridge - Engineering and Physical Sciences Research Council (EPSRC)

Policy recommendations in climate-related research often ‘an afterthought’, major analysis finds ‘Origami’ method could speed up diagnosis of neurodegenerative disease Client Challenge ‘Beautiful energy sandwich’ could power next-generation solar and lighting Widely-used technique for assessing IVF embryos may be flawed, study suggests ‘Artificial cartilage’ could improve arthritis treatment Why common blood pressure readings may be misleading – and how to fix them New era of UK physics research begins with opening of Cambridge’s Ray Dolby Centre Researchers demonstrate the UK’s first long-distance ultra-secure communication over a quantum network Scientists develop ‘smart pyjamas’ to monitor sleep disorders
Brain cancer cells can be ‘reprogrammed’ to stop them from spreading
Sarah Collin · 2025-09-02 · via University of Cambridge - Engineering and Physical Sciences Research Council (EPSRC)

Scientists have found a way to stop brain cancer cells spreading by essentially ‘freezing’ a key molecule in the brain.

The finding could pave the way for a new type of treatment for glioblastoma, the most aggressive form of brain cancer, although extensive testing will be required before it can be trialled in patients. Glioblastoma is the most common type of brain cancer, with a five-year survival rate of just 5%.

The researchers, from the University of Cambridge, found that cancer cells rely on the flexibility of hyaluronic acid (HA) — a sugar-like polymer that makes up much of the brain’s supporting structure — to latch onto receptors on the surface of cancer cells to trigger their spread throughout the brain.

By locking HA molecules in place so that they lose this flexibility, the researchers were able to ‘reprogramme’ glioblastoma cells so they stopped moving and were unable to invade surrounding tissue. Their results are reported in the journal Royal Society Open Science.

“Fundamentally, hyaluronic acid molecules need to be flexible to bind to cancer cell receptors,” said Professor Melinda Duer from Cambridge’s Yusuf Hamied Department of Chemistry, who led the research. “If you can stop hyaluronic acid being flexible, you can stop cancer cells from spreading. The remarkable thing is that we didn’t have to kill the cells — we simply changed their environment, and they gave up trying to escape and invade neighbouring tissue.”

Glioblastoma, like all brain cancers, is difficult to treat. Even when tumours are surgically removed, cancer cells that have already infiltrated the brain often cause regrowth within months. Current drug treatments struggle to penetrate the tumour mass, and radiotherapy can only delay, not prevent, recurrence of the cancer.

However, the approach developed by the Cambridge team does not target tumour cells directly, but instead attempts to change the tumour’s surrounding environment – the extracellular matrix – to stop its spread.

“Nobody has ever tried to change cancer outcomes by changing the matrix around the tumour,” said Duer. “This is the first example where a matrix-based therapy could be used to reprogramme cancer cells.”

Using nuclear magnetic resonance (NMR) spectroscopy, the team showed that HA molecules twist into shapes that allow them to bind strongly to CD44 — a receptor on cancer cells that drives invasion. When HA was cross-linked and ‘frozen’ into place, those signals were shut down.

The effect was seen even at low concentrations of HA, suggesting the cells were not being physically trapped but instead reprogrammed into a dormant state.

The study may also explain why glioblastoma often returns at the site of surgery. A build-up of fluid, or oedema, at the surgical site dilutes HA, making it more flexible and potentially encouraging cell invasion. By freezing HA in place, it could be possible to prevent recurrence.

“This could be a real opportunity to slow glioblastoma progression,” said Duer. “And because our approach doesn’t require drugs to enter every single cancer cell, it could in principle work for many solid tumours where the surrounding matrix drives invasion.

“Cancer cells behave the way they do in part because of their environment. If you change their environment, you can change the cells.”

The researchers are hoping to conduct further testing in animal models, which could lead to clinical trials in patients.

The research was supported in part by the European Research Council and the Engineering and Physical Sciences Research Council (EPSRC), part of UK Research and Innovation (UKRI). Melinda Duer is a Fellow of Robinson College, Cambridge.

Melinda Duer will be discussing her research on Saturday 27 September, as part of the Cambridge Alumni Festival 2025

Reference:
Uliana Bashtanova, Agne Kuraite, Rakesh Rajan, Melinda J Duer. ‘Molecular flexibility of hyaluronic acid has a profound effect on invasion of cancer cells.’ Royal Society Open Science (2025). DOI: 10.1098/rsos.251036