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Low oxygen, high risk: How tumours adapt to become more aggressive

8 Aug 2016
Low oxygen, high risk: How tumours adapt to become more aggressive

One of the many reasons tumours are so difficult to treat is that they are able to adapt whenever they are exposed to unfavourable conditions.

Hypoxia, or a lack of oxygen, is one example of a phenomenon that should weaken the tumour, but instead, the malignant cells are able to compensate and drive more aggressive disease behaviour.

Now, scientists at The Wistar Institute have identified a novel mechanism that selectively operates in hypoxic tumours to enable tumour cells to thrive and continue to proliferate despite a low oxygen environment.

Dario C. Altieri, M.D., Wistar's President and CEO and lead author of the study, and colleagues showed how the activation of this pathway leads to an unfavourable prognosis for patients with gliomas -- a type of brain tumour -- and how the pathway could be a valuable therapeutic target in cancer.

The findings were published in the journal Cancer Cell.

"Hypoxia is a nearly universal hallmark of aggressive tumour growth, and up until now, we really haven't been able to home in on a pathway responsible for this behaviour," said Altieri, who is also director of The Wistar Institute Cancer Center and the Robert & Penny Fox Distinguished Professor. "Our study pinpoints a novel way in which tumour cells not only survive but actually continue to divide in spite of a low oxygen environment. In essence, this provides a much-needed answer for exactly how tumour cells are able to get the energy they need to persist when faced with unfavourable conditions."

Mitochondria, known as the "powerhouse" of cells because of their role in energy production, are the main source of hypoxia-induced reprogramming in tumours.

The Altieri lab showed that the protein Akt, which plays a key role in cell signalling and metabolism, accumulates in mitochondria during hypoxia.

When this happens, the protein PDK1 is phosphorylated at a unique site, and a complex responsible for cellular respiration is shut down.

The pathway then uses the tumour's metabolism to break down glucose and use its energy to reduce cell death and maintain proliferation.

The mitochondrial signalling between Akt and PDK1 was analysed in a cohort of 116 patients with gliomas.

The activation of this signalling pathway progressively increased in different types of gliomas, with the highest activity seen in patients with glioblastoma, a particularly difficult-to-treat form of brain cancer that represents approximately 15 percent of all brain tumours.

"We are excited about our results because there are drugs that exist that specifically target Akt in cancer. These drugs have produced limited clinical responses to date, but we believe with further investigation that we may be able to repurpose these drugs as a viable approach to impair a tumour's ability to adapt to hypoxia," said Young Chan Chae, Ph.D., an associate staff scientist in the Altieri lab and first author of the study.

Source: The Wistar Institute