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Previous research has shown that mutations of the p53 gene lead to tumor growth and the spread of cancerous cells.

Using cultures of ovarian surface epithelium cells, where ovarian cancer originates, researchers found when they inactivated the p53 gene, the cells began to move and invade the underlying gelatinous protein mixture used in the lab that resembles an extracellular tissue environment.

“People thought that cell motility and invasion were part of later stages of cancer, but we show that this characteristic can be found in cells at the very beginning of cancer formation,” says Chang-Il Hwang, a graduate student in the lab of Alexander Nikitin, professor of biomedical sciences at Cornell University.

Under normal circumstances, p53 regulates the expression of a receptor protein called MET. But when p53 mutates, MET overexpresses, leading to cell movement and invasive growth.

Researchers report in the journal Proceedings of the National Academy of Sciences they found two distinct pathways by which p53 regulates and suppresses MET.

“One of the next steps is to study ways to inhibit MET,” says Hwang. “Our findings support the idea that suppression of MET could be a particularly reasonable and effective approach to controlling cancer carrying p53 mutations.

“We hope our findings can be generalized into other types of cancer as well.”

The research shows the p53 and MET network were consistent in both lung and colon cancer.

Mutations of p53 take many forms, with the most common mutation affecting one of the pathways that regulates MET but not the other pathway. By understanding how different p53 mutations affect each of the two pathways, researchers may one day develop individualized cancer therapies by suppressing MET, says Hwang.

“Different p53 mutations may affect the cancer from different angles,” he adds.

The study was funded by the National Institutes of Health, the Marsha Rivkin Center for Ovarian Cancer, Cornell’s College of Veterinary Medicine and the Ovarian Cancer Research Fund.

More news from Cornell University: www.news.cornell.edu