Stories about: Fernando Camargo

‘Druggable’ cancer target found in pathway regulating organ size

Inactivating NUAK2 curbs cell proliferation in liver cancer
Reducing cancer proliferation: A small molecule that inactivates NUAK2, part of the Hippo/YAP pathway, reduces the number of cancerous cells in the mouse liver. (WEI-CHIEN YUAN/BOSTON CHILDREN’S HOSPITAL)

It’s known that cancer involves unchecked cell growth and that a pathway that regulates the size of organs, known as Hippo, is also involved in cancer. It’s further known that a major player in this pathway, YAP, drives many types of tumors. What’s been lacking is how to turn this knowledge into a practical cancer treatment. In a study published today in Nature Communications, researchers at Boston Children’s Hospital identify a target downstream of YAP, called NUAK2, and show that it can readily be inactivated with a small molecule.

“The Hippo pathway, and especially YAP, has been hard to target with drugs,” says senior study author Fernando Camargo, PhD, of Boston Children’s Stem Cell Research program. “This is the first demonstration of a ‘druggable’ molecule that could be targeted in any type of tumor driven by YAP.”

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News Note: Cell ‘barcodes’ trace the natural development of blood

in situ blood development
(Credit: Stem Cell Program, Boston Children’s Hospital)

Genetic labels, or “barcodes,” are shedding new light on the natural process of blood development and immune-cell production, finds a study published in Nature this week. It was led by Fernando Camargo, PhD, and first author Alejo Rodriguez Fraticelli, PhD, at Boston Children’s Hospital’s Stem Cell Research Program, the Harvard Department of Stem Cell and Regenerative Biology and the Harvard Stem Cell Institute.

Most of what we know about blood production is through observing what happens when blood stem and progenitor cells are transplanted into an animal. To observe what happens “in the wild,” researchers went in and tagged the blood stem and progenitor cells of mice, using genetic elements called transposons. This allowed them to track how the cells differentiated into five kinds of blood cells (above: megakaryocytes, erythroid cells, granulocytes, monocytes and B-cell progenitors).

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