Preventing tumour metastasis

Researchers at the Paul Scherrer Institute, together with colleagues from the pharmaceutical company F. Hoffmann-La Roche AG, have taken an important step towards the development of an agent against the metastasis of certain cancers.

Using the Swiss Light Source, they deciphered the structure of a receptor that plays a crucial role in the migration of cancer cells. This makes it possible to identify agents that could prevent the spread of certain cancer cells via the body’s lymphatic system. The researchers have now published their results in the journal Cell.
When cancer cells spread in the body, secondary tumours, called metastases, can develop. These are responsible for around 90 percent of deaths in cancer patients. An important pathway for spreading the cancer cells is through the lymphatic system, which, like the system of blood vessels, runs through the entire body and connects lymph nodes to each other. In the migration of white blood cells through this system, for example to coordinate the defense against pathogens, one special membrane protein, the chemokine receptor 7 (CCR7) plays an important role. It sits in the shell of the cells, the cell membrane, in such a way that it can receive external signals and relay them to the interior. Within the framework of a joint project with the pharmaceutical company F. Hoffmann-La Roche AG (Roche), researchers at the Paul Scherrer Institute (PSI) have for the first time been able to decipher the structure of CCR7 and lay the foundation for the development of a drug that could prevent metastasis in certain prevalent cancer types, such as colorectal cancer.

Read more on the SLS at PSI website

Image: Steffen Brünle (right) and Jörg Standfuss at the apparatus they use to separate proteins from each other. For their study, the researchers modified insect cells to produce a human protein. To extract this from the cell, the cell was destroyed, and then the protein, whose structure the researchers have now elucidated, was separated with the help of this apparatus.
Credit: Paul Scherrer Institute/Markus Fischer