"In simple terms, we have mapped the molecular switch on the receptor that turns two important biological processes on and off, respectively. We have, in other words, pinpointed the binding site that can cause increased spreading of breast cancer cells and thus the development of metastases.
"We have studied two cellular signaling proteins with each their widely different biological influence on the so-called FGFR2b receptor. One of the proteins is involved in cell division, whereas the other controls cell movement. Both processes are important for a healthy cell, but if they spin out of control it may have serious implications, e.g. in the form of cancer cell growth and development of metastases," says Professor and protein researcher Jesper Velgaard Olsen, The Novo Nordisk Foundation Center for Protein Research, University of Copenhagen.
The findings have just been published in the scientific journal Molecular Cell.
The FGFR2b receptor is co-responsible for the optimal development of inner organs at the embryonic stage, in particular lung tissue. A dysfunction in the receptor's signal therefore has serious implications for normal lung tissue function. The receptor has also proved to play an important role in certain types of breast cancer.
The new research is based on human cancer cells and murine tissue but may, in the long run, help improve the customised treatment of, e.g., breast cancer in humans.
"Doctors currently use special biomarkers for diagnosing and treating cancers. The FGFR2b receptor may in the future serve as a new biomarker. The more we know about the body's transmission systems, the better we become at targeting medical treatment. Hopefully, we will in future be able to offer customised treatment based on the individual patient's cellular profile," says Professor Jesper Velgaard Olsen.
The researchers have used state-of-the-art technology within protein research at The Novo Nordisk Foundation Center for Protein Research.
"Using advanced mass spectrometry allows us to study cellular proteins in such detail that was previously only possible within the field of genetics. It was previously a huge challenge to analyze proteins - but today we can study thousands of proteins in a very short time," says Professor Jesper Velgaard Olsen.