Researchers learn how signaling molecule orchestrates breast cancer's spread

Apr 03, 2008

A study led by researchers at Memorial Sloan-Kettering Cancer Center (MSKCC) has uncovered how breast tumors use a particular type of molecule to promote metastasis -- the spread of cancer cells. Metastasis is the cause of approximately 90 percent of all cancer-related deaths. The study is published in the April 4, 2008, issue of Cell.

The work examines how cells in the body communicate with each other through cytokines, signaling molecules that direct a wide range of activities such as cell growth and movement. One important cytokine -- transforming growth factor -a (TGF-a) -- normally suppresses tumor development. However, according to the findings, cancer cells in humans are able to misuse these cytokines for their own gain by compelling TGF-a to enhance a tumor's ability to spread instead of suppressing it.

Using computer-based analysis to classify patient tumor samples based on their levels of TGF-a, the researchers observed that about half of all breast tumors contained active TGF-a. The affected tumors were found to be more aggressive and more likely to metastasize to the lung during the course of the patients' disease.

Using mice for their next set of experiments, the researchers discovered that TGF-a prompts breast cancer cells to make a second cytokine, known as angiopoietin-like 4 (ANGPTL4), which enhances the ability of the cancer to spread to the lungs through the blood circulation. The results show that the breast cancer cells use ANGPTL4 to break down the thin capillaries of the lung, thus facilitating their escape into the lung tissue.

"Our work shows that TGF-a enhances human breast cancer metastasis and reveals how tumor cells learn to exploit cytokines by making them work as a relay system to promote the spread of breast cancer," said the study's senior author, Joan Massagu, PhD, Chairman of the Cancer Biology and Genetics Program at MSKCC and a Howard Hughes Medical Institute investigator.

The researchers are now seeking to determine whether TGF-a and ANGPTL4 may also be active in other types of tumors, and are evaluating ways to interfere with the action of these cytokines to prevent metastasis in cancer patients.

"Deciphering how cancer cells take advantage of these cytokines is essential for developing therapies that can prevent this process," said the study's lead author David Padua, a graduate student in Dr. Massagu's lab. "Because cytokines act outside of cells they can be more easily targeted by drugs that block their activity."

The study provides support for developing agents to interfere with TGF-a in order to prevent and treat cancer metastasis. It points at ANGPTL4 as a possible target to interrupt the TGF-a stimulus of metastasis without interfering with the molecule's beneficial effects. Several pharmaceutical companies are currently testing TGF-a-blocking compounds in clinical trials as candidate drugs against breast cancer, melanoma, and other types of cancer.

Source: Memorial Sloan-Kettering Cancer Center

Explore further: Surgery associated with better survival for patients with advanced laryngeal cancer

add to favorites email to friend print save as pdf

Related Stories

Genetic profile reveals susceptibility to cleft palate

Sep 15, 2008

For the first time, researchers from the University of Pittsburgh School of Dental Medicine have identified a series of genetic mutations that appear to be linked to significant risk for cleft palate and other dental abnormalities. ...

Recommended for you

How 'wriggling' skin cancer cells go on the move

14 hours ago

(Medical Xpress)—Scientists at King's College London have discovered a new way that melanoma skin cancer cells can invade healthy tissue and spread round the body, according to research published in Nature Co ...

User comments : 1

Adjust slider to filter visible comments by rank

Display comments: newest first

E_L_Earnhardt
not rated yet Apr 04, 2008
THERMAL effects should be monitored! ENERGY is required for mitosis, angio genesis, etc. All organic rates are temperature dependent!