A team of researchers have identified a gene that drives one of the most aggressive forms of breast cancer. They hope that by finding a way to block the gene they may be able to make the cancer less aggressive.
In their study, published in Nature Communications, the researchers found that the gene known as “inhibitor of differentiation 4” (ID4) not only indicates a highly aggressive form of triple-negative breast cancer but also appears to control it.
“We found that ID4 is produced at high levels in roughly half of all triple-negative breast cancers, and that these cancers have a particularly poor prognosis,” says project leader Dr. Alex Swarbrick. “We also showed that if you block the ID4 gene in experimental models of triple negative breast cancer, the tumor cells stop dividing.”
Around 15% of all breast cancer cases are triple-negative breast cancers. Patients that develop them typically have a higher risk of recurrence and shorter survival than patients with other forms of breast cancer.
There appears to be a division among patients with triple-negative breast cancer; some patients succumb to the disease within 3-5 years while others can survive disease-free for much longer than many non-triple-negative breast cancer patients.
The researchers discovered a likely explanation for this differentiation in survival prospects – there are two distinct forms of triple-negative breast cancer, appearing to originate from different cell types.
While the more benign form of triple-negative breast cancer appears to originate from specialized cells, the team found that the aggressive form of the disease seems to originate from stem cells.
Stem cells have the capacity to develop into a variety of different cell types in the body, and in many bodily tissues they divide to replenish other cells, providing the body with a form of internal repair. The manner in which stem cells are flexible and can spread into other tissues is similar to the way that many cancers operate.
Previous research has shown that breast stem cells are a vital part of breast growth and development during both puberty and pregnancy. The new study has now demonstrated that ID4 is responsible for determining whether these stem cells develop into specialist cells or not.
When ID4 is blocked in a stem cell, other genes that drive cell specialization are activated. In addition, the estrogen receptor and a number of other genes expressed by forms of breast cancer with better prognoses are also activated.
“Estrogen receptor-positive breast cancers have a relatively good prognosis because the drug tamoxifen is very effective at blocking the estrogen receptor and hence their growth,” explains Dr. Swarbrick.
“We speculate, therefore, that by blocking ID4 it might be possible to turn stem-cell-like breast cancers into less aggressive breast cancers that may even respond to tamoxifen. If we are correct, that would be remarkable.”
Following their discovery, the team will now investigate ID4 in order to work out the best strategy for blocking it in humans. They are also planning a mouse study to assess whether blocking ID4 can make tumors vulnerable to tamoxifen.
“We don’t know yet whether we are seeing a real estrogen-dependent cancer after ID4 is blocked – one with an effective estrogen receptor – or just a caricature of one,” states Dr. Swarbrick.
The team will be working in collaboration with a world expert on estrogen receptor function and studying these biochemical processes on a genome-wide scale as they attempt to fully understand the role that ID4 could play in the development and treatment of breast cancer.
Earlier this month, Medical News Today reported on a study finding that the shape of breast cancer cells can influence a tumor’s response to treatment. Changing the shape of these cells could be a way of making them more sensitive to treatment.