Cancer treatment resistance study identifies tumor suppressor
Cancer treatment resistance study identifies tumor suppressor
9/1/2014
Cancer treatments face resistance for various reasons, and researchers are focusing on a suppressor protein that may kill cancer cells.
Loss of the tumor suppressor p53 often contributes to therapy resistance in tumors. In the study, published in Cell Reports, the University of Kentucky's Vivek Rangnekar and his colleagues activated wild type p53 in normal cells to trigger cell death in the p53-deficient cancer cells. Because p53 is intact and functional in normal cells, the researchers harnessed its potential to inhibit the growth of p53-deficient cancer cells.
This paracrine effect was brought about by the tumor suppressor Par-4, which specifically kills cancer cells. Although other tumor suppressors exist, what makes Par-4 so special is that it is not mutated as frequently as other known suppressors, and it's "selective" in its actions in that Par-4 will only kill cancer cells and not normal cells. Importantly, it's secretion from normal cells can be induced by activating p53 so that Par-4 enters circulation, thereby potentially targeting tumor cells at distant sites.
"As normal cells far outnumber the cancer cells in patients, we sought to empower the normal cells to trigger cell death in p53-deficient cancer cells," said Rangnekar, associate director of transdisciplinary collaborations for the UK Markey Cancer Center. "Our findings have potential for targeting local, as well as metastatic tumors, and future studies will use FDA-approved drugs to induce Par-4 secretion."
The UK Markey Cancer Center is the only National Cancer Institute-designated cancer center in Kentucky. NCI-designated cancer centers are a major source of discovery and development of more effective approaches to cancer prevention, diagnosis and treatment. Rangnekar, a professor in the department of radiation medicine, also holds the Alfred Cohen Endowed Chair in Oncology Research.
Source: Science Daily: http://www.sciencedaily.com/releases/2014/01/140109175519.htm