Research Sheds Light on How Cancer Cells Become Resistant to Treatment
Behind the Cancer Headlines®
January 18, 2005
A new study by researchers at Memorial Sloan-Kettering Cancer Center and The Johns Hopkins University provides new insight into how tumor cells can become resistant to anti-cancer therapy. The study was published in the journal Proceedings of the National Academy of Sciences.
The scientists observed that a protein called P-glycoprotein (P-gp), which causes resistance to chemotherapy in many tumor types, is able to physically "jump" or transfer between tumor cells and retain its functional properties, protecting otherwise sensitive cells from the effects of anti-cancer treatment in vivo and in vitro.
According to the authors, the research is the first to demonstrate that a protein transferred between cells retains its function long enough to allow the recipient cells to survive potentially toxic drug concentrations and ultimately develop intrinsic resistance.
In other words, cells that would normally be sensitive to treatment can develop resistance to it by receiving P-glycoprotein from other cells, making chemotherapy much less efficient. Uncovering the mechanism of this unusual "jumping" of the protein between the cells can potentially improve treatment success.
The authors conclude that their findings offer a new way in which to look at how cells behave in a community of cells within a tumor mass. The results have important implications for genomic analyses within tumor samples because resistance to cancer therapy can be achieved by protein transfer alone.
Proceedings of the National Academy of Sciences, January 17, 2005 online edition
The Johns Hopkins University (http://www.jhu.edu)
Memorial Sloan-Kettering Cancer Center (http://www.mskcc.org)