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Reprogramming Stem Cells May Prevent Cancer After Radiation
The body has developed a way to neutralize stem cells damaged by radiation, and fine-tuning this process may help prevent cancer in the aftermath of full-body radiation, a study suggests.
The University of Colorado Cancer Center study, published in the journal Stem Cells, describes a natural “program” that makes stem cells damaged by radiation differentiate into other cells that can no longer survive forever. Radiation makes a stem cell lose its “stemness.” That makes sense: you don’t want damaged stem cells sticking around to crank out damaged cells.
The study also shows that this same safeguard of “programmed mediocrity” that weeds out stem cells damaged by radiation allows blood cancers to grow in cases when the full body is irradiated. And by reprogramming this safeguard, we may be able to prevent cancer in the aftermath of full body radiation.
“The body didn’t evolve to deal with leaking nuclear reactors and CT scans. It evolved to deal with only a few cells at a time receiving dangerous doses of radiation or other insults to their DNA,” says James DeGregori, PhD, investigator at the University of Colorado Cancer Center, Professor of Biochemistry and Molecular Genetics at the university’s School of Medicine, and the paper’s senior author.
DeGregori, doctoral student Courtney Fleenor, and colleagues explored the effects of full-body radiation on the blood stem cells of mice. In this case, radiation increased the probability that cells in the hematopoietic stem cell system would differentiate. However, while most followed this instruction, a few did not.
Stem cells with a very specific mutation were able to disobey the instruction to differentiate and retain their “stemness.” Genetic inhibition of the gene C/EBPA allowed a few stem cells to keep the ability to act as stem cells. With competition from other, healthy stem cells removed, the stem cells with reduced C/EBPA were able to dominate the blood cell production system. In this way, the blood system transitioned from C/EBPA+ cells to primarily C/EBPA– cells.
Mutations and other genetic alterations resulting in inhibition of the C/EBPA gene are associated with acute myeloid leukemia in humans. Thus, it’s not mutations caused by radiation but a blood system reengineered by faulty stem cells that creates cancer risk in people who have experienced radiation.
“It’s about evolution driven by natural selection,” DeGregori says. “In a healthy blood system, healthy stem cells out-compete stem cells that happen to have the C/EBPA mutation. But when radiation reduces the heath and robustness (what we call ‘fitness’) of the stem cell population, the mutated cells that have been there all along are suddenly given the opportunity to take over.”
These studies don’t just tell us why radiation makes hematopoietic stem cells (HSCs) differentiate; they also show that by activating a stem cell maintenance pathway, we can keep it from happening. Even months after irradiation, artificially activating the NOTCH signaling pathway of irradiated HSCs lets them act “stemmy” again — restarting the blood cell assembly line in these HSCs that would have otherwise differentiated in response to radiation.
When DeGregori, Fleenor, and colleagues activated NOTCH in previously irradiated HSCs, it kept the population of dangerous, C/EBPA cells at bay. Competition from non–C/EBPA-mutant stem cells, with their fitness restored by NOTCH activation, meant that there was no evolutionary space for C/EBPA-mutant stem cells.
“If I were working in a situation in which I was likely to experience full-body radiation, I would freeze a bunch of my HSCs,” DeGregori says, explaining that an infusion of healthy HSCs after radiation exposure would likely allow the healthy blood system to out-compete the radiation-exposed HSC with their “programmed mediocrity” (increased differentiation) and even HSC with cancer-causing mutations. “But there’s also hope that in the future, we could offer drugs that would restore the fitness of stem cells left over after radiation.”
Source: University of Colorado Denver; December 29, 2014.