WASHINGTON — Scientists mimicked one of cancer’s sneaky tricks to create a drug that promises to prevent a serious side effect of cancer treatment — radiation damage — or offer an antidote during a nuclear emergency.
A single dose of the experimental drug protected both mice and monkeys from what should have been lethal doses of radiation, researchers report in today’s edition of the journal Science. A study to see whether the compound is safe in people could begin as early as this summer.
It’s still early-stage research, and other efforts to create radiation protectants haven’t yet panned out. But specialists are closely watching the work — and the government is helping to fund it — because it’s a new approach to protecting the body’s most radiation-sensitive tissues from being blasted.
“It has important implications for radiation exposure,” said Dr. David Kirsch, a Duke University radiation oncologist who wasn’t involved in the drug research.
Radiation is a powerful tool to destroy cancer cells. But certain healthy tissues are especially sensitive to it, too — particularly the bone marrow and gastrointestinal tract. That vulnerability can limit how much radiation physicians can give cancer patients.
And when it comes to radiation emergencies, such as the Chernobyl accident, full-body exposure to high doses can cause an extremely lethal “GI syndrome” that has no treatment.
It turns out that radiation doesn’t kill healthy cells in the same way it kills cancer cells.
Instead, bone marrow and cells in the gastrointestinal tract overreact to what should be reparable damage and commit suicide, through a well-known process called apoptosis, explained Andrei Gudkov of the Roswell Park Cancer Institute, who led development of the drug code-named CBLB502.
Learning that was the “eureka” moment, Gudkov said. Apoptosis is the body’s way of stopping defective cells, with damaged genes, from spreading. Tumors grow because cancer cells block apoptosis in various ways, including by activating a normally dormant cell-signaling pathway called “nuclear factor-KappaB,” or NFKB.
Gudkov’s team decided to try activating that same pathway in healthy tissue, to see whether it could keep radiation-blasted cells from triggering their suicide program.
“We imitated a tumor trick,” is how Gudkov puts it.
Team members knew that flagellin, a protein from normal gut bacteria, can wake up NFKB. So they created a drug based on that natural protein.
In experiments, they injected the drug into mice and rhesus monkeys anywhere from 15 minutes to an hour before exposing the animals to lethal doses of full-body radiation. The drug dramatically improved the animals’ survival, protecting against both bone marrow and gastrointestinal destruction, with no obvious side effects.
The drug also improved survival when given to mice an hour after fairly high radiation doses, although not the very highest.
A final experiment showed that the drug didn’t block radiation from treating the tumors of the mice even as it protected their healthy tissue.
