  D. radiodurans viewed by light microscopy. Courtesy Michael Daly |
‘The mere existence of D. radiodurans suggests that almost anything is possible.’ |
An efficient system for repairing DNA is what makes the microbe so tough. High doses of radiation shatter the D. radiodurans genome, but the organism stitches the fragments back together, sometimes in just a few hours. The repaired genome appears to be as good as new.
"The organism can put its genome back together with absolute fidelity," says Claire M. Fraser, of The Institute for Genome Research (TIGR) in Rockville, Maryland. She was the leader of the TIGR team that sequenced D. radiodurans in 1999.
"I was pretty much blown away by it," says John Battista, a microbiologist at Louisiana State University in Baton Rouge, recalling his introduction to the bacterium in 1988.
The bacterium seems to live everywhere and nowhere. It has been found in environments as diverse as elephant dung and granite in Antarctic dry valleys (the environment on Earth thought to most closely resemble Mars), but no one really knows what the microbe's natural habitat is.
No place on Earth exposes life to more than a fraction of the levels of radiation D. radiodurans can withstand. Certainly none of the environments in which D. radiodurans has been found offers a clue as to why the microbe has evolved such astonishing radiation resistance.
The trait may be related to the organism's response to dehydration, which is not uncommon in nature. Dehydration and radiation, it turns out, cause very similar types of DNA damage.
Scientists have speculated that the physical arrangement of D. radiodurans' genome could help the organism accomplish its feats of DNA repair. The microbe carries between four and ten copies of its genome, rather than the usual single copy, and the copies appear to be stacked on top of each other.
 D. radiodurans viewed by electron microscopy. Courtesy Michael Daly |
The additional genomes may allow the bacterium to recover at least one complete copy of its genome after exposure to radiation. The proteins and pathways involved in suturing a fractured genome back together are now the focus of a number of studies. Initially, the genome sequence shed frustratingly little light on this question.
The microbial species commonly used in environmental cleanup—a process known as bioremediation—do not survive radiation. To create a 'superbug' that can clean up the environment and endure radiation, Daly and colleagues have inserted genes from other bacteria into D. radiodurans.
 TEM micrograph of a thin section of Deinococcus radiodurans strain R1. Courtesy Jim Fredrickson, Michael Daly and Alice Dohnalkova |
The researchers created a strain of D. radiodurans that can break down toluene, an organic chemical found in radioactive waste sites. Another engineered strain converts mercury, also found at these sites, into a much less toxic form. These genetically engineered strains cannot themselves get rid of radiation, but they may speed the cleanup and save money.
"The idea is ultimately to introduce these bacteria into contaminated environments," says Daly. He adds that the goal is probably a long way off, given the widely shared concerns about releasing genetically engineered organisms into the world.
Meanwhile, Daly and other scientists are also pursuing applications of D. radiodurans in a more exotic environment—outer space. The organism could be used in simulations to help scientists predict where to search for life on Mars or elsewhere, or help them understand how to avoid potential 'cross-contamination' between earthly and alien life forms.
Other potential uses of D. radiodurans in space—such as using the microbe for sewage treatment on long space flights or in environmental engineering to make the Martian surface more suitable for human colonization—remain in the realm of speculation. But who knows? The mere existence of D. radiodurans suggests that almost anything may be possible.
Some general properties and a chromosomal display of the organism can be found at the Deinococcus radiodurans R1genome page of TIGR.
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