Dark power: pigment seems to put radiation to good use.Call them the Hulk bugs. Just as they do for the comic book hero, gamma rays Gamma rays Electromagnetic radiation emitted from excited atomic nuclei as an integral part of the process whereby the nucleus rearranges itself into a state of lower excitation (that is, energy content). seem to make certain microscopic fungi stronger. Researchers have found hints that melanin--the same pigment that's the natural ultraviolet filter in people's skin--might enable these fungi to harness the energy of gamma radiation as well as to shield themselves from it. Microbiologist Arturo Casadevall of the Albert Einstein College of Medicine
The Albert Einstein College of Medicine (AECOM) is a graduate school of Yeshiva University. It is a private medical school located in the Jack and Pearl Resnick Campus of Yeshiva University in the Morris Park in New York City New York City: see New York, city. New York City City (pop., 2000: 8,008,278), southeastern New York, at the mouth of the Hudson River. The largest city in the U.S. recalls learning several years ago that single-cell fungi had been found thriving inside the collapsed nuclear reactor at Chernobyl, Ukraine. He and his colleagues later saw reports that the cooling water in some working nuclear reactors turns black from colonies of melanin-rich fungi. Nuclear reactors are intense sources of gamma rays, which can zap through living organisms and leave behind trails of destruction. Many microorganisms can survive in extreme environments, but Casadevall thought that something more might he going on. Perhaps the fungi were growing thanks to the radiation, not in spite of it. "The thought was that biology never wastes any energy source," he says. Casadevall says that fungi such as Cryptococcus Cryptococcus /Cryp·to·coc·cus/ (-kok´us) a genus of yeastlike fungi, including C. neofor´mans, the cause of cryptococcosis in humans.cryptococ´cal Cryp·to·coc·cus n. neoformans--which causes grave infections in AIDS patients--have layers of melanin melanin (mĕl`ənĭn), water-insoluble polymer of various compounds derived from the amino acid tyrosine. It is one of two pigments found in human skin and hair and adds brown to skin color; the other pigment is carotene, which contributes on their membranes. Melanin is rich in radicals--molecules with highly reactive unpaired electrons--that may help fend off attacks by the immune system of any organism that the fungus is trying to infect. But Casadevall wondered whether these layers might also turn gamma ray energy into a form the cell could use. To test this hypothesis, Casadevall's team exposed colonies of C. neoformans to gamma rays 500 times as intense as the normal radiation background on Earth's surface. The colonies grew up to three times as fast as normal. A mutant "albino albino (ălbī`nō) [Port.,=white], animal or plant lacking normal pigmentation. The absence of pigment is observed in the body covering (skin, hair, and feathers) and in the iris of the eye. " form of the fungus, which produced no melanin, grew at a normal pace, the team reports online in PLoS ONE. But the accelerated growth didn't prove that the fungi drew energy from the radiation, Casadevall says, so the researchers took a closer look at melanin. In one experiment, they found that gamma rays induced a four-fold increase in melanin's ability to catalyze an oxidation-reduction reaction typical of cell metabolism. They also tested melanin's response to gamma rays using electron spin resonance electron spin resonance (ESR) or electron paramagnetic resonance (EPR) Technique of spectroscopic analysis (see spectroscopy) used to identify paramagnetic substances (see , a technique similar to nuclear magnetic resonance nuclear magnetic resonance: see magnetic resonance. nuclear magnetic resonance (NMR) Selective absorption of very high-frequency radio waves by certain atomic nuclei subjected to a strong stationary magnetic field. spectroscopy. Gamma rays changed the distribution of unpaired electrons in the molecule, says Casadevall's Albert Einstein colleague Ekaterina Dadachova. These findings suggest that gamma rays kick some melanin electrons into excited states, initiating a yet-unknown process that would end up producing chemical energy, Casadevall says. This might be similar to the way in which photosynthesis supplies energy to plants, he adds. He speculates that melanin might collect energy not only from gamma rays but also from lower-energy radiation such as X rays or ultraviolet rays. "I think this is only the tip of the iceberg tip of the iceberg n. pl. tips of the iceberg A small evident part or aspect of something largely hidden: afraid that these few reported cases of the disease might only be the tip of the iceberg. ," he says. The findings are interesting, says Darrell Fisher, a radiation biologist at the Pacific Northwest National Laboratory The Pacific Northwest National Laboratory (PNNL) is one of nine United States Department of Energy (DOE) multiprogram national laboratories. The laboratory PNNL is located in Richland, Washington, and operates a marine research facility in Sequim, Washington. in Richland, Wash. However, he says, "one must be careful not to draw unwarranted conclusions." If radiation enhances the growth of fungi, he says, it's "important to understand and test the underlying mechanisms." |
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