Microbes craft unusual crystals.In the flooded tunnels of an abandoned iron mine below the town of Tennyson, Wis., scuba divers recently retrieved a curious community of bacteria that grow bizarre, hairlike crystals. "The crystals look like tangled spaghetti," says earth scientist Jill Banfield of the University of California, Berkeley The University of California, Berkeley is a public research university located in Berkeley, California, United States. Commonly referred to as UC Berkeley, Berkeley and Cal . Now, Banfield and her colleagues have figured out how the bacteria produce these structures, a discovery that could help scientists design new materials and provide clues to possible life on other planets. Working with scientists at the University of Wisconsin-Madison “University of Wisconsin” redirects here. For other uses, see University of Wisconsin (disambiguation). A public, land-grant institution, UW-Madison offers a wide spectrum of liberal arts studies, professional programs, and student activities. , Banfield and her colleagues used X rays and electron microscopy to study the microbes' chemical processes. The images revealed that the bacteria secrete secrete /se·crete/ (se-kret´) to elaborate and release a secretion. se·crete v. To generate and separate a substance from cells or bodily fluids. polymer filaments from their cell walls. Iron oxide The material used to coat the surfaces of magnetic tapes and lower-capacity disks. dissolved in the mine's water then precipitates on the filaments to form a type of crystal called akaganeite. Described in the March 12 Science, each crystal measures only a couple of nanometers wide and up to 10 micrometers long. The researchers hypothesize hy·poth·e·size v. hy·poth·e·sized, hy·poth·e·siz·ing, hy·poth·e·siz·es v.tr. To assert as a hypothesis. v.intr. To form a hypothesis. that the bacteria use the crystals to generate energy for the cell. The chemical reactions by which the crystals form produce an excess of protons on the surface of each bacterium. These protons then feed the cell's energy-generating molecular machinery. The new work could help scientists identify forms of life that might once have thrived on the iron-rich planet of Mars, says Banfield.--A.G. |
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