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 Friday, May 2, 2008 Scripps Oceanography Research Pegs ID of Red Tide Killer Bacteria gang up on algae, quashing red tide blooms Scripps Institution of Oceanography / University of California, San Diego Researchers at Scripps Institution of Oceanography at UC San Diego have identified a potential "red tide killer." Red tides and related phenomena in which microscopic algae accumulate rapidly in dense concentrations have been on the rise in recent years, causing hundreds of millions of dollars in worldwide losses to fisheries and beach tourism activities. Despite their wide-ranging impacts, such phenomena, more broadly referred to as "harmful algal blooms," remain unpredictable in not only where they appear, but how long they persist.New research at Scripps has identified a little-understood but common marine microbe as a red tide killer, and implicates the microbe in the termination of a red tide in Southern California waters in the summer of 2005.  A red tide bloom flourished along the coast of La Jolla, Calif., in June 2005. Using a series of new approaches, Scripps Oceanography's Xavier Mayali investigated the inner workings of a bloom of dinoflagellates, single-celled plankton, known by the species name Lingulodinium polyedrum. The techniques revealed that so-called Roseobacter-Clade Affiliated ("RCA cluster") bacteria-several at a time-attacked individual dinoflagellates by attaching directly to the plankton's cells, slowing their swimming speed and eventually killing them. Using DNA evidence, Mayali matched the identity of the RCA bacterium in records of algal blooms around the world.  Cells of the dinoflagellate Lingulodinium polyedrum, collected at sea during a bloom in the summer of 2005, show reddish areas signifying natural chlorophyll fluorescence, blue areas revealing DNA and green "dots" marking the cells of RCA cluster, bacteria implicated as a red tide killer. "It's possible that bacteria of this type play an important role in terminating algal blooms and regulating algal bloom dynamics in temperate marine waters all over the world," said Mayali. The research study, which was coauthored by Scripps Professors Peter Franks and Farooq Azam, is published in the May 1 edition of the journal Applied and Environmental Microbiology. "Our understanding of harmful algal blooms and red tides has been fairly primitive. For the most part we don't know how they start, for example," said Franks, a professor of biological oceanography in the Integrative Oceanography Division at Scripps. "From a practical point of view, if these RCA bacteria really do kill dinoflagellates and potentially other harmful algae that form dense blooms, down the road there may be a possibility of using them to mitigate their harmful effects."  Xavier Mayali collects seawater samples off the Scripps Pier during a red tide in summer 2005. "The work in the laboratory showed that the bacterium has to attach directly to the dinoflagellate to kill it," said Mayali, "and we found similar dynamics in the natural bloom." Franks said he found it a bizarre concept of scale that Lingulodinium dinoflagellates, which at 25 to 30 microns in diameter are known to swim through the ocean with long appendages known as flagella, are attacked by bacteria that are about one micron in size and can't swim. "It's somewhat shocking to think of something like three chipmunks attaching themselves to an elephant and taking it down," said Franks. While the RCA cluster's role in the marine ecosystem is not known, Azam, a distinguished professor of marine microbiology in the Marine Biology Research Division at Scripps, said harmful algal blooms are an important problem and consideration must be given to the fact that red tide dinoflagellates don't exist in isolation from other parts of the marine food web. Bacteria and other parts of the "microbial loop" feed on the organic matter released by the dinoflagellates and in turn the dinoflagellates are known to feed on other cells (including bacteria) when their nutrients run out.  A cell of the dinoflagellate Lingulodinium polyedrum. "The newly identified role of RCA cluster is a good illustration of the need to understand the multifarious mechanisms by which microbes influence the functioning of the marine ecosystems," Azam said. "This type of discovery is helping us understand algal bloom dynamics and the interactions among the components of planktonic ecosystems in ways that we'd imagined but previously lacked evidence," said Franks. The National Oceanic and Atmospheric Administration's ECOHAB (Ecology of Harmful Algal Blooms) program funded the research. # # # Note to broadcast and cable producers: University of California, San Diego provides an on-campus satellite uplink facility for live or pre-recorded television interviews. Please phone or e-mail the media contact listed above to arrange an interview. Scripps Institution of Oceanography, at University of California, San Diego, is one of the oldest, largest and most important centers for global science research and education in the world. The National Research Council has ranked Scripps first in faculty quality among oceanography programs nationwide Now in its second century of discovery, the scientific scope of the institution has grown to include biological, physical, chemical, geological, geophysical and atmospheric studies of the earth as a system. Hundreds of research programs covering a wide range of scientific areas are under way today in 65 countries. The institution has a staff of about 1,300, and annual expenditures of approximately $155 million from federal, state and private sources. Scripps operates one of the largest U.S. academic fleets with four oceanographic research ships and one research platform for worldwide exploration. |
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Cells of blooming dinoflagellates swim in a characteristically corkscrew pattern in a small chamber filmed with a 50-times magnification lens. 
Dinoflagellates incubated with the RCA bacterium are not moving and sink downwards. ContactsRelated LinksShare This Story |
