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The Biological Bulletin, Vol 189, Issue 2 69-76, Copyright © 1995 by Marine Biological Laboratory
RESEARCH NOTES |
G. H. Renninger, L. Kass, R. A. Gleeson, C. L. Van Dover, B-A. Battelle, R. N. Jinks, E. D. Herzog and S. C. Chamberlain
Biophysics Group, Department of Physics, University of Guelph, Guelph, Ontario N1G 2W1, Canada
Organisms dependent on deep-sea hydrothermal vents for their existence face extinction when their vents expire, unless they can establish populations on neighboring vents or on new vent sites. Propagules, including larvae and motile adults, are readily dispersed broadly by seafloor currents, but how they recognize active hydrothermal sites is problematical. Compelling evidence that vent organisms can find and colonize hydrothermal sites has been provided by a series of observations on the East Pacific Rise (1). New hydrothermal vents created there following a volcanic eruption on the seafloor in March 1991 were colonized by sessile invertebrates in less than one year. On the Mid-Atlantic Ridge, shrimp that normally cluster on sulfide surfaces have been observed to swim directly back to the surfaces when displaced from them. How do vent animals locate new or existing vents? Passive transport by currents (2) or active swimming without guidance by some physical cue is not likely to result in success (3). Chemicals present in hydrothermal fluids have been proposed as attractants. We provide the first evidence of a chemosensory response in a vent invertebrate to sulfides, which are prevalent in vent fluids and provide the energy,for chemosynthetic primary production at vents.
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