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Science 19 September 1986:
Vol. 233. no. 4770, pp. 1306 - 1308
DOI: 10.1126/science.233.4770.1306
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Articles

A Methanotrophic Marine Molluscan (Bivalvia, Mytilidae) Symbiosis: Mussels Fueled by Gas

JAMES J. CHILDRESS 1, C. R. FISHER 1, J. M. BROOKS 2, M. C. KENNICUTT II 2, R. BIDIGARE 2, and A. E. ANDERSON 1

1 Oceanic Biology Group, Marine Science Institute, and Department of Biological Science, University of California, Santa Barbara, CA 93106.
2 Department of Oceanography, Texas A&M University, College Station, TX 77843.

An undescribed mussel (family Mytilidae), which lives in the vicinity of hydrocarbon seeps in the Gulf of Mexico, consumes methane (the principal component of natural gas) at a high rate. The methane consumption is limited to the gills of these animals and is apparently due to the abundant intracellular bacteria found there. This demonstrates a methane-based symbiosis between an animal and intracellular bacteria. Methane consumption is dependent on the availability of oxygen and is inhibited by acetylene. The consumption of methane by these mussels is associated with a dramatic increase in oxygen consumption and carbon dioxide production. As the methane consumption of the bivalve can exceed its carbon dioxide production, the symbiosis may be able to entirely satisfy its carbon needs from methane uptake. The very light (dgr13C = -51 to -57 per mil) stable carbon isotope ratios found in this animal support methane (dgr13C = -45 per mil at this site) as the primary carbon source for both the mussels and their symbionts.

Submitted on April 7, 1986
Accepted on June 26, 1986


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