SYMBIOTIC ASSIMILATION OF CO₂ IN TWO HYDROTHERMAL VENT ANIMALS, THE MUSSEL BATHYMODIOLUS THERMOPHILUS AND THE TUBE WORM RIFTIA PACHYPTILA

¹ Department of Biology, Woods Hole Oceanographic Institution, Woods Hole, Massachusetts 02543

Shipboard studies showed major differences in the incorporation of CO₂ by the specific prokaryotic symbionts of two deep-sea vent invertebrates. The rate of CO₂ fixation was optimal at approximately 22° C in fresh trophosome material from the pogonophoran tube worm Riftia pachyptila. Sulfide, but not thiosulfate, served as the electron donor. Thirty-five percent of the aerobic rate remained in deoxygenated samples presumably due to traces of hemoglobin-bound oxygen. Gill preparations from the mytilid mussel Bathymodiolus thermophilus, however, assimilated CO₂ with a maximum rate at 12° to 15° C. Thiosulfate, but not sulfide, served as the electron donor. The activity was completely inhibited in deoxygenated samples. These metabolic dissimilarities between the symbionts of the two hosts extend to DNA base ratios and cell sizes. Partial fractionation of the mussel gill preparation yielded a prokaryotic or "bacterial" fraction that showed a CO₂ assimilation rate three-fold higher than that of the crude homogenate. This activity was not affected by the in situ hydrostatic pressure of 250 atm (100% barotolerance). The mussel gill symbiont represents the first sulfur-oxidizing vent prokaryote with psychrophilic growth characteristics. The natural distribution of R. pachyptila and B. thermophilus within the physico-chemical regime ofthe immediate vent vicinity corresponds well with the metabolic differences of their symbionts.

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