Physiological dynamics of chemosynthetic symbionts in hydrothermal vent snails
Autor: | Roxanne A. Beinart, Jessica E. Mitchell, Jennifer Delaney, Peter R. Girguis, Corinna Breusing, Sean P. Sylva, Jeffrey S. Seewald |
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Rok vydání: | 2020 |
Předmět: |
0106 biological sciences
Zoology Biology 010603 evolutionary biology 01 natural sciences Microbiology Article 03 medical and health sciences Alviniconcha Hydrothermal Vents Gammaproteobacteria Animals Symbiosis Ecosystem Phylogeny Ecology Evolution Behavior and Systematics 030304 developmental biology Chemosynthesis 0303 health sciences Host (biology) fungi Niche segregation biology.organism_classification Holobiont Metabolism Energy source Hydrothermal vent |
Zdroj: | The ISME Journal |
ISSN: | 1751-7370 1751-7362 |
DOI: | 10.1038/s41396-020-0707-2 |
Popis: | Symbioses between invertebrate animals and chemosynthetic bacteria form the basis of hydrothermal vent ecosystems worldwide. In the Lau Basin, deep-sea vent snails of the genus Alviniconcha associate with either Gammaproteobacteria (A. kojimai, A. strummeri) or Campylobacteria (A. boucheti) that use sulfide and/or hydrogen as energy sources. While the A. boucheti host–symbiont combination (holobiont) dominates at vents with higher concentrations of sulfide and hydrogen, the A. kojimai and A. strummeri holobionts are more abundant at sites with lower concentrations of these reductants. We posit that adaptive differences in symbiont physiology and gene regulation might influence the observed niche partitioning between host taxa. To test this hypothesis, we used high-pressure respirometers to measure symbiont metabolic rates and examine changes in gene expression among holobionts exposed to in situ concentrations of hydrogen (H2: ~25 µM) or hydrogen sulfide (H2S: ~120 µM). The campylobacterial symbiont exhibited the lowest rate of H2S oxidation but the highest rate of H2 oxidation, with fewer transcriptional changes and less carbon fixation relative to the gammaproteobacterial symbionts under each experimental condition. These data reveal potential physiological adaptations among symbiont types, which may account for the observed net differences in metabolic activity and contribute to the observed niche segregation among holobionts. |
Databáze: | OpenAIRE |
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