Stable Isotopes (δ13C and δ15N) in Two Depth-Segregated Species of Deep-Sea Gorgonian Octocorals from the Eastern Pacific

Sarah Barnes, Scripps College, Claremont, CA, United States, Branwen Williams, Claremont McKenna-Pitzer-Scripps Colleges, W.M. Keck Science Department, Claremont, CA, United States and Peter John Etnoyer, NOAA, Center for Coastal Environmental Health and Biomolecular Research, Charleston, SC, United States
Abstract:
Found across the world’s oceans and with ages up to hundreds of years, deep-sea gorgonian octocorals represent valuable archives of past oceanic climate change. Similar to the rings of trees, deep-sea gorgonian octocorals form their skeletons in distinct growth increments, and the chemical composition of these growth bands record changes in their environment over time. The ratios of carbon and nitrogen stable isotopes in the sinking particulate organic matter (POM) that the corals feed upon drive the δ13C and δ15N of the organic material in their growth bands. Changes in the coral skeletal δ13C and δ15N therefore reflect changes in surface water nutrient levels and primary productivity. Here, we measured δ13C and δ15N across the growth bands of three Acanthogorgia sp. and two Eugoria rubens specimens collected from the Channel Islands National Marine Sanctuary in California in 2015 to study inter- and intraspecies variability and develop these species as archives of surface water processes. The taxa represent two different depth strata in the Southern California Bight; Acanthogorgia are typically observed 150-400 meters deep, while Eugorgia corals occur in relatively shallower waters between 50-100 meters deep. Results will be interpreted in the context of eastern Pacific POM values and local environmental influences to examine changes in the corals’ food source. Results will also provide information on subsequent alteration of carbon and nitrogen after their incorporation into Acanthogorgia and Eugoria skeletons to aid future study of these corals as proxy records of oceanic climate change.