OS13A-2018
Population-Level Transcriptomic Responses of the Southern Ocean Salp Salpa thompsoni to Environment Variability of the Western Antarctic Peninsula Region

Monday, 14 December 2015
Poster Hall (Moscone South)
Ann C Bucklin, University of Connecticut, Marine Sciences, Groton, CT, United States, Paola G Batta Lona, CICESE National Center for Scientific Research and Higher Education of Mexico, Departamento de Biotecnologia Marina, Ensenada, Mexico, Amy E. Maas, Bermuda Institute of Ocean Sciences, St. George's, Bermuda, Rachel J O'Neill, University of Connecticut, Center for Genome Innovation and Department of Molecular and Cell Biology, Storrs, CT, United States and Peter H Wiebe, Woods Hole Oceanographic Inst, Woods Hole, MA, United States
Abstract:
In response to the changing Antarctic climate, the Southern Ocean salp Salpa thompsoni has shown altered patterns of distribution and abundance that are anticipated to have profound impacts on pelagic food webs and ecosystem dynamics. The physiological and molecular processes that underlay ecological function and biogeographical distribution are key to understanding present-day dynamics and predicting future trajectories. This study examined transcriptome-wide patterns of gene expression in relation to biological and physical oceanographic conditions in coastal, shelf and offshore waters of the Western Antarctic Peninsula (WAP) region during austral spring and summer 2011. Based on field observations and collections, seasonal changes in the distribution and abundance of salps of different life stages were associated with differences in water mass structure of the WAP. Our observations are consistent with previous suggestions that bathymetry and currents in Bransfield Strait could generate a retentive cell for an overwintering population of S. thompsoni, which may generate the characteristic salp blooms found throughout the region later in summer. The statistical analysis of transcriptome-wide patterns of gene expression revealed differences among salps collected in different seasons and from different habitats (i.e., coastal versus offshore) in the WAP. Gene expression patterns also clustered by station in austral spring – but not summer – collections, suggesting stronger heterogeneity of environmental conditions. During the summer, differentially expressed genes covered a wider range of functions, including those associated with stress responses. Future research using novel molecular transcriptomic / genomic characterization of S. thompsoni will allow more complete understanding of individual-, population-, and species-level responses to environmental variability and prediction of future dynamics of Southern Ocean food webs and ecosystems.