Hyperiid amphipods from the Gulf of Ulloa and offshore region, Baja California: The possible role of the gelatinous zooplankton as a transport vector into the coastal shelf waters

Lavaniegos, Bertha E.

doi:10.1371/journal.pone.0233071

Cited by 2 publications

(1 citation statement)

References 60 publications

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“…Correspondingly, most of our samples were from late spring/early summer. Hyperiids will also remain below the mixed layer during both day and night, feeding on copepods and other zooplankton [50], which could account for a similar uniform structure across later eddy life stages with some exceptions that could be attributed to differences in the movement patterns of gelatinous zooplankton hosts used by hyperiids [51]. Notably, small copepods in anticyclonic eddies persisted at the eddy core relative to the eddy edge in later life stages when other zooplankton like large copepods and hyperiids exhibited declines in abundance.…”

Section: Discussionmentioning

confidence: 99%

Food or physics: plankton communities structured across Gulf of Alaska eddies

Kroeger

Gentemann

García‐Reyes

et al. 2021

Preprint

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Oceanic features, such as mesoscale eddies that entrap and transport water masses, create heterogeneous seascapes to which biological communities may respond. To date, however, our understanding of how internal eddy dynamics influence plankton community structuring is limited by sparse sampling of eddies and their associated biotic communities. In this paper, we used 10 years of archived Continuous Plankton Recorder (CPR) data (2002-2013) associated with 9 mesoscale eddies in the Northeast Pacific/Gulf of Alaska to test the hypothesis that eddy origin and rotational direction determines the structure and dynamics of entrained plankton communities. Using generalized additive models and accounting for confounding factors (e.g., timing of sampling), we found peak diatom abundance within both cyclonic and anticyclonic eddies near the eddy edge. Zooplankton abundances, however, varied with distance to the eddy center/edge by rotational type and eddy life stage, and differed by taxonomic group. For example, the greatest abundance of small copepods was found near the center of anticyclonic eddies during eddy maturation and decay, but near the edge of cyclonic eddies during eddy formation and intensification. Distributions of copepod abundances across eddy surfaces were not mediated by phytoplankton distribution. Our results therefore suggest that physical mechanisms such as internal eddy dynamics exert a direct impact on the structure of zooplankton communities rather than indirect mechanisms involving potential food resources.

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Section: Discussionmentioning

confidence: 99%