Current-Oriented Swimming by Jellyfish and Its Role in Bloom Maintenance

S. Fossette; A.C. Gleiss; J. Chalumeau; T. Bastian; C.D. Armstrong; S. Vandenabeele; M. Karpytchev; G.C. Hays

doi:10.1016/j.cub.2014.11.050

Back

Current-Oriented Swimming by Jellyfish and Its Role in Bloom Maintenance

Journal article

Peer reviewed

Current-Oriented Swimming by Jellyfish and Its Role in Bloom Maintenance

S. Fossette, A.C. Gleiss, J. Chalumeau, T. Bastian, C.D. Armstrong, S. Vandenabeele, M. Karpytchev and G.C. Hays

Current Biology, Vol.25(3), pp.342-347

2015

DOI: https://doi.org/10.1016/j.cub.2014.11.050

Files and links (1)

url

Free to Read *No subscription requiredView

Abstract

Cross-flows (winds or currents) affect animal movements [1, 2 and 3]. Animals can temporarily be carried off course or permanently carried away from their preferred habitat by drift depending on their own traveling speed in relation to that of the flow [1]. Animals able to only weakly fly or swim will be the most impacted (e.g., [4]). To circumvent this problem, animals must be able to detect the effects of flow on their movements and respond to it [1 and 2]. Here, we show that a weakly swimming organism, the jellyfish Rhizostoma octopus, can orientate its movements with respect to currents and that this behavior is key to the maintenance of blooms and essential to reduce the probability of stranding. We combined in situ observations with first-time deployment of accelerometers on free-ranging jellyfish and simulated the behavior observed in wild jellyfish within a high-resolution hydrodynamic model. Our results show that jellyfish can actively swim countercurrent in response to current drift, leading to significant life-history benefits, i.e., increased chance of survival and facilitated bloom formation. Current-oriented swimming may be achieved by jellyfish either directly detecting current shear across their body surface [ 5] or indirectly assessing drift direction using other cues (e.g., magnetic, infrasound). Our coupled behavioral-hydrodynamic model provides new evidence that current-oriented swimming contributes to jellyfish being able to form aggregations of hundreds to millions of individuals for up to several months, which may have substantial ecosystem and socioeconomic consequences [ 6 and 7]. It also contributes to improve predictions of jellyfish blooms’ magnitude and movements in coastal waters.

Details

Title: Current-Oriented Swimming by Jellyfish and Its Role in Bloom Maintenance
Authors/Creators: S. Fossette (Author/Creator) - Swansea University
A.C. Gleiss (Author/Creator) - Swansea University
J. Chalumeau (Author/Creator) - La Rochelle Université
T. Bastian (Author/Creator) - Swansea University
C.D. Armstrong (Author/Creator) - Swansea University
S. Vandenabeele (Author/Creator) - Swansea University
M. Karpytchev (Author/Creator) - La Rochelle Université
G.C. Hays (Author/Creator) - Deakin University
Publication Details: Current Biology, Vol.25(3), pp.342-347
Publisher: Elsevier
Identifiers: 991005539592007891
Copyright: © 2015 Elsevier Ltd
Murdoch Affiliation: Murdoch University
Language: English
Resource Type: Journal article

UN Sustainable Development Goals (SDGs)

This output has contributed to the advancement of the following goals:

Source: InCites

Metrics

74 Record Views

88 Times Cited - Web of Science

InCites Highlights

These are selected metrics from InCites Benchmarking & Analytics tool, related to this output

Collaboration types: Domestic collaboration; International collaboration
Citation topics: 3 Agriculture, Environment & Ecology; 3.2 Marine Biology; 3.2.1032 Marine Zooplankton
Web Of Science research areas: Biochemistry & Molecular Biology; Biology; Cell Biology
ESI research areas: Biology & Biochemistry