Barrier Nicolas auteur aut IRD Lengaigne Matthieu auteur aut IRD Rault Jonathan auteur aut IRD Person Renaud auteur aut IRD Ethe C. auteur aut IRD Aumont Olivier auteur aut IRD Maury Olivier auteur aut IRD text journalArticle eng text/pdf born digital access The El Nino/Southern Oscillation is known to strongly impact marine ecosystems and fisheries. In particular, El Nino years are characterized, among other things, by a decrease in tuna catches in the western Pacific and an increase in the central Pacific, whereas these catches accumulate in the far western Pacific during La Nina conditions. However, the processes driving this zonal shift in the tuna catch (changing habitat conditions, currents or food availability) remain unclear. Here, we use an hindcast simulation from the mechanistic ecosystem model APECOSM that reasonably reproduces the observed zonal shift of the epipelagic community in response to ENSO to understand the mechanisms underlying this shift.Although the response of modeled epipelagic communities to El Nino is relatively similar for the different size classes studied, the processes responsible for these changes vary considerably by organism size. One of the major results of our analysis is the critical role of eastward passive transport by El Nino-related surface current anomalies for all size classes. While the effects of passive transport dominate the effects of growth and predation changes for large organisms, this is not the case for intermediate-sized organisms in the western Pacific, where the decrease in biomass is first explained by increased predation and then decreased foraging success. For small organisms, changes in growth rate, induced by the influence of temperature on fish physiology, is an important process that reinforces the biomass increase induced by passive horizontal transport in the eastern Pacific and the biomass decrease induced by increased predation by intermediate -sized organisms near the dateline. Finally, contrary to what is often assumed, our model shows that active habitat-based movements are not required to explain the westward biomass shifts that are observed during ENSO.This study illustrates the relevance of using a mechanistic ecosystem model to disentangle the role of the different processes controlling biomass changes. It highlights the essential dynamic role of ocean currents in shaping the response of marine communities to climate variability and its interaction with biological (e.g. growth) and ecological (e.g. foraging and predation) processes, whose relative importance varies with organisms' size and contribute to modify the community structure. specialized Fish Biomass ENSO El Nino La Nina Ecosystem modeling DEB Advection Growh Predation Equatorial Pacific APECOSM Epipelagic Ecosystem Habitat PACIFIQUE 036 020 032 213 103002 [16 p.] 2023 0079-6611 https://www.documentation.ird.fr/hor/fdi:010087518 10.1016/j.pocean.2023.103002 0079-6611 [F B010087518] https://www.documentation.ird.fr/hor/fdi:010087518 https://www.documentation.ird.fr/intranet/publi/2023-05/010087518.pdf Accès réservé (Intranet de l'IRD) IRD - Base Horizon / Pleins textes 2023-05-12 2025-02-24 fdi:010087518 fre