Modelling the spatial abundance of a migratory predator A call for transboundary marine protected areas

Aim During their migration, highly mobile species cross multiple jurisdictional boundaries and multiple not‐specific marine protected areas (MPAs). When identifying the critical habitats where individuals aggregate, these areas can be ideal candidates for MPAs. This study was focused on the endanger...

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Published inDiversity & distributions Vol. 25; no. 3; pp. 346 - 360
Main Authors García-Barón, Isabel, Authier, Matthieu, Caballero, Ainhoa, Vázquez, José A., Santos, M. Begoña, Murcia, José Luis, Louzao, Maite
Format Journal Article
LanguageEnglish
Published Oxford John Wiley & Sons Ltd 01.03.2019
John Wiley & Sons, Inc
Subjects
Abundance
Balaenoptera physalus
Baleen whale
BIODIVERSITY RESEARCH
Breeding
Cetacea
critical areas
distance sampling
Marine protected areas
Migration
migratory predator
Migratory species
oceanographic surveys
Polls & surveys
Predictions
Protected areas
Relative abundance
Reliability analysis
Sea surface temperature
Spatial distribution
spatial modelling
Species
Summer
transboundary marine protected areas
Whales
Wildlife conservation
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Summary:Aim During their migration, highly mobile species cross multiple jurisdictional boundaries and multiple not‐specific marine protected areas (MPAs). When identifying the critical habitats where individuals aggregate, these areas can be ideal candidates for MPAs. This study was focused on the endangered fin whale (Balaenoptera physalus) for which there is little knowledge on its distribution and abundance in non‐breeding temperate latitudes. Location Bay of Biscay (BoB). Methods Firstly, we modelled the relative abundance of fin whales by means of generalized additive models (GAMs) using data collected on the PELACUS (2007–2008) and JUVENA (2013–2016) oceanographic surveys during late summer. Secondly, we evaluated the reliability of the predictions by distinguishing environmental extrapolations and interpolations. Finally, we identified critical areas of highest predicted abundance and we assessed whether existing MPAs comprised within the Natura 2000 network and designated for other species offer protection to fin whales in the BoB. Results Fin whales were especially abundant in deep off‐shore waters, mainly associated with intermediate temperature water values in the inner part of the BoB. The years with the highest relative predicted abundances (an average of 1,500 whales) matched with years when warmer sea surface temperature extended into larger areas. In colder years, the average predicted abundance dropped to 400 whales. The main critical area for fin whales (defined by the highest 40% of abundance) was common for both surveys, and it was located in the south‐eastern part of the BoB. Main conclusions Our study contributes to the identification of important concentration areas of fin whales during late summer, based on reliable spatial predictions. The assessment of the current Natura 2000 network highlights the fact that only three MPAs marginally covered the critical area we have identified for fin whales. We propose a transboundary potential MPA to aid the conservation of the species in the BoB.
ISSN:1366-9516
1472-4642
DOI:10.1111/ddi.12877