Habitat partitioning in Antarctic krill: Spawning hotspots and nursery areas.

Sévrine F Sailley,Cathy H Lucas,Simeon L Hill,Angus Atkinson,Frances A Perry,Erik V Thuesen,Daniel J Mayor,Geraint A Tarling

doi:10.1371/journal.pone.0219325

Sévrine F Sailley, Cathy H Lucas + Show 6 more

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https://doi.org/10.1371/journal.pone.0219325

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Abstract

Antarctic krill, Euphausia superba, have a circumpolar distribution but are concentrated within the south-west Atlantic sector, where they support a unique food web and a commercial fishery. Within this sector, our first goal was to produce quantitative distribution maps of all six ontogenetic life stages of krill (eggs, nauplii plus metanauplii, calyptopes, furcilia, juveniles, and adults), based on a compilation of all available post 1970s data. Using these maps, we then examined firstly whether “hotspots” of egg production and early stage nursery occurred, and secondly whether the available habitat was partitioned between the successive life stages during the austral summer and autumn, when krill densities can be high. To address these questions, we compiled larval krill density records and extracted data spanning 41 years (1976–2016) from the existing KRILLBASE-abundance and KRILLBASE-length-frequency databases. Although adult males and females of spawning age were widely distributed, the distribution of eggs, nauplii and metanauplii indicates that spawning is most intense over the shelf and shelf slope. This contrasts with the distributions of calyptope and furcilia larvae, which were concentrated further offshore, mainly in the Southern Scotia Sea. Juveniles, however, were strongly concentrated over shelves along the Scotia Arc. Simple environmental analyses based on water depth and mean water temperature suggest that krill associate with different habitats over the course of their life cycle. From the early to late part of the austral season, juvenile distribution moves from ocean to shelf, opposite in direction to that for adults. Such habitat partitioning may reduce intraspecific competition for food, which has been suggested to occur when densities are exceptionally high during years of strong recruitment. It also prevents any potential cannibalism by adults on younger stages. Understanding the location of krill spawning and juvenile development in relation to potentially overlapping fishing activities is needed to protect the health of the south-west Atlantic sector ecosystem.

Highlights

Antarctic krill (Euphausia superba), hereafter “krill”, provide a key link between primary production and a suite of predator species [1,2,3,4]
The first circumpolar distribution maps of krill were compiled from data collected during the Discovery Investigations during the 1920s and 1930s which have been been fundamental to our understanding of krill [16,17]
KRILLBASE-length-frequency Held at the UK Polar Data Centre at the British Antarctic Survey, Cambridge [6]

Summary

Introduction

Antarctic krill (Euphausia superba), hereafter “krill”, provide a key link between primary production and a suite of predator species [1,2,3,4]. Krill are an important grazer species in the Southern Ocean [5] with an estimated biomass of between 300 and 500 million tonnes [6] Their importance in the diets of vertebrate predators is well documented [7] with populations of penguins, whales, seals, and albatrosses all exhibiting a dependence on krill [8,9,10,11]. The first circumpolar distribution maps of krill were compiled from data collected during the Discovery Investigations during the 1920s and 1930s which have been been fundamental to our understanding of krill [16,17] These maps revealed that the circumpolar distribution is assymetric, with higher concentrations in the south-west Atlantic, the sector where the current fishery operates. More recent studies have added further detail, showing that the sector 0o-90oW contains 70% of the total stock [18]

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