Genetic and phenotypic differentiation of lumpfish (Cyclopterus lumpus) across the North Atlantic: implications for conservation and aquaculture.

Benjamin Alexander Whittaker,Sofia Consuegra,Carlos Garcia De Leaniz

doi:10.7717/peerj.5974

Benjamin Alexander Whittaker, Sofia Consuegra + Show 1 more

Open Access

https://doi.org/10.7717/peerj.5974

Copy DOI

Journal: PeerJ	Publication Date: Nov 20, 2018
Citations: 27	License type: CC BY 4.0

Affiliation: Swansea University

Abstract

Demand for lumpfish (Cyclopterus lumpus) has increased exponentially over the last decade, both for their roe, which is used as a caviar substitute, and increasingly also as cleaner fish to control sea lice in salmon farming. The species is classified as Near Threatened by the IUCN and there are growing concerns that over-exploitation of wild stocks and translocation of hatchery-reared lumpfish may compromise the genetic diversity of native populations. We carried out a comparative analysis of genetic and phenotypic variation across the species’ range to estimate the level of genetic and phenotypic differentiation, and determined patterns of gene flow at spatial scales relevant to management. We found five genetically distinct groups located in the West Atlantic (USA and Canada), Mid Atlantic (Iceland), East Atlantic (Faroe Islands, Ireland, Scotland, Norway and Denmark), English Channel (England) and Baltic Sea (Sweden). Significant phenotypic differences were also found, with Baltic lumpfish growing more slowly, attaining a higher condition factor and maturing at a smaller size than North Atlantic lumpfish. Estimates of effective population size were consistently low across the North East Atlantic (Iceland, Faroe Islands and Norway), the area where most wild lumpfish are fished for their roe, and also for the aquaculture industry. Our study suggests that some lumpfish populations are very small and have low genetic diversity, which makes them particularly vulnerable to over-exploitation and genetic introgression. To protect them we advocate curtailing fishing effort, closing the breeding cycle of the species in captivity to reduce dependence on wild stocks, restricting the translocation of genetically distinct populations, and limiting the risk of farm escapes.

Highlights

The control of parasitic sea-lice (Lepeophtheirus salmonis) is one of the most pressing problems facing salmon farming (Torrissen et al, 2013; Treasurer, 2002), as sea-lice have become resistant to chemical treatment (Aaen et al, 2015; Lees et al, 2008) and threaten the sustainability of the industry
Most lumpfish used in salmon farming are still derived from wild broodstock (Jonassen et al, 2018a), and as they are generally used in a single salmon production cycle (Powell et al, 2018a), satisfying aquaculture demands can put considerable pressure on wild stocks
Our results indicate the existence of significant phenotypic differences across the range, that mimic to some extent the observed genetic differences

Summary

Introduction

The control of parasitic sea-lice (Lepeophtheirus salmonis) is one of the most pressing problems facing salmon farming (Torrissen et al, 2013; Treasurer, 2002), as sea-lice have become resistant to chemical treatment (Aaen et al, 2015; Lees et al, 2008) and threaten the sustainability of the industry. Several species of cleaner fish have been used as an alternative to the use of antiparasitic therapeutants (Treasurer, 2018), but the lumpfish. (Cyclopterus lumpus) is proving the most useful as, in contrast to other cleaner fish like wrasse, it continues to feed on sea lice at low temperatures and is easier to rear in captivity (Imsland et al, 2014; Powell et al, 2018a). Most lumpfish used in salmon farming are still derived from wild broodstock (Jonassen et al, 2018a), and as they are generally used in a single salmon production cycle (Powell et al, 2018a), satisfying aquaculture demands can put considerable pressure on wild stocks

Methods

Discussion

Conclusion