Understanding age-specific dispersal in fishes through hydrodynamic modelling, genetic simulations and microsatellite DNA analysis

Authors

Oliver Berry, Commonwealth Scientific and Industrial Research Organisation, Western AustraliaFollow
Phillip England, Commonwealth Scientific and Industrial Research Organisation, Tasmania
Ross J. Marriott, Department of Fisheries, Western Australia
Christopher P. Burridge, Commonwealth Scientific and Industrial Research Organisation, Western Australia
Stephen J. Newman, Department of Fisheries, Western AustraliaFollow

Document Type

Article

Publication Date

3-15-2012

Journal Title

Molecular Ecology

ISSN

Print: 0962-1083 Electronic: 1365-294X

Keywords

Dispersal, Fish, Hydrodynamic model, Microsatellite

Disciplines

Aquaculture and Fisheries | Behavior and Ethology | Genetics | Natural Resources and Conservation | Population Biology

Abstract

Many marine species have vastly different capacities for dispersal during larval, juvenile and adult life stages, and this has the potential to complicate the identification of population boundaries and the implementation of effective management strategies such as marine protected areas. Genetic studies of population structure and dispersal rarely disentangle these differences and usually provide only lifetime-averaged information that can be considered by managers. We address this limitation by combining age-specific autocorrelation analysis of microsatellite genotypes, hydrodynamic modelling and genetic simulations to reveal changes in the extent of dispersal during the lifetime of a marine fish. We focus on an exploited coral reef species, Lethrinus nebulosus, which has a circum-tropical distribution and is a key component of a multispecies fishery in northwestern Australia. Conventional population genetic analyses revealed extensive gene flow in this species over vast distances (up to 1500 km). Yet, when realistic adult dispersal behaviours were modelled, they could not account for these observations, implying adult dispersal does not dominate gene flow. Instead, hydrodynamic modelling showed that larval L. nebulosus are likely to be transported hundreds of kilometres, easily accounting for the observed gene flow. Despite the vast scale of larval transport, juvenile L. nebulosus exhibited fine-scale genetic autocorrelation, which declined with age. This implies both larval cohesion and extremely limited juvenile dispersal prior to maturity. The multidisciplinary approach adopted in this study provides a uniquely comprehensive insight into spatial processes in this marine fish.

Recommended Citation

BERRY, O., ENGLAND, P., MARRIOTT, R.J., BURRIDGE, C.P. and NEWMAN, S.J. (2012), Understanding age-specific dispersal in fishes through hydrodynamic modelling, genetic simulations and microsatellite DNA analysis. Molecular Ecology, 21: 2145-2159. https://doi.org/10.1111/j.1365-294X.2012.05520.x