Seascape genomics reveals fine‐scale patterns of dispersal for a reef fish along the ecologically divergent coast of Northwestern Australia

• Published in: Molecular ecology Vol. 26; no. 22; pp. 6206 - 6223
• Main Authors: DiBattista, Joseph D., Travers, Michael J., Moore, Glenn I., Evans, Richard D., Newman, Stephen J., Feng, Ming, Moyle, Samuel D., Gorton, Rebecca J., Saunders, Thor, Berry, Oliver
• Format: Journal Article
• Language: English
• Published: England Blackwell Publishing Ltd 01.11.2017
• Subjects: Animal Distribution; Animals; Australia; biodiversity; Canning; Cluster Analysis; Coastal waters; Coasts; Computational fluid dynamics; Computer Simulation; coral reef; Coral Reefs; DArTseq; Dispersal; Dispersion; Environmental conditions; environmental gradients; Fluid flow; Gene polymorphism; Genetic structure; Genetics, Population; Genomics; Genotype; Geography; Hydrodynamics; Kimberley; Lutjanus carponotatus; marine; Marine ecology; Marine resources; Models, Genetic; Oceans; Perciformes - genetics; Polymorphism; Polymorphism, Single Nucleotide; Population Dynamics; Population genetics; Reef fish; Resource management; Shallow water; Single-nucleotide polymorphism; Taxa; Tidal currents; Tidal range; Water Movements; Australia; DArTseq; biodiversity; coral reef; Kimberley; environmental gradients; marine
• ISSN: 0962-1083; 1365-294X
• DOI: 10.1111/mec.14352

Understanding the drivers of dispersal among populations is a central topic in marine ecology and fundamental for spatially explicit management of marine resources. The extensive coast of Northwestern Australia provides an emerging frontier for implementing new genomic tools to comparatively identify patterns of dispersal across diverse and extreme environmental conditions. Here, we focused on the stripey snapper (Lutjanus carponotatus), which is important to recreational, charter‐based and customary fishers throughout the Indo‐West Pacific. We collected 1,016 L. carponotatus samples at 51 locations in the coastal waters of Northwestern Australia ranging from the Northern Territory to Shark Bay and adopted a genotype‐by‐sequencing approach to test whether realized connectivity (via larval dispersal) was related to extreme gradients in coastal hydrodynamics. Hydrodynamic simulations using CONNIE and a more detailed treatment in the Kimberley Bioregion provided null models for comparison. Based on 4,402 polymorphic single nucleotide polymorphism loci shared across all individuals, we demonstrated significant genetic subdivision between the Shark Bay Bioregion in the south and all locations within the remaining, more northern bioregions. More importantly, we identified a zone of admixture spanning a distance of 180 km at the border of the Kimberley and Canning bioregions, including the Buccaneer Archipelago and adjacent waters, which collectively experiences the largest tropical tidal range and some of the fastest tidal currents in the world. Further testing of the generality of this admixture zone in other shallow water species across broader geographic ranges will be critical for our understanding of the population dynamics and genetic structure of marine taxa in our tropical oceans.