Integrated Population Genomic Analysis and Numerical Simulation to Estimate Larval Dispersal of Acanthaster cf. solaris Between Ogasawara and Other Japanese Regions

Mizuki Horoiwa,Hiroki Taninaka,Nina Yasuda,Takehiko Itoh,Yosuke Ameda,Takehisa Yamakita,Atsushi Toyoda,Taisei Kikuchi,Takashi Nakamura,Tetsuro Sasaki,Hideaki Yuasa,Rei Kajitani

doi:10.3389/fmars.2021.688139

Abstract

The estimation of larval dispersal on an ecological timescale is significant for conservation of marine species. In 2018, a semi-population outbreak of crown-of-thorns sea star, Acanthaster cf. solaris, was observed on a relatively isolated oceanic island, Ogasawara. The aim of this study was to assess whether this population outbreak was caused by large-scale larval recruitment (termed secondary outbreak) from the Kuroshio region. We estimated larval dispersal of the coral predator A. cf. solaris between the Kuroshio and Ogasawara regions using both population genomic analysis and simulation of oceanographic dispersal. Population genomic analysis revealed overall genetically homogenized patterns among Ogasawara and other Japanese populations, suggesting that the origin of the populations in the two regions is the same. In contrast, a simulation of 26-year oceanographic dispersal indicated that larvae are mostly self-seeded in Ogasawara populations and have difficulty reaching Ogasawara from the Kuroshio region within one generation. However, a connectivity matrix produced by the larval dispersal simulation assuming a Markov chain indicated gradual larval dispersal migration from the Kuroshio region to Ogasawara in a stepping-stone manner over multiple years. These results suggest that the 2018 outbreak was likely the result of self-seeding, including possible inbreeding (as evidenced by clonemate analysis), as large-scale larval dispersal from the Kurishio population to the Ogasawara population within one generation is unlikely. Instead, the population in Ogasawara is basically sustained by self-seedings, and the outbreak in 2018 was also most likely caused by successful self-seedings including possible inbreeding, as evidenced by clonemate analysis. This study also highlighted the importance of using both genomic and oceanographic methods to estimate larval dispersal, which provides significant insight into larval dispersal that occurs on ecological and evolutionary timescales.

Highlights

Many benthic marine invertebrates in coral reef ecosystems exhibit planktonic larval dispersal during their early life histories
Using all single nucleotide polymorphisms (SNPs) options, we obtained a total of 464 SNPs, which were used for all subsequent analyses except for Structure analysis
This study examined larval dispersal of the coral predator A. cf. solaris between the Kuroshio region and Ogasawara using population genomic analysis and oceanographic simulation to test the secondary outbreak hypothesis

Summary

Introduction

Many benthic marine invertebrates in coral reef ecosystems exhibit planktonic larval dispersal during their early life histories. Such larval dispersal connects different populations and forms a meta-population structure (Shanks, 2009). The data obtained by population genetic analysis reflect the biological processes of larval dispersal and recruitment. These results include larval dispersal occurring on an ecological timescale and reflect historical gene flow and genetic breaks caused by past climate change and plate tectonics (Benzie, 1999a; Crandall et al, 2014). It is important to integrate different methods to estimate larval dispersal (Marko and Hart, 2017), few studies have attempted to do so (but see Alberto et al, 2011; Schunter et al, 2011; Nakabayashi et al, 2019; Taninaka et al, 2019)

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