Abstract
Migratory organisms have their own life histories that efficiently link multiple ecosystems. Therefore, comprehensive understanding of migration ecologies of these organisms is essential for both species conservation and ecosystem management. However, monitoring migration at fine spatiotemporal scales, especially in open marine systems, often requires huge costs and effort. Recently, environmental DNA (eDNA) techniques that utilize DNA released from living organisms into their environment became available for monitoring wild animals without direct handling. In this study, we conducted an eDNA survey for understanding marine migration of an endemic fish species, Shishamo smelt (Spirinchus lanceolatus). We examined 1) seasonal habitat changes in coastal regions and 2) environmental factors potentially driving the migration of this species. The eDNA concentrations along a 100 km-long coastline exhibited spatiotemporal variation, suggesting that this species shifts their habitat away from nearshore areas between spring and summer. We also found a significantly negative association between the eDNA concentration and sea surface temperature. That finding suggests that the offshore migration of this species is associated with increased sea surface temperature. This study reveals new aspects of S. lanceolatus life history in coastal regions. Together with our previous eDNA study on the freshwater migration of S. lanceolatus, this study illustrates the potential of eDNA techniques for understanding the whole life history of this migratory species.
Highlights
IntroductionTheir life-history strategies determine the fate of individuals and influence structures and dynamics of populations, communities, and ecosystems [1]
We evaluated the relationships between Environmental DNA (eDNA) concentrations and environmental factors using generalized linear mixed models (GLMMs) with negative binomial distribution
The eDNA shed by S. lanceolatus was detected in 73 out of the 98 seawater samples (Fig 2A)
Summary
Their life-history strategies determine the fate of individuals and influence structures and dynamics of populations, communities, and ecosystems [1]. Anadromous fishes migrate between saltwater and freshwater to complete their life cycles These large-scale migrations sustain ecosystem structures and functions through food webs and by transporting marine-derived nutrients to riparian zones [2,3,4]. Because such migrations can be the key to maintaining community dynamics and ecosystem functions, proper monitoring of fish migration is essential for both species conservation and ecosystem management.
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