Distinctive stable isotope ratios in important zooplankton species in relation to estuarine salinity gradients: Potential tracer of fish migration

To assess the potential of stable isotope ratios as an indicator of fish migration within estuaries, stable isotope ratios in important zooplankton species were analyzed in relation to estuarine salinity gradients. Gut contents from migratory juveniles of the euryhaline marine fish Lateolabrax japonicus were examined along the Chikugo River estuary of the Ariake Sea, which has the most developed estuarine turbidity maximum (ETM) in Japan. Early juveniles in March and April preyed primarily on two copepod species; Sinocalanus sinensis at lower salinities and Acartia omorii at higher salinities. Late juveniles (standard length > 40 mm) at lower salinities preyed exclusively on the mysid Acanthomysis longirostris until July and complementarily on the decapod Acetes japonicus in August. These prey species were collected along the estuary during the springesummer seasons of 2003 and 2004, and their carbon and nitrogen stable isotope ratios (d13C and d15N) were evaluated. The d13C values of prey species were distinct from each other and were primarily depleted within and in close proximity to the ETM (salinity < 10); S. sinensis ( 26.6&) < Acanthomysis longirostris ( 23.3&) < Acartia omorii ( 21.1&) < Acetes japonicus ( 18.5&). The overall gradient of d13C with salinity occurred for all prey species and showed minor temporal fluctuations, while it was not directly influenced by the d13C values in particulate organic matter along the estuary. In contrast to d13C, the d15N values of prey species did not exhibit any clear relationship with salinity. The present study demonstrated that d13C has the potential for application as a tracer of fish migration into lower salinity areas including the ETM.