Physiological responses to estuarine stress gradient affect performance and field distribution of the non-native crustacean Synidotea laticauda

Physiological responses to estuarine stress gradient affect performance and field distribution of the non-native crustacean Synidotea laticauda

Naturalised populations in estuaries are characteristic of non-native species tolerant to the salinity gradient. The non-native isopod Synidotea laticauda, since the first record in 1991 in a European estuary, has been continuously recorded in others (e.g. in 1994 in the Guadalquivir estuary). Possi...

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Bibliographic Details
Published in:Estuarine, coastal and shelf science Vol. 225; p. 106233
Main Authors: Ruiz-Delgado, M.Carmen, González-Ortegón, Enrique, Herrera, Inma, Drake, Pilar, Almón, Bruno, Vilas, César, Baldó, Francisco
Format: Journal Article
Language:English
Published: Elsevier Ltd 30-09-2019
Subjects:
Osmoregulation
Physiological tolerance
Potential respiration rate
Salinity gradient
Survival
Synidotea laticauda
Physiological tolerance
Osmoregulation
Synidotea laticauda
Potential respiration rate
Salinity gradient
Survival
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Summary:Naturalised populations in estuaries are characteristic of non-native species tolerant to the salinity gradient. The non-native isopod Synidotea laticauda, since the first record in 1991 in a European estuary, has been continuously recorded in others (e.g. in 1994 in the Guadalquivir estuary). Possible links between physiology and its successful establishment in the Guadalquivir estuary were explored through the combination of physiological studies and field distribution (7 years). Survival, osmoregulation and potential respiration rate were estimated under different experimental salinity conditions. This non-native species is naturalised, with presence of juveniles and adults during most of the year. Spatial patterns were closely related to the salinity gradient showing the highest densities at its isosmotic point (salinity = 20). Survival experiments showed a high tolerance (survival > 80%) to salinity changes between 5 and 35 and no mortality close to its isosmotic point. In addition, acute salinity changes had a clear effect on the potential respiration rate. Overall, our results suggests that the weak osmoregulatory capacity of S. laticauda determined its salinity-dependent distribution pattern, showing high densities at physiologically more favourable salinities, minimizing the energy required for osmoregulation and therefore its mortality risk. •We explore links between the success establishment and physiology of S. laticauda.•S. laticauda showed a salinity-dependent distribution pattern in the studied estuary.•S. laticauda is a weak osmoregulator with high tolerance to sudden salinity changes.•S. laticauda mainly inhabits the estuarine stretch in which adult's hyperregulated.•We provide insights about the mechanisms underlying naturalization of S. laticuada.
ISSN:0272-7714
1096-0015
DOI:10.1016/j.ecss.2019.05.015