Abstract:Temperatures regulate metabolism of marine ectotherms and thereby influence development, reproduction, and, as a consequence, dispersal. Despite the importance of water temperatures in the epidemiology of marine diseases, for the parasitic copepod Lepeophtheirus salmonis, the effect of high and low temperatures has not been methodically investigated. Here, we examined the effects of a wide temperature range (3-20°C) on L. salmonis larval development, adult body size, reproductive outputs, and infestation success. Further, we tested if dispersal of salmon lice differed with two temperature-dependent development times to the infective stage (30 and 60 degree-days) using an individual-based dispersal model. Development times followed universal models of temperature dependence described for other marine ectotherms. Water temperatures had a negative relationship with development times, adult body size, and reproductive outputs, except at 3°C, where larvae failed to reach the infective stage and all parameters were decreased, indicating low temperatures are more detrimental than high temperatures. The predictable effect of temperatures on lice development and reproduction will have important applications, such as predicting dispersal and population connectivity, to assist in controlling lice epidemics.Résumé : La température régule le métabolisme des ectothermes marins, influençant ainsi leur développement, leur reproduction et, par conséquent, leur dispersion. Malgré l'importance de la température de l'eau dans l'épidémiologie des maladies marines, pour le copépode parasitique Lepeophtheirus salmonis, l'effet de températures élevées ou basses n'a pas fait l'objet d'un examen méthodique. Nous examinons les effets d'une grande fourchette de températures (3-20°C) sur le développement des larves, la taille du corps des adultes, l'efficacité de la reproduction et le succès des infestations de L. salmonis. Nous vérifions également si la dispersion du pou du poisson est différente pour deux temps de développement dépendant de la température avant le stade infectieux (30 et 60 degrés-jours) en utilisant un modèle de dispersion basé sur l'individu. Les temps de dével-oppement suivent des modèles universels de dépendance de la température décrits pour d'autres ectothermes marins. La température de l'eau est négativement reliée au temps de développement, à la taille du corps des adultes et à l'efficacité de la reproduction, sauf à 3°C, température à laquelle les larves n'atteignent pas le stade infectieux et tous les paramètres diminuent, indiquant que les basses températures sont plus néfastes que les températures élevées. L'effet prévisible de la température sur le développement et la reproduction des poux aura d'importantes applications, notamment dans la prédiction de la dispersion et la connectivité des populations, pour aider à maîtriser les épidémies de poux. [Traduit par la Rédaction]
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Vertical salmon lice behaviour as a response to environmental conditions and its influence on regional dispersion in a fjord system
The salmon louse Lepeophtheirus salmonis is a major parasite of salmon, and is able to travel between farms during its pelagic phases. We investigated the spatial dispersion of L. salmonis planktonic stages in the Hardangerfjord, Norway, using an individual-based model and a fjord circulation model. The models allowed us to investigate how assumptions about swimming responses to environmental cues affect vertical distribution, development and horizontal transport. The rules governing vertical distributions include passive particles remaining fixed at constant depths, but also prescribed responses of active particles to environmental cues such as ambient light level, salinity and temperature. Horizontal dispersion was affected by the vertical distribution scheme (rules) of the particles (each representing an individual planktonic-stage L. salmonis). When particles were held fixed in the surface layer, the horizontal dispersion and the area potentially affected by a source of lice decreased relative to the distribution that was predicted when lice had vertical migration behaviours. The simulations also showed that swimming triggered by both light and temperature may result in a diel migration pattern. If the particles sought out the warmest areas during juvenile stages, development to the infectious stage was reduced by up to 1 d. Better information is required on the actual response of lice to a set of vertical environmental factors to improve predictions of lice dispersal in fjords.
The Norwegian government has decided that the aquaculture industry shall grow, provided that the growth is environmentally sustainable. Sustainability is scored based on the mortality of wild salmonids caused by the parasitic salmon lice. Salmon lice infestation pressure has traditionally been monitored through catching wild sea trout and Arctic char using nets or traps or by trawling after Atlantic salmon postsmolts. However, due to that the Norwegian mainland coastline is nearly 25 000 km, complementary methods that may be used in order to give complete results are needed. We have therefore developed an operational salmon lice model, which calculates the infestation pressure all along the coast in near real-time based on a hydrodynamical ocean model and a salmon lice particle tracking model. The hydrodynamic model generally shows a negative temperature bias and a positive salinity bias compared to observations. The modeled salmon lice dispersion correlates with measured lice on wild salmonids caught using traps or nets. This allows for using two complementary data sources in order to determine the infestation pressure of lice originating from fish farms on wild salmonids, and thereby provide an improved monitoring system for assessing risk and sustainability which forms the basis for knowledge-based advice to management authorities.
Salmon lice dispersion in a northern Norwegian fjord system and the impact of vertical movements
The abundance and distribution of salmon lice Lepeophtheirus salmons originating from fish farms in a northern Norwegian fjord during the summer of 2010 was investigated by means of a numerical model, underpinned by field observations. In order to evaluate the robust-ness of the simulated distribution of the lice, we reran the simulation several times, changing the vertical responses of the lice to environmental cues such as light and turbulence, in addition to altering their vertical swimming velocity. The model was able to realistically reproduce the observed currents and stratification in the region. The simulated distribution of lice was not sensitive to different implementations of surface light nor to the light sensitivity level of the lice. However , the vertical swimming velocity and a mixing parameter influenced both their vertical distribution and horizontal dispersion. The aggregation of lice along land was influenced by their response to turbulent water. The simulated infectious stages of the lice were transported on average 20 to 45 km from their release site. The simulated concentrations of infectious lice varied in synchronisation with lice infestations observed on wild fish in the area. Less than 1% of the simulated lice reached a farm site. The ratio between internal and external exposure ranged from 7 to 57%. Farms in the north of the fjord system were more exposed to lice released in the south than vice versa. KEY WORDS: Salmon lice · Lepeophtheirus salmonis · Dispersion · Fjord · Aquaculture management · IBM · Model
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