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The impact of salinity on a saline water insect: contrasting survival and energy budget
Lambret, P.; Janssens, L.; Stoks, R. (2021). The impact of salinity on a saline water insect: contrasting survival and energy budget. J. Insect Physiol. 131: 104224. https://dx.doi.org/10.1016/j.jinsphys.2021.104224
In: Journal of insect physiology. Pergamon Press: London; New York. ISSN 0022-1910; e-ISSN 1879-1611, more
Peer reviewed article  

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Keyword
    Lestes macrostigma
Author keywords
    Cellular Energy Allocation; Energy storage; Lestes macrostigma; Niche selection; Phenoloxidase; Stress

Authors  Top 
  • Lambret, P., more
  • Janssens, L.
  • Stoks, R., more

Abstract
    Water salinity is a major driver of aquatic insects’ distribution. Saline species are usually generalists with high survival and performance at both low and high salinity levels. Yet, costs of high salinity may be underestimated as these are most often measured in terms of larval life history traits, while effects of larval stressors may only be detectable when looking at physiological traits and traits in the adult stage. Here, we assessed the lethal and sublethal physiological effects of embryonic and larval exposure to a range of salinity levels in the damselfly Lestes macrostigma, both during and after metamorphosis. This species inhabits temporary freshwaters where salinity increases during the drying phase. Salinity had no effect on egg hatching success within the range 2–9.5 g/L sea salt (conductivity range 3.45–14.52 mS/cm). With increasing salinity (up to 16 g/L, 23.35 mS/cm), growth rate decreased and larvae took longer to emerge and did so at a smaller size. Larval survival to metamorphosis increased with salinity up to 8 g/L (12.45 mS/cm) and then declined at 16 g/L. Exposure to salinity in the larval stage had no effect across metamorphosis on both the adult thorax muscle mass and flight performance, and the investment in immune function. Increasing salinity in the larval stage also had no effect on the energy available but increased the energy consumption in the adult stage, resulting in a lower net energy budget. These negative sublethal effects of increasing salinity hence bridged metamorphosis and contrasted with the mortality data, suggesting that the higher mortality at the low salinity levels selected for larvae with the best body condition. Our results highlight the importance of taking into account other life-history and physiological traits, besides mortality, ideally across different life stages, to better understand and predict consequences of increasing salinization on freshwater insects.

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