Abstract
Knowing the relationship between size, morphological traits and swimming performance of fish is essential to understand the swimming capacity to successfully surpass these obstacles and the selective pressure that barriers in rivers and streams could exert on fish. Northern straight-mouth nase, an endemic potamodromous cyprinid fish species from the Northwest of the Iberian Peninsula, was selected to carry out volitionally swimming performance experiments in an open channel against three different flow velocities, using telemetry and video cameras. The use of thin-plate spline, on 10 landmarks, evidenced unknown patterns linked to velocity barriers. At lower flow velocity, size is the main factor explaining the swimming performance; thus, large individuals swim up more efficiently. In contrast, at high flow velocities, shape becomes the essential explanatory variable; thereby, streamlined body shapes with a higher relative position of the tail and a narrower caudal peduncle are more efficient. The obtained results show the existence of a relationship between fish morphology and swimming performance, with potential consequences due to selection pressures associated with velocity barriers and their implications on behavioural and dispersal processes. To sum up, velocity barriers could exert a selection pressure on nase populations, so the fishway design and removal should be (re)considered.
Highlights
Rivers are among the most threatened ecosystems worldwide (Grzybowski & Glinska-Lewczuk, 2019)
We considered a single attempt for each fish per trial, registering the one in which Dmax was reached, since it maximizes swimming capacity
Distance ascent and fatigue time did not differ between the same velocity trials (Dmax: Wilcoxon rank sum test, p [ 0.27; Ft: Wilcoxon rank sum test, p [ 0.41)
Summary
Rivers are among the most threatened ecosystems worldwide (Grzybowski & Glinska-Lewczuk, 2019). Velocity barriers bring about spatio-temporal environmental variation that affects the gene flow and selection (Cooke & Hinch, 2013) This results in a variation in fish migratory behaviour and associated traits within and among individuals, reducing the phenotypic and genetic variance in populations (Tamario et al, 2019). Artificial selection caused by barriers could become underlying force generating this variation, by modifying their dispersal behaviour (Apgar et al, 2017; Branco et al, 2017) This variation may influence the phenotypic and genetic structure of fish populations, as much for upstream movements as for downstream ones (Silva et al, 2018)
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