Abstract
Body and head shape among fishes both vary between environments influenced by water velocity and across ontogeny. Although the shape changes associated with variation in average water velocity and ontogeny are well documented, few studies have tested for the interaction between these two variables (i.e., does ontogenetic shape variation differ between velocity environments). We use geometric morphometrics to characterize shape differences in Trichomycterus areolatus, a freshwater catfish found in high and low-velocity environments in Chile. We identify a significant interaction between velocity environment and body size (i.e., ontogeny). Ontogenetic patterns of shape change are consistent with other studies, but velocity environment differentially affects the ontogenetic trajectory of shape development in T. areolatus. Shape change over ontogeny appears more constrained in high-velocity environments compared to low-velocity environments.
Highlights
Morphometric traits in animals and plants are shaped by the selective pressures of their environments resulting in interspecific variation in shape [1,2,3,4]
Ontogenetic shape change in the body was mainly associated with relative warp 1, with minor contributions from relative warps 4, 5, and 6
Fish from the high-velocity environment had a significantly lower magnitude of shape change over ontogeny compared to fish from the low-velocity environment (DHigh = 0.0339, DLow = 0.0494,)
Summary
Morphometric traits in animals and plants are shaped by the selective pressures of their environments resulting in interspecific variation in shape [1,2,3,4]. Shape responds sensitively to environmental pressures such as predation, resource use, competition, temperature, water velocity, and water availability [5,6,7,8,9,10]. Head and body size changed in two Australian snakes (Pseudechis porphyriacus and Dendrelaphis punctulatus) following introduction of a toxic cane toad (Bufo marinus), and head shape changed among species in the Neotropical cichlid genus Geophagus depending on prey availability [11,12]. Examples include differences in head shape in wall lizards (Podarcis bocagei) between saxicolous and ground-dwelling habitats; wing morphology in speckled wood butterflies (Parage aegeria) along a latitudinal gradient; tail, head and ear length in West African Dwarf goats (Capra aegagrus hircus) among agro-ecological zones and swimming performance and shape
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