Abstract
Biotic‐environment interactions have long been considered an important factor in functional phenotype differentiation in organisms. The differentiation processes determining functional phenotypes can reveal important mechanisms yielding differences in specific functions of animal traits in the ecosystem. In the present study, we examined functional morphological variations in relation to increasing geographic altitude. Six fish species were examined for how environment factors affect intra‐specific functional morphology in the subtropical Pearl River in southern China. Functional morphology traits revealed variable effects due to geographic elevation, although spatial autocorrelation existed among the species tested. The results showed that high‐elevation individuals had a more narrow‐bodied morphology, with more flexible maneuvrability when swimming, and more evenly distributed musculature than low‐elevation individuals. Low‐elevation individuals preyed upon larger food sources than high‐elevation individuals in some species. Fish functional morphology was strongly affected by regional environmental factors (such as elevation and water temperature) and physical characteristics of local rivers (such as flow velocity, river fractals, and coefficients of fluvial facies). In addition, the effects of the regional factors were stronger than those of the local factors in the Pearl River. Furthermore, it was found that morphological traits associated with locomotion were primarily effected by the river's physical characteristics. While morphological traits associated with food acquisition were primarily affected by water chemical factors (such as DO, water clarity, NH 4‐N concentration, and TDS). These results demonstrated that habitat has an influence on the biological morphology of fish species, which further affects the functioning of the organism within the ecosystem.
Highlights
The aim of eco‐morphological research was to understand the re‐ sponses of organisms’ morphological characteristics to their habitat characteristics across individuals, populations, and species (Motta, Norton, & Luczkovich, 1995; Wainwright, 1991; Wikramanayake, 1990)
It is becoming accepted that a focus on functional morphology as it relates to environmental gradients could be used to identify general patterns of variation and make better predictions of the responses of natural communities to environmental changes (Olden, Jackson, & Peres‐Neto, 2002; Pease, González‐Díaz, Rodiles‐ Hernández, & Winemiller, 2012)
Functional morphology traits as‐ sociated with food acquisition were primarily ef‐ fected by water chemical factors, such as water clarity, DO, NH4–N concentration, and TDS
Summary
The aim of eco‐morphological research was to understand the re‐ sponses of organisms’ morphological characteristics to their habitat characteristics across individuals, populations, and species (Motta, Norton, & Luczkovich, 1995; Wainwright, 1991; Wikramanayake, 1990). It has subsequently been shown that mor‐ phological differences can result from phenotypic plasticity, where habitat variables directly influence the phenotype of an organism (Bears, Drever, & Martin, 2008; Pigliucci, 2005) Another group of species that has been well studied is freshwa‐ ter fish (Chapman et al, 2015). Later studies revealed that several ecological characteristics of freshwater fish species are linked with morphology variations in the bodies of freshwater fish species (Blanck, Tedesco, & Lamouroux, 2007; Gatz, 1979; Webb, 1984) These characteristics mainly include predation (Brönmark & Miner, 1992) and habitat use (Leal, Junqueira, & Pompeu, 2011). The present study allowed for prediction of how patterns of functional morphology of fish respond to the patterns of habitat gradients
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