Abstract
Few studies have evaluated phenotypic plasticity at the community level, considering, for example, plastic responses in an entire species assemblage. In addition, none of these studies have addressed the relationship between phenotypic plasticity and community structure. Within this context, here we assessed the magnitude of seasonal changes in digestive traits (seasonal flexibility), and of changes during short-term fasting (flexibility during fasting), occurring in an entire fish assemblage, comprising ten species, four trophic levels, and a 37-fold range in body mass. In addition, we analyzed the relationship between estimates of digestive flexibility and three basic assemblage structure attributes, i.e., species trophic position, body size, and relative abundance. We found that: (1) Seasonal digestive flexibility was not related with species trophic position or with body size; (2) Digestive flexibility during fasting tended to be inversely correlated with body size, as expected from scaling relationships; (3) Digestive flexibility, both seasonal and during fasting, was positively correlated with species relative abundance. In conclusion, the present study identified two trends in digestive flexibility in relation to assemblage structure, which represents an encouraging departure point in the search of general patterns in phenotypic plasticity at the local community scale.
Highlights
Phenotypic plasticity refers to changes in organisms’ traits due to changes in internal or external environmental conditions [1]
We found that: (1) Species trophic position was not correlated with seasonal flexibility for any morphometric variable (Table 5); (2) Species standard length was
Phenotypic plasticity has been suggested as the main mechanism for species persistence under a global environmental change scenario [5,6,7,8,9,10]
Summary
Phenotypic plasticity refers to changes in organisms’ traits due to changes in internal or external environmental conditions [1]. These adjustments could imply different kinds of phenotypic traits, from gene expression to life-history, and they usually constitute adaptations to cope with environmental variability [2,3,4]. To our knowledge, none of these studies have addressed the relationship between phenotypic plasticity and community structure This gap in current knowledge is relevant since the ultimate effect of all those factors associated with global environmental change will depend on processes and phenomena occurring at the local community scale [18,19]
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