Data from: Exotic flower visitors exploit large floral trait spaces resulting in asymmetric resource partitioning with native visitors
Data files
Jun 13, 2018 version files 591.61 KB
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Kuppler et al. Emission rate of floral volatiles.csv
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Kuppler et al. exploited space overlap of native and exotic flower visitors (single dimensions).xlsx
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Kuppler et al. exploited space size of native and exotic flower visitors (single dimensions).csv
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Kuppler et al. Native and exotic flower-visitor species observed in the study.csv
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Kuppler et al. Native and exotic plant species observed in the study.csv
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Kuppler et al. Native and exotic species exploited space size and overlap (full exploited space).csv
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Kuppler et al. Native and exotic species exploited space size and overlap (Morphology).csv
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Kuppler et al. Native and exotic species exploited space size and overlap (scent).csv
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Kuppler et al. Native and exotic species exploited space size and overlap (weather).csv
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Kuppler et al. Plot descripition.csv
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Abstract
1.Exotic species often cause severe alterations in native communities due to their ability to rapidly and efficiently utilize a broad spectrum of resources. In flower-visitor interactions, the breadth of resource use by native and exotic animals as well as the partitioning of resources among them is often estimated based on the number of (shared) plant species used as resources. However, whether a flower visitor is able to exploit plant resources has been shown to be delimited by functional floral traits such as morphological barriers or attractive or repellent chemical cues. Each of the ecologically relevant traits can be viewed as a dimension of a Hutchinsonian n-dimensional hypervolume, which characterizes the range of phenotypes exploitable by a species.
2.In this study, we quantified the sizes and overlaps of n-dimensional hypervolumes defined by floral traits that are exploitable by native and exotic flower visitors (afterwards referred to as exploited space, ES). In the heavily invaded Hawai'i Volcanoes National Park, USA, we phenotyped 40 native and exotic plant species and recorded flower-visitor interactions. To quantify the size and overlap of ES, we applied dynamic range boxes (dynRB).
3.On average, exotic flower visitors were more generalized in resource use (larger ES) than natives ones, which is additionally indicated by the absence of native flower visitors on exotic flowering plant species. In particular, ES based on floral scent emission was larger for exotic flower visitors compared to native ones. The unevenly expanded ES of native and exotic animals led to an asymmetric overlap of floral ES where the exotic flower visitors shared only a small proportion of their ES with natives but occupied a large proportion of the ES of natives.
4.The asymmetry in resource use of native and exotic flower visitors suggests a potential advantage in resource exploitation of the latter, potentially explaining their success in Hawaiian ecosystems. Predicted range expansion of exotic plant and animal species may further increase the competition for and reduce the availability of resources for native animals. This may lead to further declines of native species and increasing threats for Hawaiian ecosystems.