TY - JOUR
T1 - Similarity of stream insect trait profiles across biogeographic regions
AU - Kunz, Stefan
AU - Kefford, Ben J.
AU - Usseglio-Polatera, Philippe
AU - Hawkins, Charles P.
AU - Poff, N. Le Roy
AU - Akamagwuna, Frank
AU - Odume, Nelson
AU - Schmidt-Kloiber, Astrid
AU - Graf, Wolfram
AU - Metzeling, Leon
AU - Matthaei, Christoph D.
AU - Phillips, Ngaire
AU - Schäfer, Ralf B.
N1 - Funding Information:
We thank Luic Damien for supporting the analysis of the comparison of trait composition between climatic regions in Europe and Verena Schreiner for discussing and reviewing the trait data. Funding was provided by the German Research Society (DFG, project number 338785727).
Publisher Copyright:
© 2024 The Authors. Diversity and Distributions published by John Wiley & Sons Ltd.
PY - 2024/4
Y1 - 2024/4
N2 - Aim: Habitat templet theory predicts that the functional niches of species evolved in response to selection pressures imposed by each species' spatial–temporal environment. Consequently, similar environmental conditions should lead to convergence in the biological trait composition of biogeographically independent assemblages. Given their high diversity and ubiquitous occurrence, stream insects represent an ideal group to test convergence. Such an analysis should provide insight into both how spatially variable stream insect traits are and how transferable trait–environment relationships are across large spatial scales. We tested two hypotheses: (1) functional niches of stream insects are similar across Australia, Europe, North America, New Zealand and Southern Africa, and (2) the variability in trait profiles of stream insects is positively related to climatic variability within regions. Location: Australia, Europe, North America, New Zealand and Southern Africa. Methods: We used trait datasets from each region to compare functional niches and to delineate groups of insects with similar trait profiles (hereafter, trait profile groups or TPGs) in each region. We identified the traits most important in separating TPGs. Finally, we assessed if trait profile variability between TPGs was associated with climatic variability within each region. Results: We found that functional niches of families largely overlapped across the regions examined, except for partial deviations of some Australian families, but that only two trait combinations characterized TPGs across all regions. Feeding mode and respiration traits consistently drove the separation of families into TPGs. The variability of trait profiles slightly increased with increasing climatic variability. Main Conclusions: Although our study did not allow to demonstrate mechanisms, it is the first to show large similarities between stream insect functional niches across different biogeographic regions, which might be an indication of their convergence. An important factor shaping stream insect assemblages over these large scales might be climate, indicated by the higher trait profile variation in regions with more diverse climates.
AB - Aim: Habitat templet theory predicts that the functional niches of species evolved in response to selection pressures imposed by each species' spatial–temporal environment. Consequently, similar environmental conditions should lead to convergence in the biological trait composition of biogeographically independent assemblages. Given their high diversity and ubiquitous occurrence, stream insects represent an ideal group to test convergence. Such an analysis should provide insight into both how spatially variable stream insect traits are and how transferable trait–environment relationships are across large spatial scales. We tested two hypotheses: (1) functional niches of stream insects are similar across Australia, Europe, North America, New Zealand and Southern Africa, and (2) the variability in trait profiles of stream insects is positively related to climatic variability within regions. Location: Australia, Europe, North America, New Zealand and Southern Africa. Methods: We used trait datasets from each region to compare functional niches and to delineate groups of insects with similar trait profiles (hereafter, trait profile groups or TPGs) in each region. We identified the traits most important in separating TPGs. Finally, we assessed if trait profile variability between TPGs was associated with climatic variability within each region. Results: We found that functional niches of families largely overlapped across the regions examined, except for partial deviations of some Australian families, but that only two trait combinations characterized TPGs across all regions. Feeding mode and respiration traits consistently drove the separation of families into TPGs. The variability of trait profiles slightly increased with increasing climatic variability. Main Conclusions: Although our study did not allow to demonstrate mechanisms, it is the first to show large similarities between stream insect functional niches across different biogeographic regions, which might be an indication of their convergence. An important factor shaping stream insect assemblages over these large scales might be climate, indicated by the higher trait profile variation in regions with more diverse climates.
KW - large-scale comparison
KW - stream insect traits
KW - trait convergence
UR - http://www.scopus.com/inward/record.url?scp=85182250101&partnerID=8YFLogxK
U2 - 10.1111/ddi.13812
DO - 10.1111/ddi.13812
M3 - Article
AN - SCOPUS:85182250101
SN - 1366-9516
VL - 30
SP - 1
EP - 17
JO - Diversity and Distributions
JF - Diversity and Distributions
IS - 4
M1 - e13812
ER -