Weaker Plant‐Frugivore Trait Matching Towards the Tropics and on Islands

ABSTRACT Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared...

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Published inEcology letters Vol. 28; no. 1; pp. e70061 - n/a
Main Authors Huang, Xiao, Dalsgaard, Bo, Chen, Si‐Chong
Format Journal Article
LanguageEnglish
Published England Blackwell Publishing Ltd 01.01.2025
John Wiley and Sons Inc
Subjects
Animals
avian frugivore
beak
Beak - anatomy & histology
Biodiversity
biogeography
Biological Evolution
Biotic factors
biotic interaction
Birds
Birds - physiology
coevolution
Continents
co‐evolution
Diet
endozoochory
Feeding Behavior
Flowers & plants
frugivores
Frugivory
Fruit
fruit size
Fruits
Herbivory
Islands
latitude
Matching
Optimal foraging
Plant species
Plants
seed dispersal
Species
species diversity
Synthesis
Tropical Climate
Tropical environments
biotic interaction
endozoochory
avian frugivore
seed dispersal
biogeography
co‐evolution
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Abstract ABSTRACT Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network‐level mean beak size, and with a smaller proportion of fleshy‐fruited species (measured as the proportion of fleshy‐fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co‐evolution between interacting species and optimal foraging for bird species. This study investigates beak‐fruit size matching in frugivory to understand the strength of biotic interactions globally. Analysing 354 avian frugivory networks across different latitudes and insularity, the study finds that beak‐fruit size matching is stronger at higher latitudes and on continents compared to lower latitudes and islands. These results support Darwin's hypothesis that biotic interactions are weaker on islands but challenge Wallace's view that interactions are stronger in the tropics, with implications for ecological and evolutionary theories on global biodiversity patterns.
AbstractList Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network‐level mean beak size, and with a smaller proportion of fleshy‐fruited species (measured as the proportion of fleshy‐fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co‐evolution between interacting species and optimal foraging for bird species.
Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network‐level mean beak size, and with a smaller proportion of fleshy‐fruited species (measured as the proportion of fleshy‐fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co‐evolution between interacting species and optimal foraging for bird species. This study investigates beak‐fruit size matching in frugivory to understand the strength of biotic interactions globally. Analysing 354 avian frugivory networks across different latitudes and insularity, the study finds that beak‐fruit size matching is stronger at higher latitudes and on continents compared to lower latitudes and islands. These results support Darwin's hypothesis that biotic interactions are weaker on islands but challenge Wallace's view that interactions are stronger in the tropics, with implications for ecological and evolutionary theories on global biodiversity patterns.
Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network-level mean beak size, and with a smaller proportion of fleshy-fruited species (measured as the proportion of fleshy-fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co-evolution between interacting species and optimal foraging for bird species.Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network-level mean beak size, and with a smaller proportion of fleshy-fruited species (measured as the proportion of fleshy-fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co-evolution between interacting species and optimal foraging for bird species.
ABSTRACT Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin and Wallace, biologists have debated whether biotic interactions are stronger towards the tropics and on continents, when compared to temperate regions and islands. Here, based on 354 avian frugivory networks accounting for 22,199 interactions between 1247 bird species and 2126 plant species, we quantified trait matching strength, which reflects interaction strength and specificity, across gradients of latitude and insularity globally. We found that matching between beak size and fruit size was significantly stronger towards the poles and on continents, when compared with the tropics and on islands. As underlining ecological factors, trait matching was stronger with a larger proportion of frugivory (measured as the mean proportion of fruits in bird diets) and network‐level mean beak size, and with a smaller proportion of fleshy‐fruited species (measured as the proportion of fleshy‐fruited plant species in the botanical country where the network was located). These findings suggest that the latitudinal and insular patterns in trait matching are driven by biotic factors that may relate to trait co‐evolution between interacting species and optimal foraging for bird species. This study investigates beak‐fruit size matching in frugivory to understand the strength of biotic interactions globally. Analysing 354 avian frugivory networks across different latitudes and insularity, the study finds that beak‐fruit size matching is stronger at higher latitudes and on continents compared to lower latitudes and islands. These results support Darwin's hypothesis that biotic interactions are weaker on islands but challenge Wallace's view that interactions are stronger in the tropics, with implications for ecological and evolutionary theories on global biodiversity patterns.
Author Huang, Xiao
Dalsgaard, Bo
Chen, Si‐Chong
AuthorAffiliation 3 Section for Molecular Ecology and Evolution Globe Institute, University of Copenhagen Copenhagen Denmark
1 State Key Laboratory of Plant Diversity and Specialty Crops, Wuhan Botanical Garden Chinese Academy of Sciences Wuhan China
2 University of Chinese Academy of Sciences Beijing China
4 Millennium Seed Bank Royal Botanic Gardens Kew Wakehurst UK
AuthorAffiliation_xml – name: 2 University of Chinese Academy of Sciences Beijing China
– name: 4 Millennium Seed Bank Royal Botanic Gardens Kew Wakehurst UK
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– name: 1 State Key Laboratory of Plant Diversity and Specialty Crops, Wuhan Botanical Garden Chinese Academy of Sciences Wuhan China
Author_xml – sequence: 1
  givenname: Xiao
  orcidid: 0009-0000-4762-8864
  surname: Huang
  fullname: Huang, Xiao
  organization: University of Chinese Academy of Sciences
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  givenname: Bo
  orcidid: 0000-0003-2867-2805
  surname: Dalsgaard
  fullname: Dalsgaard, Bo
  organization: Globe Institute, University of Copenhagen
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  givenname: Si‐Chong
  orcidid: 0000-0002-6855-2595
  surname: Chen
  fullname: Chen, Si‐Chong
  email: chensichong0528@gmail.com
  organization: Royal Botanic Gardens Kew
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Issue 1
Keywords biotic interaction
endozoochory
avian frugivore
seed dispersal
biogeography
co‐evolution
Language English
License Attribution-NonCommercial
2025 The Author(s). Ecology Letters published by John Wiley & Sons Ltd.
This is an open access article under the terms of the http://creativecommons.org/licenses/by-nc/4.0/ License, which permits use, distribution and reproduction in any medium, provided the original work is properly cited and is not used for commercial purposes.
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Notes Si‐Chong Chen was supported by the National Natural Science Foundation of China (32371612), and the start‐up research grant from Wuhan Botanic Garden (E1559902). BD was supported by Independent Research Fund Denmark (0135‐00333B).
Funding
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Funding: Si‐Chong Chen was supported by the National Natural Science Foundation of China (32371612), and the start‐up research grant from Wuhan Botanic Garden (E1559902). BD was supported by Independent Research Fund Denmark (0135‐00333B).
Editor: Marlee A Tucker
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Snippet ABSTRACT Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity....
Biotic interactions play an important role in species diversification and maintenance and, thus, are regarded as the architecture of biodiversity. Since Darwin...
SourceID pubmedcentral
proquest
pubmed
crossref
wiley
SourceType Open Access Repository
Aggregation Database
Index Database
Publisher
StartPage e70061
SubjectTerms Animals
avian frugivore
beak
Beak - anatomy & histology
Biodiversity
biogeography
Biological Evolution
Biotic factors
biotic interaction
Birds
Birds - physiology
coevolution
Continents
co‐evolution
Diet
endozoochory
Feeding Behavior
Flowers & plants
frugivores
Frugivory
Fruit
fruit size
Fruits
Herbivory
Islands
latitude
Matching
Optimal foraging
Plant species
Plants
seed dispersal
Species
species diversity
Synthesis
Tropical Climate
Tropical environments
Title Weaker Plant‐Frugivore Trait Matching Towards the Tropics and on Islands
URI https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fele.70061
https://www.ncbi.nlm.nih.gov/pubmed/39829283
https://www.proquest.com/docview/3163329761
https://www.proquest.com/docview/3157550544
https://www.proquest.com/docview/3200322022
https://pubmed.ncbi.nlm.nih.gov/PMC11744342
Volume 28
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