Global change and species interactions in terrestrial ecosystems

The main drivers of global environmental change (CO₂ enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among spec...

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Bibliographic Details
Published inEcology letters Vol. 11; no. 12; pp. 1351 - 1363
Main Authors Tylianakis, Jason M, Didham, Raphael K, Bascompte, Jordi, Wardle, David A
Format Journal Article
LanguageEnglish
Published Oxford, UK Oxford, UK : Blackwell Publishing Ltd 01.12.2008
Blackwell Publishing Ltd
Blackwell
Subjects
Animal and plant ecology
Animal, plant and microbial ecology
Animals
Biodiversity
Biological and medical sciences
Carbon dioxide
Climate change
Climatology. Bioclimatology. Climate change
CO
CO2
Comparative studies
competition
Data analysis
disease
Earth, ocean, space
Ecology
Ecosystem
Environmental changes
Exact sciences and technology
External geophysics
Food Chain
food web
Fundamental and applied biological sciences. Psychology
General aspects
global warming
Greenhouse Effect
Health and Pathology
Herbivory
interaction effect
Invasions
Land use
land-use change
Meteorology
mycorrhiza
mycorrhizae
Nitrogen
nitrogen deposition
parasite
parasites
Pathogens
Plant Physiological Phenomena
pollination
Predictions
seed dispersal
Symbiosis - physiology
Terrestrial ecosystems
Competition
Modification
Disease
Carbon dioxide
CO2
land-use change
Food web
seed dispersal
Ecosystem
Planetary scale
Terrestrial environment
Warming
Atmospheric fallout
pollination
Interaction
nitrogen deposition
interaction effect
Symbiont
Land use
Dynamical climatology
Climate change
parasite
global warming
Global change
Mycorrhiza
Interspecific relation
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Abstract The main drivers of global environmental change (CO₂ enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
AbstractList The main drivers of global environmental change (CO2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
The main drivers of global environmental change (CO sub(2) enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
The main drivers of global environmental change (CO2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.The main drivers of global environmental change (CO2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
The main drivers of global environmental change (CO₂ enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
The main drivers of global environmental change (CO2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions. [PUBLICATION ABSTRACT]
The main drivers of global environmental change (CO 2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter species distributions, and recent evidence shows that they exert pervasive impacts on various antagonistic and mutualistic interactions among species. In this review, we synthesize data from 688 published studies to show that these drivers often alter competitive interactions among plants and animals, exert multitrophic effects on the decomposer food web, increase intensity of pathogen infection, weaken mutualisms involving plants, and enhance herbivory while having variable effects on predation. A recurrent finding is that there is substantial variability among studies in both the magnitude and direction of effects of any given GEC driver on any given type of biotic interaction. Further, we show that higher order effects among multiple drivers acting simultaneously create challenges in predicting future responses to global environmental change, and that extrapolating these complex impacts across entire networks of species interactions yields unanticipated effects on ecosystems. Finally, we conclude that in order to reliably predict the effects of GEC on community and ecosystem processes, the greatest single challenge will be to determine how biotic and abiotic context alters the direction and magnitude of GEC effects on biotic interactions.
Author Didham, Raphael K.
Bascompte, Jordi
Tylianakis, Jason M.
Wardle, David A.
Author_xml – sequence: 1
  fullname: Tylianakis, Jason M
– sequence: 2
  fullname: Didham, Raphael K
– sequence: 3
  fullname: Bascompte, Jordi
– sequence: 4
  fullname: Wardle, David A
BackLink http://pascal-francis.inist.fr/vibad/index.php?action=getRecordDetail&idt=20877238$$DView record in Pascal Francis
https://www.ncbi.nlm.nih.gov/pubmed/19062363$$D View this record in MEDLINE/PubMed
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Issue 12
Keywords Competition
Modification
Disease
Carbon dioxide
CO2
land-use change
Food web
seed dispersal
Ecosystem
Planetary scale
Terrestrial environment
Warming
Atmospheric fallout
pollination
Interaction
nitrogen deposition
interaction effect
Symbiont
Land use
Dynamical climatology
Climate change
parasite
global warming
Global change
Mycorrhiza
Interspecific relation
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Snippet The main drivers of global environmental change (CO₂ enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter...
The main drivers of global environmental change (CO2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter...
The main drivers of global environmental change (CO 2 enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter...
The main drivers of global environmental change (CO sub(2) enrichment, nitrogen deposition, climate, biotic invasions and land use) cause extinctions and alter...
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SubjectTerms Animal and plant ecology
Animal, plant and microbial ecology
Animals
Biodiversity
Biological and medical sciences
Carbon dioxide
Climate change
Climatology. Bioclimatology. Climate change
CO
CO2
Comparative studies
competition
Data analysis
disease
Earth, ocean, space
Ecology
Ecosystem
Environmental changes
Exact sciences and technology
External geophysics
Food Chain
food web
Fundamental and applied biological sciences. Psychology
General aspects
global warming
Greenhouse Effect
Health and Pathology
Herbivory
interaction effect
Invasions
Land use
land-use change
Meteorology
mycorrhiza
mycorrhizae
Nitrogen
nitrogen deposition
parasite
parasites
Pathogens
Plant Physiological Phenomena
pollination
Predictions
seed dispersal
Symbiosis - physiology
Terrestrial ecosystems
Title Global change and species interactions in terrestrial ecosystems
URI https://api.istex.fr/ark:/67375/WNG-45WP5NH8-Z/fulltext.pdf
https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1461-0248.2008.01250.x
https://www.ncbi.nlm.nih.gov/pubmed/19062363
https://www.proquest.com/docview/203712732
https://www.proquest.com/docview/19413766
https://www.proquest.com/docview/48115528
https://www.proquest.com/docview/69874423
Volume 11
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