IMBIV   05474
INSTITUTO MULTIDISCIPLINARIO DE BIOLOGIA VEGETAL
Unidad Ejecutora - UE
artículos
Título:
Towards an assessment of multiple ecosystem processes
Autor/es:
DE BELLO, F.; LAVOREL, S.; DÍAZ, S.; HARRINGTON, R.; CORNELISSEN, J.H.C.; BARDGETT,R.D.; BERG, M. P.; CIPRIOTTI, P.; FELDS, C.K.; HERING, D.; DA SILVA, P.M.; POTTS, S.G.; SANDING, L.; SOUSA, J.P.; STORKEY, J.; WARDLE DA; HARRISON, P.
Revista:
BIODIVERSITY AND CONSERVATION
Editorial:
SPRINGER
Referencias:
Año: 2010 vol. 19 p. 2873 - 2893
ISSN:
0960-3115
Resumen:
Abstract Managing ecosystems to ensure the provision of multiple ecosystem services is
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
Managing ecosystems to ensure the provision of multiple ecosystem services is
a key challenge for applied ecology. Functional traits are receiving increasing attention as
the main ecological attributes by which different organisms and biological communities
influence ecosystem services through their effects on underlying ecosystem processes.
Here we synthesize concepts and empirical evidence on linkages between functional traits
and ecosystem services across different trophic levels. Most of the 247 studies reviewed
considered plants and soil invertebrates, but quantitative traitservice associations have
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.
been documented for a range of organisms and ecosystems, illustrating the wide applicability
of the trait approach. Within each trophic level, specific processes are affected by a
combination of traits while particular key traits are simultaneously involved in the control
of multiple processes. These multiple associations between traits and ecosystem processes
can help to identify predictable traitservice clusters that depend on several trophic levels,
such as clusters of traits of plants and soil organisms that underlie nutrient cycling, herbivory,
and fodder and fibre production. We propose that the assessment of traitservice
clusters will represent a crucial step in ecosystem service monitoring and in balancing the
delivery of multiple, and sometimes conflicting, services in ecosystem management.